S25FS512SAGNFB010 [INFINEON]
Quad SPI Flash;型号: | S25FS512SAGNFB010 |
厂家: | Infineon |
描述: | Quad SPI Flash |
文件: | 总160页 (文件大小:3304K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
S25FS512S
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Features
• Serial peripheral interface (SPI) with multi-I/O
- SPI clock polarity and phase modes 0 and 3
- Double data rate (DDR) option
- Extended addressing: 24- or 32-bit address options
- Serial command subset and footprint compatible with S25FL-A, S25FL-K, S25FL-P, and S25FL-S SPI families
- Multi I/O command subset and footprint compatible with S25FL-P, and S25FL-S SPI families
• Read
- Commands: Normal, Fast, Dual I/O, Quad I/O, DDR Quad I/O
- Modes: Burst wrap, continuous (XIP), QPI
- Serial flash discoverable parameters (SFDP) and common flash interface (CFI) for configuration information
• Program
- 256 or 512 bytes page programming buffer
- Program suspend and resume
- Automatic error checking and correction (ECC) – Internal hardware ECC with single bit error correction
• Erase
- Hybrid sector option
• Physical set of eight 4-KB sectors and one 224-KB sector at the top or bottom of address space with all
remaining sectors of 256-KB
- Uniform sector option
• Uniform 256-KB blocks
- Erase suspend and resume
- Erase status evaluation
• Cycling endurance
- 100,000 program-erase cycles, minimum
• Data retention
- 20 year data retention, minimum
• Security features
- One time program (OTP) array of 1024 bytes
- Block protection:
• Status Register bits to control protection against program or erase of a contiguous range of sectors.
• Hardware and software control options
- Advanced sector protection (ASP)
• Individual sector protection controlled by boot code or password
• Option for password control of read access
• Technology
- 65-nm MIRRORBIT™ technology with Eclipse architecture
• Supply voltage
- 1.7 V to 2.0 V
Datasheet
www.infineon.com
Please read the Important Notice and Warnings at the end of this document
page 1 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Logic block diagram
• Temperature range / grade
- Industrial (-40°C to +85°C)
- Industrial plus (-40°C to +105°C)
- Automotive, AEC-Q100 grade 3 (-40°C to +85°C)
- Automotive, AEC-Q100 grade 2 (-40°C to +105°C)
- Automotive, AEC-Q100 grade 1 (-40°C to +125°C)
• Packages (all Pb-free)
- 16-lead SOIC 300 mil (SO3016)
- WSON 6 8 mm (WNH008)
- BGA-24 6 8 mm
• 5 5 ball (FAB024) footprint
- Known good die and known tested die
Logic block diagram
CS#
SCK
SRAM
MIRRORBIT
Array
SI/IO0
Y Decoders
Data Latch
I/O
SO/IO1
Control
Logic
WP#/IO2
RESET#/IO3
Data Path
Datasheet
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SPI Multi-I/O, 1.8 V
Performance summary
Performance summary
Maximum read rates
Command
Clock rate (MHz)
MBps
6.25
16.5
33
Read
50
133
133
133
80
Fast Read
Dual Read
Quad Read
66
DDR Quad I/O Read
80
Typical program and erase rates
Operation
KBps
711
1078
17
Page programming (256-bytes page buffer)
Page programming (512-bytes page buffer)
4-KB Physical sector erase (Hybrid sector option)
256-KB Sector erase (Uniform logical sector option)
275
Typical current consumption, 40°C to +85°C
Operation
Serial Read 50 MHz
Serial Read 133 MHz
Quad Read 133 MHz
Quad DDR Read 80 MHz
Program
Current (mA)
10
20
60
70
60
Erase
60
Standby
0.07
0.006
Deep power down
Datasheet
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SPI Multi-I/O, 1.8 V
Table of contents
Table of contents
Features ...........................................................................................................................................1
Logic block diagram ..........................................................................................................................2
Performance summary ......................................................................................................................3
Table of contents...............................................................................................................................4
1 Overview .......................................................................................................................................9
1.1 General description ................................................................................................................................................9
1.2 Migration notes .....................................................................................................................................................10
1.2.1 Features comparison.........................................................................................................................................10
1.2.2 Known differences from prior generations ......................................................................................................11
2 SPI with multiple input / output (SPI-MIO) ......................................................................................13
3 Pinout and signal description.........................................................................................................14
3.1 SOIC 16-lead package...........................................................................................................................................14
3.2 8-connector package ............................................................................................................................................14
3.3 BGA connection diagram......................................................................................................................................14
3.4 Multiple Input / Output (MIO)...............................................................................................................................15
3.5 Serial Clock (SCK)..................................................................................................................................................15
3.6 Chip Select (CS#)...................................................................................................................................................16
3.7 Serial Input (SI) / IO0.............................................................................................................................................16
3.8 Serial Output (SO) / IO1 ........................................................................................................................................16
3.9 Write Protect (WP#) / IO2......................................................................................................................................16
3.10 IO3 / RESET#........................................................................................................................................................17
3.11 Voltage Supply (VCC) ...........................................................................................................................................17
3.12 Supply and Signal Ground (VSS) .........................................................................................................................17
3.13 Not Connected (NC) ............................................................................................................................................17
3.14 Reserved for Future Use (RFU) ...........................................................................................................................17
3.15 Do Not Use (DNU)................................................................................................................................................17
3.16 Block diagrams ...................................................................................................................................................18
4 Signal protocols............................................................................................................................19
4.1 SPI clock modes ....................................................................................................................................................19
4.1.1 Single data rate (SDR)........................................................................................................................................19
4.1.2 Double data rate (DDR)......................................................................................................................................19
4.2 Command protocol...............................................................................................................................................20
4.2.1 Command sequence examples .........................................................................................................................21
4.3 Interface states .....................................................................................................................................................24
4.3.1 Power-off............................................................................................................................................................25
4.3.2 Low power hardware data protection ..............................................................................................................25
4.3.3 Power-on (Cold) reset........................................................................................................................................25
4.3.4 Hardware (Warm) reset .....................................................................................................................................25
4.3.5 Interface standby...............................................................................................................................................25
4.3.6 Instruction cycle (Legacy SPI mode).................................................................................................................25
4.3.7 Instruction cycle (QPI mode).............................................................................................................................26
4.3.8 Single input cycle — Host to Memory transfer .................................................................................................26
4.3.9 Single latency (Dummy) cycle ...........................................................................................................................26
4.3.10 Single output cycle — Memory to Host transfer.............................................................................................26
4.3.11 Dual input cycle — Host to Memory transfer ..................................................................................................26
4.3.12 Dual latency (Dummy) cycle............................................................................................................................26
4.3.13 Dual output cycle — Memory to Host transfer................................................................................................27
4.3.14 Quad input cycle — Host to Memory transfer.................................................................................................27
4.3.15 Quad latency (Dummy) cycle ..........................................................................................................................27
4.3.16 Quad output cycle — Memory to Host transfer ..............................................................................................27
4.3.17 DDR Quad input cycle — Host to Memory transfer.........................................................................................27
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Table of contents
4.3.18 DDR latency cycle.............................................................................................................................................27
4.3.19 DDR Quad output cycle — Memory to Host transfer ......................................................................................28
4.4 Configuration Register effects on the interface ..................................................................................................28
4.5 Data protection.....................................................................................................................................................28
4.5.1 Power-up............................................................................................................................................................28
4.5.2 Low power..........................................................................................................................................................28
4.5.3 Clock pulse count...............................................................................................................................................28
4.5.4 DPD .....................................................................................................................................................................28
5 Electrical specifications.................................................................................................................29
5.1 Absolute maximum ratings ..................................................................................................................................29
5.2 Thermal resistance ...............................................................................................................................................29
5.3 Latchup characteristics ........................................................................................................................................29
5.4 Operating ranges ..................................................................................................................................................30
5.4.1 Power supply voltages.......................................................................................................................................30
5.4.2 Temperature ranges ..........................................................................................................................................30
5.4.3 Input signal overshoot.......................................................................................................................................30
5.5 Power-up and power-down..................................................................................................................................31
5.6 DC characteristics .................................................................................................................................................33
5.6.1 Active power and standby power modes .........................................................................................................36
5.6.2 Deep power down mode (DPD).........................................................................................................................36
6 Timing specifications ....................................................................................................................37
6.1 Key to switching waveforms.................................................................................................................................37
6.2 AC test conditions .................................................................................................................................................37
6.2.1 Capacitance characteristics ..............................................................................................................................38
6.3 Reset ......................................................................................................................................................................39
6.3.1 Power on (Cold) reset ........................................................................................................................................39
6.3.2 IO3 / RESET# input initiated hardware (Warm) reset.......................................................................................40
6.4 SDR AC characteristics .........................................................................................................................................42
6.4.1 Clock timing .......................................................................................................................................................43
6.4.2 Input / output timing .........................................................................................................................................43
6.5 DDR AC characteristics .........................................................................................................................................45
6.5.1 DDR input timing................................................................................................................................................46
6.5.2 DDR output timing .............................................................................................................................................46
6.5.3 DDR data valid timing using DLP.......................................................................................................................46
7 Address space maps ......................................................................................................................48
7.1 Overview................................................................................................................................................................48
7.1.1 Extended address ..............................................................................................................................................48
7.1.2 Multiple address spaces ....................................................................................................................................48
7.2 Flash memory array ..............................................................................................................................................48
7.3 ID-CFI address space.............................................................................................................................................50
7.4 JEDEC JESD216 serial flash discoverable parameters (SFDP) space .................................................................50
7.4.1 OTP address space.............................................................................................................................................50
7.5 Registers................................................................................................................................................................52
7.5.1 Status Register 1 ................................................................................................................................................53
7.5.2 Status Register 2 Volatile (SR2V) .......................................................................................................................55
7.5.3 Configuration Register 1....................................................................................................................................56
7.5.4 Configuration Register 2....................................................................................................................................59
7.5.5 Configuration Register 3....................................................................................................................................63
7.5.6 Configuration Register 4....................................................................................................................................65
7.5.7 ECC Status Register (ECCSR) .............................................................................................................................66
7.5.8 ASP Register (ASPR) ...........................................................................................................................................67
7.5.9 Password Register (PASS)..................................................................................................................................68
7.5.10 PPB Lock Register (PPBL) ................................................................................................................................68
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SPI Multi-I/O, 1.8 V
Table of contents
7.5.11 PPB Access Register (PPBAR) ..........................................................................................................................68
7.5.12 DYB Access Register (DYBAR)...........................................................................................................................69
7.5.13 SPI DDR Data Learning Registers ....................................................................................................................69
8 Data protection ............................................................................................................................70
8.1 Secure silicon region (OTP) ..................................................................................................................................70
8.1.1 Reading OTP memory space .............................................................................................................................70
8.1.2 Programming OTP memory space....................................................................................................................70
8.1.3 Infineon programmed random number ...........................................................................................................70
8.1.4 Lock bytes ..........................................................................................................................................................70
8.1.5 Write Enable command .....................................................................................................................................71
8.2 Block protection ...................................................................................................................................................71
8.2.1 Freeze bit............................................................................................................................................................72
8.2.2 Write Protect signal............................................................................................................................................72
8.2.3 Advanced sector protection ..............................................................................................................................72
8.2.4 ASP register ........................................................................................................................................................74
8.2.5 Persistent Protection bits..................................................................................................................................75
8.2.6 Dynamic Protection bits ....................................................................................................................................75
8.2.7 PPB Lock Bit (PPBL[0]).......................................................................................................................................75
8.2.8 Sector protection states summary ...................................................................................................................75
8.2.9 Persistent protection mode ..............................................................................................................................76
8.2.10 Password protection mode .............................................................................................................................76
8.3 Recommended protection process .....................................................................................................................77
9 Commands ...................................................................................................................................78
9.1 Command set summary .......................................................................................................................................79
9.1.1 Extended addressing .........................................................................................................................................79
9.1.2 Command summary by function ......................................................................................................................81
9.1.3 Read device identification.................................................................................................................................83
9.1.4 Register read or write ........................................................................................................................................83
9.1.5 Read flash array .................................................................................................................................................84
9.1.6 Program flash array ...........................................................................................................................................84
9.1.7 Erase flash array.................................................................................................................................................84
9.1.8 OTP, block protection, and advanced sector protection.................................................................................84
9.1.9 Reset ...................................................................................................................................................................84
9.1.10 DPD ...................................................................................................................................................................84
9.1.11 Reserved...........................................................................................................................................................85
9.2 Identification commands .....................................................................................................................................85
9.2.1 Read Identification (RDID 9Fh)..........................................................................................................................85
9.2.2 Read Quad Identification (RDQID AFh) .............................................................................................................86
9.2.3 Read serial flash discoverable parameters (RSFDP 5Ah) .................................................................................87
9.3 Register access commands ..................................................................................................................................88
9.3.1 Read Status Register 1 (RDSR1 05h)..................................................................................................................88
9.3.2 Read Status Register 2 (RDSR2 07h)..................................................................................................................88
9.3.3 Read Configuration Register (RDCR 35h)..........................................................................................................89
9.3.4 Write Registers (WRR 01h) .................................................................................................................................89
9.3.5 Write Enable (WREN 06h)...................................................................................................................................91
9.3.6 Write Disable (WRDI 04h) ...................................................................................................................................92
9.3.7 Clear Status Register (CLSR 30h or 82h) ...........................................................................................................93
9.3.8 ECC Status Register Read (ECCRD 19h or 4EECRD 18h) ...................................................................................94
9.3.9 Program NVDLR (PNVDLR 43h)..........................................................................................................................95
9.3.10 Write VDLR (WVDLR 4Ah)..................................................................................................................................95
9.3.11 Data Learning Pattern Read (DLPRD 41h).......................................................................................................96
9.3.12 Enter 4-Byte Address Mode (4BAM B7h) .........................................................................................................96
9.3.13 Read Any Register (RDAR 65h).........................................................................................................................96
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SPI Multi-I/O, 1.8 V
Table of contents
9.3.14 Write Any Register (WRAR 71h)........................................................................................................................98
9.3.15 Set Burst Length (SBL C0h)..............................................................................................................................99
9.4 Read memory array commands.........................................................................................................................100
9.4.1 Read (Read 03h or 4READ 13h)........................................................................................................................101
9.4.2 Fast Read (FAST_READ 0Bh or 4FAST_READ 0Ch)..........................................................................................102
9.4.3 Dual I/O Read (DIOR BBh or 4DIOR BCh).........................................................................................................102
9.4.4 Quad I/O Read (QIOR EBh or 4QIOR ECh) .......................................................................................................104
9.4.5 DDR Quad I/O Read (EDh, EEh)........................................................................................................................106
9.5 Program Flash array commands........................................................................................................................108
9.5.1 Program granularity ........................................................................................................................................108
9.5.2 Page Program (PP 02h or 4PP 12h) .................................................................................................................109
9.6 Erase Flash Array commands .............................................................................................................................110
9.6.1 Parameter 4 KB-Sector erase (P4E 20h or 4P4E 21h) .....................................................................................110
9.6.2 Sector Erase (SE D8h or 4SE DCh) ...................................................................................................................111
9.6.3 Bulk Erase (BE 60h or C7h) ..............................................................................................................................113
9.6.4 Evaluate Erase Status (EES D0h) .....................................................................................................................114
9.6.5 Erase or Program Suspend (EPS 85h, 75h, B0h).............................................................................................115
9.6.6 Erase or Program Resume (EPR 7Ah, 8Ah, 30h)..............................................................................................118
9.7 One time program array commands..................................................................................................................119
9.7.1 OTP Program (OTPP 42h) ................................................................................................................................119
9.7.2 OTP Read (OTPR 4Bh)......................................................................................................................................119
9.8 Advanced Sector Protection commands...........................................................................................................120
9.8.1 ASP Read (ASPRD 2Bh) ....................................................................................................................................120
9.8.2 ASP Program (ASPP 2Fh) .................................................................................................................................120
9.8.3 DYB Read (DYBRD FAh or 4DYBRD E0h)...........................................................................................................121
9.8.4 DYB Write (DYBWR FBh or 4DYBWR E1h).........................................................................................................122
9.8.5 PPB Read (PPBRD FCh or 4PPBRD E2h) ..........................................................................................................123
9.8.6 PPB Program (PPBP FDh or 4PPBP E3h).........................................................................................................123
9.8.7 PPB Erase (PPBE E4h) ......................................................................................................................................124
9.8.8 PPB Lock Bit Read (PLBRD A7h) ......................................................................................................................124
9.8.9 PPB Lock Bit Write (PLBWR A6h) .....................................................................................................................125
9.8.10 Password Read (PASSRD E7h).......................................................................................................................125
9.8.11 Password Program (PASSP E8h) ...................................................................................................................126
9.8.12 Password Unlock (PASSU E9h)......................................................................................................................126
9.9 Reset commands ................................................................................................................................................127
9.9.1 Software Reset Enable (RSTEN 66h) ...............................................................................................................128
9.9.2 Software Reset (RST 99h) ................................................................................................................................128
9.9.3 Legacy Software Reset (RESET F0h)................................................................................................................128
9.9.4 Mode Bit Reset (MBR FFh)................................................................................................................................128
9.10 DPD commands.................................................................................................................................................129
9.10.1 Enter Deep Power-Down (DPD B9h)..............................................................................................................129
9.10.2 Release from Deep Power-Down (RES ABh) .................................................................................................130
10 Embedded algorithm performance tables ................................................................................... 131
11 Data integrity ........................................................................................................................... 132
11.1 Erase endurance ...............................................................................................................................................132
11.2 Data retention ...................................................................................................................................................132
12 Device identification ................................................................................................................. 133
12.1 Serial flash discoverable parameters (SFDP) address map............................................................................133
12.2 SFDP header table ............................................................................................................................................134
12.3 Device ID and common flash interface (ID-CFI) address map ........................................................................137
12.3.1 Device ID.........................................................................................................................................................137
12.4 JEDEC SFDP Rev B parameter tables ...............................................................................................................144
13 Initial delivery state .................................................................................................................. 153
Datasheet
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SPI Multi-I/O, 1.8 V
Table of contents
14 Package diagrams..................................................................................................................... 154
14.1 Special handling instructions for FBGA packages...........................................................................................156
15 Ordering information ................................................................................................................ 157
15.1 Ordering part number.......................................................................................................................................157
15.2 Valid combinations — standard .......................................................................................................................158
15.3 Valid combinations — automotive grade / AEC-Q100.....................................................................................158
Revision history ............................................................................................................................ 159
Datasheet
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Overview
1
Overview
1.1
General description
The S25FS512S device is a flash non-volatile memory product using:
• MIRRORBIT™ technology - that stores two data bits in each memory array transistor
• Eclipse architecture - that dramatically improves program and erase performance
• 65-nm process lithography
The S25FS512S connects to a host system via a serial peripheral interface (SPI). Traditional SPI single bit serial
input and output (Single I/O or SIO) is supported as well as optional two-bit (Dual I/O or DIO) and four-bit wide
Quad I/O (QIO) or quad peripheral interface (QPI) serial commands. This multiple-width interface is called SPI
Multi-I/O or MIO. In addition, there are double data rate (DDR) read commands for QIO and QPI that transfer
address and read data on both edges of the clock.
The FS-S Eclipse architecture features a Page Programming Buffer that allows up to 512 bytes to be programmed
in one operation, resulting in faster effective programming and erase than prior generation SPI program or erase
algorithms.
Executing code directly from flash memory is often called eXecute-In-Place (XIP). By using S25FS512S devices at
the higher clock rates supported, with Quad or DDR-Quad commands, the instruction read transfer rate can
match or exceed traditional parallel interface, asynchronous, NOR flash memories, while reducing signal count
dramatically.
The S25FS512S products offer high densities coupled with the flexibility and fast performance required by a
variety of mobile or embedded applications. They are an excellent solution for systems with limited space, signal
connections, and power. They are ideal for code shadowing to RAM, executing code directly (XIP), and storing
reprogrammable data.
Datasheet
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Overview
1.2
Migration notes
1.2.1
Features comparison
The S25FS512S is command subset and footprint compatible with prior generation FL-S, FL-K, and FL-P families.
However, the power supply and interface voltages are nominal 1.8V.
Table 1
SPI families comparison
Parameter
FS-S
FL-S
FL-K
FL-P
90-nm
Technology Node
Architecture
Density
65-nm
65-nm
90-nm
™
™
™
MIRRORBIT Eclipse
MIRRORBIT Eclipse
Floating Gate
4 Mb - 128 Mb
x1, x2, x4
MIRRORBIT
128 Mb - 512 Mb
x1, x2, x4
128 Mb - 1 Gb
x1, x2, x4
32 Mb - 256 Mb
x1, x2, x4
Bus Width
2.7 V - 3.6 V / 1.65 V - 3.6
Supply Voltage
1.7 V - 2.0 V
2.7 V - 3.6 V
2.7 V - 3.6 V
V V
IO
Normal Read Speed
(SDR)
6 MB/s (50 MHz)
6 MB/s (50 MHz)
6 MB/s (50 MHz)
5 MB/s (40 MHz)
Fast Read Speed (SDR)
Dual Read Speed (SDR)
Quad Read Speed (SDR)
Quad Read Speed (DDR)
Program Buffer Size
Erase Sector Size
16.5 MB/s (133 MHz)
33 MB/s (133 MHz)
66 MB/s (133 MHz)
80 MB/s (80 MHz)
256B / 512B
17 MB/s (133 MHz)
26 MB/s (104 MHz)
52 MB/s (104 MHz)
80 MB/s (80 MHz)
256B / 512B
13 MB/s (104 MHz)
26 MB/s (104 MHz)
52 MB/s (104 MHz)
—
13 MB/s (104 MHz)
20 MB/s (80 MHz)
40 MB/s (80 MHz)
—
256B
256B
64 KB / 256 KB
64 KB / 256 KB
4 KB / 32 KB / 64 KB
4 KB
64 KB / 256 KB
4 KB
Parameter Sector Size
4 KB (option)
4 KB (option)
136 KB/s (4 KB)
437 KB/s (64 KB)
Sector Erase Rate (typ.)
500 KB/s
500 KB/s
130 KB/s
Page Programming Rate
(typ.)
0.71 MB/s (256B)
1.08 MB/s (512B)
1.2 MB/s (256B)
1.5 MB/s (512B)
365 KB/s
170 KB/s
506B
OTP
1024B
1024B
Yes
768B (3x256B)
Advanced Sector
Protection
Yes
No
Auto Boot Mode
No
No
Erase Suspend/Resume
Program
Yes
Yes
Suspend/Resume
Deep Power-Down Mode
No
Yes
-40°C to +85°C / +105°C
/ +125°C
Operating Temperature -40°C to +85°C / +105°C
-40°C to +85°C
-40°C to +85°C / +105°C
Notes
1. 256B program page option only for 128 Mb and 256 Mb density FL-S devices.
2. FL-P column indicates FL129P MIO SPI device (for 128 Mb density), FL128P does not support MIO, OTP, or 4 KB sectors.
3. 64-KB sector erase option only for 128 Mb / 256 Mb density FL-P, FL-S, and FS-S devices.
4. FL-K family devices can erase 4-KB sectors in groups of 32 KB or 64 KB.
5. Only 128 Mb/256 Mb density FL-S devices have 4-KB parameter sector option.
6. 512 Mb / 1 Gb FL-S devices support 256 KB-sector only.
7. The FS512 device does not support 64 KB-sectors.
8. Refer to individual product datasheets for further details.
Datasheet
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Overview
1.2.2
Known differences from prior generations
Error reporting
1.2.2.1
FL-K and FL-P memories either do not have error status bits or do not set them if program or erase is attempted
on a protected sector. The FS-S and FL-S families do have error reporting status bits for program and erase opera-
tions. These can be set when there is an internal failure to program or erase, or when there is an attempt to
program or erase a protected sector. In these cases the program or erase operation did not complete as
requested by the command. The P_ERR or E_ERR bits and the WIP bit will be set to and remain 1 in SR1V. The
clear status register command must be sent to clear the errors and return the device to standby state.
1.2.2.2
Secure silicon region (OTP)
The FS-S size and format (address map) of the One Time Program area is different from FL-K and FL-P genera-
tions. The method for protecting each portion of the OTP area is different. For additional details, see “Secure
silicon region (OTP)” on page 70.
1.2.2.3
Configuration Register Freeze Bit
The Configuration Register 1 Freeze Bit CR1V[0], locks the state of the Block Protection bits (SR1NV[4:2] and
SR1V[4:2]), TBPARM_O bit (CR1NV[2]), and TBPROT_O bit (CR1NV[5]), as in prior generations. In the FS-S and FL-S
families the Freeze Bit also locks the state of the Configuration Register 1 BPNV_O bit (CR1NV[3]), and the Secure
Silicon Region (OTP) area.
1.2.2.4
Sector Erase commands
The command for erasing a 4-KB sector is supported only for use on 4-KB parameter sectors at the top or bottom
of the FS-S device address space.
The command for erasing an 8-KB area (two 4-KB sectors) is not supported.
The command for erasing a 32-KB area (eight 4-KB sectors) is not supported.
The 64 KB erase command is not supported for the 512 Mb density FS-S device.
1.2.2.5
Deep power-down
A Deep Power-Down (DPD) function is supported in the FS-S family devices.
1.2.2.6
WRR single register write
In some legacy SPI devices, a Write Registers (WRR) command with only one data byte would update Status
Register 1 and clear some bits in Configuration Register 1, including the Quad mode bit. This could result in
unintended exit from Quad mode. The S25FS512S only updates Status Register 1 when a single data byte is
provided. The Configuration Register 1 is not modified in this case.
1.2.2.7
Hold input not supported
In some legacy SPI devices, the IO3 input has an alternate function as a HOLD# input used to pause information
transfer without stopping the serial clock. This function is not supported in the FS-S family.
1.2.2.8
Separate reset input not supported
In some legacy SPI devices, a separate hardware RESET# input is supported in packages having more than eight
connections. The FS-S family does not support a separate RESET# input. The FS-S family provides an alternate
function for the IO3 input as a RESET# input. When the CS# signal is HIGH and the IO3 / RESET feature is enabled,
the IO3 / RESET# input is used to initiate a hardware reset when the input goes LOW.
Datasheet
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Overview
1.2.2.9
Other legacy commands not supported
• Autoboot related commands
• Bank Address related commands
• Dual Output Read
• Quad Output Read
• Quad Page Program (QPP) — replaced by page program in QPI mode
• DDR Fast Read
• DDR Dual I/O Read
1.2.2.10
New features
The FS-S family introduces new features to SPI category memories:
• Single 1.8 V power supply for core and I/O voltage.
• Configurable initial read latency (number of dummy cycles) for faster initial access time or higher clock rate
read commands.
• QPI (QPI, 4-4-4) read mode in which all transfers are 4 bits wide, including instructions.
• JEDEC JESD216 standard, serial flash discoverable parameters (SFDP) that provide device feature and config-
uration information.
• Evaluate Erase Status command to determine if the last erase operation on a sector completed successfully.
This command can be used to detect incomplete erase due to power loss or other causes. This command can
be helpful to Flash File System software in file system recovery after a power loss.
• Advanced sector protection (ASP) permanent protection. A bit is added to the ASP register to provide the option
to make protection of the Persistent Protection Bits (PPB) permanent. Also, when one of the two ASP protection
modes is selected, all OTP configuration bits in all registers are protected from further programming so that all
OTP configuration settings are made permanent. The OTP address space is not protected by the selection of an
ASP protection mode. The Freeze bit (CR1V[0]) may be used to protect the OTP Address Space.
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SPI Multi-I/O, 1.8 V
SPI with multiple input / output (SPI-MIO)
2
SPI with multiple input / output (SPI-MIO)
Many memory devices connect to their host system with separate parallel control, address, and data signals that
require a large number of signal connections and larger package size. The large number of connections increase
power consumption due to so many signals switching and the larger package increases cost.
The S25FS512S reduces the number of signals for connection to the host system by serially transferring all
control, address, and data information over 4 to 6 signals. This reduces the cost of the memory package, reduces
signal switching power, and either reduces the host connection count or frees host connectors for use in
providing other features.
The S25FS512S uses the industry standard single bit SPI and also supports optional extension commands for
two-bit (Dual) and four-bit (Quad) wide serial transfers. This multiple width interface is called SPI multi-I/O or
SPI-MIO.
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Pinout and signal description
3
Pinout and signal description
3.1
SOIC 16-lead package
16
15
14
SCK
1
2
3
IO3/RESET#
VCC
SI/IO0
RFU
RFU
NC
13
12
4
5
DNU
DNU
NC
RFU
6
11
DNU
VSS
CS#
7
8
10
9
SO/IO1
WP#/IO2
Figure 1
16-lead SOIC package, Top view[9]
3.2
8-connector package
CS#
VCC
8
7
6
1
SO/IO1
IO3/RESET#
2
WSON
WP#/IO2
3
SCK
VSS
SI/IO0
4
5
Figure 2
8-connector package (WSON 6 x 8), top view[9, 10]
3.3
BGA connection diagram
1
2
3
4
5
A
B
C
D
E
NC
NC
VSS
RFU
VCC
NC
NC
NC
NC
NC
DNU
DNU
DNU
NC
SCK
CS#
RFU WP#/IO2
SO/IO1 SI/IO0
IO3/
RESET#
NC
NC
RFU
Figure 3
Notes
24-ball BGA, 5 x 5 ball footprint (FAB024), top view[9, 11]
9. The RESET# input has an internal pull-up and may be left unconnected in the system if Quad Mode and hardware reset
are not in use.
10. There is an exposed central pad on the underside of the WSON package. This should not be connected to any voltage
or signal line on the PCB. Connecting the central pad to GND (VSS) is possible, provided PCB routing ensures 0mV
difference between voltage at the WSON GND (VSS) lead and the central exposed pad.
11. Signal connections are in the same relative positions as FAC024 BGA, allowing a single PCB footprint to use either
package.
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Pinout and signal description
Table 2
Signal description
Type
Signal name
SCK
Description
Input
Input
I/O
Serial Clock.
Chip Select.
CS#
SI / IO0
SO / IO1
Serial Input for single bit data commands or IO0 for Dual or Quad commands.
Serial Output for single bit data commands. IO1 for Dual or Quad commands.
I/O
Write Protect when not in Quad mode (CR1V[1] = 0 and SR1NV[7] = 1) (see Table 20).
IO2 when in Quad mode (CR1V[1] = 1).
The signal has an internal pull-up resistor and may be left unconnected in the host system
if not used for Quad commands or write protection. If write protection is enabled by
SR1NV[7] = 1 and CR1V[1] = 0, the host system is required to drive WP# HIGH or LOW during
a WRR or WRAR command.
WP# / IO2
I/O
I/O
IO3 in Quad-I/O mode, when Configuration Register 1 QUAD bit, CR1V[1] = 1, and CS# is
LOW.
RESET# when enabled by CR2V[5] = 1 and not in Quad-I/O mode, CR1V[1] = 0, or when
enabled in quad mode, CR1V[1] = 1 and CS# is HIGH.
IO3 / RESET#
The signal has an internal pull-up resistor and may be left unconnected in the host system
if not used for Quad commands or RESET#.
V
V
Supply
Supply
Power Supply.
Ground.
CC
SS
Not Connected. No device internal signal is connected to the package connector nor is
there any future plan to use the connector for a signal. The connection may safely be used
for routing space for a signal on a Printed Circuit Board (PCB). However, any signal
NC
Unused
connected to an NC must not have voltage levels higher than V
.
CC
Reserved for Future Use. No device internal signal is currently connected to the package
connector but there is potential future use of the connector for a signal. It is recommended
to not use RFU connectors for PCB routing channels so that the PCB may take advantage
of future enhanced features in compatible footprint devices.
RFU
Reserved
Do Not Use. A device internal signal may be connected to the package connector. The
connection may be used by Infineon for test or other purposes and is not intended for
connection to any host system signal. Any DNU signal related function will be inactive
DNU
Reserved
when the signal is at V . The signal has an internal pull-down resistor and may be left
IL
unconnected in the host system or may be tied to V . Do not use these connections for
SS
PCB signal routing channels. Do not connect any host system signal to this connection.
3.4
Multiple Input / Output (MIO)
Traditional SPI single bit wide commands (Single or SIO) send information from the host to the memory only on
the Serial Input (SI) signal. Data may be sent back to the host serially on the Serial Output (SO) signal.
Dual or Quad Input / Output (I/O) commands send instructions to the memory only on the SI / IO0 signal. Address
or data is sent from the host to the memory as bit pairs on IO0 and IO1 or four-bit (nibble) groups on IO0, IO1, IO2,
and IO3. Data is returned to the host similarly as bit pairs on IO0 and IO1 or four-bit (nibble) groups on IO0, IO1,
IO2, and IO3.
QPI mode transfers all instructions, address, and data from the host to the memory as four-bit (nibble) groups on
IO0, IO1, IO2, and IO3. Data is returned to the host similarly as four-bit (nibble) groups on IO0, IO1, IO2, and IO3.
3.5
Serial Clock (SCK)
This input signal provides the synchronization reference for the SPI interface. Instructions, addresses, or data
input are latched on the rising edge of the SCK signal. Data output changes after the falling edge of SCK, in SDR
commands, and after every edge in DDR commands.
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SPI Multi-I/O, 1.8 V
Pinout and signal description
3.6
Chip Select (CS#)
The chip select signal indicates when a command is transferring information to or from the device and the other
signals are relevant for the memory device.
When the CS# signal is at the logic HIGH state, the device is not selected and all input signals are ignored and all
output signals are high impedance. The device will be in the Standby Power mode, unless an internal embedded
operation is in progress. An embedded operation is indicated by the Status Register 1 Write-In-Progress bit
(SR1V[1]) set to ‘1’, until the operation is completed. Some example embedded operations are: Program, Erase,
or Write Registers (WRR) operations.
Driving the CS# input to the logic LOW state enables the device, placing it in the Active Power mode. After
Power-up, a falling edge on CS# is required prior to the start of any command.
3.7
Serial Input (SI) / IO0
This input signal is used to transfer data serially into the device. It receives instructions, addresses, and data to
be programmed. Values are latched on the rising edge of serial SCK clock signal.
SI becomes IO0 — an input and output during Dual and Quad commands for receiving instructions, addresses,
and data to be programmed (values latched on rising edge of serial SCK clock signal) as well as shifting out data
(on the falling edge of SCK, in SDR commands, and on every edge of SCK, in DDR commands).
3.8
Serial Output (SO) / IO1
This output signal is used to transfer data serially out of the device. Data is shifted out on the falling edge of the
serial SCK clock signal.
SO becomes IO1 — an input and output during Dual and Quad commands for receiving addresses, and data to be
programmed (values latched on rising edge of serial SCK clock signal) as well as shifting out data (on the falling
edge of SCK, in SDR commands, and on every edge of SCK, in DDR commands).
3.9
Write Protect (WP#) / IO2
When WP# is driven Low (VIL), during a WRR or WRAR command and while the Status Register Write Disable
(SRWD_NV) bit of Status Register 1 (SR1NV[7]) is set to ‘1’, it is not possible to write to Status Register 1 or Config-
uration Register 1 related registers. In this situation, a WRR command is ignored, a WRAR command selecting
SR1NV, SR1V, CR1NV, or CR1V is ignored, and no error is set.
This prevents any alteration of the Block Protection settings. As a consequence, all the data bytes in the memory
area that are protected by the Block Protection feature are also hardware protected against data modification if
WP# is Low during a WRR or WRAR command with SRWD_NV set to ‘1’.
The WP# function is not available when the Quad mode is enabled (CR1V[1] = 1). The WP# function is replaced by
IO2 for input and output during Quad mode for receiving addresses, and data to be programmed (values are
latched on rising edge of the SCK signal) as well as shifting out data (on the falling edge of SCK, in SDR commands,
and on every edge of SCK, in DDR commands).
WP# has an internal pull-up resistance; when unconnected, WP# is at VIH and may be left unconnected in the host
system if not used for Quad mode or protection.
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SPI Multi-I/O, 1.8 V
Pinout and signal description
3.10
IO3 / RESET#
IO3 is used for input and output during Quad mode (CR1V[1] = 1) for receiving addresses, and data to be
programmed (values are latched on rising edge of the SCK signal) as well as shifting out data (on the falling edge
of SCK, in SDR commands, and on every edge of SCK, in DDR commands).
The IO3 / RESET# signal may also be used to initiate the hardware reset function when the reset feature is enabled
by writing Configuration Register 2 non-volatile bit 5 (CR2V[5] = 1). The input is only treated as RESET# when the
device is not in Quad-I/O mode, CR1V[1] = 0, or when CS# is HIGH. When Quad I/O mode is in use, CR1V[1] = 1, and
the device is selected with CS# LOW, the IO3 / RESET# is used only as IO3 for information transfer. When CS# is
HIGH, the IO3 / RESET# is not in use for information transfer and is used as the RESET# input. By conditioning the
reset operation on CS# HIGH during Quad mode, the reset function remains available during Quad mode.
When the system enters a reset condition, the CS# signal must be driven HIGH as part of the reset process and
the IO3 / RESET# signal is driven LOW. When CS# goes HIGH, the IO3 / RESET# input transitions from being IO3 to
being the RESET# input. The reset condition is then detected when CS# remains HIGH and the IO3 / RESET# signal
remains LOW for tRP. If a reset is not intended, the system is required to actively drive IO3 / Reset# to HIGH along
with CS# being driven HIGH at the end of a transfer of data to the memory. Following transfers of data to the host
system, the memory will drive IO3 HIGH during tCS. This will ensure that IO3 / Reset is not left floating or being
pulled slowly to HIGH by the internal or an external passive pull-up. Thus, an unintended reset is not triggered by
the IO3 / RESET# not being recognized as HIGH before the end of tRP
.
The IO3 / RESET# signal is unused when the reset feature is disabled (CR2V[5] = 0).
The IO3 / RESET# signal has an internal pull-up resistor and may be left unconnected in the host system if not
used for Quad mode or the reset function. The internal pull-up will hold IO3 / Reset HIGH after the host system
has actively driven the signal high and then stops driving the signal.
Note that IO3 / Reset# cannot be shared by more than one SPI-MIO memory if any of them are operating in Quad
I/O mode as IO3 being driven to or from one selected memory may look like a reset signal to a second
non-selected memory sharing the same IO3 / RESET# signal.
3.11
Voltage Supply (VCC)
VCC is the voltage source for all device internal logic. It is the single voltage used for all device internal functions
including read, program, and erase.
3.12
Supply and Signal Ground (VSS)
VSS is the common voltage drain and ground reference for the device core, input signal receivers, and output
drivers.
3.13
Not Connected (NC)
No device internal signal is connected to the package connector nor is there any future plan to use the connector
for a signal. The connection may safely be used for routing space for a signal on a Printed Circuit Board (PCB).
3.14
Reserved for Future Use (RFU)
No device internal signal is currently connected to the package connector but there is potential future use of the
connector. It is recommended to not use RFU connectors for PCB routing channels so that the PCB may take
advantage of future enhanced features in compatible footprint devices.
3.15
Do Not Use (DNU)
A device internal signal may be connected to the package connector. The connection may be used by Infineon
for test or other purposes and is not intended for connection to any host system signal. Any DNU signal related
function will be inactive when the signal is at VIL. The signal has an internal pull-down resistor and may be left
unconnected in the host system or may be tied to VSS. Do not use these connections for PCB signal routing
channels. Do not connect any host system signal to these connections.
Datasheet
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Pinout and signal description
3.16
Block diagrams
RESET#
WP#
RESET#
WP#
SI
SO
SI
SO
SCK
SCK
CS2#
CS2#
CS1#
CS1#
FS-S
Flash
FS-S
Flash
SPI
Bus Master
Figure 4
Bus master and memory devices on the SPI bus — single bit data path
RESET#
RESET#
WP#
WP#
IO1
IO1
IO0
SCK
IO0
SCK
CS2#
CS2#
CS1#
CS1#
FS-S
Flash
FS-S
Flash
SPI
Bus Master
Figure 5
Bus master and memory devices on the SPI bus — dual bit data path
IO3 / RESET#
RESET# / IO3
IO2
IO2
IO1
IO1
IO0
IO0
SCK
SCK
CS1#
CS1#
FS -S
Flash
SPI
Bus Master
Figure 6
Bus master and memory devices on the SPI bus — quad bit data path
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Signal protocols
4
Signal protocols
SPI clock modes
4.1
4.1.1
Single data rate (SDR)
The S25FS512S can be driven by an embedded microcontroller (bus master) in either of the two following
clocking modes.
• Mode 0 with Clock Polarity (CPOL) = 0 and, Clock Phase (CPHA) = 0
• Mode 3 with CPOL = 1 and, CPHA = 1
For these two modes, input data into the device is always latched in on the rising edge of the SCK signal and the
output data is always available from the falling edge of the SCK clock signal.
The difference between the two modes is the clock polarity when the bus master is in standby mode and not
transferring any data.
• SCK will stay at logic LOW state with CPOL = 0, CPHA = 0
• SCK will stay at logic HIGH state with CPOL = 1, CPHA = 1
CPOL=0_CPHA=0_SCK
CPOL=1_CPHA=1_SCK
CS#
SI
MSb
SO
MSb
Figure 7
SPI SDR modes supported
Timing diagrams throughout the remainder of the document are generally shown as both Mode 0 and 3 by
showing SCK as both HIGH and LOW at the fall of CS#. In some cases, a timing diagram may show only Mode 0
with SCK LOW at the fall of CS#. In such a case, Mode 3 timing simply means clock is HIGH at the fall of CS# so no
SCK rising edge set up or hold time to the falling edge of CS# is needed for Mode 3.
SCK cycles are measured (counted) from one falling edge of SCK to the next falling edge of SCK. In Mode 0, the
beginning of the first SCK cycle in a command is measured from the falling edge of CS# to the first falling edge of
SCK because SCK is already low at the beginning of a command.
4.1.2
Double data rate (DDR)
Mode 0 and Mode 3 are also supported for DDR commands. In DDR commands, the instruction bits are always
latched on the rising edge of clock, the same as in SDR commands. However, the address and input data that
follow the instruction are latched on both the rising and falling edges of SCK. The first address bit is latched on
the first rising edge of SCK following the falling edge at the end of the last instruction bit. The first bit of output
data is driven on the falling edge at the end of the last access latency (dummy) cycle.
SCK cycles are measured (counted) in the same way as in SDR commands, from one falling edge of SCK to the
next falling edge of SCK. In Mode 0, the beginning of the first SCK cycle in a command is measured from the falling
edge of CS# to the first falling edge of SCK because SCK is already LOW at the beginning of a command.
CPOL=0_CPHA=0_SCK
CPOL=1_CPHA=1_SCK
CS#
Instruction
Address
Mode
Dummy / DLP
Read Data
Transfer_Phase
SI
Inst. 7
Inst. 0
A31 A30
A0
M7
M6
M0
SO
DLP7
DLP0
D0
D1
Figure 8
SPI DDR modes supported
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Signal protocols
4.2
Command protocol
All communication between the host system and S25FS512S devices is in the form of units called commands.
All commands begin with an 8-bit instruction that selects the type of information transfer or device operation to
be performed. Commands may also have an address, instruction modifier, latency period, data transfer to the
memory, or data transfer from the memory. All instruction, address, and data information is transferred sequen-
tially between the host system and memory device.
Command protocols are also classified by a numerical nomenclature using three numbers to reference the
transfer width of three command phases:
• instruction;
• address and instruction modifier (continuous read mode bits);
• data
Single-bit wide commands start with an instruction and may provide an address or data, all sent only on the SI
signal. Data may be sent back to the host serially on the SO signal. This is referenced as a 1-1-1 command protocol
for single-bit width instruction, single-bit width address and modifier, single-bit data.
Dual or Quad Input / Output (I/O) commands provide an address sent from the host as bit pairs on IO0 and IO1
or, four-bit (nibble) groups on IO0, IO1, IO2, and IO3. Data is returned to the host similarly as bit pairs on IO0 and
IO1 or, four-bit (nibble) groups on IO0, IO1, IO2, and IO3. This is referenced as 1-2-2 for Dual I/O and 1-4-4 for Quad
I/O command protocols.
The S25FS512S also supports a QPI mode in which all information is transferred in 4-bit width, including the
instruction, address, modifier, and data. This is referenced as a 4-4-4 command protocol.
Commands are structured as follows:
• Each command begins with CS# going LOW and ends with CS# returning HIGH. The memory device is selected
by the host driving the Chip Select (CS#) signal LOW throughout a command.
• The serial clock (SCK) marks the transfer of each bit or group of bits between the host and memory.
• Each command begins with an eight bit (byte) instruction. The instruction selects the type of information
transfer or device operation to be performed. The instruction transfers occur on SCK rising edges. However,
some read commands are modified by a prior read command, such that the instruction is implied from the
earlier command. This is called Continuous Read Mode. When the device is in Continuous Read mode, the
instruction bits are not transmitted at the beginning of the command because the instruction is the same as
the read command that initiated the Continuous Read Mode. In Continuous Read mode, the command will begin
with the read address. Thus, Continuous Read Mode removes eight instruction bits from each read command
in a series of same type read commands.
• The instruction may be standalone or may be followed by address bits to select a location within one of several
address spaces in the device. The instruction determines the address space used. The address may be either a
24-bit or a 32-bit, byte boundary, address. The address transfers occur on SCK rising edge, in SDR commands,
or on every SCK edge, in DDR commands.
• In legacy SPI mode, the width of all transfers following the instruction are determined by the instruction sent.
Following transfers may continue to be single bit serial on only the SI or Serial Output (SO) signals, they may be
done in two bit groups per (dual) transfer on the IO0 and IO1 signals, or they may be done in 4-bit groups per
(quad) transfer on the IO0-IO3 signals. Within the dual or quad groups the least significant bit is on IO0. More
significant bits are placed in significance order on each higher numbered IO signal. Single bits or parallel bit
groups are transferred in most to least significant bit order.
• In QPI mode, the width of all transfers is a 4-bit wide (quad) transfer on the IO0-IO3 signals.
• Dual and Quad I/O read instructions send an instruction modifier called Continuous Read mode bits, following
the address, to indicate whether the next command will be of the same type with an implied, rather than an
explicit, instruction. These mode bits initiate or end the continuous read mode. In continuous read mode, the
next command thus does not provide an instruction byte, only a new address and mode bits. This reduces the
time needed to send each command when the same command type is repeated in a sequence of commands.
The mode bit transfers occur on SCK rising edge, in SDR commands, or on every SCK edge, in DDR commands.
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SPI Multi-I/O, 1.8 V
Signal protocols
• The address or mode bits may be followed by write data to be stored in the memory device or by a read latency
period before read data is returned to the host.
• Write data bit transfers occur on SCK rising edge, in SDR commands, or on every SCK edge, in DDR commands.
• SCK continues to toggle during any read access latency period. The latency may be zero to several SCK cycles
(also referred to as dummy cycles). At the end of the read latency cycles, the first read data bits are driven from
the outputs on SCK falling edge at the end of the last read latency cycle. The first read data bits are considered
transferred to the host on the following SCK rising edge. Each following transfer occurs on the next SCK rising
edge, in SDR commands, or on every SCK edge, in DDR commands.
• If the command returns read data to the host, the device continues sending data transfers until the host takes
the CS# signal HIGH. The CS# signal can be driven HIGH after any transfer in the read data sequence. This will
terminate the command.
• At the end of a command that does not return data, the host drives the CS# input HIGH. The CS# signal must go
HIGH after the eighth bit, of a standalone instruction or, of the last write data byte that is transferred. That is,
the CS# signal must be driven HIGH when the number of bits after the CS# signal was driven low is an exact
multiple of eight bits. If the CS# signal does not go high exactly at the eight-bit boundary of the instruction or
write data, the command is rejected and not executed.
• All instruction, address, and mode bits are shifted into the device with the Most Significant Bits (MSb) first. The
data bits are shifted in and out of the device MSb first. All data is transferred in byte units with the lowest address
byte sent first. Following bytes of data are sent in lowest to highest byte address order i.e. the byte address
increments.
• All attempts to read the flash memory array during a program, erase, or a write cycle (embedded operations)
are ignored. The embedded operation will continue to execute without any affect. A very limited set of
commands are accepted during an embedded operation. These are discussed in the individual command
descriptions.
• Depending on the command, the time for execution varies. A command to read status information from an
executing command is available to determine when the command completes execution and whether the
command was successful.
4.2.1
Command sequence examples
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
Phase
Instruction
Figure 9
Standalone Instruction command
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
Phase
Instruction
Input Data
Figure 10
Single Bit Wide Input command
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Signal protocols
CS#
SCK
SI
SO
7
6 5 4 3 2 1 0
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
Phase
Instruction
Data 1
Data 2
Figure 11
Figure 12
Figure 13
Single Bit Wide Output command
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0 31
1
0
7
6
5
4
3
2
1
0
7
6
5
4
3
2 1
0
Phase
Address
Instruction
Data 1
Data 2
Single Bit Wide I/O command without latency
CS#
SCK
SI
SO
7 6 5 4 3 2 1 0 31
1 0
7
6 5 4 3 2 1 0
Dummy Cycles
Phase
Address
Instruction
Data 1
Single Bit Wide I/O command with latency
CS#
SCK
IO0
IO1
7
6
5
4
3
2
1
0 30
31
2
3
0
1
6
7
4
5
2
3
0
1
6
7
4
5
2
3
0
1
6
7
4
5
2
3
0
1
Phase
Instruction
Address
Mode
Dum Data 1
Data 2
Figure 14
Dual I/O command
CS#
SCK
IO0
IO1
7
6
5
4
3
2
1
0 28
29
4
5
6
7
0
1
2
3
4
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
4
0
1
2
3
4
5
6
7
0
1
2
3
5
1
2
3
5
6
7
IO2
30
6
IO3
31
7
Instruction
Mode
Address
Dummy
D1
D2
D3
D4
Phase
Figure 15
Quad I/O command
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CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
28
29
30
31
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
IO2
IO3
Mode
Dummy
D1
D2
D3
D4
Phase
Instruct.
Address
Figure 16
Figure 17
Figure 18
Quad I/O Read command in QPI mode
CS#
SCK
IO0
IO1
7
6
5
4
3
2
1
0
2824201612 8 4 0 4 0
2925211713 9 5 1 5 1
302622181410 6 2 6 2
312723191511 7 3 7 3
7 6 5 4 3 2 1 0 4 0 4 0
7 6 5 4 3 2 1 0 5 1 5 1
7 6 5 4 3 2 1 0 6 2 6 2
7 6 5 4 3 2 1 0 7 3 7 3
IO2
IO3
Phase
Instruction
Address
Mode Dummy
DLP
D1 D2
DDR Quad I/O Read
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
2824201612 8
2925211713 9
4
5
0
1
2
3
4
5
6
7
0
1
2
3
7
7
7
7
6
6
6
6
5 4
5 4
5 4
5 4
3
3
3
3
2
2
2
2
1
1
1
1
0
0
0
0
4
5
6
7
0 4
1 5
2 6
3 7
0
1
2
3
IO2
302622181410 6
312723191511 7
Address
IO3
Phase
Instruct.
Mode
Dummy
DLP
D1 D2
DDR Quad I/O Read in QPI mode
Additional sequence diagrams, specific to each command, are provided in “Commands” on page 78.
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Signal protocols
4.3
Interface states
This section describes the input and output signal levels as related to the SPI interface behavior.
Table 3
Interface states summary
IO3 /
WP# /
IO2
Interface state
V
SCK
X
CS#
X
SO / IO1 SI / IO0
CC
RESET#
Power-off
<V (low)
X
X
Z
Z
X
X
CC
Low power
<V (cut-off)
X
X
X
X
CC
Hardware data protection
Power-on (Cold) reset
≥V (min)
X
X
HH
X
X
HL
HL
X
X
X
Z
Z
Z
Z
Z
X
X
CC
Hardware (Warm) reset non-quad mode
Hardware (Warm) reset quad mode
Interface standby
≥V (min)
CC
≥V (min)
X
HH
HH
HL
X
X
CC
≥V (min)
X
X
X
CC
Instruction cycle (Legacy SPI)
≥V (min)
HT
HH
HV
HV
CC
Single input cycle
Host to Memory transfer
≥V (min)
HT
HT
HT
HL
HL
HL
HH
HH
HH
X
X
X
Z
Z
HV
X
CC
Single latency (Dummy) cycle
≥V (min)
CC
Single output cycle
Memory to Host transfer
≥V (min)
MV
X
CC
Dual input cycle
Host to Memory transfer
≥V (min)
HT
HT
HT
HL
HL
HL
HH
HH
HH
X
X
X
HV
X
HV
X
CC
Dual latency (Dummy) cycle
≥V (min)
CC
Dual output cycle
Memory to Host transfer
≥V (min)
MV
MV
CC
Quad input cycle
Host to Memory transfer
≥V (min)
HT
HT
HT
HL
HL
HL
HV
X
HV
X
HV
X
HV
X
CC
Quad latency (Dummy) cycle
≥V (min)
CC
Quad output cycle
Memory to Host transfer
≥V (min)
MV
MV
MV
MV
CC
DDR Quad input cycle
Host to Memory transfer
≥V (min)
HT
HT
HT
HL
HL
HL
HV
MV or Z
MV
HV
HV
HV
CC
DDR Latency (Dummy) cycle
≥V (min)
MV or Z MV or Z MV or Z
MV MV MV
CC
DDR Quad output cycle
Memory to Host transfer
≥V (min)
CC
Legend
Z = No driver – floating signal
HL = Host driving V
IL
HH = Host driving V
IH
HV = Either HL or HH
X = HL or HH or Z
HT = Toggling between HL and HH
ML = Memory driving V
IL
MH = Memory driving V
MV = Either ML or MH
IH
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4.3.1
Power-off
When the core supply voltage is at or below the VCC (Low) voltage, the device is considered to be powered off. The
device does not react to external signals, and is prevented from performing any program or erase operation.
4.3.2
Low power hardware data protection
When VCC is less than VCC (Cut-off) the memory device will ignore commands to ensure that program and erase
operations can not start when the core supply voltage is out of the operating range.
4.3.3
Power-on (Cold) reset
When the core voltage supply remains at or below the VCC (Low), voltage for ≥ tPD time, then rises to ≥ VCC (Minimum)
the device will begin its Power On Reset (POR) process. POR continues until the end of tPU. During tPU the device
does not react to external input signals nor drive any outputs. Following the end of tPU the device transitions to
the Interface Standby state and can accept commands. For additional information on POR see “Power on (Cold)
reset” on page 39.
4.3.4
Hardware (Warm) reset
A configuration option is provided to allow IO3 to be used as a hardware reset input when the device is not in
Quad mode or when it is in Quad mode and CS# is HIGH. When IO3 / RESET# is driven LOW for tRP time the device
starts the hardware reset process. The process continues for tRPH time. Following the end of both tRPH and the
reset hold time following the rise of RESET# (tRH) the device transitions to the Interface Standby state and can
accept commands.
4.3.5
Interface standby
When CS# is HIGH, the SPI interface is in standby state. Inputs other than RESET# are ignored. The interface waits
for the beginning of a new command. The next interface state is Instruction Cycle when CS# goes LOW to begin a
new command.
While in interface standby state, the memory device draws standby current (ISB) if no embedded algorithm is in
progress. If an embedded algorithm is in progress, the related current is drawn until the end of the algorithm
when the entire device returns to standby current draw.
A Deep Power Down (DPD) mode is supported by the S25FS512S devices. If the device has been placed in DPD
mode by the DPD (B9h) command, the interface standby current is (IDPD). The DPD command is accepted only
while the device is not performing an embedded algorithm as indicated by the Status Register-1 volatile Write In
Progress (WIP) bit being cleared to zero (SR1V[0] = 0). While in DPD mode the device ignores all commands except
the Release from DPD (RES ABh) command, that will return the device to the Interface Standby state after a delay
of tRES
.
4.3.6
Instruction cycle (Legacy SPI mode)
When the host drives the MSb of an instruction and CS# goes LOW, on the next rising edge of SCK the device
captures the MSb of the instruction that begins the new command. On each following rising edge of SCK the
device captures the next lower significance bit of the 8-bit instruction. The host keeps CS# LOW, and drives the
Write Protect (WP#) and IO3/RESET signals as needed for the instruction. However, WP# is only relevant during
instruction cycles of a WRR or WRAR command and is otherwise ignored. IO3 / RESET# is driven HIGH when the
device is not in Quad Mode (CR1V[1] = 0) or QPI Mode (CR2V[6] = 0) and hardware reset is not required.
Each instruction selects the address space that is operated on and the transfer format used during the remainder
of the command. The transfer format may be Single, Dual I/O, Quad I/O, or DDR Quad I/O. The expected next
interface state depends on the instruction received.
Some commands are standalone, needing no address or data transfer to or from the memory. The host returns
CS# HIGH after the rising edge of SCK for the eighth bit of the instruction in such commands. The next interface
state in this case is Interface Standby.
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4.3.7
Instruction cycle (QPI mode)
In QPI mode, when CR2V[6] = 1, instructions are transferred 4 bits per cycle. In this mode instruction cycles are
the same as a Quad Input Cycle (see “Quad input cycle — Host to Memory transfer” on page 27).
4.3.8
Single input cycle — Host to Memory transfer
Several commands transfer information after the instruction on the single serial input (SI) signal from host to the
memory device. The host keeps RESET# HIGH, CS# LOW, and drives SI as needed for the command. The memory
does not drive the Serial Output (SO) signal.
The expected next interface state depends on the instruction. Some instructions continue sending address or
data to the memory using additional Single Input Cycles. Others may transition to Single Latency, or directly to
Single, Dual, or Quad Output cycle states.
4.3.9
Single latency (Dummy) cycle
Read commands may have zero to several latency cycles during which read data is read from the main flash
memory array before transfer to the host. The number of latency cycles are determined by the Latency Code in
the configuration register (CR2V[3:0]). During the latency cycles, the host keeps RESET# HIGH, CS# LOW. The Write
Protect (WP#) signal is ignored. The host may drive the SI signal during these cycles or the host may leave SI
floating. The memory does not use any data driven on SI / I/O0 or other I/O signals during the latency cycles. The
memory does not drive the Serial Output (SO) or I/O signals during the latency cycles.
The next interface state depends on the command structure, i.e., the number of latency cycles, and whether the
read is single, dual, or quad width.
4.3.10
Single output cycle — Memory to Host transfer
Several commands transfer information back to the host on the single Serial Output (SO) signal. The host keeps
RESET# HIGH, CS# LOW. The Write Protect (WP#) signal is ignored. The memory ignores the Serial Input (SI) signal.
The memory drives SO with data.
The next interface state continues to be Single Output Cycle until the host returns CS# to HIGH ending the
command.
4.3.11
Dual input cycle — Host to Memory transfer
The Read Dual I/O command transfers two address or mode bits to the memory in each cycle. The host keeps
RESET# HIGH, CS# LOW. The Write Protect (WP#) signal is ignored. The host drives address on SI / IO0 and
SO / IO1.
The next interface state following the delivery of address and mode bits is a Dual Latency Cycle if there are latency
cycles needed or Dual Output Cycle if no latency is required.
4.3.12
Dual latency (Dummy) cycle
Read commands may have zero to several latency cycles during which read data is read from the main flash
memory array before transfer to the host. The number of latency cycles are determined by the Latency Code in
the configuration register (CR2V[3:0]). During the latency cycles, the host keeps RESET# HIGH, CS# LOW. The Write
Protect (WP#) signal is ignored. The host may drive the SI / IO0 and SO / IO1 signals during these cycles or the host
may leave SI / IO0 and SO / IO1 floating. The memory does not use any data driven on SI / IO0 and SO / IO1 during
the latency cycles. The host must stop driving SI / IO0 and SO / IO1 on the falling edge at the end of the last latency
cycle. It is recommended that the host stop driving them during all latency cycles so that there is sufficient time
for the host drivers to turn off before the memory begins to drive at the end of the latency cycles. This prevents
driver conflict between host and memory when the signal direction changes. The memory does not drive the
SI / IO0 and SO / IO1 signals during the latency cycles.
The next interface state following the last latency cycle is a Dual Output Cycle.
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4.3.13
Dual output cycle — Memory to Host transfer
The Read Dual Output and Read Dual I/O return data to the host two bits in each cycle. The host keeps RESET#
HIGH, CS# LOW. The Write Protect (WP#) signal is ignored. The memory drives data on the SI / IO0 and SO / IO1
signals during the dual output cycles.
The next interface state continues to be Dual Output Cycle until the host returns CS# to HIGH ending the
command.
4.3.14
Quad input cycle — Host to Memory transfer
The Quad I/O Read command transfers four address or mode bits to the memory in each cycle. In QPI mode, the
Quad I/O Read and Page Program commands transfer four data bits to the memory in each cycle, including the
instruction cycles. The host keeps CS# LOW, and drives the IO signals.
For Quad I/O Read the next interface state following the delivery of address and mode bits is a Quad Latency Cycle
if there are latency cycles needed or Quad Output Cycle if no latency is required. For QPI mode Page Program,
the host returns CS# HIGH following the delivery of data to be programmed and the interface returns to standby
state.
4.3.15
Quad latency (Dummy) cycle
Read commands may have zero to several latency cycles during which read data is read from the main flash
memory array before transfer to the host. The number of latency cycles are determined by the Latency Code in
the configuration register (CR2V[3:0]). During the latency cycles, the host keeps CS# LOW. The host may drive the
IO signals during these cycles or the host may leave the IO floating. The memory does not use any data driven on
IO during the latency cycles. The host must stop driving the IO signals on the falling edge at the end of the last
latency cycle. It is recommended that the host stop driving them during all latency cycles so that there is sufficient
time for the host drivers to turn off before the memory begins to drive at the end of the latency cycles. This
prevents driver conflict between host and memory when the signal direction changes. The memory does not
drive the IO signals during the latency cycles.
The next interface state following the last latency cycle is a Quad Output Cycle.
4.3.16
Quad output cycle — Memory to Host transfer
The Quad I/O Read returns data to the host four bits in each cycle. The host keeps CS# LOW. The memory drives
data on IO0-IO3 signals during the Quad output cycles.
The next interface state continues to be Quad Output Cycle until the host returns CS# to HIGH ending the
command.
4.3.17
DDR Quad input cycle — Host to Memory transfer
The DDR Quad I/O Read command sends address, and mode bits to the memory on all the IO signals. Four bits
are transferred on the rising edge of SCK and four bits on the falling edge in each cycle. The host keeps CS# LOW.
The next interface state following the delivery of address and mode bits is a DDR Latency Cycle.
4.3.18
DDR latency cycle
DDR Read commands may have one to several latency cycles during which read data is read from the main flash
memory array before transfer to the host. The number of latency cycles are determined by the Latency Code in
the configuration register (CR2V[3:0]). During the latency cycles, the host keeps CS# LOW. The host may not drive
the IO signals during these cycles. So that there is sufficient time for the host drivers to turn off before the memory
begins to drive. This prevents driver conflict between host and memory when the signal direction changes. The
memory has an option to drive all the IO signals with a Data Learning Pattern (DLP) during the last four latency
cycles. The DLP option should not be enabled when there are fewer than five latency cycles so that there is at
least one cycle of high impedance for turn around of the IO signals before the memory begins driving the DLP.
When there are more than four cycles of latency the memory does not drive the IO signals until the last four cycles
of latency.
The next interface state following the last latency cycle is a DDR Single, or Quad Output Cycle, depending on the
instruction.
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4.3.19
DDR Quad output cycle — Memory to Host transfer
The DDR Quad I/O Read command returns bits to the host on all the IO signals. Four bits are transferred on the
rising edge of SCK and four bits on the falling edge in each cycle. The host keeps CS# LOW.
The next interface state continues to be DDR Quad Output Cycle until the host returns CS# to HIGH ending the
command.
4.4
Configuration Register effects on the interface
The Configuration Register 2 volatile bits 3 to 0 (CR2V[3:0]) select the variable latency for all array read commands
except Read and Read SDFP (RSFDP). Read always has zero latency cycles. RSFDP always has eight latency cycles.
The variable latency is also used in the OTPR and RDAR commands.
The configuration register bit 1 (CR1V[1]) selects whether Quad mode is enabled to switch WP# to IO2 function,
RESET# to IO3 function, and thus allow Quad I/O Read and QPI mode commands. Quad mode must also be
selected to allow DDR Quad I/O Read commands.
4.5
Data protection
Some basic protection against unintended changes to stored data are provided and controlled purely by the
hardware design. These are described in “Data protection” on page 70. Other software managed protection
methods are discussed in the software section of this document.
4.5.1
Power-up
When the core supply voltage is at or below the VCC (Low) voltage, the device is considered to be powered off. The
device does not react to external signals, and is prevented from performing any program or erase operation.
Program and erase operations continue to be prevented during the Power-on Reset (POR) because no command
is accepted until the exit from POR to the Interface Standby state.
4.5.2
Low power
When VCC is less than VCC (Cut-off) the memory device will ignore commands to ensure that program and erase
operations can not start when the core supply voltage is out of the operating range.
4.5.3
Clock pulse count
The device verifies that all non-volatile memory and register data modifying commands consist of a clock pulse
count that is a multiple of eight bit transfers (byte boundary) before executing them. A command not ending on
an 8-bit (byte) boundary is ignored and no error status is set for the command.
4.5.4
DPD
In DPD mode the device responds only to the Release from DPD command (RES ABh). All other commands are
ignored during DPD mode, thereby protecting the memory from program and erase operations.
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Electrical specifications
5
Electrical specifications
5.1
Absolute maximum ratings
-65°C to +150°C
-65°C to +125°C
-0.5 V to +2.5V
-0.5 V to VCC + 0.5V
100 mA
Storage temperature plastic packages
Ambient temperature with power applied
V
CC
[13]
Input voltage with respect to Ground (V
)
SS
[14]
Output short circuit current
Notes
12. See “Input signal overshoot” on page 30 for allowed maximums during signal transition.
13. No more than one output may be shorted to ground at a time. Duration of the short circuit should not be greater than
one second.
14. Stresses above those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. This is a
stress rating only; functional operation of the device at these or any other conditions above those indicated in the
operational sections of this data sheet is not implied. Exposure of the device to absolute maximum rating conditions
for extended periods may affect device reliability.
5.2
Thermal resistance
Table 4
Thermal resistance
Parameter
Description
Junction to Ambient
Junction to Board
SO3016
WNH008
30
FAB024
38.5
Unit
37.4
Theta JA
Theta JB
Theta JC
8
10.6
10.2
°C/W
9
11.2
11.6
Junction to Case
5.3
Table 5
Latchup characteristics
Latchup specification
Description
Min
Max
VCC + 1.0
+100
Unit
Input voltage with respect to V on all input only connections
SS
-1.0
V
Input voltage with respect to V on all I/O connections
SS
-100
mA
V
current
CC
Note
15. Excludes power supply V . Test conditions: V = 1.8 V, one connection at a time tested, connections not being tested
CC
CC
are at V
.
SS
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512 Mb (64 MB) FS-S Flash
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Electrical specifications
5.4
Operating ranges
Operating ranges define those limits between which the functionality of the device is guaranteed.
5.4.1
5.4.2
Power supply voltages
VCC
1.7V to 2.0V
Temperature ranges
Spec
Parameter
Symbol
Devices
Unit
Min
Max
+85
Industrial (I)
Industrial Plus devices (V)
+105
+85
Ambient temperature
T
Automotive, AEC-Q100 grade 3 (A)
Automotive, AEC-Q100 grade 2 (B)
Automotive, AEC-Q100 grade 1 (M)
-40
°C
A
+105
+125
Note
16. Industrial Plus operating and performance parameters will be determined by device characterization and may vary
from standard industrial temperature range devices as currently shown in this specification.
5.4.3
Input signal overshoot
During DC conditions, input or I/O signals should remain equal to or between VSS and VCC. During voltage transi-
tions, inputs or I/Os may overshoot VSS to -1.0V or overshoot to VCC +1.0V, for periods up to 20 ns.
VSS to VCC
- 1.0V
<
20 ns
Figure 19
Maximum negative overshoot waveform
< 20 ns
V
V
+ 1.0V
DD
SS
to V
CC
Figure 20
Maximum positive overshoot waveform
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Electrical specifications
5.5
Power-up and power-down
The device must not be selected at power-up or power-down (that is, CS# must follow the voltage applied on VCC
until VCC reaches the correct value as follows:
)
• VCC (min) at power-up, and then for a further delay of tPU
• VSS at power-down
A simple pull-up resistor on Chip Select (CS#) can usually be used to insure safe and proper power-up and
power-down.
The device ignores all instructions until a time delay of tPU has elapsed after the moment that VCC rises above the
minimum VCC threshold (see Figure 21). However, correct operation of the device is not guaranteed if VCC returns
below VCC (min) during tPU. No command should be sent to the device until the end of tPU
.
The device draws IPOR during tPU. After power-up (tPU), the device is in Standby mode, draws CMOS standby
current (ISB), and the WEL bit is reset.
During power-down or voltage drops below VCC(cut-off), the voltage must drop below VCC(low) for a period of tPD
for the part to initialize correctly on power-up (see Figure 22). If during a voltage drop the VCC stays above
VCC(cut-off) the part will stay initialized and will work correctly when VCC is again above VCC(min). In the event
Power-on Reset (POR) did not complete correctly after power up, the assertion of the RESET# signal or receiving
a software reset command (RESET) will restart the POR process.
Normal precautions must be taken for supply rail decoupling to stabilize the VCC supply at the device. Each device
in a system should have the VCC rail decoupled by a suitable capacitor close to the package supply connection
(this capacitor is generally of the order of 0.1µf).
Table 6
FS-S power-up / power-down voltage and timing
Parameter
Symbol
(min)
Min
1.7
1.5
0.7
–
Max
–
Unit
V
V
V
V
V
V
V
V
(minimum operation voltage)
(Cut 0ff where re-initialization is needed)
(low voltage for initialization to occur)
(min) to Read operation
CC
CC
CC
PU
PD
CC
CC
CC
CC
CC
(cut-off)
(low)
–
V
–
t
t
300
–
µs
(low) time
10.0
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Electrical specifications
VCC (Max)
VCC (Min)
tPU
Full Device Access
Time
Figure 21
Figure 22
Datasheet
Power-up
V
(Max)
(Min)
CC
No Device Access Allowed
V
CC
Device
Access
Allowed
tPU
V
(Cut-off)
(Low)
CC
V
CC
tPD
Time
Power-down and voltage drop
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Electrical specifications
5.6
DC characteristics
Table 7
DC characteristics — Operating temperature range (–40°C to +85°C)
[17]
Symbol
Parameter
Input low voltage
Test conditions
Min
Typ
Max
0.3 x V
Unit
V
–
-0.5
–
IL
CC
V
Input high voltage
Output low voltage
Output high voltage
–
0.7 x V
–
–
–
V
+ 0.4
CC
IH
CC
V
V
I
I
= 0.1 mA
–
0.2
OL
OH
OL
V
= –0.1 mA
V
- 0.2
CC
OH
V
= V Max, V = V or V
,
,
CC
CC
IN
IH
SS
I
Input leakage current
Output leakage current
–
–
–
±2
±2
LI
CS# = V
IH
µA
V
= V Max, V = V or V
CC IN IH
CC
SS
I
–
–
LO
CS# = V
IH
Serial SDR@54 MHz
Serial SDR@133 MHz
Quad SDR@133 MHz
Quad DDR@80 MHz
10
25
60
70
18
30
65
90
[18]
I
Active power supply current (READ)
CC1
Active power supply current
I
I
CS# = V
CS# = V
–
–
60
60
100
100
CC2
CC3
CC
CC
mA
(Page Program)
Active power supply current
(WRR or WRAR)
I
I
Active power supply current (SE)
Active power supply current (BE)
CS# = V
CS# = V
–
–
60
60
100
100
CC4
CC5
CC
CC
IO3 / RESET#, CS# = V ; SI,
CC
I
Standby current
–
–
–
25
8
100
50
SB
SCK = V or V
CC
SS
µA
IO3 / RESET#, CS# =V ; SI,
CC
I
I
Deep power-down current
Power-on reset current
DPD
SCK = V or V
CC
SS
IO3 / RESET#, CS# =V ; SI,
CC
80
mA
POR
SCK = V or V
CC
SS
Notes
17. Typical values are at T = 25°C and V = 1.8V.
AI
CC
18. Outputs unconnected during read data return. Output switching current is not included.
Datasheet
33 of 160
002-00488 Rev. *N
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Electrical specifications
Table 8
Symbol
DC characteristics — Operating temperature range –40°C to +105°C
[19]
Parameter
Input low voltage
Test Conditions
Min
-0.5
Typ
Max
Unit
V
–
–
–
0.3 x V
IL
IH
CC
V
Input high voltage
Output low voltage
Output high voltage
Input leakage current
Output leakage current
0.7 x V
–
–
–
–
–
V
+ 0.4
CC
CC
V
V
I
= 0.1 mA
0.2
OL
OH
OL
V
I
= –0.1 mA
V
- 0.2
OH
CC
I
–
±4
±4
LI
V
= V Max, V = V or V , CS# = V
µA
CC
CC
IN
IH
SS
IH
I
–
LO
Serial SDR@54 MHz
Serial SDR@133 MHz
Quad SDR@133 MHz
Quad DDR@80 MHz
10
25
60
70
18
30
65
90
Active power supply
I
–
[20]
CC1
current (READ)
Active power supply
I
I
I
I
–
–
–
–
60
60
60
60
100
100
100
100
CC2
CC3
CC4
CC5
current (Page Program)
mA
Active power supply
current (WRR or WRAR)
CS# = V
CC
Active power supply
current (SE)
Active power supply
current (BE)
I
Standby current
–
–
–
25
8
300
150
80
SB
µA
IO3 / RESET#, CS# =V
;
CC
I
I
Deep power-down current
Power-on reset current
DPD
POR
SI, SCK = V or V
CC
SS
mA
Notes
19. Typical values are at T = 25°C and V = 1.8V.
AI
CC
20. Outputs unconnected during read data return. Output switching current is not included.
Datasheet
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002-00488 Rev. *N
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Electrical specifications
Table 9
Symbol
DC characteristics — Operating temperature range –40°C to +125°C
[21]
Parameter
Input low voltage
Test Conditions
Min
-0.5
Typ
Max
Unit
V
–
–
–
0.3 x V
IL
IH
CC
V
Input high voltage
Output low voltage
Output high voltage
Input leakage current
Output leakage current
0.7 x V
–
–
–
–
–
–
V
+ 0.4
CC
CC
V
V
I
I
= 0.1 mA
0.2
OL
OH
OL
V
= –0.1 mA
V
- 0.2
CC
–
OH
I
V
V
= V Max, V = V or V , CS# = V
–
±4
±4
LI
CC
CC
IN
IH
SS
IH
µA
I
= V Max, V = V or V , CS# = V
–
LO
CC
CC
IN
IH
SS
IH
Serial SDR@54 MHz
Serial SDR@133 MHz
Quad SDR@133 MHz
Quad DDR@80 MHz
10
25
60
70
18
40
65
90
Active power supply
I
–
[22]
CC1
current (READ)
Active power supply
I
I
I
I
–
–
–
–
60
60
60
60
100
100
100
100
CC2
CC3
CC4
CC5
current (Page Program)
mA
Active power supply
current (WRR or WRAR)
CS# = V
CC
Active power supply
current (SE)
Active power supply
current (BE)
I
Standby current
–
–
–
25
8
300
250
80
SB
µA
IO3 / RESET#, CS# =V ; SI,
CC
I
I
Deep power-down current
Power-on reset current
DPD
POR
SCK = V or V
CC
SS
–
mA
Notes
21. Typical values are at T = 25°C and V = 1.8V.
AI
CC
22. Outputs unconnected during read data return. Output switching current is not included.
Datasheet
35 of 160
002-00488 Rev. *N
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Electrical specifications
5.6.1
Active power and standby power modes
The device is enabled and in the Active Power mode when Chip Select (CS#) is LOW. When CS# is HIGH, the device
is disabled, but may still be in an Active Power mode until all program, erase, and write operations have
completed. The device then goes into the Standby Power mode, and power consumption drops to ISB
.
5.6.2
Deep power down mode (DPD)
DPD mode is supported by the S25FS512S devices. If the device has been placed in DPD mode by the DPD (B9h)
command, the interface standby current is (IDPD). The DPD command is accepted only while the device is not
performing an embedded algorithm as indicated by the Status Register-1 volatile Write In Progress (WIP) bit being
cleared to zero (SR1V[0] = 0). While in DPD mode, the device ignores all commands except the Release from DPD
(RES ABh) command, which will return the device to the Interface Standby state after a delay of tRES
.
Table 10
Valid enter DPD mode and release from DPD mode sequence
Current mode
CS#
SCK
Command
Next mode
Comments
Active
Low to High
N/A
N/A
Standby
–
B9h
DPD entered after CS# goes HIGH and after
the t duration (see Table 14).
Standby
DPD
High to Low
High to Low
Toggling
DPD
DPD
Enter DPD
DPD
Not Toggling
Toggling
N/A
If SCK is toggling and Command is not ABh,
device remains in DPD
Command not ABh
Release from DPD after CS# goes HIGH and
after the t
duration (see Table 14).
RES
ABh
DPD
High to Low
Toggling
Standby After CS# goes HIGH to start the release from
DPD, it is an invalid sequence to have a CS#
transition when the SCK is not toggling.
Release from DPD
Datasheet
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002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Timing specifications
6
Timing specifications
6.1
Key to switching waveforms
Input Valid at logic high or low
High Impedance
Any change permitted
Logic High Logic Low
Symbol
Output Valid at logic high or low
High Impedance
Changing, state unknown Logic High Logic Low
Figure 23
Waveform element meaning
6.2
AC test conditions
Device
Under
Test
C
L
Figure 24
Table 11
Test setup
AC measurement conditions
Symbol
Parameter
Min
–
Max
Unit
pF
C
Load capacitance
30
L
Input pulse voltage
Input slew rate
0.2 x V
0.23
0.9
0.8 V
V
CC
CC
1.25
5
V/ns
ns
Input rise and fall times
Input timing ref voltage
–
0.5 V
0.5 V
CC
CC
V
Output timing ref
voltage
Notes
23. Input slew rate measured from input pulse min to max at V max. Example: (1.9V x 0.8) - (1.9V x 0.2) = 1.14V;
CC
1.14V/1.25V/ns = 0.9 ns rise or fall time.
24. AC characteristics tables assume clock and data signals have the same slew rate (slope).
Datasheet
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002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Timing specifications
Input Levels
Output Levels
CC - 0.2V
VCC + 0.4V
0.7 x VCC
V
Timing Reference Level
0.5 x VCC
0.3 x VCC
- 0.5V
0.2V
Figure 25
Input, output, and timing reference levels
6.2.1
Capacitance characteristics
Table 12
FS512S capacitance
Parameter
Test conditions
Min
Max
Unit
C
Input capacitance (Applies to SCK, CS#, IO3 / RESET#)
Output capacitance (Applies to all I/O)
IN
1 MHz
–
8
pF
C
OUT
Note
25. Parameter values are not 100% tested. For more details, please refer to the IBIS models.
Datasheet
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002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Timing specifications
6.3
Reset
6.3.1
Power on (Cold) reset
The device executes a Power-On Reset (POR) process until a time delay of tPU has elapsed after the moment that
VCC rises above the minimum VCC threshold (see Figure 21 and Table 6). The device must not be selected (CS# to
go HIGH with VCC) during power-up (tPU), i.e. no commands may be sent to the device until the end of tPU
.
The IO3 / RESET# signal functions as the RESET# input when CS# is HIGH for more than tCS time or when Quad
Mode is not enabled CR1V[1] = 0.
RESET# is ignored during POR. If RESET# is LOW during POR and remains low through and beyond the end of tPU
,
CS# must remain HIGH until tRH after RESET# returns HIGH. RESET# must return HIGH for greater than tRS before
returning low to initiate a hardware reset.
VCC
tPU
RESET#
If RESET# is low at tPU end
CS# must be high at tPU end
tRH
CS#
Figure 26
Reset LOW at the end of POR
VCC
tPU
RESET#
If RESET# is high at tPU end
tPU
CS#
CS# may stay high or go low at tPU end
Figure 27
Reset HIGH at the end of POR
VCC
tPU
tPU
tRS
RESET#
CS#
Figure 28
POR followed by hardware reset
Datasheet
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002-00488 Rev. *N
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Timing specifications
6.3.2
IO3 / RESET# input initiated hardware (Warm) reset
The IO3 / RESET# signal functions as the RESET# input when CS# is HIGH for more than tCS time or when Quad
Mode is not enabled CR1V[1] = 0. The IO3 / RESET# input has an internal pull-up to VCC and may be left uncon-
nected if Quad mode is not used. The tCS delay after CS# goes HIGH gives the memory or host system time to drive
IO3 HIGH after its use as a Quad mode I/O signal while CS# was LOW. The internal pull-up to VCC will then hold
IO3 / RESET# HIGH until the host system begins driving IO3 / RESET#. The IO3 / RESET# input is ignored while CS#
remains HIGH during tCS, to avoid an unintended Reset operation. If CS# is driven LOW to start a new command,
IO3 / RESET# is used as IO3.
When the device is not in quad mode or, when CS# is HIGH, and IO3 / RESET# transitions from VIH to VIL for > tRP
,
following tCS, the device will reset register states in the same manner as power-on reset but, does not go through
the full reset process that is performed during POR. The hardware reset process requires a period of tRPH to
complete. If the POR process did not complete correctly for any reason during power-up (tPU), RESET# going LOW
will initiate the full POR process instead of the hardware reset process and will require tPU to complete the POR
process.
The RESET command is independent of the state of IO3 / RESET#. If IO3 / RESET# is high or unconnected, and the
RESET instruction is issued, the device will perform software reset.
Additional IO3 RESET# notes:
• IO3 / RESET# must be high for tRS following tPU or tRPH, before going low again to initiate a hardware reset.
• When IO3 / RESET# is driven LOW for at least a minimum period of time (tRP), following tCS, the device terminates
any operation in progress, makes all outputs high impedance, and ignores all read/write commands for the
duration of tRPH. The device resets the interface to standby state.
• If Quad mode and the IO3 / RESET# feature are enabled, the host system should not drive IO3 low during tCS, to
avoid driver contention on IO3. Immediately following commands that transfer data to the host in Quad mode,
e.g. Quad I/O Read, the memory drives IO3 / Reset high during tCS, to avoid an unintended Reset operation.
Immediately following commands that transfer data to the memory in Quad mode, e.g. Page Program, the host
system should drive IO3 / Reset high during tCS, to avoid an unintended Reset operation.
• If Quad mode is not enabled, and if CS# is LOW at the time IO3 / RESET# is asserted LOW, CS# must return HIGH
during tRPH before it can be asserted low again after tRH
.
Table 13
Hardware reset parameters
Parameter
Description
Limit
Time
Unit
ns
Reset setup – Prior reset end and RESET# HIGH before
RESET# LOW
t
50
RS
t
Reset pulse hold – RESET# LOW to CS# LOW
RESET# pulse width
35
200
50
µs
RPH
Min
t
RP
ns
t
Reset Hold – RESET# HIGH before CS# LOW
RH
Notes
26. IO3 / RESET# Low is ignored during power-up (t ). If Reset# is asserted during the end of t , the device will remain in
PU
PU
the reset state and t will determine when CS# may go Low.
RH
27. If Quad mode is enabled, IO3 / RESET# Low is ignored during t
CS.
28. Sum of t and t must be equal to or greater than t
RP
RH
RPH.
Datasheet
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002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Timing specifications
tRP
IO3_RESET#
CS#
Any prior reset
tRPH
tRH
tRS
tRH
tRPH
Figure 29
Hardware reset when Quad mode is not enabled and IO3 / reset# is enabled
tDIS
tRP
IO3_RESET#
Reset Pulse
tCS
tRH
tRPH
CS#
Prior access using IO3 for data
Figure 30
Hardware reset when Quad mode and IO3 / reset# are enabled
Datasheet
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002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Timing specifications
6.4
SDR AC characteristics
Table 14
AC characteristics
Symbol
Parameter
Min
Typ
Max
Unit
SCK clock frequency for READ and 4READ
instructions
F
F
F
50
SCK, R
SCK, C
SCK, D
SCK clock frequency for the following dual and
quad commands: QOR, 4QOR, DIOR, 4DIOR,
QIOR, 4QIOR
DC
133
MHz
SCK clock frequency for the following DDR
commands: QIOR, 4QIOR
80
P
SCK clock period
1/ F
SCK
SCK
t
, t
Clock high time
ns
WH CH
50% P
-5%
50% P
+5%
SCK
SCK
t
, t
Clock low time
WL CL
t
t
, t
Clock rise time (Slew rate)
Clock fall time (Slew rate)
CRT CLCH
0.1
10
V/ns
, t
CFT CHCL
CS# high time (Read Instructions)
CS# high time (Read Instructions when Reset
feature and Quad mode are both enabled)
CS# high time (Program / erase Instructions)
[33]
t
20
CS
50
–
–
t
CS# active setup time (relative to SCK)
CS# active hold time (relative to SCK)
Data in setup time
2
3
2
3
CSS
t
CSH
t
SU
t
Data in hold time
HD
ns
[30]
[31]
8
6
t
Clock low to output valid
–
1
V
t
Output hold time
–
HO
[32]
Output disable time
8
t
Output disable time (when Reset feature and
Quad mode are both enabled)
–
[33]
DIS
20
[29]
t
WP# setup time
20
WPS
–
3
[29]
t
WP# hold time
100
WPH
t
CS# high to Power-down mode
µs
µs
DPD
–
CS# high to Standby mode without electronic
signature Read
t
30
RES
Notes
29. Only applicable as a constraint for WRR or WRAR instruction when SRWD is set to ‘1’.
30. Full V range and CL = 30 pF.
CC
31. Full V range and CL = 15 pF.
CC
32. Output Hi-Z is defined as the point where data is no longer driven.
33. t and t require additional time when the Reset feature and Quad mode are enabled (CR2V[5] = 1 and CR1V[1] = 1).
CS
DIS
Datasheet
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002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Timing specifications
6.4.1
Clock timing
PSCK
tCL
tCH
VIH min
VCC / 2
VIL ma x
tCFT
tCRT
Figure 31
Clock timing
6.4.2
Input / output timing
tCS
CS#
tCSH
tCSH
tCSS
tCSS
SCK
tSU
tHD
SI
MSb IN
LSb IN
SO
Figure 32
SPI single bit input timing
tCS
CS#
SCK
SI
tV
tHO
tDIS
SO
MSb OUT
LSb OUT
Figure 33
SPI single bit output timing
Datasheet
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002-00488 Rev. *N
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Timing specifications
tCS
CS#
tCSS
tCSH
tCSH
tCSS
SCK
tSU
tHD
tV
tHO
tV
tDIS
MSB IN
LSB IN
MSB OUT
LSB OUT
IO
Figure 34
SPI SDR MIO timing
CS#
tWPH
tWPS
WP#
SCK
SI
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
SO
Phase
WRR or WRAR Instruction
Input Data
Figure 35
WP# input timing
Datasheet
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002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Timing specifications
6.5
DDR AC characteristics
Table 15
DDR 80 MHz AC characteristics operation
Symbol
Parameter
SCK clock frequency for DDR READ instruction
SCK clock period for DDR READ instruction
Clock high time
Min
DC
Typ
Max
80
Unit
F
MHz
SCK, R
P
12.5
SCK, R
t
, t
50% P
- 5%
- 5%
50% P
+ 5%
+ 5%
WH CH
SCK
SCK
SCK
SCK
t
, t
Clock low time
50% P
50% P
WL CL
CS# high time (Read instructions)
CS# high time (Read instructions when Reset
feature is enabled)
10
20
t
CS
t
CS# active setup time (Relative to SCK)
CS# active hold time (Relative to SCK)
IO in setup time
2
3
CSS
–
t
ns
CSH
t
SU
–
t
IO in hold time
1.5
1
HD
[34]
t
Clock low to output valid
Output hold time
6.0
V
t
HO
Output disable time
Output disable time (when Reset feature is
enabled)
8
t
DIS
20
t
First IO to last IO data valid time
CS# High to Power-down Mode
400
3
ps
µs
IO_skew
–
t
DPD
CS# High to Standby Mode without Electronic
Signature Read
t
30
RES
Note
34. CL = 15 pF.
Datasheet
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002-00488 Rev. *N
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Timing specifications
6.5.1
DDR input timing
tCS
CS#
tCSH
tCSH
tCSS
tCSS
SCK
tHD
tSU
tHD
tSU
tHO
Inst. MSB
IO's
LSB IN
MSB IN
Figure 36
SPI DDR input timing
6.5.2
DDR output timing
tCS
CS#
SCK
tHO
tV
tV
tDIS
IO's
MSB
LSB
Figure 37
SPI DDR output timing
6.5.3
DDR data valid timing using DLP
pSCK
tCL
tCH
SCK
tIO_SKEW
tV
tOTT
IO Slow
IO Fast
S.
Slow D1
Slow D2
tV
Fast D1
Fast D2
tV_min
tHO
tDV
D1
IO_valid
D2
Figure 38
SPI DDR data valid window
Datasheet
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002-00488 Rev. *N
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Timing specifications
The minimum data valid window (tDV) and tV minimum can be calculated as follows:
[36]
tDV = Minimum half clock cycle time (tCLH
tV _min = tHO + tIO_SKEW + tOTT
Example:
)
[35] - tOTT[37]- tIO_SKEW
80 MHz clock frequency = 12.5 ns clock period, DDR operations and duty cycle of 45% or higher
tCLH = 0.45 PSCK = 0.45 12.5 ns = 5.625 ns
Bus impedance of 45 and capacitance of 22 pf, with timing reference of 0.75VCC, the rise time from 0 to 1 or fall
time 1 to 0 is 1.4[40] RC time constant (Tau)[39] = 1.4 0.99 ns = 1.39 ns
t
OTT = Rise time or fall time = 1.39 ns.
Data valid window
DV = tCLH - tIO_SKEW - tOTT = 5.625 ns - 400 ps - 1.39 ns = 3.835 ns
t
tV minimum
tV _min = tHO + tIO_SKEW + tOTT = 1.0 ns + 400 ps + 1.39 ns = 2.79 ns
Notes
35. t
36. t
37. t
is the shorter duration of t or t .
CL CH
CLH
IO_SKEW
OTT
is the maximum difference (delta) between the minimum and maximum t (output valid) across all IO signals.
V
is the maximum Output Transition Time from one valid data value to the next valid data value on each IO. t
is
OTT
dependent on system level considerations including:
a. Memory device output impedance (drive strength).
b. System level parasitics on the IOs (primarily bus capacitance).
c. Host memory controller input V and V levels at which 0 to 1 and 1 to 0 transitions are recognized.
d.t
IH
IL
is not a specification tested by Cypress, it is system dependent and must be derived by the system designer
OTT
based on the above considerations.
38.t is the data valid window.
DV
39. Tau = R (Output Impedance) x C (Load capacitance).
40. Multiplier of Tau time for voltage to rise to 75% of V
.
CC
Datasheet
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002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Address space maps
7
Address space maps
7.1
Overview
7.1.1
Extended address
The S25FS512S supports 32-bit (4-byte) addresses to enable higher density devices than allowed by previous
generation (legacy) SPI devices that supported only 24-bit (3-byte) addresses. A 24-bit, byte resolution, address
can access only 16 MB (128 Mb) maximum density. A 32-bit, byte resolution, address allows direct addressing of
up to a 4 GB (32 Gb) address space.
Legacy commands continue to support 24-bit addresses for backward software compatibility. Extended 32-bit
addresses are enabled in two ways:
• Extended address mode — a volatile configuration register bit that changes all legacy commands to expect 32
bits of address supplied from the host system.
• 4-byte address commands — that perform both legacy and new functions, which always expect 32-bit address.
The default condition for extended address mode, after power-up or reset, is controlled by a non-volatile config-
uration bit. The default extended address mode may be set for 24 or 32-bit addresses. This enables legacy
software compatible access to the first 128 Mb of a device or for the device to start directly in 32-bit address mode.
7.1.2
Multiple address spaces
Many commands operate on the main flash memory array. Some commands operate on address spaces separate
from the main flash array. Each separate address space uses the full 24- or 32-bit address but may only define a
small portion of the available address space.
7.2
Flash memory array
The main flash array is divided into erase units called physical sectors.
The FS-S family physical sectors may be configured as a hybrid combination of eight 4-KB parameter sectors at
the top or bottom of the address space with all but one of the remaining sectors being uniform size. Because the
group of eight 4-KB parameter sectors is in total smaller than a uniform sector, the group of 4-KB physical sectors
respectively overlay (replace) the top or bottom 32 KB of the highest or lowest address uniform sector.
The parameter sector erase commands (20h or 21h) must be used to erase the 4-KB sectors individually. The
sector (uniform block) erase commands (D8h or DCh) must be used to erase any of the remaining sectors,
including the portion of highest or lowest address sector that is not overlaid by the parameter sectors. The
uniform block erase command has no effect on parameter sectors.
Configuration Register 1 non-volatile bit 2 (CR1NV[2]) equal to 0 overlays the parameter sectors at the bottom of
the lowest address uniform sector. CR1NV[2] = 1 overlays the parameter sectors at the top of the highest address
uniform sector. See “Registers” on page 52 for more information.
There is also a configuration option to remove the 4-KB parameter sectors from the address map so that all
sectors are uniform size. Configuration Register 3 volatile bit 3 (CR3V[3]) equal to 0 selects the hybrid sector
architecture with 4-KB parameter sectors. CR3V[3] = 1 selects the uniform sector architecture without parameter
sectors. Uniform physical sectors are:
• 256 KB in FS512S
The sector erase (SE) commands erase the physical 256 KB sectors of the 512 Mb device.
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Address space maps
Table 16
S25FS512S sector address map, Bottom 4-KB sectors
Address range
(Byte address)
Sector size (KB)
Sector count
Sector range
Notes
SA00
:
00000000h-00000FFFh
:
4
8
1
SA7
SA8
SA9
:
00007000h-00007FFFh
00008000h-0003FFFFh
00040000h-0007FFFFh
:
Sector Starting Address
—
224
256
Sector Ending Address
255
SA263
03FC0000h-03FFFFFFh
Table 17
S25FS512S sector address map, Top 4-KB sectors
Address range
(Byte address)
Sector size (KB)
Sector count
Sector range
Notes
SA00
:
0000000h-003FFFFh
:
256
224
4
255
1
SA254
SA255
SA256
:
03F80000h - 03FBFFFFh
03FC0000h -03FF7FFFh
03FF8000h-03FF8FFFh
:
SectorStarting Address
—
Sector Ending Address
8
SA263
03FFF000h-03FFFFFFh
Table 18
S25FS512S sector address map (Uniform sectors)
Address range
Sector size (KB)
Sector count
Sector range
Notes
(Byte address)
00000000h-0003FFFFh
:
SA00
:
Sector Starting Address
—
256
256
Sector Ending Address
SA255
03FC0000h-03FFFFFFh
Note These are condensed tables that use a couple of sectors as references. There are address ranges that are
not explicitly listed. All 4-KB sectors have the pattern XXXX000h-XXXXFFFh. All 256-KB sectors have the pattern
XX00000h-XX3FFFFh, XX40000h-XX7FFFFh, XX80000h-XXCFFFFh, or XXD0000h-XXFFFFFh.
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Address space maps
7.3
ID-CFI address space
The RDID command (9Fh) reads information from a separate flash memory address space for device identifi-
cation (ID) and Common Flash Interface (CFI) information. See “Device ID and common flash interface (ID-CFI)
address map” on page 137 for the tables defining the contents of the ID-CFI address space. The ID-CFI address
space is programmed by Infineon and read-only for the host system.
7.4
JEDEC JESD216 serial flash discoverable parameters (SFDP) space
The RSFDP command (5Ah) reads information from a separate flash memory address space for device identifi-
cation, feature, and configuration information, in accord with the JEDEC JESD216 standard for Serial Flash
Discoverable Parameters. The ID-CFI address space is incorporated as one of the SFDP parameters. See “Serial
flash discoverable parameters (SFDP) address map” on page 133 for the tables defining the contents of the
SFDP address space. The SFDP address space is programmed by Infineon and read-only for the host system.
7.4.1
OTP address space
Each FS-S Family memory device has a 1024-byte OTP address space that is separate from the main flash array.
The OTP area is divided into 32, individually lockable, 32-byte aligned and length regions.
In the 32-byte region starting at address zero:
• The 16 lowest address bytes are programmed by Infineon with a 128-bit random number. Only Infineon is able
to program zeros in these bytes. Programming ones in these byte locations is ignored and does not affect the
value programmed by Infineon. Attempting to program any zero in these byte locations will fail and set P_ERR.
• The next four higher address bytes (OTP Lock Bytes) are used to provide one bit per OTP region to permanently
protect each region from programming. The bytes are erased when shipped from Infineon. After an OTP region
is programmed, it can be locked to prevent further programming, by programming the related protection bit
in the OTP Lock Bytes.
• The next higher 12 bytes of the lowest address region are Reserved for Future Use (RFU). The bits in these RFU
bytes may be programmed by the host system but it must be understood that a future device may use those
bits for protection of a larger OTP space. The bytes are erased when shipped from Infineon.
The remaining regions are erased when shipped from Infineon, and are available for programming of additional
permanent data.
Refer to Figure 39 for a pictorial representation of the OTP memory space.
The OTP memory space is intended for increased system security. OTP values, such as the random number
programmed by Infineon, can be used to “mate” a flash component with the system CPU/ASIC to prevent device
substitution.
The configuration register FREEZE (CR1V[0]) bit protects the entire OTP memory space from programming when
set to ‘1’. This allows trusted boot code to control programming of OTP regions then set the FREEZE bit to prevent
further OTP memory space programming during the remainder of normal power-on system operation.
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32-Byte OTP Region 31
32-Byte OTP Region 30
32 Byte OTP Region 29
When programmed to 0,
each lock bit protects its related
32-byte OTP region from any
further programming
.
.
.
32-Byte OTP Region 3
32-Byte OTP Region 2
32-Byte OTP Region 1
32-Byte OTP Region 0
Region 0 Expanded View
16-Byte Random Number
...
Reserved
Byte 1Fh
Lock Bits 31 to 0
Byte 0h
Byte 10h
Figure 39
OTP address space
Table 19
Region
OTP address map
Initial delivery state
Byte address range (Hex)
Contents
(Hex)
Least Significant Byte of Infineon Programmed
Random Number
000
...
Infineon Programmed
Random Number
...
Most Significant Byte of Infineon Programmed
Random Number
00F
Region 0
Region Locking Bits
Byte 10 [bit 0] locks region 0 from programming
when = 0
010 to 013
...
Byte 13 [bit 7] locks region 31from programming
when = 0
All Bytes = FF
014 to 01F
020 to 03F
040 to 05F
...
Reserved for Future Use (RFU)
Region 1
Region 2
...
Available for User Programming
Region 31
3E0 to 3FF
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7.5
Registers
Registers are small groups of memory cells used to configure how the S25FS512S memory device operates or to
report the status of device operations. The registers are accessed by specific commands. The commands (and
hexadecimal instruction codes) used for each register are noted in each register description.
In legacy SPI memory devices the individual register bits could be a mixture of volatile, non-volatile, or OTP bits
within the same register. In some configuration options the type of a register bit could change e.g. from
non-volatile to volatile.
The S25FS512S uses separate non-volatile or volatile memory cell groups (areas) to implement the different
register bit types. However, the legacy registers and commands continue to appear and behave as they always
have for legacy software compatibility. There is a non-volatile and a volatile version of each legacy register when
that legacy register has volatile bits or when the command to read the legacy register has zero read latency. When
such a register is read the volatile version of the register is delivered. During Power-On Reset (POR), hardware
reset, or software reset, the non-volatile version of a register is copied to the volatile version to provide the
default state of the volatile register. When non-volatile register bits are written the non-volatile version of the
register is erased and programmed with the new bit values and the volatile version of the register is updated with
the new contents of the non-volatile version. When OTP bits are programmed the non-volatile version of the
register is programmed and the appropriate bits are updated in the volatile version of the register. When volatile
register bits are written, only the volatile version of the register has the appropriate bits updated.
The type for each bit is noted in each register description. The default state shown for each bit refers to the state
after power-on reset, hardware reset, or software reset if the bit is volatile. If the bit is non-volatile or OTP, the
default state is the value of the bit when the device is shipped from Infineon. Non-volatile bits have the same
cycling (erase and program) endurance as the main flash array.
Table 20
Register descriptions
Register
Abbreviation
SR1NV[7:0]
SR1V[7:0]
SR2V[7:0]
CR1NV[7:0]
CR1V[7:0]
CR2NV[7:0]
CR2V[7:0]
CR3NV[7:0]
CR3V[7:0]
CR4NV[7:0]
CR4V[7:0]
ECCSR [7:0]
ASPR[15:1]
ASPR[0]
Type
Non-volatile
Volatile
Bit location
Status Register 1
Status Register 1
Status Register 2
Volatile
Configuration Register 1
Configuration Register 1
Configuration Register 2
Configuration Register 2
Configuration Register 3
Configuration Register 3
Configuration Register 4
Configuration Register 4
ECC Status Register
ASP Register
Non-volatile
Volatile
Non-volatile
Volatile
7:0
Non-volatile
Volatile
Non-volatile
Volatile
Volatile
OTP
15:1
0
ASP Register
RFU
Password Register
PASS[63:0]
PPBL[7:1]
Non-volatile OTP
Volatile
63:0
7:1
PPB Lock Register
Volatile
PPB Lock Register
PPBL[0]
0
Read Only
PPB Access Register
PPBAR[7:0]
DYBAR[7:0]
NVDLR[7:0]
VDLR[7:0]
Non-volatile
Volatile
DYB Access Register
7:0
SPI DDR Data Learning Registers
SPI DDR Data Learning Registers
Non-volatile
Volatile
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7.5.1
Status Register 1
7.5.1.1
Status Register 1 Non-volatile (SR1NV)
Related Commands: Write Registers (WRR 01h), Read Any Register (RDAR 65h), Write Any Register (WRAR 71h).
Table 21
Status Register 1 Non-volatile (SR1NV)
Default
state
Bits Field name
Function
Type
Description
1 = Locks state of SRWD, BP, and Configuration Register-1
bits when WP# is LOW by not executing WRR or WRAR
commands that would affect SR1NV, SR1V, CR1NV, or
CR1V.
Status Register
7
SRWD_NV Write Disable
Default
Non-volatile
0 = No protection, even when WP# is LOW.
0
Programming
P_ERR_D
Non-volatile
Read Only
Provides the default state for the Programming Error
Status. Not user programmable.
6
5
Error Default
Erase Error
E_ERR_D
Non-volatile
Read Only
Provides the default state for the Erase Error Status. Not
user programmable.
Default
4
3
BP_NV2
Block
Protects the selected range of sectors (Block) from
Program or Erase when the BP bits are configured as
BP_NV1
Protection
Non-volatile
000b non-volatile (CR1NV[3] = 0). Programmed to 111b when BP
bits are configured to volatile (CR1NV[3] = 1).- after which
these bits are no longer user programmable.
Non-volatile
2
1
BP_NV0
Provides the default state for the WEL Status. Not user
programmable.
WEL_D WEL Default
Non-volatile
Read Only
0
Provides the default state for the WIP Status. Not user
programmable.
0
WIP_D
WIP Default
Status Register Write Non-volatile (SRWD_NV) SR1NV[7]: Places the device in the Hardware Protected mode
when this bit is set to ‘1’ and the WP# input is driven LOW. In this mode, the Write Registers (WRR) and Write Any
Register (WRAR) commands (that select Status Register 1 or Configuration Register 1) are ignored and not
accepted for execution, effectively locking the state of the Status Register 1 and Configuration Register 1 (SR1NV,
SR1V, CR1NV, or CR1V) bits, by making the registers read-only. If WP# is HIGH, Status Register 1 and Configuration
Register 1 may be changed by the WRR or WRAR commands. If SRWD_NV is 0, WP# has no effect and Status
Register 1 and Configuration Register 1 may be changed by the WRR or WRAR commands. WP# has no effect on
the writing of any other registers. The SRWD_NV bit has the same non-volatile endurance as the main flash array.
The SRWD (SR1V[7]) bit serves only as a copy of the SRWD_NV bit to provide zero read latency.
Program Error Default (P_ERR_D) SR1NV[6]: Provides the default state for the Programming Error Status in
SR1V[6]. This bit is not user programmable.
Erase Error (E_ERR) SR1V[5]: Provides the default state for the Erase Error Status in SR1V[5]. This bit is not user
programmable.
Block Protection (BP_NV2, BP_NV1, BP_NV0) SR1NV[4:2]: These bits define the main flash array area to be
software-protected against program and erase commands. The BP bits are selected as either volatile or
non-volatile, depending on the state of the BP non-volatile bit (BPNV_O) in the configuration register CR1NV[3].
When CR1NV[3] = 0 the non-volatile version of the BP bits (SR1NV[4:2]) are used to control Block Protection and
the WRR command writes SR1NV[4:2] and updates SR1V[4:2] to the same value. When CR1NV[3] = 1 the volatile
version of the BP bits (SR1V[4:2]) are used to control Block Protection and the WRR command writes SR1V[4:2]
and does not affect SR1NV[4:2]. When one or more of the BP bits is set to ‘1’, the relevant memory area is
protected against program and erase. The Bulk Erase (BE) command can be executed only when the BP bits are
cleared to 0’s. See “Block protection” on page 71 for a description of how the BP bit values select the memory
array area protected. The non-volatile version of the BP bits have the same non-volatile endurance as the main
flash array.
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Address space maps
Write Enable Latch Default (WEL_D) SR1NV[1]: Provides the default state for the WEL Status in SR1V[1]. This bit
is programmed by Infineon and is not user programmable.
Write In Progress Default (WIP_D) SR1NV[0]: Provides the default state for the WIP Status in SR1V[0]. This bit is
programmed by Infineon and is not user programmable.
7.5.1.2
Status Register 1 Volatile (SR1V)
Related Commands: Read Status Register (RDSR1 05h), Write Registers (WRR 01h), Write Enable (WREN 06h),
Write Disable (WRDI 04h), Clear Status Register (CLSR 30h or 82h), Read Any Register (RDAR 65h), Write Any
Register (WRAR 71h). This is the register displayed by the RDSR1 command.
Table 22
Status Register 1 Volatile (SR1V)
Field
Default
state
Bits
Function
Type
Description
Volatile copy of SR1NV[7].
name
Status Register Write
Disable
7
6
SRWD
Volatile
Programming Error
Occurred
P_ERR
Read Only
1 = Error occurred.
0 = No Error.
5
4
3
E_ERR Erase Error Occurred
BP2
Protects selected range of sectors (Block) from Program
or Erase when the BP bits are configured as volatile
(CR1NV[3] = 1). Volatile copy of SR1NV[4:2] when BP bits
are configured as non-volatile. User writable when BP
bits are configured as volatile.
BP1
Block Protection Volatile
2
BP0
SR1NV
Volatile
1 = Device accepts Write Registers (WRR and WRAR),
program, or erase commands.
0 = Device ignores Write Registers (WRR and WRAR),
program, or erase commands.
1
WEL
WIP
Write Enable Latch
Write in Progress
This bit is not affected by WRR or WRAR, only WREN and
WRDI commands affect this bit.
1= Device Busy, an embedded operation is in progress
such as program or erase.
Volatile
0 = Ready Device is in standby mode and can accept
commands.
0
Read Only
This bit is not affected by WRR or WRAR, it only provides
WIP status.
Status Register Write (SRWD) SR1V[7]: SRWD is a volatile copy of SR1NV[7]. This bit tracks any changes to the
non-volatile version of this bit.
Program Error (P_ERR) SR1V[6]: The Program Error Bit is used as a program operation success or failure
indication. When the Program Error bit is set to ‘1’, it indicates that there was an error in the last program
operation. This bit will also be set when the user attempts to program within a protected main memory sector,
or program within a locked OTP region. When the Program Error bit is set to ‘1’, this bit can be cleared to zero
with the Clear Status Register (CLSR) command. This is a read-only bit and is not affected by the WRR or WRAR
commands.
Erase Error (E_ERR) SR1V[5]: The Erase Error Bit is used as an Erase operation success or failure indication.
When the Erase Error bit is set to ‘1’, it indicates that there was an error in the last erase operation. This bit will
also be set when the user attempts to erase an individual protected main memory sector. The Bulk Erase
command will not set E_ERR if a protected sector is found during the command execution. When the Erase Error
bit is set to ‘1’, this bit can be cleared to zero with the Clear Status Register (CLSR) command. This is a read-only
bit and is not affected by the WRR or WRAR commands.
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Block Protection (BP2, BP1, BP0) SR1V[4:2]: These bits define the main flash array area to be
software-protected against program and erase commands. The BP bits are selected as either volatile or
non-volatile, depending on the state of the BP non-volatile bit (BPNV_O) in the configuration register CR1NV[3].
When CR1NV[3] = 0 the non-volatile version of the BP bits (SR1NV[4:2]) are used to control Block Protection and
the WRR command writes SR1NV[4:2] and updates SR1V[4:2] to the same value. When CR1NV[3] = 1 the volatile
version of the BP bits (SR1V[4:2]) are used to control Block Protection and the WRR command writes SR1V[4:2]
and does not affect SR1NV[4:2]. When one or more of the BP bits is set to ‘1’, the relevant memory area is
protected against program and erase. The Bulk Erase (BE) command can be executed only when the BP bits are
cleared to 0’s. See “Block protection” on page 71 for a description of how the BP bit values select the memory
array area protected.
Write Enable Latch (WEL) SR1V[1]: The WEL bit must be set to ‘1’ to enable program, write, or erase operations
as a means to provide protection against inadvertent changes to memory or register values. The Write Enable
(WREN) command execution sets the Write Enable Latch to ‘1’ to allow any program, erase, or write commands
to execute afterwards. The Write Disable (WRDI) command can be used to set the Write Enable Latch to ‘0’ to
prevent all program, erase, and write commands from execution. The WEL bit is cleared to 0 at the end of any
successful program, write, or erase operation. Following a failed operation the WEL bit may remain set and
should be cleared with a WRDI command following a CLSR command. After a power down / power up sequence,
hardware reset, or software reset, the Write Enable Latch is set to ‘0’ The WRR or WRAR command does not affect
this bit.
Write In Progress (WIP) SR1V[0]: Indicates whether the device is performing a program, write, erase operation,
or any other operation, during which a new operation command will be ignored. When the bit is set to ‘1’, the
device is busy performing an operation. While WIP is 1, only Read Status (RDSR1 or RDSR2), Read Any Register
(RDAR), Erase Suspend (ERSP), Program Suspend (PGSP), Clear Status Register (CLSR), and Software Reset
(RESET) commands are accepted. ERSP and PGSP will only be accepted if memory array erase or program opera-
tions are in progress. The status register E_ERR and P_ERR bits are updated while WIP = 1. When P_ERR or E_ERR
bits are set to one, the WIP bit will remain set to one indicating the device remains busy and unable to receive
new operation commands. A Clear Status Register (CLSR) command must be received to return the device to
standby mode. When the WIP bit is cleared to 0 no operation is in progress. This is a read-only bit.
7.5.2
Status Register 2 Volatile (SR2V)
Related Commands: Read Status Register 2 (RDSR2 07h), Read Any Register (RDAR 65h). Status Register-2 does
not have user programmable non-volatile bits, all defined bits are volatile read only status. The default state of
these bits are set by hardware.
Table 23
Status Register 2 Volatile (SR2V)
Bits
7
Field name
Function
Type
Default state
Description
6
5
RFU
Reserved
–
Reserved for Future Use.
4
3
1 = Sector Erase Status command result = Erase
Completed.
0
2
ESTAT
Erase Status
0 = Sector Erase Status command result = Erase Not
Completed.
Volatile
Read Only
1 = In erase suspend mode.
1
0
ES
PS
Erase Suspend
0 = Not in erase suspend mode.
1 = In program suspend mode.
Program Suspend
0 = Not in program suspend mode.
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Erase Status (ESTAT) SR2V[2]: The Erase Status bit indicates whether the sector, selected by an immediately
preceding Erase status command, completed the last erase command on that sector. The Erase Status command
must be issued immediately before reading SR2V to get valid erase status. Reading SR2V during a program or
erase suspend does not provide valid erase status. The erase status bit can be used by system software to detect
any sector that failed its last erase operation. This can be used to detect erase operations failed due to loss of
power during the erase operation.
Erase Suspend (ES) SR2V[1]: The Erase Suspend bit is used to determine when the device is in Erase Suspend
mode. This is a status bit that cannot be written by the user. When Erase Suspend bit is set to ‘1’, the device is in
erase suspend mode. When Erase Suspend bit is cleared to 0, the device is not in erase suspend mode. Refer to
“Erase or Program Suspend (EPS 85h, 75h, B0h)” on page 115 for details about the Erase Suspend / Resume
commands.
Program Suspend (PS) SR2V[0]: The Program Suspend bit is used to determine when the device is in Program
Suspend mode. This is a status bit that cannot be written by the user. When Program Suspend bit is set to ‘1’, the
device is in program suspend mode. When the Program Suspend bit is cleared to 0, the device is not in program
suspend mode. Refer to “Erase or Program Suspend (EPS 85h, 75h, B0h)” on page 115 for details.
7.5.3
Configuration Register 1
Configuration Register 1 controls certain interface and data protection functions. The register bits can be
changed using the WRR command with sixteen input cycles or with the WRAR command.
7.5.3.1
Configuration Register 1 Non-volatile (CR1NV)
Related Commands: Write Registers (WRR 01h), Read Any Register (RDAR 65h), Write Any Register (WRAR 71h).
Table 24
Configuration Register 1 Non-volatile (CR1NV)
Default
state
Bits Field name
Function
Type
Description
7
0
0
RFU
6
Reserved for Future Use
Non-volatile
Reserved.
Configures Start of Block
Protection
1 = BP starts at bottom (Low address).
0 = BP starts at top (High address).
5
4
3
TBPROT_O
RFU
OTP
RFU
Reserved for Future Use
Reserved.
Configures BP2-0 in Status
Register
1 = Volatile
BPNV_O
0 = Non-volatile
OTP
0
1 = 4-KB physical sectors at top (high address).
0 = 4-KB physical sectors at bottom (low address).
RFU in uniform sector configuration.
Configures Parameter
Sectors location
2
TBPARM_O
1
0
QUAD_NV Quad Non-volatile
FREEZE_D FREEZE Default
Non-volatile
Provides the default state for the QUAD bit.
Non-volatile
Read Only
Provides the default state for the Freeze bit. Not user
programmable.
Top or Bottom Protection (TBPROT_O) CR1NV[5]: This bit defines the operation of the Block Protection bits
BP2, BP1, and BP0 in the Status Register. As described in the status register section, the BP2-0 bits allow the user
to optionally protect a portion of the array, ranging from 1/64, ¼, ½, and so on, up to the entire array. When
TBPROT_O is set to ‘0’, the Block Protection is defined to start from the top (maximum address) of the array. When
TBPROT_O is set to ‘1’, the Block Protection is defined to start from the bottom (zero address) of the array. The
TBPROT_O bit is OTP and set to ‘0’ when shipped from Infineon. If TBPROT_O is programmed to 1, writing the bit
with a zero does not change the value or set the Program Error bit (P_ERR in SR1V[6]).
The desired state of TBPROT_O must be selected during the initial configuration of the device during system
manufacture; before the first program or erase operation on the main flash array. TBPROT_O must not be
programmed after programming or erasing is done in the main flash array.
CR1NV[4]: Reserved for Future Use.
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Block Protection Non-volatile (BPNV_O) CR1NV[3]: The BPNV_O bit defines whether the BP_NV 2-0 bits or the
BP 2-0 bits in the Status Register are selected to control the Block Protection feature. The BPNV_O bit is OTP and
cleared to ‘0’ with the BP_NV bits cleared to ‘000’ when shipped from Infineon. When BPNV_O is set to ‘0’ the
BP_NV 2-0 bits in the Status Register are selected to control the block protection and are written by the WRR
command. The time required to write the BP_NV bits is tW. When BPNV is set to ‘1’, the BP2-0 bits in the Status
Register are selected to control the block protection and the BP_NV 2-0 bits will be programmed to binary ‘111’.
This will cause the BP 2-0 bits to be set to binary 111 after POR, hardware reset, or command reset. When BPNV
is set to ‘1’, the WRR command writes only the volatile version of the BP bits (SR1V[4:2]). The non-volatile version
of the BP bits (SR1NV[4:2]) are no longer affected by the WRR command. This allows the BP bits to be written an
unlimited number of times because they are volatile and the time to write the volatile BP bits is the much faster
tCS volatile register write time. If BPNV_O is programmed to 1, writing the bit with a zero does not change the
value or set the Program Error bit (P_ERR in SR1V[6]).
TBPARM_O CR1NV[2]: TBPARM_O defines the logical location of the parameter block. The parameter block
consists of eight 4-KB parameter sectors, which replace a 32 KB portion of the highest or lowest address sector.
When TBPARM_O is set to ‘1’, the parameter block is in the top of the memory array address space. When
TBPARM_O is set to ‘0’ the parameter block is at the Bottom of the array. TBPARM_O is OTP and set to ‘0’ when it
ships from Infineon. If TBPARM_O is programmed to 1, writing the bit with a zero does not change the value or
set the Program Error bit (P_ERR in SR1V[6]).
The desired state of TBPARM_O must be selected during the initial configuration of the device during system
manufacture; before the first program or erase operation on the main flash array. TBPARM_O must not be
programmed after programming or erasing is done in the main flash array.
TBPROT_O can be set or cleared independent of the TBPARM_O bit. Therefore, the user can elect to store
parameter information from the bottom of the array and protect boot code starting at the top of the array, or vice
versa. Or, the user can elect to store and protect the parameter information starting from the top or bottom
together.
When the memory array is configured as uniform sectors, the TBPARM_O bit is Reserved for Future Use (RFU) and
has no effect because all sectors are uniform size.
Quad Data Width Non-volatile (QUAD_NV) CR1NV[1]: Provides the default state for the QUAD bit in CR1V[1].
The WRR or WRAR command affects this bit. Non-volatile selection of QPI mode, by programming CR2NV[6] = 1,
will also program QUAD_NV = 1 to change the non-volatile default to Quad data width mode. While QPI mode is
selected by CR2V[6] = 1, the Quad_NV bit cannot be cleared to 0.
Freeze Protection Default (FREEZE) CR1NV[0]: Provides the default state for the FREEZE bit in CR1V[0]. This bit
is not user programmable.
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7.5.3.2
Configuration Register 1 Volatile (CR1V)
Related Commands: Read Configuration Register (RDCR 35h), Write Registers (WRR 01h), Read Any Register
(RDAR 65h), Write Any Register (WRAR 71h). This is the register displayed by the RDCR command.
Table 25
Configuration Register 1 Volatile (CR1V)
Default
state
Bits Field name
Function
Type
Description
7
RFU
6
Reserved for Future Use
Volatile
Reserved
Volatile
5
TBPROT Volatile copy of TBPROT_O
Not user writable. See CR1NV[5] TBPROT_O.
Read Only
4
3
2
RFU
Reserved for Future Use
Volatile copy of BPNV_O
RFU
Reserved
BPNV
Not user writable. See CR1NV[3] BPNV_O.
Not user writable.See CR1NV[2] TBPARM_O.
Volatile
Read Only
TBPARM Volatile copy of TBPARM_O
CR1NV
1 = Quad
0 = Dual or Serial
1
0
QUAD
Quad I/O Mode
The WRR command writes the Non-Volatile
Quad bit (CR1NV[1]). See full description below.
Volatile
Lock current state of Block Protection control
bits, and OTP regions.
Lock-Down Block Protection
until next power cycle
FREEZE
1 = Block Protection and OTP locked
0 = Block Protection and OTP unlocked
TBPROT, BPNV, and TBPARM CR1V[5,3,2]: These bits are volatile copies of the related non-volatile bits of CR1NV.
These bits track any changes to the related non-volatile version of these bits.
Quad Data Width (QUAD) CR1V[1]: When set to ‘1’, this bit switches the data width of the device to 4-bit Quad
mode. That is, WP# becomes IO2 and IO3 / RESET# becomes an active I/O signal when CS# is LOW or the RESET#
input when CS# is HIGH. The WP# input is not monitored for its normal function and is internally set to HIGH
(inactive). The commands for Serial, and Dual I/O Read still function normally but, there is no need to drive the
WP# input for those commands when switching between commands using different data path widths. Similarly,
there is no requirement to drive the IO3 / RESET# during those commands (while CS# is LOW).
The QUAD bit must be set to one when using the Quad I/O Read, DDR Quad I/O Read, QPI mode (CR2V[6] = 1), and
Read Quad ID commands. While QPI mode is selected by CR2V[6] = 1, the Quad bit cannot be cleared to 0. The
WRR command writes the non-volatile version of the Quad bit (CR1NV[1]), which also causes an update to the
volatile version CR1V[1]. The WRR command can not write the volatile version CR1V[1] without first affecting the
non-volatile version CR1NV[1]. The WRAR command must be used when it is desired to write the volatile Quad
bit CR1V[1] without affecting the non-volatile version CR1NV[1].
Freeze Protection (FREEZE) CR1V[0]: The Freeze Bit, when set to ‘1’, locks the current state of the Block
Protection control bits and OTP area:
• BPNV_2-0 bits in the non-volatile Status Register 1 (SR1NV[4:2])
• BP 2-0 bits in the volatile Status Register 1 (SR1V[4:2])
• TBPROT_O, TBPARM_O, and BPNV_O bits in the non-volatile Configuration Register (CR1NV[5,3, 2])
• TBPROT, TBPARM, and BPNV bits in the volatile Configuration Register (CR1V[5, 3, 2]) are indirectly protected
in that they are shadows of the related CR1NV OTP bits and are read only
• the entire OTP memory space
• Any attempt to change the above listed bits while FREEZE = 1 is prevented.
• The WRR command does not affect the listed bits and no error status is set.
• The WRAR command does not affect the listed bits and no error status is set.
• The OTPP command, with an address within the OTP area, fails and the P-ERR status is set.
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As long as the FREEZE bit remains cleared to logic 0 the Block Protection control bits and FREEZE are writable,
and the OTP address space is programmable.
Once the FREEZE bit has been written to a logic 1 it can only be cleared to a logic 0 by a power-off to power-on
cycle or a hardware reset. Software reset will not affect the state of the FREEZE bit.
The CR1V[0] FREEZE bit is volatile and the default state of FREEZE after power-on comes from FREEZE_D in
CR1NV[0]. The FREEZE bit can be set in parallel with updating other values in CR1V by a single WRR or WRAR
command.
The FREEZE bit does not prevent the WRR or WRAR commands from changing the SRWD_NV (SR1NV[7]), Quad_NV
(CR1NV[1]), or QUAD (CR1V[1]) bits.
7.5.4
Configuration Register 2
Configuration Register 2 controls certain interface functions. The register bits can be read and changed using the
Read Any Register and Write Any Register commands. The non-volatile version of the register provides the ability
to set the POR, hardware reset, or software reset state of the controls. These configuration bits are OTP and may
only have their default state changed to the opposite value one time during system configuration. The volatile
version of the register controls the feature behavior during normal operation.
7.5.4.1
Configuration Register 2 Non-volatile (CR2NV)
Related Commands: Read Any Register (RDAR 65h), Write Any Register (WRAR 71h).
Table 26
Configuration Register 2 Non-volatile (CR2NV)
Default
Bits
Field name
Function
Type
Description
state
1 = 4-byte address
0 = 3-byte address
7
6
AL_NV
Address Length
0
1 = Enabled – QPI (4-4-4) protocol in use.
0 = Disabled – Legacy SPI protocols in use, instruction
is always serial on SI.
QA_NV
QPI
0
0
1 = Enabled – IO3 is used as RESET# input when CS# is
HIGH or Quad Mode is disabled CR1V[1] = 0.
0 = Disabled – IO3 has no alternate function, hardware
reset is disabled.
5
IO3R_NV
RFU
IO3 Reset
Reserved
OTP
4
3
2
1
0
0
1
0
0
0
Reserved for Future Use
0 to 15 latency (dummy) cycles following read address
or continuous mode bits.
RL_NV
Read Latency
Note that bit 3 has a default value of 1 and may be
programmed one time to 0 but cannot be returned to
1.
Address Length Non-volatile CR2NV[7]: This bit controls the POR, hardware reset, or software reset state of the
expected address length for all commands that require address and are not fixed 3-byte only or 4-byte (32 bit)
only address. Most commands that need an address are legacy SPI commands that traditionally used 3-byte
(24 bit) address. For device densities greater than 128 Mb a 4-byte address is required to access the entire
memory array. The address length configuration bit is used to change most 3-byte address commands to expect
4-byte address. See Table 45 for command address length. This non-volatile Address Length configuration bit
enables the device to start immediately (boot) in 4-byte address mode rather than the legacy 3-byte address
mode.
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QPI Non-volatile CR2NV[6]: This bit controls the POR, hardware reset, or software reset state of the expected
instruction width for all commands. Legacy SPI commands always send the instruction one bit wide (serial I/O)
on the SI (IO0) signal. The S25FS512S also supports the QPI mode in which all transfers between the host system
and memory are 4 bits wide on IO0 to IO3, including all instructions. This non-volatile QPI configuration bit
enables the device to start immediately (boot) in QQPIPI mode rather than the legacy serial instruction mode.
When this bit is programmed to QPI mode, the QUAD_NV bit is also programmed to Quad mode (CR1NV[1] = 1).
The recommended procedure for moving to QPI mode is to first use the WRAR command to set CR2V[6] = 1, QPI
mode. The volatile register write for QPI mode has a short and well defined time (tCS) to switch the device
interface into QPI mode. Following commands can then be immediately sent in QPI protocol. The WRAR
command can be used to program CR2NV[6] = 1, followed by polling of SR1V[0] to know when the programming
operation is completed. Similarly, to exit QPI mode, the WRAR command is used to clear CR2V[6] = 0. CR2NV[6]
cannot be erased to 0 because it is OTP.
IO3 Reset Non-volatile CR2NV[5]: This bit controls the POR, hardware reset, or software reset state of the IO3
signal behavior. Most legacy SPI devices do not have a hardware reset input signal due to the limited signal count
and connections available in traditional SPI device packages. The S25FS512S provides the option to use the IO3
signal as a hardware reset input when the IO3 signal is not in use for transferring information between the host
system and the memory. This non-volatile IO3 Reset configuration bit enables the device to start immediately
(boot) with IO3 enabled for use as a RESET# signal.
Read Latency Non-volatile CR2NV[3:0]: This bit controls the POR, hardware reset, or software reset state of the
read latency (dummy cycle) delay in all variable latency read commands. The following read commands have a
variable latency period between the end of address or mode and the beginning of read data returning to the host:
• Fast Read
• Dual I/O Read
• Quad I/O Read
• DDR Quad I/O Read
• OTPR
• RDAR
This non-volatile read latency configuration bit sets the number of read latency (dummy cycles) in use so the
device can start immediately (boot) with an appropriate read latency for the host system.
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Table 27
Latency code (cycles) versus frequency
Read command maximum frequency (MHz)
Fast Read (1-1-1)
OTPR (1-1-1)
RDAR (1-1-1)
RDAR (4-4-4)
DDR Quad I/O (1-4-4)
DDR Quad I/O (4-4-4)
[44]
Quad I/O (1-4-4)
Dual I/O (1-2-2)
Latency code
Quad I/O (4-4-4)
Mode cycles = 0
Mode cycles = 4
Mode cycles = 2
Mode cycles = 1
0
1
50
66
80
92
40
53
N/A
22
34
45
57
68
2
80
104
116
129
66
3
92
80
4
104
116
129
92
5
104
116
129
6
7
8
9
10
11
12
13
14
15
133
80
133
133
Notes
41. SCK frequency > 133 MHz SDR, or 80 MHz DDR is not supported by this family of devices.
42. The Dual I/O, Quad I/O, QPI, DDR Quad I/O, and DDR QPI, command protocols include Continuous Read Mode bits
following the address. The clock cycles for these bits are not counted as part of the latency cycles shown in the table.
Example: the legacy Quad I/O command has 2 Continuous Read Mode cycles following the address. Therefore, the
legacy Quad I/O command without additional read latency is supported only up to the frequency shown in the table
for a read latency of 0 cycles. By increasing the variable read latency the frequency of the Quad I/O command can be
increased to allow operation up to the maximum supported 133 MHz frequency.
43. Other read commands have fixed latency, e.g. Read always has zero read latency. RSFDP always has eight cycles of
latency.
44. DDR QPI is only supported for Latency Cycles 1 through 5 and for clock frequency of up to 68 MHz.
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7.5.4.2
Configuration Register 2 Volatile (CR2V)
Related Commands: Read Any Register (RDAR 65h), Write Any Register (WRAR 71h), 4BAM.
Table 28
Configuration Register 2 Volatile (CR2V)
Default
Field
Bits
Function
Type
Description
name
state
Address
1 = 4-byte address
0 = 3-byte address
7
6
AL
Length
1 = Enabled – QPI (4-4-4) protocol in use.
0 = Disabled – Legacy SPI protocols in use, instruction is always
serial on SI.
QA
QPI
1 = Enabled – IO3 is used as RESET# input when CS# is HIGH or Quad
Mode is disabled CR1V[1] = 0.
5
IO3R_S IO3 Reset
0 = Disabled – IO3 has no alternate function, hardware reset is
disabled.
Volatile CR2NV
4
3
2
1
0
RFU
RL
Reserved
Reserved for Future Use
0 to 15 latency (dummy) cycles following read address or
continuous mode bits.
Read Latency
Address Length CR2V[7]: This bit controls the expected address length for all commands that require address
and are not fixed 3-byte only or 4-byte (32 bit) only address. See Table 45 for command address length. This
volatile Address Length configuration bit enables the address length to be changed during normal operation. The
4-byte address mode (4BAM) command directly sets this bit into 4-byte address mode.
QPI CR2V[6]: This bit controls the expected instruction width for all commands. This volatile QPI configuration
bit enables the device to enter and exit QPI mode during normal operation. When this bit is set to QPI mode, the
QUAD bit is also set to Quad mode (CR1V[1] = 1). When this bit is cleared to legacy SPI mode, the QUAD bit is not
affected.
IO3 Reset CR2V[5]: This bit controls the IO3 / RESET# signal behavior. This volatile IO3 Reset configuration bit
enables the use of IO3 as a RESET# input during normal operation.
Read Latency CR2V[3:0]: This bit controls the read latency (dummy cycle) delay in variable latency read
commands These volatile configuration bits enable the user to adjust the read latency during normal operation
to optimize the latency for different commands or, at different operating frequencies, as needed.
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7.5.5
Configuration Register 3
Configuration Register 3 controls certain command behaviors. The register bits can be read and changed using
the Read Any Register and Write Any Register commands. The non-volatile register provides the POR, hardware
reset, or software reset state of the controls. These configuration bits are OTP and may be programmed to their
opposite state one time during system configuration if needed. The volatile version of Configuration Register 3
allows the configuration to be changed during system operation or testing.
7.5.5.1
Configuration Register 3 Non-volatile (CR3NV)
Related Commands: Read Any Register (RDAR 65h), Write Any Register (WRAR 71h).
Table 29
Configuration Register 3 Non-volatile (CR3NV)
Default
Bits
Field name
Function
Type
Description
state
7
6
RFU
Reserved
Reserved for Future Use
1 = Blank Check during erase enabled
0 = Blank Check disabled
5
4
3
BC_NV
02h_NV
20h_NV
Blank Check
Page Buffer Wrap
4 KB Erase
1 = Wrap at 512 bytes
0 = Wrap at 256 bytes
OTP
0
1 = 4 KB Erase disabled (Uniform Sector Architecture)
0 = 4 KB Erase enabled (Hybrid Sector Architecture)
Clear Status /
1 = 30h is Erase or Program Resume command
0 = 30h is clear status command
2
1
0
30h_NV
RFU
Resume Select
Reserved
Reserved for Future Use
Legacy Software
Reset Enable
1 = F0h Software Reset is enabled
F0h_NV
0 = F0h Software Reset is disabled (ignored)
Blank Check Non-volatile CR3NV[5]: This bit controls the POR, hardware reset, or software reset state of the
blank check during erase feature.
02h Non-volatile CR3NV[4]: This bit controls the POR, hardware reset, or software reset state of the page
programming buffer address wrap point.
20h Non-volatile CR3NV[3]: This bit controls the POR, hardware reset, or software reset state of the availability
of 4-KB parameter sectors in the main flash array address map.
30h Non-volatile CR3NV[2]: This bit controls the POR, hardware reset, or software reset state of the 30h
instruction code is used.
F0h Non-volatile CR3NV[0]: This bit controls the POR, hardware reset, or software reset state of the availability
of the Infineon legacy FL-S family software reset instruction.
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7.5.5.2
Configuration Register 3 Volatile (CR3V)
Related Commands: Read Any Register (RDAR 65h), Write Any Register (WRAR 71h).
Table 30
Configuration Register 3 Volatile (CR3V)
Default
state
Bits Field name
Function
Reserved
Type
Description
Reserved for Future Use
7
RFU
6
1 = Blank Check during erase enabled
0 = Blank Check disabled
Volatile
5
4
3
BC_V
02h_V
20h_V
Blank Check
Page Buffer Wrap
4 KB Erase
1 = Wrap at 512 bytes
0 = Wrap at 256 bytes
CR3NV
Volatile,
1 = 4 KB Erase disabled (Uniform Sector Architecture)
0 = 4 KB Erase enabled (Hybrid Sector Architecture)
Read Only
Clear Status /
1 = 30h is Erase or Program Resume command
0 = 30h is clear status command
2
1
0
30h_V
RFU
Resume Select
Reserved
Volatile
Reserved for Future Use
Legacy Software
Reset Enable
1= F0h Software Reset is enabled
F0h_V
0= F0h Software Reset is disabled (ignored)
Blank Check Volatile CR3V[5]: This bit controls the blank check during erase feature. When this feature is
enabled an erase command first evaluates the erase status of the sector. If the sector is found to have not
completed its last erase successfully, the sector is unconditionally erased. If the last erase was successful, the
sector is read to determine if the sector is still erased (blank). The erase operation is started immediately after
finding any programmed zero. If the sector is already blank (no programmed zero bit found) the remainder of the
erase operation is skipped. This can dramatically reduce erase time when sectors being erased do not need the
erase operation. When enabled the blank check feature is used within the parameter erase, sector erase, and bulk
erase commands. When blank check is disabled an erase command unconditionally starts the erase operation.
02h Volatile CR3V[4]: This bit controls the page programming buffer address wrap point. Legacy SPI devices
generally have used a 256-byte page programming buffer and defined that if data is loaded into the buffer beyond
the 255-byte location, the address at which additional bytes are loaded would be wrapped to address zero of the
buffer. The S25FS512S provides a 512-byte page programming buffer that can increase programming perfor-
mance. For legacy software compatibility, this configuration bit provides the option to continue the wrapping
behavior at the 256-byte boundary or to enable full use of the available 512-byte buffer by not wrapping the load
address at the 256-byte boundary.
20h Volatile CR3V[3]: This bit controls the availability of 4-KB parameter sectors in the main flash array address
map. The parameter sectors can overlay the highest or lowest 32-KB address range of the device or they can be
removed from the address map so that all sectors are uniform size. This bit shall not be written to a value different
than the value of CR3NV[3]. The value of CR3V[3] may only be changed by writing CR3NV[3].
30h Volatile CR3V[2]: This bit controls how the 30h instruction code is used. The instruction may be used as a
clear status command or as an alternate program / erase resume command. This allows software compatibility
with either Infineon legacy SPI devices or alternate vendor devices.
F0h Volatile CR3V[0]: This bit controls the availability of the Infineon legacy FL-S family software reset
instruction. The S25FS512S supports the industry common 66h + 99h instruction sequence for software reset.
This configuration bit allows the option to continue use of the legacy F0h single command for software reset.
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7.5.6
Configuration Register 4
Configuration Register 4 controls the main flash array read commands burst wrap behavior. The burst wrap
configuration does not affect commands reading from areas other than the main flash array e.g. read commands
for registers or OTP array. The non-volatile version of the register provides the ability to set the start up (boot)
state of the controls as the contents are copied to the volatile version of the register during the POR, hardware
reset, or software reset. The volatile version of the register controls the feature behavior during normal
operation. The register bits can be read and changed using the Read Any Register and Write Any Register
commands. The volatile version of the register can also be written by the Set Burst Length (C0h) command.
7.5.6.1
Configuration Register 4 Non-volatile (CR4NV)
Related Commands: Read Any Register (RDAR 65h), Write Any Register (WRAR 71h).
Table 31
Configuration Register 4 Non-volatile (CR4NV)
Bits
Field name
Function
Type
Default state
Description
7
6
5
OI_O
Output Impedance
See Table 32.
0 = Wrap Enabled
1 = Wrap Disabled
4
WE_O
Wrap Enable
OTP
0
3
2
1
RFU
RFU
Reserved
Reserved
Reserved for Future Use
00 = 8-byte wrap
01 = 16-byte wrap
10 = 32-byte wrap
11 = 64-byte wrap
WL_O
Wrap Length
0
Output Impedance Non-volatile CR4NV[7:5]: These bits control the POR, hardware reset, or software reset
state of the IO signal output impedance (drive strength). Multiple drive strength are available to help match the
output impedance with the system printed circuit board environment to minimize overshoot and ringing. These
non-volatile output impedance configuration bits enable the device to start immediately (boot) with the appro-
priate drive strength.
Table 32
Output impedance control
CR4NV[7:5]
impedance selection
Typical impedance to V
Typical impedance to V
SS
CC
Notes
()
()
000
001
010
011
100
101
110
111
47
45
105
64
45
35
28
24
21
Factory default
124
71
47
34
–
26
22
18
Wrap Enable Non-volatile CR4NV[4]: This bit controls the POR, hardware reset, or software reset state of the
wrap enable. The commands affected by Wrap Enable are: Quad I/O Read, and DDR Quad I/O Read. This config-
uration bit enables the device to start immediately (boot) in wrapped burst read mode rather than the legacy
sequential read mode.
Wrap Length Non-volatile CR4NV[1:0]: These bits controls the POR, hardware reset, or software reset state of
the wrapped read length and alignment. These non-volatile configuration bits enable the device to start immedi-
ately (boot) in wrapped burst read mode rather than the legacy sequential read mode.
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7.5.6.2
Configuration Register 4 Volatile (CR4V)
Related Commands: Read Any Register (RDAR 65h), Write Any Register (WRAR 71h), Set Burst Length (SBL C0h).
Table 33
Configuration Register 4 Volatile (CR4V)
Default
state
Bits
Field name
Function
Type
Description
7
6
5
OI
Output Impedance
See Table 32.
0 = Wrap Enabled
1 = Wrap Disabled
4
WE
Wrap Enable
Reserved
Volatile
CR4NV
3
2
1
RFU
Reserved for Future Use
00 = 8-byte wrap
01 = 16-byte wrap
10 = 32-byte wrap
11 = 64-byte wrap
WL
Wrap Length
0
Output Impedance CR2V[7:5]: These bits control the IO signal output impedance (drive strength). This volatile
output impedance configuration bit enables the user to adjust the drive strength during normal operation.
Wrap Enable CR4V[4]: This bit controls the burst wrap feature. This volatile configuration bit enables the device
to enter and exit burst wrapped read mode during normal operation.
Wrap Length CR4V[1:0]: These bits controls the wrapped read length and alignment during normal operation.
These volatile configuration bits enable the user to adjust the burst wrapped read length during normal
operation.
7.5.7
ECC Status Register (ECCSR)
Related Commands: ECC Read (ECCRD 18h or 19h). ECCSR does not have user programmable non-volatile bits,
all defined bits are volatile read only status. The default state of these bits are set by hardware.
The status of ECC in each ECC unit is provided by the 8-bit ECC Status Register (ECCSR). The ECC Register Read
command is written followed by an ECC unit address. The contents of the status register then indicates, for the
selected ECC unit, whether there is an error in the ECC, the ECC unit data, or that ECC is disabled for that ECC unit.
Table 34
ECC Status Register (ECCSR)
Default
state
Bits
Field name
Function
Reserved
Type
Description
Reserved for Future Use
7 to 3
RFU
1 = Single Bit Error found in the ECC unit error
correction code
2
EECC
Error in ECC
0 = No error.
Volatile,
0
Read only
1 = Single Bit Error corrected in ECC unit data.
0 = No error.
1
0
EECCD
ECCDI
Error in ECC unit data
ECC Disabled
1 = ECC is disabled in the selected ECC unit.
0 = ECC is enabled in the selected ECC unit.
ECCSR[2] = 1 indicates an error was corrected in the ECC. ECCSR[1] = 1 indicates an error was corrected in the ECC
unit data. ECCSR[0] = 1 indicates the ECC is disabled. The default state of “0” for all these bits indicates no failures
and ECC is enabled.
The ECCSR[7:3] are reserved. These have undefined high or low values that can change from one ECC status read
to another. These bits should be treated as “don’t care” and ignored by any software reading status.
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7.5.8
ASP Register (ASPR)
Related Commands: ASP Read (ASPRD 2Bh) and ASP Program (ASPP 2Fh), Read Any Register (RDAR 65h), Write
Any Register (WRAR 71h).
The ASP register is a 16-bit OTP memory location used to permanently configure the behavior of Advanced Sector
Protection (ASP) features. ASPR does not have user programmable volatile bits, all defined bits are OTP.
The default state of the ASPR bits are programmed by Infineon.
Table 35
ASP Register (ASPR)
Field
Default
state
Bits
Function
Type
Description
name
15 to 9
8
7
6
5
4
3
2
1
0
RFU
Reserved
Reserved for Future Use
OTP
RFU
1
PWDMLB
PSTMLB
RFU
Password Protection
Mode Lock Bit
0 = Password Protection Mode permanently enabled.
1 = Password Protection Mode not permanently enabled.
Reserved
Reserved for Future Use
Password Protection Mode Lock Bit (PWDMLB) ASPR[2]: When programmed to 0, the Password Protection
Mode is permanently selected.
Persistent Protection Mode Lock Bit (PSTMLB) ASPR[1]: When programmed to 0, the Persistent Protection
Mode is permanently selected.
PWDMLB (ASPR[2]) and PSTMLB (ASPR[1]) are mutually exclusive, only one may be programmed to zero.
ASPR bits may only be programmed while ASPR[2:1] = 11b. Attempting to program ASPR bits when ASPR[2:1] is
not = 11b will result in a programming error with P_ERR (SR1V[6]) set to ‘1’. After the ASP protection mode is
selected by programming ASPR[2:1] = 10b or 01b, the state of all ASPR bits are locked and permanently protected
from further programming. Attempting to program ASPR[2:1] = 00b will result in a programming error with P_ERR
(SR1V[6]) set to ‘1’.
Similarly, OTP configuration bits listed in the ASP Register description (see “ASP register” on page 74), may only
be programmed while ASPR[2:1] = 11b. The OTP configuration must be selected before selecting the ASP
protection mode. The OTP configuration bits are permanently protected from further change when the ASP
protection mode is selected. Attempting to program these OTP configuration bits when ASPR[2:1] is not = 11b
will result in a programming error with P_ERR (SR1V[6]) set to ‘1’.
The ASP protection mode should be selected during system configuration to ensure that a malicious program
does not select an undesired protection mode at a later time. By locking all the protection configuration via the
ASP mode selection, later alteration of the protection methods by malicious programs is prevented.
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7.5.9
Password Register (PASS)
Related Commands: Password Read (PASSRD E7h) and Password Program (PASSP E8h), Read Any Register (RDAR
65h), Write Any Register (WRAR 71h). The PASS register is a 64-bit OTP memory location used to permanently
define a password for the Advanced Sector Protection (ASP) feature. PASS does not have user programmable
volatile bits, all defined bits are OTP. A volatile copy of PASS is used to satisfy read latency requirements but the
volatile register is not user writable or further described.
Table 36
Password Register (PASS)
Field
Bits
Function
Type
Default state
Description
name
Non-volatile OTP storage of 64-bit password. The
password is no longer readable after the password
protection mode is selected by programming ASP
register bit 2 to zero.
Hidden
Password
63 to 0 PWD
OTP FFFFFFFF-FFFFFFFFh
7.5.10
PPB Lock Register (PPBL)
Related Commands: PPB Lock Read (PLBRD A7h, PLBWR A6h), Read Any Register (RDAR 65h).
PPBL does not have separate user programmable non-volatile bits, all defined bits are volatile read only status.
The default state of the RFU bits is set by hardware. The default state of the PPBLOCK bit is defined by the ASP
protection mode bits in ASPR[2:1]. There is no non-volatile version of the PPBL register.
The PPBLOCK bit is used to protect the PPB bits. When PPBL[0] = 0, the PPB bits can not be programmed.
Table 37
PPB Lock Register (PPBL)
Field
Bits
Function
Reserved
Type
Default state
Description
Reserved for Future Use
name
7 to 1
RFU
Volatile 00h
ASPR[2:1] = 1xb =
Persistent Protection Mode
= 1
Volatile
Read
Protect PPB
Array
0 = PPB array protected
0
PPBLOCK
ASPR[2:1] = 01b =
Password Protection Mode
= 0
1 = PPB array may be programmed or erased.
Only
7.5.11
PPB Access Register (PPBAR)
Related Commands: PPB Read (PPBRD FCh or 4PPBRD E2h), PPB Program (PPBP FDh or 4PPBP E3h), PPB Erase
(PPBE E4h).
PPBAR does not have user writable volatile bits, all PPB array bits are non-volatile. The default state of the PPB
array is erased to FFh by Infineon. There is no volatile version of the PPBAR register.
Table 38
PPB Access Register (PPBAR)
Field
Default
state
Bits
Function
Type
Description
name
00h = PPB for the sector addressed by the PPBRD or PPBP
command is programmed to 0, protecting that sector from
program or erase operations.
Read or
7 to 0
PPB
Program per Non-volatile
sector PPB
FFh
FFh = PPB for the sector addressed by the PPBRD command
is 1, not protecting that sector from program or erase opera-
tions.
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7.5.12
DYB Access Register (DYBAR)
Related Commands: DYB Read (DYBRD FAh or 4DYBRD E0h) and DYB Write (DYBWR FBh or 4DYBWR E1h).
DYBAR does not have user programmable non-volatile bits, all bits are a representation of the volatile bits in the
DYB array. The default state of the DYB array bits is set by hardware. There is no non-volatile version of the DYBAR
register.
Table 39
DYB Access Register (DYBAR)
Default
Field
Bits
Function
Type
Description
name
state
00h = DYB for the sector addressed by the DYBRD or DYBWR
command is cleared to 0, protecting that sector from program or
erase operations.
Read or Write
persectorDYB
7to0
DYB
Volatile
FF
FFh = DYB for the sector addressed by the DYBRD or DYBWR
command is set to ‘1’, not protecting that sector from program or
erase operations.
7.5.13
SPI DDR Data Learning Registers
Related Commands: Program NVDLR (PNVDLR 43h), Write VDLR (WVDLR 4Ah), Data Learning Pattern Read
(DLPRD 41h), Read Any Register (RDAR 65h), Write Any Register (WRAR 71h).
The Data Learning Pattern (DLP) resides in an 8-bit non-volatile Data Learning Register (NVDLR) as well as an 8-bit
Volatile Data Learning Register (VDLR). When shipped from Infineon, the NVDLR value is 00h. Once programmed,
the NVDLR cannot be reprogrammed or erased; a copy of the data pattern in the NVDLR will also be written to the
VDLR. The VDLR can be written to at any time, but on power cycles the data pattern will revert back to what is in
the NVDLR. During the learning phase described in the SPI DDR modes, the DLP will come from the VDLR. Each IO
will output the same DLP value for every clock edge. For example, if the DLP is 34h (or binary 00110100) then
during the first clock edge all IO’s will output 0; subsequently, the 2nd clock edge all I/O’s will output 0, the 3rd
will output 1, etc.
When the VDLR value is 00h, no preamble data pattern is presented during the dummy phase in the DDR
commands.
Table 40
Non-volatile Data Learning Register (NVDLR)
Field
name
Default
state
Bits
Function
Type
Description
OTP value that may be transferred to the host during DDR
read command latency (dummy) cycles to provide a training
pattern to help the host more accurately center the data
capture point in the received data bits.
Non-volatile
7 to 0
NVDLP Data Learning
Pattern
OTP
00h
Table 41
Bits
Volatile Data Learning Register (VDLR)
Field
Default
state
Function
Type
Description
name
Takes the
value of
Volatile copy of the NVDLP used to enable and deliver the
Data Learning Pattern (DLP) to the outputs. The VDLP may
be changed by the host during system operation.
Volatile Data
Learning
Pattern
7 to 0
VDLP
Volatile
NVDLR
during POR
or Reset
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8
Data protection
8.1
Secure silicon region (OTP)
The device has a 1024-byte One Time Program (OTP) address space that is separate from the main flash array.
The OTP area is divided into 32, individually lockable, 32-byte aligned and length regions.
The OTP memory space is intended for increased system security. OTP values can “mate” a flash component with
the system CPU/ASIC to prevent device substitution. See “OTP address space” on page 50, “OTP Program
(OTPP 42h)” on page 119, and “OTP Read (OTPR 4Bh)” on page 119.
8.1.1
Reading OTP memory space
The OTP Read command uses the same protocol as Fast Read. OTP Read operations outside the valid 1-KB OTP
address range will yield indeterminate data.
8.1.2
Programming OTP memory space
The protocol of the OTP programming command is the same as Page Program. The OTP Program command can
be issued multiple times to any given OTP address, but this address space can never be erased.
Automatic ECC is programmed on the first programming operation to each 16 byte region. Programming within
a 16 byte region more than once disables the ECC. It is recommended to program each 16 byte portion of each
32 byte region once so that ECC remains enabled to provide the best data integrity.
The valid address range for OTP Program is depicted in Figure 39. OTP Program operations outside the valid OTP
address range will be ignored, without P_ERR in SR1V set to ‘1’. OTP Program operations within the valid OTP
address range, while FREEZE = 1, will fail with P_ERR in SR1V set to ‘1’. The OTP address space is not protected
by the selection of an ASP protection mode. The Freeze bit (CR1V[0]) may be used to protect the OTP Address
Space.
8.1.3
Infineon programmed random number
Infineon standard practice is to program the low order 16 bytes of the OTP memory space (locations 0x0 to 0xF)
with a 128-bit random number using the Linear Congruential Random Number Method. The seed value for the
algorithm is a random number concatenated with the day and time of tester insertion.
8.1.4
Lock bytes
The LSb of each Lock byte protects the lowest address region related to the byte, the MSb protects the highest
address region related to the byte. The next higher address byte similarly protects the next higher eight regions.
The LSb bit of the lowest address Lock Byte protects the higher address 16 bytes of the lowest address region. In
other words, the LSb of location 0x10 protects all the Lock Bytes and RFU bytes in the lowest address region from
further programming. See “OTP address space” on page 50.
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8.1.5
Write Enable command
The Write Enable (WREN) command must be written prior to any command that modifies non-volatile data. The
WREN command sets the Write Enable Latch (WEL) bit. The WEL bit is cleared to 0 (disables writes) during
power-up, hardware reset, or after the device completes the following commands:
• Reset
• Page Program (PP or 4PP)
• Parameter 4-KB Erase (P4E or 4P4E)
• Sector Erase (SE or 4SE)
• Bulk Erase (BE)
• Write Disable (WRDI)
• Write Registers (WRR)
• Write Any Register (WRAR)
• OTP Byte Programming (OTPP)
• Advanced Sector Protection Register Program (ASPP)
• Persistent Protection Bit Program (PPBP)
• Persistent Protection Bit Erase (PPBE)
• Password Program (PASSP)
• Program Non-volatile Data Learning Register (PNVDLR)
8.2
Block protection
The Block Protect bits (Status Register bits BP2, BP1, BP0) in combination with the Configuration Register
TBPROT_O bit can be used to protect an address range of the main flash array from program and erase opera-
tions. The size of the range is determined by the value of the BP bits and the upper or lower starting point of the
range is selected by the TBPROT_O bit of the configuration register (CR1NV[5]).
Table 42
Upper array start of protection (TBPROT_O = 0)
Protected memory
(KB)
Status Register content
Protected fraction of
memory array
FS512S
512 Mb
BP2
BP1
BP0
0
1
0
1
0
1
0
1
None
0
0
Upper 64th
Upper 32nd
Upper 16th
Upper 8th
Upper 4th
Upper Half
All Sectors
1024
2048
4096
8192
16384
32768
65536
0
1
0
1
1
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Table 43
BP2
Lower array start of protection (TBPROT_O = 1)
Status Register content
Protected memory (KB)
Protected fraction of memory array
FS512S
512 Mb
BP1
BP0
0
1
0
1
0
1
0
1
None
0
0
1
0
1
Lower 64th
Lower 32nd
Lower 16th
Lower 8th
Lower 4th
Lower Half
All Sectors
1024
2048
4096
8192
16384
32768
65536
0
1
When Block Protection is enabled (i.e., any BP2-0 are set to ‘1’), Advanced Sector Protection (ASP) can still be
used to protect sectors not protected by the Block Protection scheme. In the case that both ASP and Block
Protection are used on the same sector the logical OR of ASP and Block Protection related to the sector is used.
8.2.1
Freeze bit
Bit 0 of Configuration Register 1 (CR1V[0]) is the FREEZE bit. The Freeze Bit, when set to ‘1’, locks the current state
of the Block Protection control bits and OTP area until the next power off-on cycle. Additional details in “Config-
uration Register 1 Volatile (CR1V)” on page 58
8.2.2
Write Protect signal
The Write Protect (WP#) input in combination with the Status Register Write Disable (SRWD) bit (SR1NV[7])
provide hardware input signal controlled protection. When WP# is Low and SRWD is set to ‘1’ Status Register-1
(SR1NV and SR1V) and Configuration Register 1 (CR1NV and CR1V) are protected from alteration. This prevents
disabling or changing the protection defined by the Block Protect bits (see Table 22).
8.2.3
Advanced sector protection
Advanced sector protection (ASP) is the name used for a set of independent hardware and software methods
used to disable or enable programming or erase operations, individually, in any or all sectors.
Every main flash array sector has a non-volatile Persistent Protection Bit (PPB) and a volatile Dynamic Protection
Bit (DYB) associated with it. When either bit is 0, the sector is protected from program and erase operations. The
PPB bits are protected from program and erase when the volatile PPB Lock bit is 0. There are two methods for
managing the state of the PPB Lock bit: Password Protection, and Persistent Protection. An overview of these
methods is shown in Figure 41.
Block Protection and ASP protection settings for each sector are logically ORed to define the protection for each
sector i.e. if either mechanism is protecting a sector the sector cannot be programmed or erased. Refer to “Block
protection” on page 71 for full details of the BP2-0 bits.
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Data protection
Dynamic
Protection
Bits Array
(DYB)
Persistent
Protection
Bits Array
(PPB)
Flash
Memory
Array
Sector 0
Sector 0
Sector 0
Sector 1
Sector 1
Sector 1
Block
Protection
Logic
Sector N
Sector N
Sector N
Figure 40
Sector protection control
Power On / Reset
ASPR[2]=0
ASPR[1]=0
No
No
Yes
Yes
Password Protection
Default
Persistent Protection
Persistent Protection
ASPR Bits Locked
ASPR Bits Locked
ASPR Bits Are
Programmable
PPBLOCK = 0
PPB Bits Locked
PPBLOCK = 1
PPB Bits Erasable
and Programmable
No
No
PPB Lock Bit Write
Password Unlock
Yes
Yes
PPBLOCK = 1
PPB Bits Erasable
and Programmable
PPBLOCK = 0
PPB Bits Locked
No
PPB Lock Bit Write
Default Mode allows
ASPR to be programmed
to permanently select the
Protection mode.
Yes
Persistent Protection
Mode does not protect
the PPB after power
up. The PPB bits may
be changed. A PPB
Lock Bit write command
protects the PPB bits
until the next power off
or reset.
The default mode otherwise
acts the same as the
Persistent Protection Mode.
Password Protection
Mode protects the
PPB after power up.
A password unlock
command will enable
After one of the protection
modes is selected, ASPR is
no longer programmable,
making the selected
changes to PPB.
A
PPB Lock Bit write
command turns
protection back on.
protection mode permanent.
Figure 41
Advanced sector protection overview
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The Persistent Protection method sets the PPB Lock bit to 1 during POR, or Hardware Reset so that the PPB bits
are unprotected by a device reset. There is a command to clear the PPB Lock bit to 0 to protect the PPB. There is
no command in the Persistent Protection method to set the PPB Lock bit to 1, therefore the PPB Lock bit will
remain at 0 until the next power-off or hardware reset. The Persistent Protection method allows boot code the
option of changing sector protection by programming or erasing the PPB, then protecting the PPB from further
change for the remainder of normal system operation by clearing the PPB Lock bit to 0. This is sometimes called
Boot-code controlled sector protection.
The Password method clears the PPB Lock bit to 0 during POR, or Hardware Reset to protect the PPB. A 64-bit
password may be permanently programmed and hidden for the password method. A command can be used to
provide a password for comparison with the hidden password. If the password matches, the PPB Lock bit is set
to ‘1’ to unprotect the PPB. A command can be used to clear the PPB Lock bit to 0. This method requires use of a
password to control PPB protection.
The selection of the PPB Lock bit management method is made by programming OTP bits in the ASP Register so
as to permanently select the method used.
8.2.4
ASP register
The ASP register is used to permanently configure the behavior of Advanced Sector Protection (ASP) features (see
Table 35).
As shipped from the factory, all devices default ASP to the Persistent Protection mode, with all sectors unpro-
tected, when power is applied. The device programmer or host system must then choose which sector protection
method to use. Programming either of the, one-time programmable, Protection Mode Lock Bits, locks the part
permanently in the selected mode:
• ASPR[2:1] = 11 = No ASP mode selected, Persistent Protection Mode is the default.
• ASPR[2:1] = 10 = Persistent Protection Mode permanently selected.
• ASPR[2:1] = 01 = Password Protection Mode permanently selected.
• ASPR[2:1] = 00 is an Illegal condition, attempting to program more than one bit to zero results in a programming
failure.
ASP register programming rules:
• If the password mode is chosen, the password must be programmed prior to setting the Protection Mode Lock
Bits.
• Once the Protection Mode is selected, the following OTP configuration register bits are permanently protected
from programming and no further changes to the OTP register bits is allowed:
- CR1NV[5:2]
- CR2NV
- CR3NV
- CR4NV
- ASPR
- PASS
- NVDLR
- If an attempt to change any of the registers above, after the ASP mode is selected, the operation will fail and
P_ERR (SR1V[6]) will be set to ‘1’.
The programming time of the ASP Register is the same as the typical page programming time. The system can
determine the status of the ASP register programming operation by reading the WIP bit in the Status Register.
See Table 21 for information on WIP. See “Sector protection states summary” on page 75.
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8.2.5
Persistent Protection bits
The Persistent Protection Bits (PPB) are located in a separate non-volatile flash array. One of the PPB bits is
related to each sector. When a PPB is 0, its related sector is protected from program and erase operations. The
PPB are programmed individually but must be erased as a group, similar to the way individual words may be
programmed in the main array but an entire sector must be erased at the same time. The PPB have the same
program and erase endurance as the main flash memory array. Preprogramming and verification prior to erasure
are handled by the device.
Programming a PPB bit requires the typical page programming time. Erasing all the PPBs requires typical sector
erase time. During PPB bit programming and PPB bit erasing, status is available by reading the Status register.
Reading of a PPB bit requires the initial access time of the device.
Notes
• Each PPB is individually programmed to 0 and all are erased to 1 in parallel.
• If the PPB Lock bit is 0, the PPB Program or PPB Erase command does not execute and fails without programming
or erasing the PPB.
• The state of the PPB for a given sector can be verified by using the PPB Read command.
8.2.6
Dynamic Protection bits
Dynamic Protection Bits are volatile and unique for each sector and can be individually modified. DYB only
control the protection for sectors that have their PPB set to ‘1’. By issuing the DYB Write command, a DYB is
cleared to 0 or set to ‘1’, thus placing each sector in the protected or unprotected state respectively. This feature
allows software to easily protect sectors against inadvertent changes, yet does not prevent the easy removal of
protection when changes are needed. The DYBs can be set or cleared as often as needed as they are volatile bits.
8.2.7
PPB Lock Bit (PPBL[0])
The PPB Lock Bit is a volatile bit for protecting all PPB bits. When cleared to 0, it locks all PPBs, when set to ‘1’, it
allows the PPBs to be changed. See “PPB Lock Register (PPBL)” on page 68 for more information.
The PLBWR command is used to clear the PPB Lock bit to 0. The PPB Lock Bit must be cleared to 0 only after all
the PPBs are configured to the desired settings.
In Persistent Protection mode, the PPB Lock is set to ‘1’ during POR or a hardware reset. When cleared to 0, no
software command sequence can set the PPB Lock bit to 1, only another hardware reset or power-up can set the
PPB Lock bit.
In the Password Protection mode, the PPB Lock bit is cleared to 0 during POR or a hardware reset. The PPB Lock
bit can only be set to ‘1’ by the Password Unlock command.
8.2.8
Sector protection states summary
Each sector can be in one of the following protection states:
• Unlocked — The sector is unprotected and protection can be changed by a simple command. The protection
state defaults to unprotected when the device is shipped from Infineon.
• Dynamically Locked — A sector is protected and protection can be changed by a simple command. The
protection state is not saved across a power cycle or reset.
• Persistently Locked — A sector is protected and protection can only be changed if the PPB Lock Bit is set to ‘1’.
The protection state is non-volatile and saved across a power cycle or reset. Changing the protection state
requires programming and or erase of the PPB bits.
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Table 44
Sector protection states
Protection bit values
Sector state
PPB lock
PPB
DYB
1
Unprotected – PPB and DYB are changeable
1
0
1
0
1
Protected – PPB and DYB are changeable
0
1
0
0
1
Unprotected – PPB not changeable, DYB is changeable
Protected – PPB not changeable, DYB is changeable
0
1
0
8.2.9
Persistent protection mode
The Persistent Protection method sets the PPB Lock bit to 1 during POR or Hardware Reset so that the PPB bits
are unprotected by a device hardware reset. Software reset does not affect the PPB Lock bit. The PLBWR
command can clear the PPB Lock bit to 0 to protect the PPB. There is no command to set the PPB Lock bit
therefore the PPB Lock bit will remain at 0 until the next power-off or hardware reset.
8.2.10
Password protection mode
Password Protection Mode allows an even higher level of security than the Persistent Sector Protection Mode, by
requiring a 64-bit password for unlocking the PPB Lock bit. In addition to this password requirement, after power
up and hardware reset, the PPB Lock bit is cleared to 0 to ensure protection at power-up. Successful execution
of the Password Unlock command by entering the entire password sets the PPB Lock bit to 1, allowing for sector
PPB modifications.
Password protection notes:
• Once the Password is programmed and verified, the Password Mode (ASPR[2] = 0) must be set in order to prevent
reading the password.
• The Password Program Command is only capable of programming 0s. Programming a ‘1’ after a cell is
programmed as a ‘0’ results in the cell left as a ‘0’ with no programming error set.
• The password is all 1s when shipped from Infineon. It is located in its own memory space and is accessible
through the use of the Password Program, Password Read, RDAR, and WRAR commands.
• All 64-bit password combinations are valid as a password.
• The Password Mode, once programmed, prevents reading the 64-bit password and further password
programming. All further program and read commands to the password region are disabled and these
commands are ignored or return undefined data. There is no means to verify what the password is after the
Password Mode Lock Bit is selected. Password verification is only allowed before selecting the Password
Protection mode.
• The Protection Mode Lock Bits are not erasable.
• The exact password must be entered in order for the unlocking function to occur. If the password unlock
command provided password does not match the hidden internal password, the unlock operation fails in the
same manner as a programming operation on a protected sector. The P_ERR bit is set to one, the WIP Bit remains
set, and the PPB Lock bit remains cleared to 0.
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• The Password Unlock command cannot be accepted any faster than once every 100 µs ± 20 µs. This makes it
take an unreasonably long time (58 million years) for a hacker to run through all the 64-bit combinations in an
attempt to correctly match a password. The Read Status Register 1 command may be used to read the WIP bit
to determine when the device has completed the password unlock command or is ready to accept a new
password command. When a valid password is provided the password unlock command does not insert the
100 µs delay before returning the WIP bit to zero.
• If the password is lost after selecting the Password Mode, there is no way to set the PPB Lock bit.
• ECC status may only be read from sectors that are readable. In read protection mode the addresses are forced
to the boot sector address. ECC status is only in that sector while read protection mode is active.
8.3
Recommended protection process
During system manufacture, the flash device configuration should be defined by:
• Programming the OTP configuration bits in CR1NV[5, 3:2], CR2NV, CR3NV, and CR4NV as desired.
• Program the Secure Silicon Region (OTP area) as desired.
• Program the PPB bits as desired via the PPBP command.
• Program the NVDLR if it will be used in DDR read commands.
• Program the Password register (PASS) if password protection will be used.
• Program the ASP Register as desired, including the selection of the persistent or password ASP protection mode
in ASPR[2:1]. It is very important to explicitly select a protection mode so that later accidental or malicious
programming of the ASP register and OTP configuration is prevented. This is to ensure that only the intended
OTP protection and configuration features are enabled.
During system power up and boot code execution:
• Trusted boot code can determine whether there is any need to program additional SSR (OTP area) information.
If no SSR changes are needed the FREEZE bit (CR1V[0]) can be set to ‘1’ to protect the SSR from changes during
the remainder of normal system operation while power remains on.
• If the persistent protection mode is in use, trusted boot code can determine whether there is any need to modify
the persistent (PPB) sector protection via the PPBP or PPBE commands. If no PPB changes are needed the
PPBLOCK bit can be cleared to 0 via the PPBL to protect the PPB bits from changes during the remainder of
normal system operation while power remains on.
The dynamic (DYB) sector protection bits can be written as desired via the DYBAR.
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Commands
9
Commands
All communication between the host system and S25FS512S memory devices is in the form of units called
commands.
All commands begin with an instruction that selects the type of information transfer or device operation to be
performed. Commands may also have an address, instruction modifier, latency period, data transfer to the
memory, or data transfer from the memory. All instruction, address, and data information is transferred sequen-
tially between the host system and memory device.
Command protocols are also classified by a numerical nomenclature using three numbers to reference the
transfer width of three command phases:
• instruction
• address and instruction modifier (mode)
• data
Single bit wide commands start with an instruction and may provide an address or data, all sent only on the SI
signal. Data may be sent back to the host serially on the SO signal. This is referenced as a 1-1-1 command protocol
for single bit width instruction, single bit width address and modifier, single bit data.
Dual or Quad Input / Output (I/O) commands provide an address sent from the host as bit pairs on IO0 and IO1
or, four-bit (nibble) groups on IO0, IO1, IO2, and IO3. Data is returned to the host similarly as bit pairs on IO0 and
IO1 or, four-bit (nibble) groups on IO0, IO1, IO2, and IO3. This is referenced as 1-2-2 for Dual I/O and 1-4-4 for Quad
I/O command protocols.
The S25FS512S also supports a QPI mode in which all information is transferred in 4-bit width, including the
instruction, address, modifier, and data. This is referenced as a 4-4-4 command protocol.
Commands are structured as follows:
• Each command begins with an eight bit (byte) instruction. However, some read commands are modified by a
prior read command, such that the instruction is implied from the earlier command. This is called Continuous
Read Mode. When the device is in continuous read mode, the instruction bits are not transmitted at the
beginning of the command because the instruction is the same as the read command that initiated the
Continuous Read Mode. In Continuous Read mode the command will begin with the read address. Thus,
Continuous Read Mode removes eight instruction bits from each read command in a series of same type read
commands.
• The instruction may be standalone or may be followed by address bits to select a location within one of several
address spaces in the device. The address may be either a 24-bit or 32-bit, byte boundary, address.
• The Serial Peripheral Interface with Multiple IO provides the option for each transfer of address and data infor-
mation to be done one, two, or four bits in parallel. This enables a trade off between the number of signal
connections (IO bus width) and the speed of information transfer. If the host system can support a two or four
bit wide IO bus the memory performance can be increased by using the instructions that provide parallel two
bit (dual) or parallel four bit (quad) transfers.
• In legacy SPI Multiple IO mode, the width of all transfers following the instruction are determined by the
instruction sent. Following transfers may continue to be single bit serial on only the SI or Serial Output (SO)
signals, they may be done in two bit groups per (dual) transfer on the IO0 and IO1 signals, or they may be done
in 4-bit groups per (quad) transfer on the IO0-IO3 signals. Within the dual or quad groups the least significant
bit is on IO0. More significant bits are placed in significance order on each higher numbered IO signal. Single
bits or parallel bit groups are transferred in most to least significant bit order.
• In QPI mode, the width of all transfers, including instructions, is a 4-bit wide (quad) transfer on the IO0-IO3
signals.
• Dual I/O and Quad I/O read instructions send an instruction modifier called mode bits, following the address,
to indicate that the next command will be of the same type with an implied, rather than an explicit, instruction.
The next command thus does not provide an instruction byte, only a new address and mode bits. This reduces
the time needed to send each command when the same command type is repeated in a sequence of commands.
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Commands
• The address or mode bits may be followed by write data to be stored in the memory device or by a read latency
period before read data is returned to the host.
• Read latency may be zero to several SCK cycles (also referred to as dummy cycles).
• All instruction, address, mode, and data information is transferred in byte granularity. Addresses are shifted
into the device with the most significant byte first. All data is transferred with the lowest address byte sent first.
Following bytes of data are sent in lowest to highest byte address order i.e. the byte address increments.
• All attempts to read the flash memory array during a program, erase, or a write cycle (embedded operations)
are ignored. The embedded operation will continue to execute without any affect. A very limited set of
commands are accepted during an embedded operation. These are discussed in the individual command
descriptions. While a program, erase, or write operation is in progress, it is recommended to check that the
Write-In Progress (WIP) bit is 0 before issuing most commands to the device, to ensure the new command can
be accepted.
• Depending on the command, the time for execution varies. A command to read status information from an
executing command is available to determine when the command completes execution and whether the
command was successful.
• Although host software in some cases is used to directly control the SPI interface signals, the hardware interfaces
of the host system and the memory device generally handle the details of signal relationships and timing. For
this reason, signal relationships and timing are not covered in detail within this software interface focused
section of the document. Instead, the focus is on the logical sequence of bits transferred in each command
rather than the signal timing and relationships. Following are some general signal relationship descriptions to
keep in mind. For additional information on the bit level format and signal timing relationships of commands,
see “Command protocol” on page 20.
- The host always controls the Chip Select (CS#), Serial Clock (SCK), and Serial Input (SI) – SI for single bit wide
transfers. The memory drives Serial Output (SO) for single bit read transfers. The host and memory alternately
drive the IO0-IO3 signals during Dual and Quad transfers.
- All commands begin with the host selecting the memory by driving CS# LOW before the first rising edge of
SCK. CS# is kept LOW throughout a command and when CS# is returned HIGH the command ends. Generally,
CS# remains LOW for eight bit transfer multiples to transfer byte granularity information. Some commands
will not be accepted if CS# is returned HIGH not at an 8-bit boundary.
9.1
Command set summary
Extended addressing
9.1.1
To accommodate addressing above 128 Mb, there are two options:
1. Instructions that always require a 4-byte address, used to access up to 32 Gb of memory.
Command name
4READ
Function
Read
Instruction (Hex)
13
0C
BC
EC
EE
12
21
DC
18
E0
E1
E2
4FAST_READ
4DIOR
Read Fast
Dual I/O Read
Quad I/O Read
DDR Quad I/O Read
Page Program
Parameter 4-KB Erase
Erase 64 / 256 KB
ECC Status Read
DYB Read
4QIOR
4DDRQIOR
4PP
4P4E
4SE
4ECCRD
4DYBRD
4DYBWR
4PPBRD
DYBWR
PPB Read
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Commands
Command name
Function
Instruction (Hex)
4PPBP
PPB Program
E3
2. A 4-byte address mode for backward compatibility to the 3-byte address instructions. The standard 3-byte
instructions can be used in conjunction with a 4-byte address mode controlled by the Address Length config-
uration bit (CR2V[7]). The default value of CR2V[7] is loaded from CR2NV[7] (following power up, hardware
reset, or software reset), to enable default 3-byte (24-bit) or 4-byte (32 bit) addressing. When the address length
(CR2V[7]) set to ‘1’, the legacy commands are changed to require 4 bytes (32-bits) for the address field. The
following instructions can be used in conjunction with the 4-byte address mode configuration to switch from
3 bytes to 4 bytes of address field.
Command name
READ
Function
Read
Instruction (Hex)
03
0B
BB
EB
ED
02
20
D8
65
71
D0
42
4B
19
FA
FB
FC
FD
FAST_READ
DIOR
Read Fast
Dual I/O Read
Quad I/O Read
DDR Quad I/O Read)
Page Program
Parameter 4 KB Erase
Erase 256 KB
Read Any Register
Write Any Register
Evaluate Erase Status
OTP Program
OTP Read
QIOR
DDRQIOR
PP
P4E
SE
RDAR
WRAR
EES
OTPP
OTPR
ECCRD
DYBRD
DYBWR
PPBRD
PPBP
ECC Status Read
DYB Read
DYBWR
PPB Read
PPB Program
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Commands
9.1.2
Command summary by function
Table 45
S25FS512S command set (Sorted by function)
Maximum Address
frequency length
Command
Instruction
value (Hex)
Function
Command description
name
QPI
(MHz)
(Bytes)
RDID
Read ID (JEDEC Manufacturer ID and JEDEC CFI)
9F
5A
133
0
Read
Read JEDEC Serial Flash Discoverable
Parameters
RSFDP
50
3
Device ID
Yes
No
RDQID
RDSR1
RDSR2
RDCR
RDAR
WRR
Read Quad ID
AF
05
07
35
65
01
04
06
71
133
133
133
133
133
133
133
133
133
0
Read Status Register 1
Read Status Register 2
Read Configuration Register 1
Read Any Register
0
0
0
3 or 4
0
Write Register (Status 1, Configuration 1)
Write Disable
WRDI
WREN
WRAR
0
Write Enable
0
Write Any Register
3 or 4
Yes
Clear Status Register 1 — Erase / Program Fail
Reset
This command may be disabled and the
instruction value instead used for a program /
erase resume command -
CLSR
30
133
0
Register
Access
See “Configuration Register 3” on page 63.
Clear Status Register 1 (Alternate instruction) —
Erase / Program Fail Reset
CLSR
82
133
0
4BAM
SBL
Enter 4-byte Address Mode
Set Burst Length
B7
C0
D0
19
18
41
43
4A
03
13
0B
0C
BB
BC
EB
EC
ED
EE
133
133
133
133
133
133
133
133
50
0
No
0
EES
Evaluate Erase Status
3 or 4
ECCRD
4ECCRD
DLPRD
PNVDLR
WVDLR
READ
3 or 4
Yes
ECC Read
4
Data Learning Pattern Read
0
Program NV Data Learning Register
Write Volatile Data Learning Register
0
0
3 or 4
4
Read
4READ
50
No
FAST_READ
4FAST_READ
DIOR
133
133
133
133
133
133
80
3 or 4
4
Fast Read
3 or 4
4
Read Flash
Array
Dual I/O Read
Quad I/O Read
DDR Quad I/O Read
4DIOR
QIOR
3 or 4
4
4QIOR
Yes
DDRQIOR
4DDRQIOR
3 or 4
4
80
Note
45. Commands not supported in QPI mode have undefined behavior if sent when the device is in QPI mode.
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Commands
Table 45
Function
S25FS512S command set (Sorted by function) (continued)
Maximum Address
frequency length
Command
name
Instruction
value (Hex)
Command description
QPI
(MHz)
(Bytes)
3 or 4
4
PP
4PP
P4E
4P4E
SE
02
12
20
21
D8
DC
60
C7
75
85
B0
7A
8A
Program
Page Program
Flash Array
3 or 4
4
Parameter 4 KB-Sector Erase
Erase 256 KB
3 or 4
4
Erase Flash
Array
4SE
BE
Bulk Erase
BE
Bulk Erase (alternate instruction)
Erase / Program Suspend
Yes
EPS
EPS
EPS
EPR
EPR
Erase / Program Suspend (alternate instruction)
0
Erase
Erase / Program Resume
/Program
Suspend
/Resume
Erase / Program Resume (alternate instruction)
Erase / Program Resume (alternate instruction
This command may be disabled and the
instruction value instead used for a clear status
command —
EPR
30
See “Configuration Register 3” on page 63.
One Time
Program
Array
OTPP
OTPR
OTP Program
OTP Read
42
4B
133
No
3 or 4
DYBRD
4DYBRD
DYBWR
4DYBWR
PPBRD
4PPBRD
PPBP
FA
E0
FB
E1
FC
E2
FD
E3
E4
2B
2F
A7
A6
E7
E8
E9
DYB Read
4
3 or 4
4
Yes
DYB Write
PPB Read
PPB Program
3 or 4
4
3 or 4
4
Advanced
Sector
4PPBP
PPBE
PPB Erase
Protection
ASPRD
ASPP
ASP Read
No
ASP Program
PLBRD
PLBWR
PASSRD
PASSP
PASSU
PPB Lock Bit Read
PPB Lock Bit Write
Password Read
Password Program
Password Unlock
0
Note
45. Commands not supported in QPI mode have undefined behavior if sent when the device is in QPI mode.
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Commands
Table 45
Function
S25FS512S command set (Sorted by function) (continued)
Maximum Address
frequency length
Command
name
Instruction
value (Hex)
Command description
Software Reset Enable
QPI
(MHz)
(Bytes)
RSTEN
RST
66
99
F0
FF
B9
AB
Yes
No
Software Reset
Reset
RESET
MBR
DPD
Legacy Software Reset
Mode Bit Reset
133
0
Enter Deep Power-Down Mode
Release from Deep Power-Down Mode
Yes
DPD
RES
Note
45. Commands not supported in QPI mode have undefined behavior if sent when the device is in QPI mode.
9.1.3
Read device identification
There are multiple commands to read information about the device manufacturer, device type, and device
features. SPI memories from different vendors have used different commands and formats for reading infor-
mation about the memories. The S25FS512S supports the three device information commands.
9.1.4
Register read or write
There are multiple registers for reporting embedded operation status or controlling device configuration
options. There are commands for reading or writing these registers. Registers contain both volatile and
non-volatile bits. Non-volatile bits in registers are automatically erased and programmed as a single (write)
operation.
9.1.4.1
Monitoring operation status
The host system can determine when a write, program, erase, suspend or other embedded operation is complete
by monitoring the Write in Progress (WIP) bit in the Status Register. The Read from Status Register 1 command
or Read Any Register command provides the state of the WIP bit. The program error (P_ERR) and erase error
(E_ERR) bits in the status register indicate whether the most recent program or erase command has not
completed successfully. When P_ERR or E_ERR bits are set to one, the WIP bit will remain set to one indicating
the device remains busy and unable to receive most new operation commands. Only status read (RDSR1 05h),
Read Any Register (RDAR 65h), status clear (CLSR 30h or 82h), and software reset (RSTEN 66h, RST 99h or RESET
F0h) are valid commands when P_ERR or E_ERR is set to ‘1’. A Clear Status Register (CLSR) followed by a Write
Disable (WRDI) command must be sent to return the device to standby state. Clear Status Register clears the WIP,
P_ERR, and E_ERR bits. WRDI clears the WEL bit. Alternatively, Hardware Reset, or Software Reset (RST or RESET)
may be used to return the device to standby state.
9.1.4.2
Configuration
There are commands to read, write, and protect registers that control interface path width, interface timing,
interface address length, and some aspects of data protection.
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Commands
9.1.5
Read flash array
Data may be read from the memory starting at any byte boundary. Data bytes are sequentially read from incre-
mentally higher byte addresses until the host ends the data transfer by driving CS# input High. If the byte address
reaches the maximum address of the memory array, the read will continue at address zero of the array.
There are several different read commands to specify different access latency and data path widths. Double Data
Rate (DDR) commands also define the address and data bit relationship to both SCK edges:
• The Read command provides a single address bit per SCK rising edge on the SI signal with read data returning
a single bit per SCK falling edge on the SO signal. This command has zero latency between the address and the
returning data but is limited to a maximum SCK rate of 50 MHz.
• Other read commands have a latency period between the address and returning data but can operate at higher
SCK frequencies. The latency depends on a configuration register read latency value.
• The Fast Read command provides a single address bit per SCK rising edge on the SI signal with read data
returning a single bit per SCK falling edge on the SO signal.
• Dual or Quad I/O Read commands provide address two bits or four bits per SCK rising edge with read data
returning two bits, or four bits of data per SCK falling edge on the IO0-IO3 signals.
• Quad Double Data Rate read commands provide address four bits per every SCK edge with read data returning
four bits of data per every SCK edge on the IO0-IO3 signals.
9.1.6
Program flash array
Programming data requires two commands: Write Enable (WREN), and Page Program (PP). The Page Program
command accepts from 1 byte up to 256 or 512 consecutive bytes of data (page) to be programmed in one
operation. Programming means that bits can either be left at 1, or programmed from 1 to 0. Changing bits from
0 to 1 requires an erase operation.
9.1.7
Erase flash array
The Parameter Sector Erase, Sector Erase, or Bulk Erase commands set all the bits in a sector or the entire
memory array to ‘1’. A bit needs to be first erased to 1 before programming can change it to ‘0’. While bits can be
individually programmed from a ‘1’ to ‘0’, erasing bits from 0 to 1 must be done on a sector-wide or array-wide
(bulk) level. The Write Enable (WREN) command must precede an erase command.
9.1.8
OTP, block protection, and advanced sector protection
There are commands to read and program a separate One Time Programmable (OTP) array for permanent data
such as a serial number. There are commands to control a contiguous group (block) of flash memory array sectors
that are protected from program and erase operations.There are commands to control which individual flash
memory array sectors are protected from program and erase operations.
9.1.9
Reset
There are commands to reset to the default conditions present after power on to the device. However, the
software reset commands do not affect the current state of the FREEZE or PPB Lock bits. In all other respects a
software reset is the same as a hardware reset.
There is a command to reset (exit from) the Continuous Read Mode.
9.1.10
DPD
A Deep Power-Down (DPD) mode is supported by the S25FS512S devices. If the device has been placed in DPD
mode by the DPD (B9h) command, the interface standby current is (IDPD). The DPD command is accepted only
while the device is not performing an embedded algorithm as indicated by the Status Register-1 volatile Write In
Progress (WIP) bit being cleared to zero (SR1V[0] = 0). While in DPD mode the device ignores all commands except
the Release from DPD (RES ABh) command, that will return the device to the Interface Standby state after a delay
of tRES
.
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Commands
9.1.11
Reserved
Some instructions are reserved for future use. In this generation of the S25FS512S some of these command
instructions may be unused and not affect device operation, some may have undefined results.
Some commands are reserved to ensure that a legacy or alternate source device command is allowed without
effect. This allows legacy software to issue some commands that are not relevant for the current generation
S25FS512S with the assurance these commands do not cause some unexpected action.
Some commands are reserved for use in special versions of the FS-S not addressed by this document or for a
future generation. This allows new host memory controller designs to plan the flexibility to issue these command
instructions. The command format is defined if known at the time this document revision is published.
9.2
Identification commands
9.2.1
Read Identification (RDID 9Fh)
The Read Identification (RDID) command provides read access to manufacturer identification, device identifi-
cation, and Common Flash Interface (CFI) information. The manufacturer identification is assigned by JEDEC. The
CFI structure is defined by JEDEC standard. The device identification and CFI values are assigned by Infineon.
The JEDEC Common Flash Interface (CFI) specification defines a device information structure, which allows a
vendor-specified software flash management program (driver) to be used for entire families of flash devices.
Software support can then be device-independent, JEDEC manufacturer ID independent, forward and
backward-compatible for the specified flash device families. System vendors can standardize their flash drivers
for long-term software compatibility by using the CFI values to configure a family driver from the CFI information
of the device in use.
Any RDID command issued while a program, erase, or write cycle is in progress is ignored and has no effect on
execution of the program, erase, or write cycle that is in progress.
The RDID instruction is shifted on SI. After the last bit of the RDID instruction is shifted into the device, a byte of
manufacturer identification, two bytes of device identification, extended device identification, and CFI infor-
mation will be shifted sequentially out on SO. As a whole this information is referred to as ID-CFI. See “Device ID
and common flash interface (ID-CFI) address map” on page 137 for the detail description of the ID-CFI
contents.
Continued shifting of output beyond the end of the defined ID-CFI address space will provide undefined data. The
RDID command sequence is terminated by driving CS# to the logic HIGH state anytime during data output.
The maximum clock frequency for the RDID command is 133 MHz.
CS#
SCK
SI
SO
7 6 5 4 3 2 1 0
Instruction
7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Data1 DataN
Phase
Figure 42
Read Identification (RDID) command sequence
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Commands
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3 and the
returning data is shifted out on IO0-IO3.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruction
D1
D2
D3
D4
D5
Figure 43
Read Identification (RDID) QPI mode command
9.2.2
Read Quad Identification (RDQID AFh)
The Read Quad Identification (RDQID) command provides read access to manufacturer identification, device
identification, and Common Flash Interface (CFI) information. This command is an alternate way of reading the
same information provided by the RDID command while in QPI mode. In all other respects the command behaves
the same as the RDID command.
The command is recognized only when the device is in QPI Mode (CR2V[6] = 1). The instruction is shifted in on
IO0-IO3. After the last bit of the instruction is shifted into the device, a byte of manufacturer identification, two
bytes of device identification, extended device identification, and CFI information will be shifted sequentially out
on IO0-IO3. As a whole this information is referred to as ID-CFI. See “Device ID and common flash interface
(ID-CFI) address map” on page 137 for the detail description of the ID-CFI contents.
Continued shifting of output beyond the end of the defined ID-CFI address space will provide undefined data. The
command sequence is terminated by driving CS# to the logic HIGH state anytime during data output.
The maximum clock frequency for the command is 133 MHz.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruction
D1
D2
D3
D4
D5
Figure 44
Read Quad Identification (RDQID) command sequence
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Commands
9.2.3
Read serial flash discoverable parameters (RSFDP 5Ah)
The command is initiated by shifting on SI the instruction code ‘5Ah’, followed by a 24-bit address of 000000h,
followed by 8 dummy cycles. The SFDP bytes are then shifted out on SO starting at the falling edge of SCK after
the dummy cycles. The SFDP bytes are always shifted out with the MSb first. If the 24-bit address is set to any
other value, the selected location in the SFDP space is the starting point of the data read. This enables random
access to any parameter in the SFDP space. The RSFDP command is supported up to 50 MHz.
CS#
SCK
SI
SO
7 6 5 4 3 2 1 0 23
Instruction
1 0
7
6 5 4 3 2 1 0
Phase
Address
Dummy Cycles
Data 1
Figure 45
RSFDP command sequence
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3 and the
returning data is shifted out on IO0-IO3.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
20
21
22
23
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
IO2
IO3
Dummy
D1
D2
D3
Phase
Instruct.
Address
D4
Figure 46
RSFDP QPI Mode command sequence
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Commands
9.3
Register access commands
Read Status Register 1 (RDSR1 05h)
9.3.1
The Read Status Register 1 (RDSR1) command allows the Status Register 1 contents to be read from SO. The
volatile version of Status Register 1 (SR1V) contents may be read at any time, even while a program, erase, or
write operation is in progress. It is possible to read Status Register 1 continuously by providing multiples of eight
clock cycles. The status is updated for each eight cycle read. The maximum clock frequency for the RDSR1 (05h)
command is 133 MHz.
CS#
SCK
SI
SO
7 6 5 4 3 2 1 0
Instruction
7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Status Updated Status
Phase
Figure 47
Read Status Register 1 (RDSR1) command sequence
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3 and the
returning data is shifted out on IO0-IO3, two clock cycles per byte.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruct.
D1
D2
D3
D4
D5
Figure 48
Read Status Register 1 (RDSR1) QPI Mode command
9.3.2
Read Status Register 2 (RDSR2 07h)
The Read Status Register 2 (RDSR2) command allows the Status Register 2 contents to be read from SO. The
Status Register 2 contents may be read at any time, even while a program, erase, or write operation is in progress.
It is possible to read the Status Register 2 continuously by providing multiples of eight clock cycles. The status is
updated for each eight cycle read. The maximum clock frequency for the RDSR2 command is 133 MHz.
CS#
SCK
SI
SO
7 6 5 4 3 2 1 0
Instruction
7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Status Updated Status
Phase
Figure 49
Read Status Register 2 (RDSR2) command
In QPI mode, Status Register 2 may be read via the Read Any Register command, see “Read Any Register (RDAR
65h)” on page 96.
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Commands
9.3.3
Read Configuration Register (RDCR 35h)
The Read Configuration Register (RDCR) command allows the volatile Configuration Register (CR1V) contents to
be read from SO. It is possible to read CR1V continuously by providing multiples of eight clock cycles. The config-
uration register contents may be read at any time, even while a program, erase, or write operation is in progress.
CS#
SCK
SI
SO
7 6 5 4 3 2 1 0
7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Repeat Register Read
Register Read
Phase
Instruction
Figure 50
Read Configuration Register (RDCR) command sequence
In QPI mode, Configuration Register 1 may be read via the Read Any Register command, see “Read Any Register
(RDAR 65h)” on page 96.
9.3.4
Write Registers (WRR 01h)
The Write Registers (WRR) command allows new values to be written to both the Status Register 1 and Configu-
ration Register 1. Before the Write Registers (WRR) command can be accepted by the device, a Write Enable
(WREN) command must be received. After the Write Enable (WREN) command has been decoded successfully,
the device will set the Write Enable Latch (WEL) in the Status Register to enable any write operations.
The Write Registers (WRR) command is entered by shifting the instruction and the data bytes on SI. The Status
Register is one data byte in length.
The WRR operation first erases the register then programs the new value as a single operation. The Write Registers
(WRR) command will set the P_ERR or E_ERR bits if there is a failure in the WRR operation. See “Status Register
1 Volatile (SR1V)” on page 54 for a description of the error bits. Any status or configuration register bit reserved
for the future must be written as ‘0’.
CS# must be driven to the logic HIGH state after the eighth or sixteenth bit of data has been latched. If not, the
Write Registers (WRR) command is not executed. If CS# is driven HIGH, after the eighth cycle then only the Status
Register 1 is written; otherwise, after the sixteenth cycle both the status and configuration registers are written.
As soon as CS# is driven to the logic HIGH state, the self-timed Write Registers (WRR) operation is initiated. While
the Write Registers (WRR) operation is in progress, the Status Register may still be read to check the value of the
Write-In Progress (WIP) bit. The Write-In Progress (WIP) bit is a ‘1’ during the self-timed Write Registers (WRR)
operation, and is a ‘0’ when it is completed. When the Write Registers (WRR) operation is completed, the Write
Enable Latch (WEL) is set to ‘0’. The maximum clock frequency for the WRR command is 133 MHz.
This command is also supported in QPI mode. In QPI mode, the instruction and data is shifted in on IO0-IO3, two
clock cycles per byte.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
Phase
Instruction
Input Status Register-1
Figure 51
Write Registers (WRR) command sequence – 8 data bits
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Commands
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
7
6
5
4
3 2 1 0
Phase
Instruction
Input Status Register-1
Input Configuration Register-1
Figure 52
Write Registers (WRR) command sequence – 16 data bits
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruct.
Input Status
Input Config
Figure 53
Write Registers (WRR) command sequence – 16 data bits QPI mode
The Write Register (WRR) command writes the non-volatile version of the Quad bit (CR1NV[1]), which also causes
an update to the volatile version CR1V[1]. The WRR command can not write the volatile version CR1V[1] without
first affecting the non-volatile version CR1NV[1]. The WRAR command must be used when it is desired to write
the volatile Quad bit CR1V[1] without affecting the non-volatile version CR1NV[1].
The Write Registers (WRR) command allows the user to change the values of the Block Protect (BP2, BP1, and
BP0) bits in either the Non-volatile Status Register 1 or in the volatile Status Register 1, to define the size of the
area that is to be treated as read-only. The BPNV_O bit (CR1NV[3]) controls whether WRR writes the non-volatile
or volatile version of Status Register 1. When CR1NV[3] = 0 WRR writes SR1NV[4:2]. When CR1NV[3] = 1 WRR writes
SR1V[4:2].
The Write Registers (WRR) command also allows the user to set the Status Register Write Disable (SRWD) bit to ‘1’
or a ‘0’. The Status Register Write Disable (SRWD) bit and Write Protect (WP#) signal allow the BP bits to be
hardware protected.
When the Status Register Write Disable (SRWD) bit of the Status Register is a ‘0’ (its initial delivery state), it is
possible to write to the status register provided that the Write Enable Latch (WEL) bit has previously been set by
a Write Enable (WREN) command, regardless of the whether Write Protect (WP#) signal is driven to the logic HIGH
or logic LOW state.
When the Status Register Write Disable (SRWD) bit of the status register is set to ‘1’, two cases need to be
considered, depending on the state of Write Protect (WP#):
• If Write Protect (WP#) signal is driven to the logic HIGH state, it is possible to write to the status and configuration
registers provided that the Write Enable Latch (WEL) bit has previously been set to ‘1’ by initiating a Write Enable
(WREN) command.
• If Write Protect (WP#) signal is driven to the logic LOW state, it is not possible to write to the status and config-
uration registers even if the Write Enable Latch (WEL) bit has previously been set to ‘1’ by a Write Enable (WREN)
command. Attempts to write to the status and configuration registers are rejected, not accepted for execution,
and no error indication is provided. As a consequence, all the data bytes in the memory area that are protected
by the Block Protect (BP2, BP1, BP0) bits of the status register, are also hardware protected by WP#.
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Commands
The WP# hardware protection can be provided:
• by setting the Status Register Write Disable (SRWD) bit after driving Write Protect (WP#) signal to the logic LOW
state;
• or by driving Write Protect (WP#) signal to the logic LOW state after setting the Status Register Write Disable
(SRWD) bit to ‘1’.
The only way to release the hardware protection is to pull the Write Protect (WP#) signal to the logic HIGH state.
If WP# is permanently tied high, hardware protection of the BP bits can never be activated.
Table 46
WP#
Block protection modes
Memory content
Protected area Unprotected area
SRWD
Mode
Write protection of registers
Bit
1
1
1
0
Status and Configuration Registers are
Writable (if WREN command has set the Protected against Page Ready to accept Page
WEL bit). The values in the SRWD, BP2, Program, Sector Erase, Program, and Sector
Software
Protected
BP1, and BP0 bits and those in the
and Bulk Erase
Erase commands
0
0
Configuration Register can be changed
Status and Configuration Registers are
Hardware Write Protected. The values Protected against Page Ready to accept Page
in the SRWD, BP2, BP1, and BP0 bits and Program, Sector Erase, Program or Erase
Hardware
Protected
0
1
those in the Configuration Register
cannot be changed
and Bulk Erase
commands
Notes
46. The Status Register originally shows 00h when the device is first shipped from Infineon to the customer.
47. Hardware protection is disabled when Quad Mode is enabled (CR1V[1] = 1). WP# becomes IO2; therefore, it cannot be
utilized.
9.3.5
Write Enable (WREN 06h)
The Write Enable (WREN) command sets the Write Enable Latch (WEL) bit of the Status Register 1 (SR1V[1]) to ‘1’.
The Write Enable Latch (WEL) bit must be set to ‘1’ by issuing the Write Enable (WREN) command to enable write,
program and erase commands.
CS# must be driven into the logic HIGH state after the eighth bit of the instruction byte has been latched in on SI.
Without CS# being driven to the logic HIGH state after the eighth bit of the instruction byte has been latched in
on SI, the write enable operation will not be executed.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
Phase
Instruction
Figure 54
Write Enable (WREN) command sequence
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3, two clock
cycles per byte.
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Commands
CS#
SCK
IO0
4
5
6
7
0
1
2
3
IO1
IO2
IO3
Phase
Instruction
Figure 55
Write Enable (WREN) command sequence QPI mode
9.3.6
Write Disable (WRDI 04h)
The Write Disable (WRDI) command clears the Write Enable Latch (WEL) bit of the Status Register 1 (SR1V[1]) to a
‘0’.
The Write Enable Latch (WEL) bit may be cleared to ‘0’ by issuing the Write Disable (WRDI) command to disable
Page Program (PP), Sector Erase (SE), Bulk Erase (BE), Write Registers (WRR or WRAR), OTP Program (OTPP), and
other commands, that require WEL be set to ‘1’ for execution. The WRDI command can be used by the user to
protect memory areas against inadvertent writes that can possibly corrupt the contents of the memory. The WRDI
command is ignored during an embedded operation while WIP bit = 1.
CS# must be driven into the logic HIGH state after the eighth bit of the instruction byte has been latched in on SI.
Without CS# being driven to the logic HIGH state after the eighth bit of the instruction byte has been latched in
on SI, the write disable operation will not be executed.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
Phase
Instruction
Figure 56
Write Disable (WRDI) command sequence
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3, two clock
cycles per byte.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruction
Figure 57
Write Disable (WRDI) command sequence QPI mode
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Commands
9.3.7
Clear Status Register (CLSR 30h or 82h)
The Clear Status Register command resets bit SR1V[5] (Erase Fail Flag) and bit SR1V[6] (Program Fail Flag). It is
not necessary to set the WEL bit before a Clear Status Register command is executed. The Clear Status Register
command will be accepted even when the device remains busy with WIP set to ‘1’, as the device does remain busy
when either error bit is set. The WEL bit will be unchanged after this command is executed.
The legacy Clear Status Register (CLSR 30h) instruction may be disabled and the 30h instruction value instead
used for a program / erase resume command, see “Configuration Register 3” on page 63. The Clear Status
Register alternate instruction (CLSR 82h) is always available to clear the status register.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
Phase
Instruction
Figure 58
Clear Status Register (CLSR) command sequence
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3, two clock
cycles per byte.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruction
Figure 59
Clear Status Register (CLSR) command sequence QPI mode
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Commands
9.3.8
ECC Status Register Read (ECCRD 19h or 4EECRD 18h)
To read the ECC Status Register, the command is followed by the ECC unit address, the four least significant bits
(LSb) of address must be set to zero. This is followed by the number of dummy cycles selected by the read latency
value in CR2V[3:0]. Then the 8-bit contents of the ECC Register, for the ECC unit selected, are shifted out on SO 16
times, once for each byte in the ECC Unit. If CS# remains LOW the next ECC unit status is sent through SO 16 times,
once for each byte in the ECC Unit. The maximum operating clock frequency for the ECC READ command is 133
MHz.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
A
1
0
7
6
5
4
3
2
1
0
Phase
Instruction
Address
Dummy Cycles
Data 1
Figure 60
ECC Status Register Read command sequence[48, 49]
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3, two clock
cycles per byte.
CS#
SCLK
IO0
IO1
4
5
6
7
0
1
2
3
20
21
22
23
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruct.
Address
Dummy
D1
D2
D3
D4
Figure 61
ECCRD (19h), QPI Mode, CR2[7] = 0, command sequence
CS#
SCLK
IO0
4
5
6
7
0
1
2
3
28
29
30
31
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
0
4
0
4
0
IO1
5
6
7
1
2
3
5
6
7
1
2
3
5
6
7
1
2
3
IO2
IO3
Phase
Instruct.
Address
Dummy
D1
D2
D3
D4
Figure 62
Notes
ECCRD (19h), QPI Mode, CR2[7] = 1, or 4ECCRD (18h) command sequence
48. A = MSb of address = 23 for Address length (CR2V[7] = 0, or 31 for CR2V[7] = 1 with command 19h.
49. A = MSb of address = 31 with command 18h.
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Commands
9.3.9
Program NVDLR (PNVDLR 43h)
Before the Program NVDLR (PNVDLR) command can be accepted by the device, a Write Enable (WREN) command
must be issued and decoded by the device. After the Write Enable (WREN) command has been decoded success-
fully, the device will set the Write Enable Latch (WEL) to enable the PNVDLR operation.
The PNVDLR command is entered by shifting the instruction and the data byte on SI.
CS# must be driven to the logic HIGH state after the eighth (8th) bit of data has been latched. If not, the PNVDLR
command is not executed. As soon as CS# is driven to the logic HIGH state, the self-timed PNVDLR operation is
initiated. While the PNVDLR operation is in progress, the Status Register may be read to check the value of the
Write-In Progress (WIP) bit. The Write-In Progress (WIP) bit is a ‘1’ during the self-timed PNVDLR cycle, and is a ‘0’
when it is completed. The PNVDLR operation can report a program error in the P_ERR bit of the status register.
When the PNVDLR operation is completed, the Write Enable Latch (WEL) is set to ‘0’. The maximum clock
frequency for the PNVDLR command is 133 MHz.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
Phase
Instruction
Input Data
Figure 63
Program NVDLR (PNVDLR) command sequence
9.3.10
Write VDLR (WVDLR 4Ah)
Before the Write VDLR (WVDLR) command can be accepted by the device, a Write Enable (WREN) command must
be issued and decoded by the device. After the Write Enable (WREN) command has been decoded successfully,
the device will set the Write Enable Latch (WEL) to enable WVDLR operation.
The WVDLR command is entered by shifting the instruction and the data byte on SI.
CS# must be driven to the logic HIGH state after the eighth (8th) bit of data has been latched. If not, the WVDLR
command is not executed. As soon as CS# is driven to the logic HIGH state, the WVDLR operation is initiated with
no delays. The maximum clock frequency for the PNVDLR command is 133 MHz.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
Phase
Instruction
Input Data
Figure 64
Write VDLR (WVDLR) command sequence
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Commands
9.3.11
Data Learning Pattern Read (DLPRD 41h)
The instruction is shifted on SI, then the 8-bit DLP is shifted out on SO. It is possible to read the DLP continuously
by providing multiples of eight clock cycles. The maximum operating clock frequency for the DLPRD command
is 133 MHz.
CS#
SCK
SI
SO
7 6 5 4 3 2 1 0
7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Repeat Register Read
Instruction
Register Read
Phase
Figure 65
DLP Read (DLPRD) command sequence
9.3.12
Enter 4-Byte Address Mode (4BAM B7h)
The enter 4-byte Address Mode (4BAM) command sets the volatile Address Length bit (CR2V[7]) to 1 to change
most 3-byte address commands to require 4 bytes of address. The Read SFDP (RSFDP) command is the only
3-byte command that is not affected by the Address Length bit. RSFDP is required by the JEDEC JESD216 standard
to always have only 3 bytes of address.
A hardware or software reset is required to exit the 4-byte address mode.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
Phase
Instruction
Figure 66
Enter 4-Byte Address Mode (4BAM B7h) command sequence
9.3.13
Read Any Register (RDAR 65h)
The Read Any Register (RDAR) command provides a way to read all device registers - non-volatile and volatile.
The instruction is followed by a 3- or 4-byte address (depending on the address length configuration CR2V[7],
followed by a number of latency (dummy) cycles set by CR2V[3:0]. Then the selected register contents are
returned. If the read access is continued the same addressed register contents are returned until the command
is terminated – only one register is read by each RDAR command.
Reading undefined locations provides undefined data.
The RDAR command may be used during embedded operations to read Status Register 1 (SR1V).
The RDAR command is not used for reading registers that act as a window into a larger array: PPBAR, and DYBAR.
There are separate commands required to select and read the location in the array accessed.
The RDAR command will read invalid data from the PASS register locations if the ASP Password protection mode
is selected by programming ASPR[2] to 0.
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SPI Multi-I/O, 1.8 V
Commands
Table 47
Register address map
Byte address
Register name
Description
(Hex)
00000000
00000001
00000002
00000003
00000004
00000005
...
SR1NV
N/A
CR1NV
CR2NV
CR3NV
CR4NV
N/A
Non-volatile Status and Configuration Registers
N/A
00000010
...
NVDLR
N/A
Non-volatile Data Learning Register
N/A
00000020
00000021
00000022
00000023
00000024
00000025
00000026
00000027
...
PASS[7:0]
PASS[15:8]
PASS[23:16]
PASS[31:24]
PASS[39:32]
PASS[47:40]
PASS[55:48]
PASS[63:56]
N/A
Non-volatile Password Register
N/A
00000030
00000031
...
ASPR[7:0]
ASPR[15:8]
N/A
Non-volatile
00800000
00800001
00800002
00800003
00800004
00800005
...
SR1V
SR2V
CR1V
Volatile Status and Configuration Registers
CR2V
CR3V
CR4V
N/A
N/A
00800010
...
VDLR
Volatile Data Learning Register
N/A
N/A
00800040
...
PPBL
Volatile PPB Lock Register
N/A
N/A
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Commands
CS#
SCK
SI
SO
7 6 5 4 3 2 1 0 A
Instruction
1 0
7
6 5 4 3 2 1 0
Data 1
Phase
Address
Dummy Cycles
Figure 67
Read Any Register Read command sequence[50]
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3, two clock
cycles per byte.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
A-3
A-2
A-1
A
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruct.
Address
Dummy
D1
D2
D3
D4
Figure 68
Read Any Register, QPI Mode, command sequence[50]
9.3.14
Write Any Register (WRAR 71h)
The Write Any Register (WRAR) command provides a way to write any device register - non-volatile/volatile. The
instruction is followed by a 3 or 4-byte address (depending on the address length configuration CR2V[7], followed
by one byte of data to write in the address selected register.
Before the WRAR command can be accepted by the device, a Write Enable (WREN) command must be issued and
decoded by the device, which sets the Write Enable Latch (WEL) in the Status Register to enable any write opera-
tions. The WIP bit in SR1V may be checked to determine when the operation is completed. The P_ERR and E_ERR
bits in SR1V may be checked to determine if any error occurred during the operation.
Some registers have a mixture of bit types and individual rules controlling which bits may be modified. Some bits
are read only, some are OTP.
Read only bits are never modified and the related bits in the WRAR command data byte are ignored without
setting a program or erase error indication (P_ERR or E_ERR in SR1V). Hence, the value of these bits in the WRAR
data byte do not matter.
OTP bits may only be programmed to the level opposite of their default state. Writing of OTP bits back to their
default state is ignored and no error is set.
Non-volatile bits which are changed by the WRAR data, require non-volatile register write time (tW) to be updated.
The update process involves an erase and a program operation on the non-volatile register bits. If either the erase
or program portion of the update fails the related error bit and WIP in SR1V will be set to ‘1’.
Volatile bits which are changed by the WRAR data, require the volatile register write time (tCS) to be updated.
Status Register 1 may be repeatedly read (polled) to monitor the Write-In-Progress (WIP) bit (SR1V[0]) and the
error bits (SR1V[6,5]) to determine when the register write is completed or failed. If there is a write failure, the
clear status command is used to clear the error status and enable the device to return to standby state.
Note
50. A = MSb of address = 23 for Address length CR2V[7] = 0, or 31 for CR2V[7] = 1.
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Commands
However, the PPBL register can not be written by the WRAR command. Only the PPB Lock Bit Write (PLBWR)
command can write the PPBL register.
The command sequence and behavior is the same as the PP or 4PP command with only a single byte of data
provided. See “Page Program (PP 02h or 4PP 12h)” on page 109.
The address map of the registers is the same as shown for “Read Any Register (RDAR 65h)” on page 96.
9.3.15
Set Burst Length (SBL C0h)
The Set Burst Length (SBL) command is used to configure the Burst Wrap feature. Burst Wrap is used in
conjunction with Quad I/O Read and DDR Quad I/O Read, in legacy SPI or QPI mode, to access a fixed length and
alignment of data. Certain applications can benefit from this feature by improving the overall system code
execution performance. The Burst Wrap feature allows applications that use cache, to start filling a cache line
with instruction or data from a critical address first, then fill the remainder of the cache line afterwards within a
fixed length (8/16/32/64-bytes) of data, without issuing multiple read commands.
The Set Burst Length (SBL) command writes the CR4V register bits 4, 1, and 0 to enable or disable the wrapped
read feature and set the wrap boundary. Other bits of the CR4V register are not affected by the SBL command.
When enabled the wrapped read feature changes the related read commands from sequentially reading until the
command ends, to reading sequentially wrapped within a group of bytes.
When CR4V[4] = 1, the wrap mode is not enabled and unlimited length sequential read is performed.
When CR4V[4] = 0, the wrap mode is enabled and a fixed length and aligned group of 8-, 16-, 32-, or 64- bytes is
read starting at the byte address provided by the read command and wrapping around at the group alignment
boundary.
The group of bytes is of length and aligned on an 8-, 16-, 32-, or 64- byte boundary. CR4V[1:0] selects the boundary.
See “Configuration Register 4 Volatile (CR4V)” on page 66.
The starting address of the read command selects the group of bytes and the first data returned is the addressed
byte. Bytes are then read sequentially until the end of the group boundary is reached. If the read continues the
address wraps to the beginning of the group and continues to read sequentially. This wrapped read sequence
continues until the command is ended by CS# returning HIGH.
Table 48
Example burst wrap sequences
Wrap
CR4V[4,1:0]
value (Hex)
Start address
boundary
(Hex)
Address Sequence (Hex)
(Bytes)
1X
00
Sequential
8
XXXXXX03 03, 04, 05, 06, 07, 08, 09, 0A, 0B, 0C, 0D, 0E, 0F, 10, 11, 12, 13, 14, 15, 16, 17, 18, ...
XXXXXX00 00, 01, 02, 03, 04, 05, 06, 07, 00, 01, 02, ...
XXXXXX07 07, 00, 01, 02, 03, 04, 05, 06, 07, 00, 01, ...
XXXXXX02 02, 03, 04, 05, 06, 07, 08, 09, 0A, 0B, 0C, 0D, 0E, 0F, 00, 01, 02, 03, ...
XXXXXX0C 0C, 0D, 0E, 0F, 00, 01, 02, 03, 02, 03, 04, 05, 06, 07, 08, 09, 0A, 0B, 0C, 0D, 0E, ...
01
02
16
32
0A, 0B, 0C, 0D, 0E, 0F, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 1A, 1B, 1C, 1D, 1E, 1F,
XXXXXX0A
00, 01, 02, 03, 04, 05, 06, 07, 08, 09, 0A, 0B, 0C, 0D, 0E, 0F, ...
1E, 1F, 00, 01, 02, 03, 04, 05, 06, 07, 08, 09, 0A, 0B, 0C, 0D, 0E, 0F, 10, 11, 12, 13,
XXXXXX1E
14, 15, 16, 17, 18, 19, 1A, 1B, 1C, 1D, 1E, 1F, 00, ...
03, 04, 05, 06, 07, 08, 09, 0A, 0B, 0C, 0D, 0E, 0F, 10, 11, 12, 13, 14, 15, 16, 17, 18,
XXXXXX03 19, 1A, 1B, 1C, 1D, 1E, 1F, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 2A, 2B, 2C, 2D, 2E,
2F, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 3A, 3B, 3C, 3D, 3E, 3F, 00, 01, 02 ...
03
64
2E, 2F, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 3A, 3B, 3C, 3D, 3E, 3F, 00, 01, 02, 03,
XXXXXX2E 04, 05, 06, 07, 08, 09, 0A, 0B, 0C, 0D, 0E, 0F, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19,
1A, 1B, 1C, 1D, 1E, 1F, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 2A, 2B, 2C, 2D, 2E, 2F, ...
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Commands
The power-on reset, hardware reset, or software reset default burst length can be changed by programming
CR4NV with the desired value using the WRAR command.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
Phase
Instruction
Input Data
Figure 69
Set Burst Length command sequence
9.4
Read memory array commands
Read commands for the main flash array provide many options for prior generation SPI compatibility or
enhanced performance SPI:
• Some commands transfer address or data on each rising edge of SCK. These are called Single Data Rate
commands (SDR).
• Some SDR commands transfer address one bit per rising edge of SCK and return data 1 bit of data per rising
edge of SCK. These are called Single width commands.
• Some SDR commands transfer both address and data 2 or 4 bits per rising edge of SCK. These are called Dual
I/O for 2 bit, Quad I/O, and QPI for 4 bit. QPI also transfers instructions 4 bits per rising edge.
• Some commands transfer address and data on both the rising edge and falling edge of SCK. These are called
Double Data Rate (DDR) commands.
• There are DDR commands for 4 bits of address or data per SCK edge. These are called Quad I/O DDR and QPI
DDR for 4 bit per edge transfer.
All of these commands, except QPI Read, begin with an instruction code that is transferred one bit per SCK rising
edge. QPI Read transfers the instruction 4 bits per SCK rising edge.The instruction is followed by either a 3- or
4-byte address transferred at SDR or DDR. Commands transferring address or data 2 or 4 bits per clock edge are
called Multiple I/O (MIO) commands. For S25FS512S devices, the traditional SPI 3-byte addresses are unable to
directly address all locations in the memory array. Separate 4-byte address read commands are provided for
access to the entire address space. These devices may be configured to take a 4-byte address from the host
system with the traditional 3-byte address commands. The 4-byte address mode for traditional commands is
activated by setting the Address Length bit in Configuration Register 2 to 0.
The Quad I/O and QPI commands provide a performance improvement option controlled by mode bits that are
sent following the address bits. The mode bits indicate whether the command following the end of the current
read will be another read of the same type, without an instruction at the beginning of the read. These mode bits
give the option to eliminate the instruction cycles when doing a series of Quad read accesses.
Some commands require delay cycles following the address or mode bits to allow time to access the memory
array - read latency. The delay or read latency cycles are traditionally called dummy cycles. The dummy cycles
are ignored by the memory thus any data provided by the host during these cycles is ‘don’t care’ and the host
may also leave the SI signal at high impedance during the dummy cycles. When MIO commands are used the host
must stop driving the IO signals (outputs are high impedance) before the end of last dummy cycle. When DDR
commands are used the host must not drive the I/O signals during any dummy cycle. The number of dummy
cycles varies with the SCK frequency or performance option selected via the Configuration Register 2 (CR2V[3:0])
Latency Code. Dummy cycles are measured from SCK falling edge to next SCK falling edge. SPI outputs are tradi-
tionally driven to a new value on the falling edge of each SCK. Zero dummy cycles means the returning data is
driven by the memory on the same falling edge of SCK that the host stops driving address or mode bits.
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The DDR commands may optionally have an 8-edge Data Learning Pattern (DLP) driven by the memory, on all
data outputs, in the dummy cycles immediately before the start of data. The DLP can help the host memory
controller determine the phase shift from SCK to data edges so that the memory controller can capture data at
the center of the data eye.
When using SDR I/O commands at higher SCK frequencies (>50 MHz), an LC that provides 1 or more dummy cycles
should be selected to allow additional time for the host to stop driving before the memory starts driving data, to
minimize I/O driver conflict. When using DDR I/O commands with the DLP enabled, an LC that provides 5 or more
dummy cycles should be selected to allow 1 cycle of additional time for the host to stop driving before the
memory starts driving the 4-cycle DLP.
Each read command ends when CS# is returned High at any point during data return. CS# must not be returned
High during the mode or dummy cycles before data returns as this may cause mode bits to be captured incor-
rectly; making it indeterminate as to whether the device remains in continuous read mode.
9.4.1
Read (Read 03h or 4READ 13h)
The instruction
• 03h (CR2V[7] = 0) is followed by a 3-byte address (A23-A0) or
• 03h (CR2V[7] = 1) is followed by a 4-byte address (A31-A0) or
• 13h is followed by a 4-byte address (A31-A0)
Then the memory contents, at the address given, are shifted out on SO. The maximum operating clock frequency
for the READ command is 50 MHz.
The address can start at any byte location of the memory array. The address is automatically incremented to the
next higher address in sequential order after each byte of data is shifted out. The entire memory can therefore
be read out with one single read instruction and address 000000h provided. When the highest address is reached,
the address counter will wrap around and roll back to 000000h, allowing the read sequence to be continued
indefinitely.
CS#
SCK
SI
SO
7 6 5 4 3 2 1 0 A
1 0
7
6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Instruction
Data 1
Data N
Phase
Address
Figure 70
Read command sequence (3-byte address, 03h or 13h)
Note
51. A = MSb of address = 23 for CR2V[7] = 0, or 31 for CR2V[7] = 1 or command 13h.
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9.4.2
Fast Read (FAST_READ 0Bh or 4FAST_READ 0Ch)
The instruction
• 0Bh (CR2V[7] = 0) is followed by a 3-byte address (A23-A0) or
• 0Bh (CR2V[7] = 1) is followed by a 4-byte address (A31-A0) or
• 0Ch is followed by a 4-byte address (A31-A0)
The address is followed by dummy cycles depending on the latency code set in the Configuration Register
CR2V[3:0]. The dummy cycles allow the device internal circuits additional time for accessing the initial address
location. During the dummy cycles the data value on SO is ‘don’t care’ and may be high impedance. Then the
memory contents, at the address given, are shifted out on SO.
The maximum operating clock frequency for FAST READ command is 133 MHz.
The address can start at any byte location of the memory array. The address is automatically incremented to the
next higher address in sequential order after each byte of data is shifted out. The entire memory can therefore
be read out with one single read instruction and address 000000h provided. When the highest address is reached,
the address counter will wrap around and roll back to 000000h, allowing the read sequence to be continued
indefinitely.
CS#
SCK
SI
SO
7 6 5 4 3 2 1 0 A
1 0
7
6 5 4 3 2 1 0
Instruction
Dummy Cycles
Data 1
Phase
Address
Figure 71
Fast Read (FAST_READ) command sequence (3-byte address, 0Bh [CR2V[7] = 0)[52]
9.4.3
Dual I/O Read (DIOR BBh or 4DIOR BCh)
The instruction
• BBh (CR2V[7] = 0) is followed by a 3-byte address (A23-A0) or
• BBh (CR2V[7] = 1) is followed by a 4-byte address (A31-A0) or
• BCh is followed by a 4-byte address (A31-A0)
The Dual I/O Read commands improve throughput with two I/O signals — IO0 (SI) and IO1 (SO). This command
takes input of the address and returns read data two bits per SCK rising edge. In some applications, the reduced
address input and data output time might allow for code execution in place (XIP) i.e. directly from the memory
device.
The maximum operating clock frequency for Dual I/O Read is 133 MHz.
The Dual I/O Read command has continuous read mode bits that follow the address so, a series of Dual I/O Read
commands may eliminate the 8-bit instruction after the first Dual I/O Read command sends a mode bit pattern
of Axh that indicates the following command will also be a Dual I/O Read command. The first Dual I/O Read
command in a series starts with the 8-bit instruction, followed by address, followed by four cycles of mode bits,
followed by an optional latency period. If the mode bit pattern is Axh the next command is assumed to be an
additional Dual I/O Read command that does not provide instruction bits. That command starts with address,
followed by mode bits, followed by optional latency.
Note
52. A = MSb of address = 23 for CR2V[7] = 0, or 31 for CR2V[7] = 1 or command 0Ch.
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Variable latency may be added after the mode bits are shifted into SI and SO before data begins shifting out of
IO0 and IO1. This latency period (dummy cycles) allows the device internal circuitry enough time to access data
at the initial address. During the dummy cycles, the data value on SI and SO are ‘don’t care’ and may be high
impedance. The number of dummy cycles is determined by the frequency of SCK. The latency is configured in
CR2V[3:0].
The continuous read feature removes the need for the instruction bits in a sequence of read accesses and greatly
improves code execution (XIP) performance. The upper nibble (bits 7-4) of the Mode bits control the length of the
next Dual I/O Read command through the inclusion or exclusion of the first byte instruction code. The lower
nibble (bits 3-0) of the Mode bits are ‘don’t care’ (“x”) and may be high impedance. If the Mode bits equal Axh,
then the device remains in Dual I/O Continuous Read Mode and the next address can be entered (after CS# is
raised high and then asserted low) without the BBh or BCh instruction, as shown in Figure 73; thus, eliminating
eight cycles of the command sequence. The following sequences will release the device from Dual I/O Continuous
Read mode; after which, the device can accept standard SPI commands:
1. During the Dual I/O continuous read command sequence, if the Mode bits are any value other than Axh, then
the next time CS# is raised high the device will be released from Dual I/O continuous read mode.
2. Send the Mode Reset command.
Note that the four-mode bit cycles are part of the device’s internal circuitry latency time to access the initial
address after the last address cycle that is clocked into IO0 (SI) and IO1 (SO).
It is important that the I/O signals be set to high-impedance at or before the falling edge of the first data out clock.
At higher clock speeds the time available to turn off the host outputs before the memory device begins to drive
(bus turn around) is diminished. It is allowed and may be helpful in preventing I/O signal contention, for the host
system to turn off the I/O signal outputs (make them high impedance) during the last two ‘don’t care’ mode cycles
or during any dummy cycles.
Following the latency period the memory content, at the address given, is shifted out two bits at a time through
IO0 (SI) and IO1 (SO). Two bits are shifted out at the SCK frequency at the falling edge of SCK signal.
The address can start at any byte location of the memory array. The address is automatically incremented to the
next higher address in sequential order after each byte of data is shifted out. The entire memory can therefore
be read out with one single read instruction and address 000000h provided. When the highest address is reached,
the address counter will wrap around and roll back to 000000h, allowing the read sequence to be continued
indefinitely.
CS# should not be driven high during mode or dummy bits as this may make the mode bits indeterminate.
CS#
SCK
IO0
IO1
7
6
5
4
3
2
1
0
A-1
A
2
3
0
1
6
7
4
5
2
3
0
1
6
7
4
5
2
3
0
1
6
7
4
5
2
3
0
1
Phase
Instruction
Address
Mode
Dum
Data1
Data2
Figure 72
Dual I/O Read command sequence (BBh)[53-55]
Notes
53. A = MSb of address = 23 for Address length (CR2V[7] = 0, or 31 for CR2V[7] = 1 with command BBh.
54. A = MSb of address = 31 with command BBh.
55. Least significant 4 bits of Mode are don’t care and it is optional for the host to drive these bits. The host may turn off
drive during these cycles to increase bus turn around time between Mode bits from host and returning data from the
memory.
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CS#
SCK
IO0
IO1
6
7
4
5
2
3
0
1
A-1
A
2
3
0
1
6
7
4
5
2
3
0
1
6
7
4
5
2
3
0
1
6
7
4
5
2
3
0
1
Phase
DataN
Address
Mode
Dum
Data1
Data2
Figure 73
Dual I/O Continuous Read command sequence (BBh])[56, 57]
9.4.4
Quad I/O Read (QIOR EBh or 4QIOR ECh)
The instruction
• EBh (CR2V[7] = 0) is followed by a 3-byte address (A23-A0) or
• EBh (CR2V[7] = 1) is followed by a 4-byte address (A31-A0) or
• ECh is followed by a 4-byte address (A31-A0)
The Quad I/O Read command improves throughput with four I/O signals: IO0-IO3. It allows input of the address
bits four bits per serial SCK clock. In some applications, the reduced instruction overhead might allow for code
execution (XIP) directly from S25FS512S devices. The QUAD bit of the configuration register must be set (CR1V[1]
= 1) to enable the Quad capability of S25FS512S devices.
The maximum operating clock frequency for Quad I/O Read is 133 MHz.
For the Quad I/O Read command, there is a latency required after the mode bits (described below) before data
begins shifting out of IO0-IO3. This latency period (i.e., dummy cycles) allows the device’s internal circuitry
enough time to access data at the initial address. During latency cycles, the data value on IO0-IO3 are ‘don’t care’
and may be high impedance. The number of dummy cycles is determined by the frequency of SCK. The latency
is configured in CR2V[3:0].
Following the latency period, the memory contents at the address given, is shifted out four bits at a time through
IO0-IO3. Each nibble (4 bits) is shifted out at the SCK frequency by the falling edge of the SCK signal.
The address can start at any byte location of the memory array. The address is automatically incremented to the
next higher address in sequential order after each byte of data is shifted out. The entire memory can therefore
be read out with one single read instruction and address 000000h provided. When the highest address is reached,
the address counter will wrap around and roll back to 000000h, allowing the read sequence to be continued
indefinitely.
Address jumps can be done without the need for additional Quad I/O Read instructions. This is controlled through
the setting of the Mode bits (after the address sequence, as shown in Figure 74). This added feature removes the
need for the instruction sequence and greatly improves code execution (XIP). The upper nibble (bits 7-4) of the
Mode bits control the length of the next Quad I/O instruction through the inclusion or exclusion of the first byte
instruction code. The lower nibble (bits 3-0) of the Mode bits are ‘don’t care’ (x). If the Mode bits equal Axh, then
the device remains in Quad I/O High Performance Read Mode and the next address can be entered (after CS# is
raised HIGH and then asserted low) without requiring the EBh or ECh instruction, as shown in Figure 76; thus,
eliminating eight cycles for the command sequence.
The following sequences will release the device from Quad I/O High Performance Read mode; after which, the
device can accept standard SPI commands:
1. During the Quad I/O Read Command Sequence, if the Mode bits are any value other than Axh, then the next
time CS# is raised HIGH the device will be released from Quad I/O High Performance Read mode.
2. Send the Mode Reset command.
Notes
56. A = MSb of address = 23 for Address length (CR2V[7] = 0, or 31 for CR2V[7] = 1 with command BBh.
57. A = MSb of address = 31 with command BBh.
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Note that the two mode bit clock cycles and additional wait states (i.e., dummy cycles) allow the device’s internal
circuitry latency time to access the initial address after the last address cycle that is clocked into IO0-IO3.
It is important that the IO0-IO3 signals be set to high-impedance at or before the falling edge of the first data out
clock. At higher clock speeds the time available to turn off the host outputs before the memory device begins to
drive (bus turn around) is diminished. It is allowed and may be helpful in preventing IO0-IO3 signal contention,
for the host system to turn off the IO0-IO3 signal outputs (make them high impedance) during the last ‘don’t care’
mode cycle or during any dummy cycles.
CS# should not be driven high during mode or dummy bits as this may make the mode bits indeterminate.
In QPI mode (CR2V[6] = 1), the Quad I/O instructions are sent 4 bits per SCK rising edge. The remainder of the
command protocol is identical to the Quad I/O commands.
CS#
SCK
IO0
IO1
7
6
5
4
3
2
1
0
A-3
A-2
A-1
A
4
5
6
7
0
1
2
3
4
5
6
7
0
1
0
1
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruction
Address Mode
Dummy
D1
D2
D3
D4
Figure 74
Quad I/O Read command sequence (EBh or ECh)[58, 59]
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
A-3
A-2
A-1
A
4
5
6
7
0
1
2
3
4
5
6
7
4
5
6
7
0
1
2
3
4
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
5
6
7
IO2
0
1
IO3
Phase
Instruct.
Address
Mode
Dummy
D1
D2
D3
D4
Figure 75
Quad I/O Read command sequence (EBh or ECh), QPI Mode[58, 59]
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
A-3
A-2
A-1
A
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
IO2
IO3
Phase
DN-1
DN
Address
Mode
Dummy
D1
D2
D3
D4
Figure 76
Continuous Quad I/O Read command sequence (EBh or ECh)[58, 59]
Notes
58. A = MSb of address = 23 for Address length (CR2V[7] = 0, or 31 for CR2V[7] = 1 with command EBh.
59. A = MSb of address = 31 with command ECh.
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Commands
9.4.5
DDR Quad I/O Read (EDh, EEh)
The DDR Quad I/O Read command improves throughput with four I/O signals: IO0-IO3. It is similar to the Quad
I/O Read command but allows input of the address four bits on every edge of the clock. In some applications, the
reduced instruction overhead might allow for code execution (XIP) directly from S25FS512S devices. The QUAD
bit of the Configuration Register must be set (CR1V[1] = 1) to enable the Quad capability.
The instruction
• EDh (CR2V[7] = 0) is followed by a 3-byte address (A23-A0) or
• EDh (CR2V[7] = 1) is followed by a 4-byte address (A31-A0) or
• EEh is followed by a 4-byte address (A31-A0)
The address is followed by mode bits. Then the memory contents, at the address given, is shifted out, in a DDR
fashion, with four bits at a time on each clock edge through IO0-IO3.
The maximum operating clock frequency for DDR Quad I/O Read command is 80 MHz.
For DDR Quad I/O Read, there is a latency required after the last address and mode bits are shifted into the IO0-IO3
signals before data begins shifting out of IO0-IO3. This latency period (dummy cycles) allows the device’s internal
circuitry enough time to access the initial address. During these latency cycles, the data value on IO0-IO3 are
‘don’t care’ and may be high impedance. When the Data Learning Pattern (DLP) is enabled the host system must
not drive the IO signals during the dummy cycles. The IO signals must be left high impedance by the host so that
the memory device can drive the DLP during the dummy cycles.
The number of dummy cycles is determined by the frequency of SCK. The latency is configured in CR2V[3:0].
Mode bits allow a series of Quad I/O DDR commands to eliminate the 8-bit instruction after the first command
sends a complementary mode bit pattern, as shown in Figure 77. This feature removes the need for the eight bit
SDR instruction sequence and dramatically reduces initial access times (improves XIP performance). The Mode
bits control the length of the next DDR Quad I/O Read operation through the inclusion or exclusion of the first
byte instruction code. If the upper nibble (IO[7:4]) and lower nibble (IO[3:0]) of the Mode bits are complementary
(i.e. 5h and Ah) the device transitions to Continuous DDR Quad I/O Read Mode and the next address can be
entered (after CS# is raised HIGH and then asserted LOW) without requiring the EDh or EEh instruction, as shown
in Figure 78, thus eliminating eight cycles from the command sequence. The following sequences will release
the device from Continuous DDR Quad I/O Read mode; after which, the device can accept standard SPI
commands:
1. During the DDR Quad I/O Read Command Sequence, if the Mode bits are not complementary the next time CS#
is raised high and then asserted low the device will be released from DDR Quad I/O Read mode.
2. Send the Mode Reset command.
The address can start at any byte location of the memory array. The address is automatically incremented to the
next higher address in sequential order after each byte of data is shifted out. The entire memory can therefore
be read out with one single read instruction and address 000000h provided. When the highest address is reached,
the address counter will wrap around and roll back to 000000h, allowing the read sequence to be continued
indefinitely.
CS# should not be driven HIGH during mode or dummy bits as this may make the mode bits indeterminate. Note
that the memory devices may drive the IOs with a preamble prior to the first data value. The preamble is a Data
Learning Pattern (DLP) that is used by the host controller to optimize data capture at higher frequencies. The
preamble drives the IO bus for the four clock cycles immediately before data is output. The host must be sure to
stop driving the IO bus prior to the time that the memory starts outputting the preamble.
The preamble is intended to give the host controller an indication about the round trip time from when the host
drives a clock edge to when the corresponding data value returns from the memory device. The host controller
will skew the data capture point during the preamble period to optimize timing margins and then use the same
skew time to capture the data during the rest of the read operation. The optimized capture point will be deter-
mined during the preamble period of every read operation. This optimization strategy is intended to compensate
for both the PVT (process, voltage, temperature) of both the memory device and the host controller as well as
any system level delays caused by flight time on the PCB.
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512 Mb (64 MB) FS-S Flash
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Commands
Although the data learning pattern (DLP) is programmable, the following example shows example of the DLP of
34h. The DLP 34h (or 00110100) will be driven on each of the active outputs (i.e. all four SIOs). This pattern was
chosen to cover both ‘DC’ and ‘AC’ data transition scenarios. The two DC transition scenarios include data low
for a long period of time (two half clocks) followed by a high going transition (001) and the complementary low
going transition (110). The two AC transition scenarios include data low for a short period of time (one half clock)
followed by a high going transition (101) and the complementary low going transition (010). The DC transitions
will typically occur with a starting point closer to the supply rail than the AC transitions that may not have fully
settled to their steady state (DC) levels. In many cases the DC transitions will bound the beginning of the data
valid period and the AC transitions will bound the ending of the data valid period. These transitions will allow the
host controller to identify the beginning and ending of the valid data eye. Once the data eye has been charac-
terized the optimal data capture point can be chosen. See “SPI DDR Data Learning Registers” on page 69 for
more details.
In QPI mode (CR2V[6] = 1), the DDR Quad I/O instructions are sent 4 bits per SCK rising edge. The remainder of the
command protocol is identical to the DDR Quad I/O commands.
CS#
SCK
IO0
IO1
A-2
A-2
A-1
A
7
6
5
4
3
2
1
0
12
13
8
9
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
7
7
7
7
6
6
6
6
5
5
5
5
4
4
4
4
3
3
3
3
2
2
2
2
1
1
1
1
0
0
0
0
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
IO2
14 10
15 11
IO3
Phase
Instruction
Address Mode
Dummy
DLP
D1 D2
Figure 77
DDR Quad I/O Read Initial Access (EDh or EEh)[60, 61]
CS#
SCK
IO0
IO1
A-3
A-2
A-1
A
12
13
8
9
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
4
5
6
7
0
1
2
3
4
0
1
2
3
4
5
6
7
0
1
2
3
1
2
3
5
6
7
IO2
14 10
15 11
Address
IO3
Phase
Mode
Dummy
D1
D2
D3
D4
D5
Figure 78
Continuous DDR Quad I/O Read Subsequent Access (EDh or EEh)[60, 61]
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
A-3
A-2
A-1
A
12
13
8
9
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
7
7
7
7
6
6
6
6
5
5
5
5
4
4
4
4
3
3
3
3
2
2
2
2
1
1
1
1
0
0
0
0
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
IO2
14 10
15 11
IO3
Phase
Instruct.
Address
Mode
Dummy
DLP
D1
D2
Figure 79
Notes
DDR Quad I/O Read Initial Access (EDh or EEh), QPI mode[60, 61]
60. A = MSb of address = 23 for Address length (CR2V[7] = 0, or 31 for CR2V[7] = 1 with command EDh.
61. A = MSb of address = 31 with command EEh.
Datasheet
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Commands
9.5
Program Flash array commands
9.5.1
Program granularity
9.5.1.1
Automatic ECC
Each 16 byte aligned and 16 byte length Programming Block has an automatic Error Correction Code (ECC) value.
The data block plus ECC form an ECC unit. In combination with Error Detection and Correction (EDC) logic the
ECC is used to detect and correct any single bit error found during a read access. When data is first programmed
within an ECC unit the ECC value is set for the entire ECC unit. If the same ECC unit is programmed more than once
the ECC value is changed to disable the EDC function. A sector erase is needed to again enable Automatic ECC on
that Programming Block. The 16 byte Program Block is the smallest program granularity on which Automatic ECC
is enabled.
These are automatic operations transparent to the user. The transparency of the Automatic ECC feature
enhances data accuracy for typical programming operations which write data once to each ECC unit but, facili-
tates software compatibility to previous generations of FL family of products by still allowing for single byte
programming and bit walking in which the same ECC unit is programmed more than once. When an ECC unit has
Automatic ECC disabled, EDC is not done on data read from the ECC unit location.
An ECC status register is provided for determining if ECC is enabled on an ECC unit and whether any errors have
been detected and corrected in the ECC unit data or the ECC. The ECC Status Register Read (ECCRD) command
is used to read the ECC status on any ECC unit.
Error Detection and Correction (EDC) is applied to all parts of the Flash address spaces other than registers. An
Error Correction Code (ECC) is calculated for each group of bytes protected and the ECC is stored in a hidden area
related to the group of bytes. The group of protected bytes and the related ECC are together called an ECC unit.
• ECC is calculated for each 16 byte aligned and length ECC unit
• Single Bit EDC is supported with 8 ECC bits per ECC unit, plus 1 bit for an ECC disable Flag
• Sector erase resets all ECC disable flags in a sector to the default state (enabled)
• ECC is programmed as part of the standard Program commands operation
• ECC is disabled automatically if multiple programming operations are done on the same ECC unit.
• Single byte programming or bit walking is allowed but disables ECC on the second program to the same 16 byte
ECC unit.
• The ECC disable flag is programmed when ECC is disabled
• To re-enable ECC for an ECC unit that has been disabled, the Sector that includes the ECC unit must be erased
• To ensure the best data integrity provided by EDC, each ECC unit should be programmed only once so that ECC
is stored for that unit and not disabled.
• The calculation, programming, and disabling of ECC is done automatically as part of programming operations.
The detection and correction if needed is done automatically as part of read operations. The host system sees
only corrected data from a read operation.
• ECC protects the OTP region — however a second program operation on the same ECC unit will disable ECC
permanently on that ECC unit (OTP is one time programmable, hence an erase operation to re-enable the ECC
enable/indicator bit is prohibited)
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Commands
9.5.1.2
Page programming
Page Programming is done by loading a Page Buffer with data to be programmed and issuing a programming
command to move data from the buffer to the memory array. This sets an upper limit on the amount of data that
can be programmed with a single programming command. Page Programming allows up to a page size (either
256 or 512 bytes) to be programmed in one operation. The page size is determined by the configuration register
bit CR3V[4]. The page is aligned on the page size address boundary. It is possible to program from one bit up to
a page size in each Page programming operation. It is recommended that a multiple of 16-byte length and aligned
Program Blocks be written. This insures that Automatic ECC is not disabled. For the very best performance,
programming should be done in full pages of 512 bytes aligned on 512-byte boundaries with each Page being
programmed only once.
9.5.1.3
Single byte programming
Single Byte Programming allows full backward compatibility to the legacy standard SPI Page Programming (PP)
command by allowing a single byte to be programmed anywhere in the memory array. While single byte
programming is supported, this will disable Automatic ECC on the 16 byte ECC unit where the byte is located.
9.5.2
Page Program (PP 02h or 4PP 12h)
The Page Program (PP) command allows bytes to be programmed in the memory (changing bits from 1 to 0).
Before the Page Program (PP) commands can be accepted by the device, a Write Enable (WREN) command must
be issued and decoded by the device. After the Write Enable (WREN) command has been decoded successfully,
the device sets the Write Enable Latch (WEL) in the Status Register to enable any write operations.
The instruction
• 02h (CR2V[7] = 0) is followed by a 3-byte address (A23-A0) or
• 02h (CR2V[7] = 1) is followed by a 4-byte address (A31-A0) or
• 12h is followed by a 4-byte address (A31-A0)
and at least one data byte on SI. Depending on CR3V[4], the page size can either be 256 or 512 bytes. Up to a page
can be provided on SI after the 3-byte address with instruction 02h or 4-byte address with instruction 12h has
been provided.
If more data is sent to the device than the space between the starting address and the page aligned end boundary,
the data loading sequence will wrap from the last byte in the page to the zero byte location of the same page and
begin overwriting any data previously loaded in the page. The last page worth of data is programmed in the page.
This is a result of the device being equipped with a page program buffer that is only page size in length. If less
than a page of data is sent to the device, these data bytes will be programmed in sequence, starting at the
provided address within the page, without having any affect on the other bytes of the same page.
Using the Page Program (PP) command to load an entire page, within the page boundary, will save overall
programming time versus loading less than a page into the program buffer.
The programming process is managed by the flash memory device internal control logic. After a programming
command is issued, the programming operation status can be checked using the Read Status Register 1
command. The WIP bit (SR1V[0]) will indicate when the programming operation is completed. The P_ERR bit
(SR1V[6]) will indicate if an error occurs in the programming operation that prevents successful completion of
programming. This includes attempted programming of a protected area.
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Commands
CS#
SCK
SI
SO
7
6
5
4 3
2
1
0 A
5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Phase
Instruction
Address
Input Data 1
Input Data2
Figure 80
Page Program (PP 02h or 4PP 12h) command sequence[62]
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3, two clock
cycles per byte.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
A-3
A-2
A-1
A
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruct.
Address
Input D1 Input D2 Input D3 Input D4
Figure 81
Page Program (PP 02h or 4PP 12h) QPI mode command sequence[62]
9.6
Erase Flash Array commands
9.6.1
Parameter 4 KB-Sector erase (P4E 20h or 4P4E 21h)
The main flash array address map may be configured to overlay 4-KB parameter sectors over the lowest address
portion of the lowest address uniform sector (bottom parameter sectors) or over the highest address portion of
the highest address uniform sector (top parameter sectors). The main flash array address map may also be
configured to have only uniform size sectors. The parameter sector configuration is controlled by the configu-
ration bit CR3V[3]. The P4E and 4P4E commands are ignored when the device is configured for uniform sectors
only (CR3V[3] = 1).
The Parameter 4 KB-sector Erase commands set all the bits of a 4-KB parameter sector to 1 (all bytes are FFh).
Before the P4E or 4P4E command can be accepted by the device, a Write Enable (WREN) command must be issued
and decoded by the device, which sets the Write Enable Latch (WEL) in the Status Register to enable any write
operations.
The instruction
• 20h [CR2V[7] = 0] is followed by a 3-byte address (A23-A0), or
• 20h [CR2V[7] = 1] is followed by a 4-byte address (A31-A0), or
• 21h is followed by a 4-byte address (A31-A0)
CS# must be driven into the logic HIGH state after the twenty-fourth or thirty-second bit of the address has been
latched in on SI. This will initiate the beginning of internal erase cycle, which involves the pre-programming and
erase of the chosen sector of the flash memory array. If CS# is not driven HIGH after the last bit of address, the
sector erase operation will not be executed.
As soon as CS# is driven HIGH, the internal erase cycle will be initiated. With the internal erase cycle in progress,
the user can read the value of the Write-In Progress (WIP) bit to determine when the operation has been
completed. The WIP bit will indicate a ‘1’. when the erase cycle is in progress and a ‘0’ when the erase cycle has
been completed.
Note
62. A = MSb of address = A23 for PP 02h, or A31 for 4PP 12h.
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512 Mb (64 MB) FS-S Flash
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Commands
A P4E or 4P4E command applied to a sector that has been write protected through the Block Protection bits or
ASP, will not be executed and will set the E_ERR status. A P4E command applied to a sector that is larger than
4 KB will not be executed and will not set the E_ERR status.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
A
1
0
Phase
Instruction
Address
Figure 82
Parameter Sector Erase (P4E 20h or 4P4E 21h) command sequence[63]
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3, two clock
cycles per byte.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
A-3
A-2
A-1
A
4
0
1
2
3
5
IO2
6
7
IO3
Phase
Instructtion
Address
Figure 83
Parameter Sector Erase (P4E 20h or 4P4E 21h) QPI mode command sequence[63]
9.6.2
Sector Erase (SE D8h or 4SE DCh)
The Sector Erase (SE) command sets all bits in the addressed sector to 1 (all bytes are FFh). Before the Sector
Erase (SE) command can be accepted by the device, a Write Enable (WREN) command must be issued and
decoded by the device, which sets the Write Enable Latch (WEL) in the Status Register to enable any write opera-
tions.
The instruction
• D8h [CR2V[7] = 0] is followed by a 3-byte address (A23-A0), or
• D8h [CR2V[7] = 1] is followed by a 4-byte address (A31-A0), or
• DCh is followed by a 4-byte address (A31-A0)
CS# must be driven into the logic HIGH state after the twenty-fourth or thirty-second bit of address has been
latched in on SI. This will initiate the erase cycle, which involves the pre-programming and erase of the chosen
sector. If CS# is not driven HIGH after the last bit of address, the sector erase operation will not be executed.
As soon as CS# is driven into the logic HIGH state, the internal erase cycle will be initiated. With the internal erase
cycle in progress, the user can read the value of the Write-In Progress (WIP) bit to check if the operation has been
completed. The WIP bit will indicate a ‘1’ when the erase cycle is in progress and a ‘0’ when the erase cycle has
been completed.
A Sector Erase (SE) command applied to a sector that has been Write Protected through the Block Protection bits
or ASP, will not be executed and will set the E_ERR status.
Note
63. A = MSb of address = A23 for P4E 20h with CR2V[7] = 0, or A31 for P4E 20h with CR2V[7] = 1 or 4P4E 21h.
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Commands
A device configuration option (CR3V[3]) determines whether 4-KB parameter sectors are in use. When CR3V[3] =
0, 4-KB parameter sectors overlay a portion of the highest or lowest address 32-KB of the device address space.
If a sector erase command is applied to a 256-KB range that is overlaid by 4-KB sectors, the overlaid 4-KB sectors
are not affected by the erase. When CR3V[3] = 1, there are no 4-KB parameter sectors in the device address space
and the Sector Erase command always operates on fully visible 256-KB sectors.
ASP has a PPB and a DYB protection bit for each physical sector, including any 4-KB sectors.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
A
1
0
Phase
Instruction
Address
Figure 84
Sector Erase (SE D8h or 4SE DCh) command sequence[64]
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3, two clock
cycles per byte.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
A-3
A-2
A-1
A
4
0
1
2
3
5
IO2
6
7
IO3
Phase
Instruction
Address
Figure 85
Sector Erase (SE D8h or 4SE DCh) QPI mode command sequence[64]
Note
64. A = MSb of address = A23 for SE D8h with CR2V[7] = 0, or A31 for SE D8h with CR2V[7] = 1 or 4P4E DCh.
Datasheet
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Commands
9.6.3
Bulk Erase (BE 60h or C7h)
The Bulk Erase (BE) command sets all bits to 1 (all bytes are FFh) inside the entire flash memory array. Before the
BE command can be accepted by the device, a Write Enable (WREN) command must be issued and decoded by
the device, which sets the Write Enable Latch (WEL) in the Status Register to enable any write operations.
CS# must be driven into the logic HIGH state after the eighth bit of the instruction byte has been latched in on SI.
This will initiate the erase cycle, which involves the pre-programming and erase of the entire flash memory array.
If CS# is not driven HIGH after the last bit of instruction, the BE operation will not be executed.
As soon as CS# is driven into the logic HIGH state, the erase cycle will be initiated. With the erase cycle in progress,
the user can read the value of the Write-In Progress (WIP) bit to determine when the operation has been
completed. The WIP bit will indicate a ‘1’ when the erase cycle is in progress and a ‘0’ when the erase cycle has
been completed.
A BE command can be executed only when the Block Protection (BP2, BP1, BP0) bits are set to ‘0’s. If the BP bits
are not zero, the BE command is not executed and E_ERR is not set. The BE command will skip any sectors
protected by the DYB or PPB and the E_ERR status will not be set.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
Phase
Instruction
Figure 86
Bulk Erase command sequence
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3, two clock
cycles per byte.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruction
Figure 87
Bulk Erase command sequence QPI mode
Datasheet
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Commands
9.6.4
Evaluate Erase Status (EES D0h)
The Evaluate Erase Status (EES) command verifies that the last erase operation on the addressed sector was
completed successfully. If the selected sector was successfully erased the erase status bit (SR2V[2]) is set to ‘1’.
If the selected sector was not completely erased SR2V[2] is 0.
The EES command can be used to detect erase operations failed due to loss of power, reset, or failure during the
erase operation.
The EES instruction is followed by a 3- or 4-byte address, depending on the address length configuration
(CR2V[7]). The EES command requires tEES to complete and update the erase status in SR2V. The WIP bit
(SR1V[0]) may be read using the RDSR1 (05h) command, to determine when the EES command is finished. Then
the RDSR2 (07h) or the RDAR (65h) command can be used to read SR2V[2]. If a sector is found not erased with
SR2V[2] = 0, the sector must be erased again to ensure reliable storage of data in the sector.
The Write Enable command (to set the WEL bit) is not required before the EES command. However, the WEL bit
is set by the device itself and cleared at the end of the operation, as visible in SR1V[1] when reading status.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
A
1
0
Phase
Instruction
Address
Figure 88
EES command sequence[64]
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3, two clock
cycles per byte.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
A-3
A-2
A-1
A
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruction
Address
Figure 89
EES QPI mode command sequence[64]
Note
65. A = MSb of address = A23 for CR2V[7] = 0, or A31 for CR2V[7] = 1.
Datasheet
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Commands
9.6.5
Erase or Program Suspend (EPS 85h, 75h, B0h)
There are three instruction codes for Program or Erase Suspend (EPS) to enable legacy and alternate source
software compatibility.
The EPS command allows the system to interrupt a programming or erase operation and then read from any
other non-erase-suspended sector or non-program-suspended-page. Program or Erase Suspend is valid only
during a programming or sector erase operation. A Bulk Erase operation cannot be suspended.
The Write in Progress (WIP) bit in Status Register 1 (SR1V[0]) must be checked to know when the programming or
erase operation has stopped. The Program Suspend Status bit in the Status Register 2 (SR2[0]) can be used to
determine if a programming operation has been suspended or was completed at the time WIP changes to 0. The
Erase Suspend Status bit in the Status Register 2 (SR2[1]) can be used to determine if an erase operation has been
suspended or was completed at the time WIP changes to 0. The time required for the suspend operation to
complete is tSL (see Table 51).
An Erase can be suspended to allow a program operation or a read operation. During an erase suspend, the DYB
array may be read to examine sector protection and written to remove or restore protection on a sector to be
programmed.
A program operation may be suspended to allow a read operation.
A new erase operation is not allowed with an already suspended erase or program operation. An erase command
is ignored in this situation.
Datasheet
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512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Commands
Table 49
Commands allowed during program or erase suspend
Instruction Instruction Allowed during Allowed during
Comment
name
code (Hex) erase suspend program suspend
Required for array program during erase suspend. Only
allowed if there is no other program suspended program
operation (SR2V[0] = 0). A program command will be
ignored while there is a suspended program. If a program
command is sent for a location within an erase
suspended sector the program operation will fail with the
P_ERR bit set.
PP
02
–
X
–
READ
03
05
All array reads allowed in suspend.
Needed to read WIP to determine end of suspend
process.
RDSR1
Alternate way to read WIP to determine end of suspend
process.
RDAR
WREN
RDSR2
65
06
07
Required for program command within erase suspend.
Needed to read suspend status to determine whether the
operation is suspended or complete.
Required for array program during erase suspend. Only
allowed if there is no other program suspended program
operation (SR2V[0] = 0). A program command will be
ignored while there is a suspended program. If a program
command is sent for a location within an erase
suspended sector the program operation will fail with the
P_ERR bit set.
4PP
12
4READ
CLSR
13
30
X
–
All array reads allowed in suspend.
Clear status may be used if a program operation fails
during erase suspend. Note the instruction is only valid if
enabled for clear status by CR4NV[2=1].
X
Clear status may be used if a program operation fails
during erase suspend.
CLSR
EPR
82
30
–
Required to resume from erase or program suspend.
Note the command must be enabled for use as a resume
command by CR3NV[2] = 1.
EPR
EPR
7A
8A
66
99
0B
0C
7A
8A
BB
BC
Required to resume from erase or program suspend.
Reset allowed anytime.
X
RSTEN
RST
FAST_READ
4FAST_READ
EPR
All array reads allowed in suspend.
Required to resume from erase suspend.
All array reads allowed in suspend.
–
X
EPR
DIOR
4DIOR
It may be necessary to remove and restore dynamic
protection during erase suspend to allow programming
during erase suspend.
DYBRD
FA
It may be necessary to remove and restore dynamic
protection during erase suspend to allow programming
during erase suspend.
–
DYBWR
PPBRD
FB
FC
Allowed for checking persistent protection before
attempting a program command during erase suspend.
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Commands
Table 49
Commands allowed during program or erase suspend (continued)
Instruction Instruction Allowed during Allowed during
Comment
name
code (Hex) erase suspend program suspend
4DYBRD
E0
It may be necessary to remove and restore dynamic
protection during erase suspend to allow programming
during erase suspend.
4DYBWR
4PPBRD
E1
–
Allowed for checking persistent protection before
E2
EB
attempting a program command during erase suspend.
QIOR
4QIOR
X
EC
All array reads allowed in suspend.
DDRQIOR
4DDRQIOR
RESET
ED
X
EE
F0
FF
Reset allowed anytime.
MBR
May need to reset a read operation during suspend.
Reading at any address within an erase-suspended sector or program-suspended page produces undetermined
data.
The WRR, WRAR, or PPB Erase commands are not allowed during Erase or Program Suspend, it is therefore not
possible to alter the Block Protection or PPB bits during Erase Suspend. If there are sectors that may need
programming during Erase suspend, these sectors should be protected only by DYB bits that can be turned off
during Erase Suspend.
After an erase-suspended program operation is complete, the device returns to the erase-suspend mode. The
system can determine the status of the program operation by reading the WIP bit in the Status Register, just as
in the standard program operation.
tSL
CS#
SCK
SI
SO
7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
7 6 5 4 3 2 1 0
Instr. During Suspend
7 6 5 4 3 2 1 0
Read Status Instruction
Status
Phase
Phase
Suspend Instruction
Repeat Status Read Until Suspended
Figure 90
Program or Erase Suspend command sequence
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
Phase
Instruction
Figure 91
Erase or Program Suspend command sequence
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Commands
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3, two clock
cycles per byte.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruction
Figure 92
Erase or Program Suspend command sequence QPI mode
9.6.6
Erase or Program Resume (EPR 7Ah, 8Ah, 30h)
An Erase or Program Resume command must be written to resume a suspended operation. There are three
instruction codes for Erase or Program Resume (EPR) to enable legacy and alternate source software compati-
bility.
After program or read operations are completed during a program or erase suspend the Erase or Program
Resume command is sent to continue the suspended operation.
After an Erase or Program Resume command is issued, the WIP bit in the Status Register 1 will be set to ‘1’ and
the programming operation will resume if one is suspended. If no program operation is suspended the
suspended erase operation will resume. If there is no suspended program or erase operation the resume
command is ignored.
Program or erase operations may be interrupted as often as necessary, e.g. a program suspend command could
immediately follow a program resume command but, in order for a program or erase operation to progress to
completion there must be some periods of time between resume and the next suspend command greater than
or equal to tRS (see Table 51).
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
Phase
Instruction
Figure 93
Erase or Program Resume command sequence
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruction
Figure 94
Erase or Program Resume command sequence QPI mode
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Commands
9.7
One time program array commands
OTP Program (OTPP 42h)
9.7.1
The OTP Program command programs data in the One Time Program region, which is in a different address space
from the main array data. The OTP region is 1024 bytes so, the address bits from A31 to A10 must be zero for this
command. Refer to “OTP address space” on page 50 for details on the OTP region.
Before the OTP Program command can be accepted by the device, a Write Enable (WREN) command must be
issued and decoded by the device, which sets the Write Enable Latch (WEL) in the status register to enable any
write operations. The WIP bit in SR1V may be checked to determine when the operation is completed. The P_ERR
bit in SR1V may be checked to determine if any error occurred during the operation.
To program the OTP array in bit granularity, the rest of the bits within a data byte can be set to ‘1’.
Each region in the OTP memory space can be programmed one or more times, provided that the region is not
locked. Attempting to program zeros in a region that is locked will fail with the P_ERR bit in SR1V set to ‘1’.
Programming ones, even in a protected area does not cause an error and does not set P_ERR. Subsequent OTP
programming can be performed only on the un-programmed bits (that is, 1 data). Programming more than once
within an ECC unit will disable ECC on that unit.
The protocol of the OTP Program command is the same as the Page Program command. See “Page Program (PP
02h or 4PP 12h)” on page 109 for the command sequence.
9.7.2
OTP Read (OTPR 4Bh)
The OTP Read command reads data from the OTP region. The OTP region is 1024 bytes so, the address bits from
A31 to A10 must be zero for this command. Refer to “OTP address space” on page 50 for details on the OTP
region. The protocol of the OTP Read command is similar to the Fast Read command except that it will not wrap
to the starting address after the OTP address is at its maximum; instead, the data beyond the maximum OTP
address will be undefined. The OTP Read command read latency is set by the latency value in CR2V[3:0]. See
“Fast Read (FAST_READ 0Bh or 4FAST_READ 0Ch)” on page 102 for the command sequence.
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Commands
9.8
Advanced Sector Protection commands
ASP Read (ASPRD 2Bh)
9.8.1
The ASP Read instruction 2Bh is shifted into SI by the rising edge of the SCK signal. Then the 16-bit ASP register
contents are shifted out on the serial output SO, least significant byte first. Each bit is shifted out at the SCK
frequency by the falling edge of the SCK signal. It is possible to read the ASP register continuously by providing
multiples of 16 clock cycles. The maximum operating clock frequency for the ASP Read (ASPRD) command is 133
MHz.
CS#
SCK
SI
SO
7
6 5 4 3 2 1 0
7
6
5
4
3
2
1
0
7
6 5 4 3 2 1 0
Phase
Instruction
Output ASPR Low Byte Output ASPR High Byte
Figure 95
ASPRD command
9.8.2
ASP Program (ASPP 2Fh)
Before the ASP Program (ASPP) command can be accepted by the device, a Write Enable (WREN) command must
be issued. After the Write Enable (WREN) command has been decoded, the device will set the Write Enable Latch
(WEL) in the Status Register to enable any write operations.
The ASPP command is entered by driving CS# to the logic LOW state, followed by the instruction and two data
bytes on SI, least significant byte first. The ASP Register is two data bytes in length.
The ASPP command affects the P_ERR and WIP bits of the status and configuration registers in the same manner
as any other programming operation.
CS# input must be driven to the logic HIGH state after the sixteenth bit of data has been latched in. If not, the
ASPP command is not executed. As soon as CS# is driven to the logic HIGH state, the self-timed ASPP operation
is initiated. While the ASPP operation is in progress, the status register may be read to check the value of the
Write-In Progress (WIP) bit. The Write-In Progress (WIP) bit is a ‘1’ during the self-timed ASPP operation, and is a
‘0’ when it is completed. When the ASPP operation is completed, the Write Enable Latch (WEL) is set to ‘0’.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
7
6
5
4
3 2 1 0
Phase
Instruction
Input ASPR Low Byte
Input ASPR High Byte
Figure 96
ASPP command
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Commands
9.8.3
DYB Read (DYBRD FAh or 4DYBRD E0h)
The instruction is latched into SI by the rising edge of the SCK signal. The instruction is followed by the 24- or
32-bit address, depending on the address length configuration CR2V[7], selecting location zero within the desired
sector. Note, the high order address bits not used by a particular density device must be zero. Then the 8-bit DYB
access register contents are shifted out on the serial output SO. Each bit is shifted out at the SCK frequency by
the falling edge of the SCK signal. It is possible to read the same DYB access register continuously by providing
multiples of eight clock cycles. The address of the DYB register does not increment so this is not a means to read
the entire DYB array. Each location must be read with a separate DYB Read command. The maximum operating
clock frequency for READ command is 133 MHz.
CS#
SCK
SI
SO
7 6 5 4 3 2 1 0 A
1 0
7
6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Phase
Address
Instruction
Register
Repeat Register
Figure 97
DYBRD command sequence[66, 67]
This command is also supported in QPI mode. In QPI mode, the instruction and address is shifted in on IO0-IO3
and returning data is shifted out on IO0-IO3.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
A-3
A-2
A-1
A
4
0
1
2
3
4
5
6
7
0
1
2
3
5
IO2
6
7
IO3
Phase
Instruction
Address
Output DYBAR
Figure 98
DYBRD QPI mode command sequence[66, 67]
Note
66. A = MSb of address = 23 for Address length (CR2V[7] = 0, or 31 for CR2V[7] = 1 with command FAh.
67. A = MSb of address = 31 with command E0h.
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Commands
9.8.4
DYB Write (DYBWR FBh or 4DYBWR E1h)
Before the DYB Write (DYBWR) command can be accepted by the device, a Write Enable (WREN) command must
be issued. After the Write Enable (WREN) command has been decoded, the device will set the Write Enable Latch
(WEL) in the status register to enable any write operations.
The DYBWR command is entered by driving CS# to the logic LOW state, followed by the instruction, followed by
the 24- or 32-bit address, depending on the address length configuration CR2V[7], selecting location zero within
the desired sector (note, the high order address bits not used by a particular density device must be zero), then
the data byte on SI. The DYB Access Register is one data byte in length. The data value must be 00h to protect or
FFh to unprotect the selected sector.
The DYBWR command affects the P_ERR and WIP bits of the status and configuration registers in the same
manner as any other programming operation. CS# must be driven to the logic HIGH state after the eighth bit of
data has been latched in. As soon as CS# is driven to the logic HIGH state, the self-timed DYBWR operation is
initiated. While the DYBWR operation is in progress, the status register may be read to check the value of the
Write-In Progress (WIP) bit. The Write-In Progress (WIP) bit is a ‘1’ during the self-timed DYBWR operation, and is
a ‘0’ when it is completed. When the DYBWR operation is completed, the Write Enable Latch (WEL) is set to ‘0’.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
31
5
4
3
2
1
0
7
6
5
4
3
2
1
0
Phase
Instruction
Address
Input Data
Figure 99
DYBWR command sequence[68, 69]
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3, two clock
cycles per byte.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
A-3
A-2
A-1
A
4
0
1
2
3
4
5
6
7
0
1
2
3
5
IO2
6
7
IO3
Phase
Instruction
Address
Input DYBAR
Figure 100
DYBWR QPI mode command sequence[68, 69]
Note
68. A = MSb of address = 23 for Address length (CR2V[7] = 0, or 31 for CR2V[7] = 1 with command FBh.
69. A = MSb of address = 31 with command E1h.
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Commands
9.8.5
PPB Read (PPBRD FCh or 4PPBRD E2h)
The instruction E2h is shifted into SI by the rising edges of the SCK signal, followed by the 24- or 32-bit address,
depending on the address length configuration CR2V[7], selecting location zero within the desired sector (note,
the high order address bits not used by a particular density device must be zero). Then the 8-bit PPB access
register contents are shifted out on SO.
It is possible to read the same PPB access register continuously by providing multiples of eight clock cycles. The
address of the PPB register does not increment so this is not a means to read the entire PPB array. Each location
must be read with a separate PPB Read command. The maximum operating clock frequency for the PPB Read
command is 133 MHz.
CS#
SCK
SI
SO
7 6 5 4 3 2 1 0 A
1 0
7
6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Phase
Address
Instruction
Register
Repeat Register
Figure 101
PPBRD command sequence[70, 71]
9.8.6
PPB Program (PPBP FDh or 4PPBP E3h)
Before the PPB Program (PPBP) command can be accepted by the device, a Write Enable (WREN) command must
be issued. After the Write Enable (WREN) command has been decoded, the device will set the Write Enable Latch
(WEL) in the status register to enable any write operations.
The PPBP command is entered by driving CS# to the logic LOW state, followed by the instruction, followed by the
24 or 32-bit address, depending on the address length configuration CR2V[7], selecting location zero within the
desired sector (note, the high order address bits not used by a particular density device must be zero).
The PPBP command affects the P_ERR and WIP bits of the status and configuration registers in the same manner
as any other programming operation.
CS# must be driven to the logic HIGH state after the last bit of address has been latched in. If not, the PPBP
command is not executed. As soon as CS# is driven to the logic HIGH state, the self-timed PPBP operation is
initiated. While the PPBP operation is in progress, the status register may be read to check the value of the
Write-In Progress (WIP) bit. The Write-In Progress (WIP) bit is a ‘1’ during the self-timed PPBP operation, and is a
‘0’ when it is completed. When the PPBP operation is completed, the Write Enable Latch (WEL) is set to ‘0’.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
A
1
0
Phase
Instruction
Address
Figure 102
Notes
PPBP command sequence[72, 73]
70. A = MSb of address = 23 for Address length (CR2V[7] = 0, or 31 for CR2V[7] = 1 with command FCh.
71. A = MSb of address = 31 with command E2h.
72. A = MSb of address = 23 for Address length (CR2V[7] = 0, or 31 for CR2V[7] = 1 with command FDh.
73. A = MSb of address = 31 with command E3h.
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Commands
9.8.7
PPB Erase (PPBE E4h)
The PPB Erase (PPBE) command sets all PPB bits to 1. Before the PPB Erase command can be accepted by the
device, a Write Enable (WREN) command must be issued and decoded by the device, which sets the Write Enable
Latch (WEL) in the status register to enable any write operations.
The instruction E4h is shifted into SI by the rising edges of the SCK signal.
CS# must be driven into the logic HIGH state after the eighth bit of the instruction byte has been latched in on SI.
This will initiate the beginning of internal erase cycle, which involves the pre-programming and erase of the entire
PPB memory array. Without CS# being driven to the logic HIGH state after the eighth bit of the instruction, the
PPB erase operation will not be executed.
With the internal erase cycle in progress, the user can read the value of the Write-In Progress (WIP) bit to check if
the operation has been completed. The WIP bit will indicate a ‘1’ when the erase cycle is in progress and a ‘0’ when
the erase cycle has been completed. Erase suspend is not allowed during PPB Erase.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
Phase
Instruction
Figure 103
PPB erase command sequence
9.8.8
PPB Lock Bit Read (PLBRD A7h)
The PPB Lock Bit Read (PLBRD) command allows the PPB Lock Register contents to be read out of SO. It is
possible to read the PPB lock register continuously by providing multiples of eight clock cycles. The PPB Lock
Register contents may only be read when the device is in standby state with no other operation in progress. It is
recommended to check the Write-In Progress (WIP) bit of the status register before issuing a new command to
the device.
CS#
SCK
SI
SO
7
6 5 4 3 2 1 0
7
6
5
4
3
2
1
0
7
6 5 4 3 2 1 0
Phase
Instruction
Register Read
Repeat Register Read
Figure 104
PPB Lock Register Read command sequence
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Commands
9.8.9
PPB Lock Bit Write (PLBWR A6h)
The PPB Lock Bit Write (PLBWR) command clears the PPB Lock Register to zero. Before the PLBWR command can
be accepted by the device, a Write Enable (WREN) command must be issued and decoded by the device, which
sets the Write Enable Latch (WEL) in the Status Register to enable any write operations.
The PLBWR command is entered by driving CS# to the logic LOW state, followed by the instruction.
CS# must be driven to the logic HIGH state after the eighth bit of instruction has been latched in. If not, the PLBWR
command is not executed. As soon as CS# is driven to the logic HIGH state, the self-timed PLBWR operation is
initiated. While the PLBWR operation is in progress, the status register may still be read to check the value of the
Write-In Progress (WIP) bit. The Write-In Progress (WIP) bit is a ‘1’ during the self-timed PLBWR operation, and is
a ‘0’ when it is completed. When the PLBWR operation is completed, the Write Enable Latch (WEL) is set to ‘0’. The
maximum clock frequency for the PLBWR command is 133 MHz.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
Phase
Instruction
Figure 105
PPB Lock Bit Write command sequence
9.8.10
Password Read (PASSRD E7h)
The correct password value may be read only after it is programmed and before the Password Mode has been
selected by programming the Password Protection Mode bit to 0 in the ASP Register (ASP[2]). After the Password
Protection Mode is selected the password is no longer readable, the PASSRD command will output undefined
data.
The PASSRD command is shifted into SI. Then the 64-bit password is shifted out on the serial output SO, least
significant byte first, most significant bit of each byte first. Each bit is shifted out at the SCK frequency by the
falling edge of the SCK signal. It is possible to read the password continuously by providing multiples of 64 clock
cycles. The maximum operating clock frequency for the PASSRD command is 133 MHz.
CS#
SCK
SI
SO
7
6 5 4 3 2 1 0
7
6
5
4
3
2
1
0
6 5 4 3 2 1 0
Phase
Instruction
Data 1
Data N
Figure 106
Password Read command sequence
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Commands
9.8.11
Password Program (PASSP E8h)
Before the Password Program (PASSP) command can be accepted by the device, a Write Enable (WREN)
command must be issued and decoded by the device. After the Write Enable (WREN) command has been
decoded, the device sets the Write Enable Latch (WEL) to enable the PASSP operation.
The password can only be programmed before the Password Mode is selected by programming the Password
Protection Mode bit to 0 in the ASP Register (ASP[2]). After the Password Protection Mode is selected the PASSP
command is ignored.
The PASSP command is entered by driving CS# to the logic LOW state, followed by the instruction and the
password data bytes on SI, least significant byte first, most significant bit of each byte first. The password is 64
bits in length.
CS# must be driven to the logic HIGH state after the 64th bit of data has been latched. If not, the PASSP command
is not executed. As soon as CS# is driven to the logic HIGH state, the self-timed PASSP operation is initiated. While
the PASSP operation is in progress, the status register may be read to check the value of the Write-In Progress
(WIP) bit. The Write-In Progress (WIP) bit is a ‘1’ during the self-timed PASSP cycle, and is a ‘0’ when it is
completed. The PASSP command can report a program error in the P_ERR bit of the status register. When the
PASSP operation is completed, the Write Enable Latch (WEL) is set to ‘0’. The maximum clock frequency for the
PASSP command is 133 MHz.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
7
6
5
4
3 2 1 0
Phase
Instruction
Input Password Low Byte
Input Password High Byte
Figure 107
Password Program command sequence
9.8.12
Password Unlock (PASSU E9h)
The PASSU command is entered by driving CS# to the logic LOW state, followed by the instruction and the
password data bytes on SI, least significant byte first, most significant bit of each byte first. The password is 64
bits in length.
CS# must be driven to the logic HIGH state after the 64th bit of data has been latched. If not, the PASSU command
is not executed. As soon as CS# is driven to the logic HIGH state, the self-timed PASSU operation is initiated. While
the PASSU operation is in progress, the status register may be read to check the value of the Write-In Progress
(WIP) bit. The Write-In Progress (WIP) bit is a ‘1’ during the self-timed PASSU cycle, and is a ‘0’ when it is
completed.
If the PASSU command supplied password does not match the hidden password in the Password Register, an
error is reported by setting the P_ERR bit to 1. The WIP bit of the status register also remains set to ‘1’. It is
necessary to use the CLSR command to clear the status register, the RESET command to software reset the
device, or drive the RESET# input low to initiate a hardware reset, in order to return the P_ERR and WIP bits to 0.
This returns the device to standby state, ready for new commands such as a retry of the PASSU command.
If the password does match, the PPB Lock bit is set to ‘1’. The maximum clock frequency for the PASSU command
is 133 MHz.
CS#
SCK
SI
SO
7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Input Password Low Byte
Input Password High
Instruction
Phase
Figure 108
Password Unlock command sequence
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SPI Multi-I/O, 1.8 V
Commands
9.9
Reset commands
Software controlled Reset commands restore the device to its initial power up state, by reloading volatile
registers from non-volatile default values. However, the volatile FREEZE bit in the Configuration Register CR1V[0]
and the volatile PPB Lock bit in the PPB Lock Register are not changed by a software reset. The software reset
cannot be used to circumvent the FREEZE or PPB Lock bit protection mechanisms for the other security config-
uration bits.
The Freeze bit and the PPB Lock bit will remain set at their last value prior to the software reset. To clear the
FREEZE bit and set the PPB Lock bit to its protection mode selected power on state, a full power-on-reset
sequence or hardware reset must be done.
The non-volatile bits in the configuration register (CR1NV), TBPROT_O, TBPARM, and BPNV_O, retain their
previous state after a Software Reset.
The Block Protection bits BP2, BP1, and BP0, in the status register (SR1V) will only be reset to their default value
if FREEZE = 0.
A reset command (RST or RESET) is executed when CS# is brought HIGH at the end of the instruction and requires
t
RPH time to execute.
In the case of a previous Power-up Reset (POR) failure to complete, a reset command triggers a full power-up
sequence requiring tPU to complete.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
Phase
Instruction
Figure 109
Software Reset command sequence
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3, two clock
cycles per byte.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruction
Figure 110
Software Reset command sequence QPI mode
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Commands
9.9.1
Software Reset Enable (RSTEN 66h)
The Reset Enable (RSTEN) command is required immediately before a Reset command (RST) such that a software
reset is a sequence of the two commands. Any command other than RST following the RSTEN command, will
clear the reset enable condition and prevent a later RST command from being recognized.
9.9.2
Software Reset (RST 99h)
The Reset (RST) command immediately following a RSTEN command, initiates the software reset process.
9.9.3
Legacy Software Reset (RESET F0h)
The Legacy Software Reset (RESET) is a single command that initiates the software reset process. This command
is disabled by default but can be enabled by programming CR3V[0] = 1, for software compatibility with Infineon
legacy FL-S devices.
9.9.4
Mode Bit Reset (MBR FFh)
The Mode Bit Reset (MBR) command is used to return the device from continuous high performance read mode
back to normal standby awaiting any new command. Because some device packages lack a hardware RESET#
input and a device that is in a continuous high performance read mode may not recognize any normal SPI
command, a system hardware reset or software reset command may not be recognized by the device. It is recom-
mended to use the MBR command after a system reset when the RESET# signal is not available or, before sending
a software reset, to ensure the device is released from continuous high performance read mode.
The MBR command sends Ones on SI or IO0 for 8 SCK cycles. IO1 to IO3 are ‘don’t care’ during these cycles.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
Phase
Instruction
Figure 111
Mode Bit Reset command sequence
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3, two clock
cycles per byte.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruction
Figure 112
Mode Bit Reset command sequence QPI mode
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Commands
9.10
DPD commands
9.10.1
Enter Deep Power-Down (DPD B9h)
Although the standby current during normal operation is relatively low, standby current can be further reduced
with the Deep Power-Down command. The lower power consumption makes the Deep Power-Down (DPD)
command especially useful for battery powered applications (see IDPD in “DC characteristics” on page 33).
The DPD command is accepted only while the device is not performing an embedded algorithm as indicated by
the Status Register 1 volatile Write In Progress (WIP) bit being cleared to zero (SR1V[0] = 0).
The command is initiated by driving the CS# pin LOW and shifting the instruction code ‘B9h’ as shown in
Figure 113. The CS# pin must be driven high after the eighth bit has been latched. If this is not done the Deep
Power-Down command will not be executed. After CS# is driven HIGH, the power-down state will be entered
within the time duration of tDPD (refer to “Timing specifications” on page 37).
While in the power-down state only the Release from Deep Power-Down command, which restores the device to
normal operation, will be recognized. All other commands are ignored. This includes the Read Status Register
command, which is always available during normal operation. Ignoring all but one command also makes the
Power Down state useful for write protection. The device always powers-up in the interface standby state with
the standby current of ICC1
.
CS#
SCK
SI
7
6
5
4
3
2
1
0
SO
Phase
Instruction
Figure 113
Deep Power-Down command sequence
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3, two clock
cycles per byte.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruction
Figure 114
DPD command sequence QPI mode
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Commands
9.10.2
Release from Deep Power-Down (RES ABh)
The Release from Deep Power-Down command is used to release the device from the deep power-down state. In
some legacy SPI devices the RES command could also be used to obtain the device electronic identification (ID)
number. However, the device ID function is not supported by the RES command.
To release the device from the deep power-down state, the command is issued by driving the CS# pin LOW,
shifting the instruction code ‘ABh’ and driving CS# HIGH as shown in Figure 115. Release from deep power-down
will take the time duration of tRES (“Timing specifications” on page 37) before the device will resume normal
operation and other commands are accepted. The CS# pin must remain HIGH during the tRES time duration.
Hardware Reset will also release the device from the DPD state as part of the hardware reset process.
CS#
SCK
SI
SO
7
6
5
4
3
2
1
0
Phase
Instruction
Figure 115
Release from Deep Power-Down command sequence
This command is also supported in QPI mode. In QPI mode, the instruction is shifted in on IO0-IO3, two clock
cycles per byte.
CS#
SCK
IO0
IO1
4
5
6
7
0
1
2
3
IO2
IO3
Phase
Instruction
Figure 116
RES command sequence QPI mode
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Embedded algorithm performance tables
10
Table 50
Embedded algorithm performance tables
Program and erase performance[76, 77, 78]
[75]
Symbol
Parameter
Min
Typ
240
Max
Unit
t
Non-volatile Register Write Time
750
ms
W
Page Programming (512 bytes)
Page Programming (256 bytes)
475
360
2000
2000
t
µs
PP
Sector Erase Time (256 KB physical sectors)
Sector Erase Time (4 KB sectors)
930
240
220
20
2900
725
720
25
t
ms
sec
µs
SE
–
[74]
t
Bulk Erase Time (S25FS512S)
BE
Evaluate Erase Status Time (64-KB or 4-KB physical sectors)
Evaluate Erase Status Time (256-KB physical or logical sectors)
tEES
80
100
Notes
74. Not 100% tested.
75. Typical program and erase times assume the following conditions: 25°C, V = 1.8V; random data pattern.
CC
76. The programming time for any OTP programming command is the same as t . This includes OTPP 42h, PNVDLR 43h,
PP
ASPP 2Fh, and PASSP E8h.
77. The programming time for the PPBP E3h command is the same as t . The erase time for PPBE E4h command is the
PP
same as t
.
SE
78. Data retention of 20 years is based on 1k erase cycles or less.
Table 51
Program or erase suspend AC parameters
Parameter
Typ Max Unit
Comments
Suspend latency (t
)
–
50
The time from Suspend command until the WIP bit is 0.
SL
Minimum is the time needed to issue the next Suspend
command but ≥ typical periods are needed for Program or
Erase to progress to completion.
µs
Resume to next Program Suspend (t
)
100
–
RS
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Data integrity
11
Data integrity
11.1
Erase endurance
Table 52
Erase endurance
Parameter
Minimum
Unit
Program/Erase cycles per main Flash array sectors
Program/Erase cycles per PPB array or Non-volatile register array
Note
100K
P/E cycle
[79]
79. Each write command to a non-volatile register causes a P/ E cycle on the entire non-volatile register array. OTP bits and
registers internally reside in a separate array that is not P/E cycled.
11.2
Data retention
Table 53
Data retention
Parameter
Test conditions
10K program/erase cycles
Minimum time
Unit
20
2
Data Retention Time
Years
Contact Infineon Sales or an FAE representative for additional information on data integrity. An application note
is available at: www.infineon.com/appnotes.
Datasheet
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Device identification
12
Device identification
12.1
Serial flash discoverable parameters (SFDP) address map
The SFDP address space has a header starting at address zero that identifies the SFDP data structure and provides
a pointer to each parameter. One parameter is mandated by the JEDEC JESD216 standard. Cypress provides an
additional parameter by pointing to the ID-CFI address space, i.e. the ID-CFI address space is a sub-set of the SFDP
address space. The JEDEC parameter is located within the ID-CFI address space and is thus both a CFI parameter
and an SFDP parameter. In this way both SFDP and ID-CFI information can be accessed by either the RSFDP or
RDID commands.
Table 54
SFDP overview map
Byte address
Description
0000h
,,,
Location zero within JEDEC JESD216B SFDP space – start of SFDP header
Remainder of SFDP header followed by undefined space
Location zero within ID-CFI space – start of ID-CFI parameter tables
ID-CFI parameters
1000h
...
Start of SFDP parameter tables which are also grouped as one of the CFI parameter tables (the CFI
parameter itself starts at 108Eh, the SFDP parameter table data is double word aligned starting at 1090h)
1090h
...
Remainder of SFDP parameter tables followed by either more CFI parameters or undefined space
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Device identification
12.2
SFDP header table
Table 55
SFDP header
SFDP byte SFDP Dword
Data
Description
address
name
This is the entry point for Read SFDP (5Ah) command i.e. location zero within
SFDP space ASCII “S”.
00h
53h
SFDP Header
1st DWORD
01h
02h
03h
46h
44h
50h
ASCII “F”
ASCII “D”
ASCII “P”
SFDP Minor Revision (06h = JEDEC JESD216 Revision B).
This revision is backward compatible with all prior minor revisions. Minor
revisions are changes that define previously reserved fields, add fields to the
end, or that clarify definitions of existing fields. Increments of the minor revision
value indicate that previously reserved parameter fields may have been
assigned a new definition or entire Dwords may have been added to the
parameter table. However, the definition of previously existing fields is
unchanged and therefore remain backward compatible with earlier SFDP
parameter table revisions. Software can safely ignore increments of the minor
revision number, as long as only those parameters the software was designed
to support are used i.e. previously reserved fields and additional Dwords must
be masked or ignored . Do not do a simple compare on the minor revision
number, looking only for a match with the revision number that the software is
designed to handle. There is no problem with using a higher number minor
revision.
04h
06h
SFDP Header
2nd DWORD
SFDP Major Revision
05h
01h
This is the original major revision. This major revision is compatible with all SFDP
reading and parsing software.
06h
07h
08h
05h
FFh
00h
Number of Parameter Headers (zero based, 05h = 6 parameters)
Unused
Parameter ID LSB (00h = JEDEC SFDP Basic SPI Flash Parameter)
Parameter Minor Revision (00h = JESD216)
- This older revision parameter header is provided for any legacy SFDP reading
and parsing software that requires seeing a minor revision 0 parameter header.
SFDP software designed to handle later minor revisions should continue reading
parameter headers looking for a higher numbered minor revision that contains
additional parameters for that software revision.
09h
00h
Parameter
Header 0
1st DWORD
Parameter Major Revision (01h = The original major revision - all SFDP software
is compatible with this major revision.
0Ah
0Bh
0Ch
01h
09h
90h
Parameter Table Length (in double words = Dwords = 4 byte units) 09h = 9
Dwords
Parameter Table Pointer Byte 0 (Dword = 4-byte aligned)
JEDEC Basic SPI Flash parameter byte offset = 1090h
Parameter
Header 0
0Dh
0Eh
0Fh
10h
00h
FFh
Parameter Table Pointer Byte 1
2nd DWORD
Parameter Table Pointer Byte 2
Parameter ID MSB (FFh = JEDEC defined legacy Parameter ID)
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Device identification
Table 55
SFDP header (continued)
SFDP byte SFDP Dword
Data
Description
address
name
10h
00h
Parameter ID LSB (00h = JEDEC SFDP Basic SPI Flash Parameter)
Parameter Minor Revision (05h = JESD216 Revision A)
- This older revision parameter header is provided for any legacy SFDP reading
and parsing software that requires seeing a minor revision 5 parameter header.
SFDP software designed to handle later minor revisions should continue reading
parameter headers looking for a later minor revision that contains additional
parameters.
11h
05h
Parameter
Header 1
1st DWORD
Parameter Major Revision (01h = The original major revision - all SFDP software
is compatible with this major revision.
12h
13h
14h
01h
10h
90h
Parameter Table Length (in double words = Dwords = 4 byte units) 10h = 16
Dwords
Parameter Table Pointer Byte 0 (Dword = 4 byte aligned)
JEDEC Basic SPI Flash parameter byte offset = 1090h address
Parameter
Header 1
15h
16h
17h
18h
19h
10h
00h
FFh
00h
06h
Parameter Table Pointer Byte 1
2nd DWORD
Parameter Table Pointer Byte 2
Parameter ID MSB (FFh = JEDEC defined Parameter)
Parameter ID LSB (00h = JEDEC SFDP Basic SPI Flash Parameter)
Parameter Minor Revision (06h = JESD216 Revision B)
Parameter
Header 2
Parameter Major Revision (01h = The original major revision - all SFDP software
is compatible with this major revision.
1Ah
1Bh
1Ch
01h
10h
90h
1st DWORD
Parameter Table Length (in double words = Dwords = 4 byte units) 10h = 16
Dwords
Parameter Table Pointer Byte 0 (Dword = 4 byte aligned)
JEDEC Basic SPI Flash parameter byte offset = 1090h address
Parameter
Header 2
1Dh
1Eh
1Fh
20h
21h
10h
00h
FFh
81h
00h
Parameter Table Pointer Byte 1
2nd DWORD
Parameter Table Pointer Byte 2
Parameter ID MSB (FFh = JEDEC defined Parameter)
Parameter ID LSB (81h = SFDP Sector Map Parameter)
Parameter Minor Revision (00h = Initial version as defined in JESD216 Revision B)
Parameter
Header 3
Parameter Major Revision (01h = The original major revision - all SFDP software
that recognizes this parameter’s ID is compatible with this major revision.
22h
23h
24h
01h
1st DWORD
Parameter Table Length (in double words = Dwords = 4 byte units) OPN
10h (512 Mb) Dependent
16 = 10h (512 Mb)
Parameter Table Pointer Byte 0 (Dword = 4 byte aligned)
JEDEC parameter byte offset = 10D8h
D8h
Parameter
Header 3
25h
26h
27h
28h
29h
10h
00h
FFh
84h
00h
Parameter Table Pointer Byte 1
2nd DWORD
Parameter Table Pointer Byte 2
Parameter ID MSB (FFh = JEDEC defined Parameter)
Parameter ID LSB (00h = SFDP 4 Byte Address Instructions Parameter)
Parameter Minor Revision (00h = Initial version as defined in JESD216 Revision B)
Parameter
Header 4
Parameter Major Revision (01h = The original major revision - all SFDP software
that recognizes this parameter’s ID is compatible with this major revision.
2Ah
2Bh
01h
02h
1st DWORD
Parameter Table Length (in double words = Dwords = 4 byte units) (2h = 2
Dwords)
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SPI Multi-I/O, 1.8 V
Device identification
Table 55
SFDP header (continued)
SFDP byte SFDP Dword
Data
Description
address
name
Parameter Table Pointer Byte 0 (Dword = 4 byte aligned)
JEDEC parameter byte offset = 10D0h
2Ch
D0h
Parameter
Header 4
2Dh
2Eh
2Fh
10h
00h
FFh
Parameter Table Pointer Byte 1
2nd DWORD
Parameter Table Pointer Byte 2
Parameter ID MSB (FFh = JEDEC defined Parameter)
Parameter ID LSB (Cypress Vendor Specific ID-CFI parameter)
Legacy Manufacturer ID 01h = AMD / Cypress
30h
31h
32h
01h
Parameter Minor Revision (01h = ID-CFI updated with SFDP Rev B table)
Parameter
Header 5
Parameter Major Revision (01h = The original major revision - all SFDP software
that recognizes this parameter’s ID is compatible with this major revision.
1st DWORD
Parameter Table Length (in double words = Dwords = 4 byte units) Parameter
Table Length (in double words = Dwords = 4 byte units)
33h
34h
47h (512 Mb)
00h
Parameter Table Pointer Byte 0 (Dword = 4 byte aligned)
Entry point for ID-CFI parameter is byte offset = 1000h relative to SFDP location
zero.
Parameter
Header 5
35h
36h
37h
10h
00h
01h
Parameter Table Pointer Byte 1
2nd DWORD
Parameter Table Pointer Byte 2
Parameter ID MSB (01h = JEDEC JEP106 Bank Number 1)
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Device identification
12.3
Device ID and common flash interface (ID-CFI) address map
12.3.1
Device ID
Table 56
Manufacturer and Device ID
Byte address
Data
Description
00h
01h
02h
01h
Manufacturer ID for Cypress
02h (512 Mb)
20h (512 Mb)
Device ID Most Significant Byte — Memory Interface Type
Device ID Least Significant Byte — Density
ID-CFI Length - Number bytes following. Adding this value to the current location
of 03h gives the address of the last valid location in the ID-CFI legacy address
map. The legacy CFI address map ends with the Primary Vendor-Specific
Extended Query. The original legacy length is maintained for backward software
compatibility. However, the CFI Query Identification String also includes a
pointer to the Alternate Vendor-Specific Extended Query that contains
additional information related to the FS-S family.
03h
4Dh
Physical Sector Architecture
00h (Uniform 256-KB
physical sectors)
04h
The S25FS512S may be configured with or without 4-KB parameter sectors in
addition to the uniform sectors.
05h
06h
07h
08h
09h
0Ah
0Bh
0Ch
0Dh
0Eh
0Fh
81h (S25FS512S)
Family ID
ASCII characters for Model. Refer to “Ordering part number” on page 157 for
the model number definitions.
xxh
Reserved
Table 57
CFI query identification string
Data
Byte address
Description
Query Unique ASCII string “QRY”
10h
11h
12h
51h
52h
59h
13h
14h
02h
00h
Primary OEM Command Set
FL-P backward compatible command set ID
15h
16h
40h
00h
Address for Primary Extended Table
17h
18h
53h
46h
Alternate OEM Command Set
ASCII characters “FS” for SPI (F) interface, S Technology
19h
1Ah
51h
00h
Address for Alternate OEM Extended Table
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Device identification
Table 58
CFI system interface string
Byte address
Data
17h
Description
Min. (erase / program): 100 millivolts BCD)
Max. (erase / program): 100 millivolts BCD)
1Bh
1Ch
1Dh
1Eh
1Fh
20h
21h
22h
23h
24h
25h
26h
V
V
V
V
CC
CC
PP
PP
19h
Min. voltage (00h = no V present)
PP
00h
09h
Max. voltage (00h = no V present)
PP
N
Typical timeout per single byte program 2 µs
N
Typical timeout for Min. size Page program 2 µs (00h = not supported)
N
0Ah (256 KB)
11h (512 Mb)
Typical timeout per individual sector erase 2 ms
N
Typical timeout for full chip erase 2 ms (00h = not supported)
N
Max. timeout for byte program 2 times typical
02h
03h
N
Max. timeout for page program 2 times typical
N
Max. timeout per individual sector erase 2 times typical
N
Max. timeout for full chip erase 2 times typical (00h = not supported)
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Device identification
Table 59
Device geometry definition for bottom boot initial delivery state
Byte address
Data
1Ah (512 Mb)
02h
Description
N
27h
28h
Device Size = 2 bytes
Flash Device Interface Description:
0000h = x8 only
0001h = x16 only
0002h = x8/x16 capable
0003h = x32 only
29h
01h
0004h = Single I/O SPI, 3-byte address
0005h = Multi I/O SPI, 3-byte address
0102h = Multi I/O SPI, 3- or 4-byte address
N
2Ah
2Bh
08h
00h
Max. number of bytes in multi-byte write = 2
0000h = Not supported
0008h = 256B page
0009h = 512B page
Number of Erase Block Regions within device
1 = Uniform Device, >1 = Boot Device
2Ch
03h
2Dh
2Eh
2Fh
30h
31h
32h
33h
07h
00h
10h
Erase Block Region 1 Information (refer to JEDEC JEP137)
8 sectors = 8-1 = 0007h
4-KB sectors = 256 bytes x 0010h
00h
80h
Erase Block Region 2 Information (refer to JEDEC JEP137)
512 Mb:
1 sectors = 1-1 = 0000h
00h (128 Mb)
00h (256 Mb)
03h (512 Mb)
224-KB sector = 256 bytes x 0380h
34h
35h
FEh
00h (128 Mb)
01h (256 Mb)
00h (512 Mb)
01h (1 Gb
36h
37h
Erase Block Region 3 Information
512 Mb:
255 sectors = 255-1 = 00FEh
256-KB sectors = 0400h x 256 bytes
00h
01h (128 Mb)
01h (256 Mb)
04h (512 Mb)
04h (1 Gb)
38h
39h thru 3Fh
FFh
RFU
Note
80. FS512S devices are user configurable to have either a hybrid sector architecture (with eight 4-KB sectors / one 224-KB
sector and all remaining sectors are uniform 256 KB) or a uniform sector architecture with all sectors uniform 256 KB.
FS-S devices are also user configurable to have the 4-KB parameter sectors at the top of memory address space. The
CFI geometry information of the above table is relevant only to the initial delivery state. All devices are initially shipped
from Cypress with the hybrid sector architecture with the 4-KB sectors located at the bottom of the array address map.
However, the device configuration TBPARM bit CR1NV[2] may be programed to invert the sector map to place the 4-KB
sectors at the top of the array address map. The 20h_NV bit (CR3NV[3} may be programmed to remove the 4-KB sectors
from the address map. The flash device driver software must examine the TBPARM and 20h_NV bits to determine if the
sector map was inverted or hybrid sectors removed at a later time.
Datasheet
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SPI Multi-I/O, 1.8 V
Device identification
Table 60
CFI primary vendor-specific extended query
Byte address
Data
50h
52h
49h
31h
33h
Description
40h
41h
42h
43h
44h
Query-unique ASCII string “PRI”
Major version number = 1, ASCII
Minor version number = 3, ASCII
Address Sensitive Unlock (Bits 1-0)
00b = Required, 01b = Not Required
Process Technology (Bits 5-2)
0000b = 0.23 µm Floating Gate
0001b = 0.17 µm Floating Gate
0010b = 0.23 µm MirrorBit
45h
21h
0011b = 0.11 µm Floating Gate
0100b = 0.11 µm MirrorBit
0101b = 0.09 µm MirrorBit
1000b = 0.065 µm MirrorBit
Erase Suspend
46h
47h
48h
02h
01h
00h
0 = Not Supported, 1 = Read Only, 2 = Read and Program
Sector Protect
00 = Not Supported, X = Number of sectors in group
Temporary Sector Unprotect
00 = Not Supported, 01 = Supported
Sector Protect/Unprotect Scheme
04 = High Voltage Method
49h
08h
05 = Software Command Locking Method
08 = Advanced Sector Protection Method
Simultaneous Operation
4Ah
4Bh
00h
01h
00 = Not Supported, X = Number of Sectors
Burst Mode (Synchronous sequential read) support
00 = Not Supported, 01 = Supported
Page Mode Type, initial delivery configuration, user configurable for 512B page
00 = Not Supported, 01 = 4 Word Read Page, 02 = 8 Read Word Page, 03 = 256 Byte Program Page,
04 = 512 Byte Program Page
4Ch
03h
00h
ACC (Acceleration) Supply Minimum
00 = Not Supported, 100 mV
4Dh
4Eh
ACC (Acceleration) Supply Maximum
00 = Not Supported, 100 mV
WP# Protection
01 = Whole Chip
4Fh
50h
07h
01h
04 = Uniform Device with Bottom WP Protect
05 = Uniform Device with Top WP Protect
07 = Uniform Device with Top or Bottom Write Protect (user configurable)
Program Suspend
00 = Not Supported, 01 = Supported
The Alternate Vendor-Specific Extended Query provides information related to the expanded command set
provided by the FS-S family. The alternate query parameters use a format in which each parameter begins with
an identifier byte and a parameter length byte. Driver software can check each parameter ID and can use the
length value to skip to the next parameter if the parameter is not needed or not recognized by the software.
Datasheet
140 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Device identification
Table 61
CFI alternate vendor-specific extended query header
Byte address
Data
41h
4Ch
54h
32h
30h
Description
51h
52h
53h
54h
55h
Query-unique ASCII string “ALT”
Major version number = 2, ASCII
Minor version number = 0, ASCII
Table 62
CFI alternate vendor-specific extended query parameter 0
Parameter
relative byte
address offset
Data
Description
00h
00h
10h
Parameter ID (Ordering Part Number)
Parameter Length (The number of following bytes in this parameter. Adding this
value to the current location value +1 = the first byte of the next parameter).
01h
02h
03h
04h
05h
06h
07h
08h
09h
0Ah
0Bh
0Ch
0Dh
0Eh
0Fh
10h
11h
53h
32h
ASCII “S” for manufacturer (Infineon)
ASCII “25” for Product Characters (Single Die SPI)
35h
46h
ASCII “FS” for Interface Characters (SPI 1.8V)
ASCII characters for density
53h
35h (512 Mb)
31h (512 Mb)
32h (512 Mb)
53h
™
ASCII “S” for Technology (65-nm MIRRORBIT )
FFh
FFh
FFh
Reserved for Future Use
FFh
FFh
xxh
ASCII characters for Model.
Refer to “Ordering part number” on page 157 for the model number definitions.
xxh
Datasheet
141 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Device identification
Table 63
CFI alternate vendor-Specific extended query parameter 80h address options
Parameter
relative byte
Data
Description
Parameter ID (Ordering Part Number)
address offset
00h
80h
01h
Parameter Length (The number of following bytes in this parameter. Adding this
value to the current location value +1 = the first byte of the next parameter)
01h
Bits 7:5 – Reserved = 111b
Bit 4 – Address Length Bit in CR2V[7] – Yes= 0b
Bit 3 – AutoBoot support – No = 1b
02h
EBh
Bit 2 – 4 byte address instructions supported – Yes= 0b
Bit 1 – Bank address + 3 byte address instructions supported –No = 1b
Bit 0 - 3 byte address instructions supported – No = 1b
Table 64
CFI alternate vendor-specific extended query parameter 84h suspend commands
Parameter
relative byte
address offset
Data
Description
Parameter ID (Suspend Commands)
00h
84h
08h
Parameter Length (The number of following bytes in this parameter. Adding this
value to the current location value +1 = the first byte of the next parameter)
01h
02h
03h
04h
05h
06h
07h
08h
09h
75h
32h
7Ah
64h
75h
32h
7Ah
64h
Program suspend instruction code
Program suspend latency maximum (µs)
Program resume instruction code
Program resume to next suspend typical (µs)
Erase suspend instruction code
Erase suspend latency maximum (µs)
Erase resume instruction code
Erase resume to next suspend typical (µs)
Table 65
CFI alternate vendor-specific extended query parameter 88h data protection
Parameter
relative byte
address offset
Data
Description
00h
88h
04h
Parameter ID (Data Protection)
Parameter Length (The number of following bytes in this parameter. Adding this
value to the current location value +1 = the first byte of the next parameter)
01h
N
02h
03h
0Ah
01h
OTP size 2 bytes, FFh = Not supported
OTP address map format, 01h = FL-S and FS-S format, FFh = not supported
Block Protect Type, model dependent
00h = FL-P, FL-S, FS-S
04h
05h
xxh
xxh
FFh = Not supported
Advanced Sector Protection type, model dependent
01h = FL-S and FS-S ASP
Datasheet
142 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Device identification
Table 66
CFI alternate vendor-specific extended query parameter 8Ch reset timing
Parameter
relative byte
Data
Description
address offset
00h
8Ch
06h
Parameter ID (Reset Timing)
Parameter Length (The number of following bytes in this parameter. Adding this
value to the current location value +1 = the first byte of the next parameter).
01h
02h
03h
96h
01h
POR maximum value
N
POR maximum exponent 2 µs
Hardware Reset maximum value, FFh = not supported (the initial delivery state
has hardware reset disabled but it may be enabled by the user at a later time)
04h
23h
N
05h
06h
07h
00h
23h
00h
Hardware Reset maximum exponent 2 µs
Software Reset maximum value, FFh = Not supported
N
Software Reset maximum exponent 2 µs
Table 67
CFI alternate vendor-Specific extended query parameter 94h ECC
Parameter
relative byte
address offset
Data
Description
00h
01h
02h
94h
01h
10h
Parameter ID (ECC)
Parameter Length (The number of following bytes in this parameter. Adding this
value to the current location value +1 = the first byte of the next parameter).
ECC unit size byte, FFh = ECC disabled
Table 68
CFI alternate vendor-Specific extended query parameter F0h RFU
Parameter
relative byte
address offset
Data
Description
00h
F0h
09h
Parameter ID (RFU)
Parameter Length (The number of following bytes in this parameter. Adding this
value to the current location value +1 = the first byte of the next parameter).
01h
02h
...
FFh
FFh
FFh
RFU
0Ah
This parameter type (Parameter ID F0h) may appear multiple times and have a different length each time. The
parameter is used to reserve space in the ID-CFI map or to force space (pad) to align a following parameter to a
required boundary.
Datasheet
143 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Device identification
12.4
JEDEC SFDP Rev B parameter tables
From the view point of the CFI data structure, all of the SFDP parameter tables are combined into a single CFI
Parameter as a contiguous byte sequence.
From the viewpoint of the SFDP data structure, there are three independent parameter tables. Two of the tables
have a fixed length and one table has a variable structure and length depending on the device density Ordering
Part Number (OPN). The Basic Flash Parameter table and the 4-byte Address Instructions Parameter table have
a fixed length and are presented below as a single table. This table is Table 69 of the overall CFI parameter.
The JEDEC Sector Map Parameter table structure and length depends on the density OPN and is presented as a
set of tables, one for each device density. The appropriate table for the OPN is Section 2 of the overall CFI
parameter and is appended to Section 1.
Datasheet
144 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Device identification
Table 69
CFI alternate vendor-specific extended query parameter A5h, JEDEC SFDP Rev B, section 1,
basic flash parameter and 4-byte address instructions parameter
CFI parameter
relative byte
address offset
SFDP parameter
SFDP Dword
relative byte
Data
Description
name
address offset
00h
--
N/A
A5h
CFI Parameter ID (JEDEC SFDP)
CFI Parameter Length (The number of following bytes in this parameter.
Adding this value to the current location value +1 = the first byte of the next
parameter). OPN dependent:
01h
--
N/A
88h (512 Mb)
18Dw + 16Dw = 34Dw * 4B = 136B = 88h B (512 Mb)
Start of SFDP JEDEC parameter, located at 1090h in the overall SFDP
address space.
Bits 7:5 = unused = 111b
02h
03h
04h
00h
01h
02h
E7h
FFh
Bit 4:3 = 06h is status register write instruction and status register is default
nonvolatile= 00b
Bit 2 = Program Buffer > 64 bytes = 1
Bits 1:0 = Uniform 4-KB erase unavailable = 11b
JEDEC Basic Flash
Parameter
Bits 15:8 = Uniform 4-KB erase opcode = not supported = FFh
Bit 23 = Unused = 1b
Dword-1
Bit 22 = Supports Quad Out Read = No = 0b
Bit 21 = Supports Quad I/O Read = Yes =1b
Bit 20 = Supports Dual I/O Read = Yes = 1b
Bit19 = Supports DDR 0= No, 1 = Yes; FS-SAG = 0b, FS-SDS = 1b
Bit 18:17 = Number of Address Bytes, 3 or 4 = 01b
Bit 16 = Supports Dual Out Read = No = 0b
B2h (FSxxxSAG)
BAh (FSxxxSDS)
05h
06h
07h
08h
09h
03h
04h
05h
06h
07h
FFh
FFh
Bits 31:24 = Unused = FFh
JEDEC Basic Flash
Parameter
FFh
Density in bits, zero based, 512 Mb = 1FFFFFFFh
FFh
Dword-2
1Fh (512 Mb)
Bits 7:5 = number of Quad I/O (1-4-4) Mode cycles = 010b
0Ah
0Bh
0Ch
0Dh
0Eh
0Fh
08h
09h
0Ah
0Bh
0Ch
0Dh
48h
EBh
FFh
FFh
FFh
FFh
Bits 4:0 = number of Quad I/O Dummy cycles = 01000b (Initial Delivery State)
JEDEC Basic Flash
Parameter
Quad I/O instruction code
Bits 23:21 = number of Quad Out (1-1-4) Mode cycles = 111b
Bits 20:16 = number of Quad Out Dummy cycles = 11111b
Dword-3
Quad Out instruction code
Bits 7:5 = number of Dual Out (1-1-2) Mode cycles = 111b
Bits 4:0 = number of Dual Out Dummy cycles = 11111b
Dual Out instruction code
JEDEC Basic Flash
Parameter
Bits 23:21 = number of Dual I/O (1-2-2) Mode cycles = 100b
Bits 20:16 = number of Dual I/O Dummy cycles = 01000b (Initial Delivery
State)
Dword-4
10h
11h
0Eh
0Fh
88h
BBh
Dual I/O instruction code
Bits 7:5 RFU = 111b
Bit 4 = QPI supported = Yes = 1b
Bits 3:1 RFU = 111b
12h
10h
FEh
Bit 0 = Dual All not supported = 0b
JEDEC Basic Flash
Parameter
13h
14h
15h
16h
17h
11h
12h
13h
14h
15h
FFh
FFh
FFh
FFh
FFh
Bits 15:8 = RFU = FFh
Bits 23:16 = RFU = FFh
Bits 31:24 = RFU = FFh
Bits 7:0 = RFU = FFh
Bits 15:8 = RFU = FFh
Dword-5
JEDEC Basic Flash
Parameter
Bits 23:21 = number of Dual All Mode cycles = 111b
Bits 20:16 = number of Dual All Dummy cycles = 11111b
18h
16h
FFh
Dword-6
19h
1Ah
1Bh
17h
18h
19h
FFh
FFh
FFh
Dual All instruction code
Bits 7:0 = RFU = FFh
Bits 15:8 = RFU = FFh
JEDEC Basic Flash
Parameter
Bits 23:21 = number of QPI Mode cycles = 010b
Bits 20:16 = number of QPI Dummy cycles = 01000b
1Ch
1Dh
1Ah
1Bh
48h
EBh
Dword-7
QPI mode Quad I/O (4-4-4) instruction code
Datasheet
145 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Device identification
Table 69
CFI alternate vendor-specific extended query parameter A5h, JEDEC SFDP Rev B, section 1,
basic flash parameter and 4-byte address instructions parameter (continued)
CFI parameter
relative byte
address offset
SFDP parameter
SFDP Dword
relative byte
Data
Description
name
address offset
1Eh
1Fh
20h
21h
22h
23h
24h
25h
26h
27h
28h
1Ch
1Dh
1Eh
1Fh
20h
21h
22h
23h
24h
25h
26h
0Ch
20h
10h
D8h
12h
D8h
00h
FFh
82h
42h
11h
Erase type 1 size 2N bytes = 4 KB = 0Ch for Hybrid (Initial Delivery State)
Erase type 1 instruction
Erase type 2 size 2N bytes = 64 KB = 10h
JEDEC Basic Flash
Parameter
Dword-8
Erase type 2 instruction
Erase type 3 size 2N bytes = 256 KB = 12h
Erase type 3 instruction
Erase type 4 size 2N bytes = not supported = 00h
JEDEC Basic Flash
Parameter
Dword-9
Erase type 4 instruction = not supported = FFh
Bits 31:30 = Erase type 4 Erase, Typical time units (00b: 1 ms, 01b: 16 ms, 10b:
128 ms, 11b: 1 s) = 1S = 11b (RFU)
Bits 29:25 = Erase type 4 Erase, Typical time count = 11111b (RFU)
Bits 24:23 = Erase type 3 Erase, Typical time units (00b: 1 ms, 01b: 16 ms, 10b:
128 ms, 11b: 1 s) = 128mS = 10b
Bits 22:18 = Erase type 3 Erase, Typical time count = 00100b (typ erase time
= count +1 * units = 5*128mS = 640mS)
Bits 17:16 = Erase type 2 Erase, Typical time units (00b: 1 ms, 01b: 16 ms, 10b:
128 ms, 11b: 1 s) = 16mS = 01b
JEDEC Basic Flash
Parameter
Bits 15:11 = Erase type 2 Erase, Typical time count = 01000b ( typ erase time
= count +1 * units = 9*16mS = 144mS)
Dword-10
Bits 10:9 = Erase type 1 Erase, Typical time units (00b: 1 ms, 01b: 16 ms, 10b:
128 ms, 11b: 1 s) = 16mS = 01b
29h
27h
FFh
Bits 8:4 = Erase type 1 Erase, Typical time count = 01000b ( typ erase time =
count +1 * units = 9*16mS = 144mS)
Bits 3:0 = Multiplier from typical erase time to maximum erase time =
2*(N+1), N=2h = 6x multiplier
Binary Fields: 11-11111-10-00100-01-01000-01-01000-0010
Nibble Format: 1111_1111_0001_0001_0100_0010_1000_0010
Hex Format: FF_11_42_82
2Ah
2Bh
2Ch
28h
29h
2Ah
91h
26h
07h
Bit 31 Reserved = 1b
Bits 30:29 = Chip Erase, Typical time units (00b: 16 ms, 01b: 256 ms, 10b: 4 s,
11b: 64 s) = 512 Mb = 64s = 11b
Bits 28:24 = Chip Erase, Typical time count, (count+1)*units,
512 Mb = 00010b = 2+1*64uS = 192s
Bits 23 = Byte Program Typical time, additional byte units (0b:1uS, 1b:8uS)
= 1uS = 0b
Bits 22:19 = Byte Program Typical time, additional byte count,
(count+1)*units, count = 0000b, (typ Program time = count +1 * units = 1*1uS
= 1uS
Bits 18 = Byte Program Typical time, first byte units (0b:1uS, 1b:8uS) = 8uS =
1b
Bits 17:14 = Byte Program Typical time, first byte count, (count+1)*units,
count = 1100b, ( typ Program time = count +1 * units = 13*8uS = 104uS
Bits 13 = Page Program Typical time units (0b:8uS, 1b:64uS) = 64uS = 1b
Bits 12:8 = Page Program Typical time count, (count+1)*units, count =
00110b, ( typ Program time = count +1 * units = 7*64uS = 448uS)
Bits 7:4 = Page size 2N, N=9h, = 512B page
JEDEC Basic Flash
Parameter
Dword-11
Bits 3:0 = Multiplier from typical time to maximum for Page or Byte program
= 2*(N+1), N=1h = 4x multiplier
2Dh
2Bh
E2h (512 Mb)
128 Mb
Binary Fields: 1-10-01000-0-0000-1-1100-1-00110-1001-0001
Nibble Format: 1100_1000_0000_0111_0010_0110_1001_0001
Hex Format: C8_07_26_91
256 Mb
Binary Fields: 1-10-10001-0-0000-1-1100-1-00110-1001-0001
Nibble Format: 1101_0001_0000_0111_0010_0110_1001_0001
Hex Format: D1_07_26_91
512 Mb
Binary Fields: 1-11-00010-0-0000-1-1100-1-00110-1001-0001
Nibble Format: 1110_0010_0000_0111_0010_0110_1001_0001
Hex Format: E2_07_26_91
Datasheet
146 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Device identification
Table 69
CFI alternate vendor-specific extended query parameter A5h, JEDEC SFDP Rev B, section 1,
basic flash parameter and 4-byte address instructions parameter (continued)
CFI parameter
relative byte
address offset
SFDP parameter
SFDP Dword
relative byte
Data
Description
name
address offset
2Eh
2Fh
30h
2Ch
2Dh
2Eh
ECh
83h
18h
Bit 31 = Suspend and Resume supported = 0b
Bits 30:29 = Suspend in-progress erase max latency units (00b: 128ns, 01b:
1us, 10b: 8us, 11b: 64us) = 8us= 10b
Bits 28:24 = Suspend in-progress erase max latency count = 00100b, max
erase suspend latency = count +1 * units = 5*8uS = 40uS
Bits 23:20 = Erase resume to suspend interval count = 0001b, interval = count
+1 * 64us = 2 * 64us = 128us
Bits 19:18 = Suspend in-progress program max latency units (00b: 128ns,
01b: 1us, 10b: 8us, 11b: 64us) = 8us= 10b
Bits 17:13 = Suspend in-progress program max latency count = 00100b, max
erase suspend latency = count +1 * units = 5*8uS = 40uS
Bits 12:9 = Program resume to suspend interval count = 0001b, interval =
count +1 * 64us = 2 * 64us = 128us
Bit 8 = RFU = 1b
JEDEC Basic Flash
Parameter
Bits 7:4 = Prohibited operations during erase suspend
= xxx0b: May not initiate a new erase anywhere (erase nesting not permitted)
+ xx1xb: May not initiate a page program in the erase suspended sector size
+ x1xxb: May not initiate a read in the erase suspended sector size
+ 1xxxb: The erase and program restrictions in bits 5:4 are sufficient
= 1110b
Dword-12
31h
2Fh
44h
Bits 3:0 = Prohibited Operations During Program Suspend
= xxx0b: May not initiate a new erase anywhere (erase nesting not permitted)
+ xx0xb: May not initiate a new page program anywhere (program nesting
not permitted)
+ x1xxb: May not initiate a read in the program suspended page size
+ 1xxxb: The erase and program restrictions in bits 1:0 are sufficient
= 1100b
Binary Fields: 0-10-00100-0001-10-00100-0001-1-1110-1100
Nibble Format: 0100_0100_0001_1000_1000_0011_1110_1100
Hex Format: 44_18_83_EC
32h
33h
34h
35h
36h
37h
38h
30h
31h
32h
33h
34h
35h
36h
8Ah
85h
7Ah
75h
F7h
BDh
D5h
Bits 31:24 = Erase Suspend Instruction = 75h
Bits 23:16 = Erase Resume Instruction = 7Ah
Bits 15:8 = Program Suspend Instruction = 85h
Bits 7:0 = Program Resume Instruction = 8Ah
JEDEC Basic Flash
Parameter
Dword-13
Bit 31 = Deep Power Down Supported = supported = 0
Bits 30:23 = Enter Deep Power Down Instruction = B9h
Bits 22:15 = Exit Deep Power Down Instruction = ABh
Bits 14:13 = Exit Deep Power Down to next operation delay units = (00b:
128ns, 01b: 1us, 10b: 8us, 11b: 64us) = 1us = 01b
Bits 12:8 = Exit Deep Power Down to next operation delay count = 11101b,
Exit Deep Power Down to next operation delay = (count+1)*units = 29+1 *1us
= 30us
JEDEC Basic Flash
Parameter
Bits 7:4 = RFU = Fh
Bit 3:2 = Status Register Polling Device Busy
= 01b: Legacy status polling supported = Use legacy polling by reading the
Status Register with 05h instruction and checking WIP bit[0] (0=ready;
1=busy).
Dword-14
39h
37h
5Ch
= 01b
Bits 1:0 = RFU = 11b
Binary Fields: 0-10111001-10101011-01-11101-1111-01-11
Nibble Format: 0101_1100_1101_0101_1011_1101_1111_0111
Hex Format: 5C_D5_BD_F7
Datasheet
147 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Device identification
Table 69
CFI alternate vendor-specific extended query parameter A5h, JEDEC SFDP Rev B, section 1,
basic flash parameter and 4-byte address instructions parameter (continued)
CFI parameter
relative byte
address offset
SFDP parameter
SFDP Dword
relative byte
Data
Description
name
address offset
3Ah
3Bh
3Ch
38h
39h
3Ah
8Ch
F6h
5Dh
Bits 31:24 = RFU = FFh
Bit 23 = Hold and WP Disable = not supported = 0b
Bits 22:20 = Quad Enable Requirements
= 101b: QE is bit 1 of the Status Register 2. Status register 1 is read using Read
Status instruction 05h. Status register 2 is read using instruction 35h. QE is
set via Write Status instruction 01h with two data bytes where bit 1 of the
second byte is one. It is cleared via Write Status with two data bytes where
bit 1 of the second byte is zero.
Bits 19:16 0-4-4 Mode Entry Method
= xxx1b: Mode Bits[7:0] = A5h Note: QE must be set prior to using this mode
+ x1xxb: Mode Bit[7:0]=Axh
+ 1xxxb: RFU
= 1101b
Bits 15:10 0-4-4 Mode Exit Method
= xx_xxx1b: Mode Bits[7:0] = 00h will terminate this mode at the end of the
current read operation
+ xx_1xxxb: Input Fh (mode bit reset) on DQ0-DQ3 for 8 clocks. This will
terminate the mode prior to the next read operation.
+ x1_xxxxb: Mode Bit[7:0] != Axh
JEDEC Basic Flash
Parameter
+ 1x_x1xx: RFU
Dword-15
= 11_1101
Bit 9 = 0-4-4 mode supported = 1
3Dh
3Bh
FFh
Bits 8:4 = 4-4-4 mode enable sequences
= x_1xxxb: device uses a read-modify-write sequence of operations: read
configuration using instruction 65h followed by address 800003h, set bit 6,
write configuration using instruction 71h followed by address 800003h. This
configuration is volatile.
= 01000b
Bits 3:0 = 4-4-4 mode disable sequences
= x1xxb: device uses a read-modify-write sequence of operations: read
configuration using instruction 65h followed by address 800003h, clear bit
6, write configuration using instruction 71h followed by address 800003h..
This configuration is volatile.
+ 1xxxb: issue the Soft Reset 66/99 sequence
= 1100b
Binary Fields: 11111111-0-101-1101-111101-1-01000-1100
Nibble Format: 1111_1111_0101_1101_1111_0110_1000-1100
Hex Format: FF_5D_F6_8C
3Eh
3Fh
40h
3Ch
3Dh
3Eh
F0h
30h
F8h
Bits 31:24 = Enter 4-Byte Addressing
= xxxx_xxx1b: issue instruction B7h (preceding write enable not required)
+ xx1x_xxxxb: Supports dedicated 4-Byte address instruction set. Consult
vendor data sheet for the instruction set definition.
+ 1xxx_xxxxb: Reserved
= 10100001b
Bits 23:14 = Exit 4-Byte Addressing
= xx_xx1x_xxxxb: Hardware reset
+ xx_x1xx_xxxxb: Software reset (see bits 13:8 in this DWORD)
+ xx_1xxx_xxxxb: Power cycle
+ x1_xxxx_xxxxb: Reserved
+ 1x_xxxx_xxxxb: Reserved
= 11_1110_0000b
Bits 13:8 = Soft Reset and Rescue Sequence Support
= x1_xxxxb: issue reset enable instruction 66h, then issue reset instruction
99h. The reset
JEDEC Basic Flash
Parameter
enable, reset sequence may be issued on 1, 2, or 4 wires depending on the
device operating mode.
Dword-16
+ 1x_xxxxb: exit 0-4-4 mode is required prior to other reset sequences above
if the device
41h
3Fh
A1h
may be operating in this mode.
= 110000b
Bit 7 = RFU = 1
Bits 6:0 = Volatile or Nonvolatile Register and Write Enable Instruction for
Status Register 1
= + xx1_xxxxb: Status Register 1 contains a mix of volatile and nonvolatile
bits. The 06h
instruction is used to enable writing of the register.
+ x1x_xxxxb: Reserved
+ 1xx_xxxxb: Reserved
= 1110000b
Binary Fields: 10100001-1111100000-110000-1-1110000
Nibble Format: 1010_0001_1111_1000_0011_0000_1111_0000
Hex Format: A1_F8_30_F0
Datasheet
148 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Device identification
Table 69
CFI alternate vendor-specific extended query parameter A5h, JEDEC SFDP Rev B, section 1,
basic flash parameter and 4-byte address instructions parameter (continued)
CFI parameter
relative byte
address offset
SFDP parameter
SFDP Dword
relative byte
Data
Description
name
address offset
42h nonvolatile
40h
41h
42h
6Bh
8Eh
FFh
Supported = 1, Not Supported = 0
Bits 31:20 = RFU = FFFh
43h
44h
Bit 19 = Support for nonvolatile individual sector lock write command,
Instruction=E3h = 1
Bit 18 = Support for nonvolatile individual sector lock read command,
Instruction=E2h = 1
Bit 17 = Support for volatile individual sector lock Write command,
Instruction=E1h = 1
Bit 16 = Support for volatile individual sector lock Read command,
Instruction=E0h = 1
Bit 15 = Support for (1-4-4) DTR_Read Command, Instruction=EEh = 1
Bit 14 = Support for (1-2-2) DTR_Read Command, Instruction=BEh = 0
Bit 13 = Support for (1-1-1) DTR_Read Command, Instruction=0Eh = 0
Bit 12 = Support for Erase Command – Type 4 = 0
JEDEC 4 Byte
Address Instruc-
tions Parameter
Dword-1
Bit 11 = Support for Erase Command – Type 3 = 1
Bit 10 = Support for Erase Command – Type 2 = 1
45h
43h
FFh
Bit 9 = Support for Erase Command – Type 1 = 1
Bit 8 = Support for (1-4-4) Page Program Command, Instruction=3Eh =0
Bit 7 = Support for (1-1-4) Page Program Command, Instruction=34h = 0
Bit 6 = Support for (1-1-1) Page Program Command, Instruction=12h = 1
Bit 5 = Support for (1-4-4) FAST_READ Command, Instruction=ECh = 1
Bit 4 = Support for (1-1-4) FAST_READ Command, Instruction=6Ch = 0
Bit 3 = Support for (1-2-2) FAST_READ Command, Instruction=BCh = 1
Bit 2 = Support for (1-1-2) FAST_READ Command, Instruction=3Ch = 0
Bit 1 = Support for (1-1-1) FAST_READ Command, Instruction=0Ch = 1
Bit 0 = Support for (1-1-1) READ Command, Instruction=13h = 1
46h
47h
48h
49h
44h
45h
46h
47h
21h
DCh
DCh
FFh
JEDEC 4 Byte
Address Instruc-
tions Parameter
Dword-2
Bits 31:24 = FFh = Instruction for Erase Type 4: RFU
Bits 23:16 = DCh = Instruction for Erase Type 3
Bits 15:8 = DCh = Instruction for Erase Type 2
Bits 7:0 = 21h = Instruction for Erase Type 1
Sector Map parameter table notes
Table 70 provides a means to identify how the device address map is configured and provides a sector map for
each supported configuration. This is done by defining a sequence of commands to read out the relevant config-
uration register bits that affect the selection of an address map. When more than one configuration bit must be
read, all the bits are concatenated into an index value that is used to select the current address map.
To identify the sector map configuration in FS512S the following configuration bits are read in the following MSb
to LSb order to form the configuration map index value:
• CR3NV[3] — 0 = Hybrid Architecture, 1 = Uniform Architecture
• CR1NV[2] — 0 = 4 KB parameter sectors at bottom, 1 = 4 KB sectors at top
The value of some configuration bits may make other configuration bit values not relevant (don’t care), hence
not all possible combinations of the index value define valid address maps. Only selected configuration bit
combinations are supported by the SFDP Sector Map Parameter Table. Other combinations must not be used in
configuring the sector address map when using this SFDP parameter table to determine the sector map. The
following index value combinations are supported.
Table 70
Device
Sector map parameter
CR3NV[3]
CR1NV[2] Index Value
Description
4 KB sectors at bottom with remainder 256 KB sectors
4 KB sectors at top with remainder 256 KB sectors
Uniform 256 KB sectors
0
0
1
0
1
0
01h
03h
05h
FS512S
Datasheet
149 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Device identification
Table 71
CFI alternate vendor-specific extended query parameter A5h, JEDEC SFDP Rev B,
section 2, sector map parameter table, 512 Mb
CFI parameter SFDP parameter
relative byte
relative byte
SFDP D word name
Data
Description
address offset
address offset
4Ah
4Bh
4Ch
48h
49h
4Ah
FCh
65h
FFh
Bits 31:24 = Read data mask = 0000_1000b: Select bit 3 of the data byte for
20h_NV value
0= Hybrid map with 4-KB parameter sectors
1= Uniform map
Bits 23:22 = Configuration detection command address length = 11b: Variable
length
JEDEC Sector Map
Parameter Dword-1
Config. Detect-1
Bits 21:20 = RFU = 11b
Bits 19:16 = Configuration detection command latency = 1111b: variable latency
Bits 15:8 = Configuration detection instruction = 65h: Read any register
Bits 7:2 = RFU = 111111b
4Dh
4Bh
08h
Bit 1 = Command Descriptor = 0
Bit 0 = not the end descriptor = 0
4Eh
4Fh
50h
51h
52h
53h
54h
4Ch
4Dh
4Eh
4Fh
50h
51h
52h
04h
00h
00h
00h
FCh
65h
FFh
JEDEC Sector Map
Parameter Dword-2
Config. Detect-1
Bits 31:0 = Sector map configuration detection command address =
00_00_00_04h: address of CR3NV
Bits 31:24 = Read data mask = 0000_0100b: Select bit 2 of the data byte for
TBPARM_O value
0= 4-KB parameter sectors at bottom
1= 4-KB parameter sectors at top
Bits 23:22 = Configuration detection command address length = 11b: Variable
length
JEDEC Sector Map
Parameter Dword-3
Config. Detect-2
Bits 21:20 = RFU = 11b
Bits 19:16 = Configuration detection command latency = 1111b: variable latency
Bits 15:8 = Configuration detection instruction = 65h: Read any register
Bits 7:2 = RFU = 111111b
55h
53h
04h
Bit 1 = Command Descriptor = 0
Bit 0 = not the end descriptor = 0
56h
57h
58h
59h
5Ah
5Bh
5Ch
54h
55h
56h
57h
58h
59h
5Ah
02h
00h
00h
00h
JEDEC Sector Map
Parameter Dword-4
Config. Detect-2
Bits 31:0 = Sector map configuration detection command address =
00_00_00_02h: address of CR1NV
FDh Bits 31:24 = Read data mask = 0000_0010b: Select bit 1 of the data byte for
D8h_NV value
65h
FFh
0= 64-KB uniform sectors
1= 256-KB uniform sectors
Bits 23:22 = Configuration detection command address length = 11b: Variable
length
JEDEC Sector Map
Parameter Dword-5
Config. Detect-3
Bits 21:20 = RFU = 11b
Bits 19:16 = Configuration detection command latency = 1111b: variable latency
Bits 15:8 = Configuration detection instruction = 65h: Read any register
Bits 7:2 = RFU = 111111b
5Dh
5Bh
02h
Bit 1 = Command Descriptor = 0
Bit 0 = The end descriptor = 1
5Eh
5Fh
60h
61h
62h
63h
64h
5Ch
5Dh
5Eh
5Fh
60h
61h
62h
04h
00h
00h
00h
FEh
01h
02h
JEDEC Sector Map
Parameter Dword-6
Config. Detect-3
Bits 31:0 = Sector map configuration detection command address =
00_00_00_04h: address of CR3NV
Bits 31:24 = RFU = FFh
Bits 23:16 = Region count (Dwords -1) = 02h: Three regions
Bits 15:8 = Configuration ID = 01h: 4-KB sectors at bottom with remainder 256-KB
sectors
JEDEC Sector Map
Parameter Dword-7
Config-1 Header
Bits 7:2 = RFU = 111111b
Bit 1 = Map Descriptor = 1
65h
63h
FFh
Bit 0 = not the end descriptor = 0
Datasheet
150 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Device identification
Table 71
CFI alternate vendor-specific extended query parameter A5h, JEDEC SFDP Rev B,
section 2, sector map parameter table, 512 Mb (continued)
CFI parameter SFDP parameter
relative byte
relative byte
SFDP D word name
Data
Description
address offset
address offset
66h
67h
68h
64h
65h
66h
F1h
7Fh
00h
Bits 31:8 = Region size = 00007Fh:
Region size as count-1 of 256 Byte units = 8 x 4 KB sectors = 32 KB
Count = 32 KB/256 = 128, value = count -1 = 128 -1 = 127 = 7Fh
Bits 7:4 = RFU = Fh
Erase Type not supported = 0/ supported = 1
Bit 3 = Erase Type 4 support = 0b
JEDEC Sector Map
Parameter Dword-8
Config-1 Region-0
--- Erase Type 4 is not defined
Bit 2 = Erase Type 3 support = 0b
--- Erase Type 3 is 256-KB erase and is supported in the 4-KB sector region
Bit 1 = Erase Type 2 support = 0b
69h
67h
00h
--- Erase Type 2 is 64-KB erase and is not supported in the 4-KB sector region
Bit 0 = Erase Type 1 support = 1b
--- Erase Type 1 is 4-KB erase and is supported in the 4-KB sector region
6Ah
6Bh
6Ch
68h
69h
6Ah
F4h
7Fh
03h
Bits 31:8 = Region size = 00037Fh:
Region size as count-1 of 256 Byte units = 1 x 224 KB sectors = 224 KB
Count = 224 KB/256 = 896, value = count -1 = 896 -1 = 895 = 37Fh
Bits 7:4 = RFU = Fh
Erase Type not supported = 0/ supported = 1
Bit 3 = Erase Type 4 support = 0b
JEDEC Sector Map
Parameter Dword-9
Config-1 Region-1
--- Erase Type 4 is not defined
Bit 2 = Erase Type 3 support = 1b
--- Erase Type 3 is 256-KB erase and is supported in the 32-KB sector region
Bit 1 = Erase Type 2 support = 0b
6Dh
6Bh
00h
--- Erase Type 2 is 64-KB erase and is not supported in the 32-KB sector region
Bit 0 = Erase Type 1 support = 0b
--- Erase Type 1 is 4-KB erase and is not supported in the 32-KB sector region
6Eh
6Fh
70h
6Ch
6Dh
6Eh
F4h
FFh
FBh
Bits 31:8 = 512 Mb device Region size = 03FBFFh:
Region size as count-1 of 256 Byte units = 255 x 256 KB sectors = 65280 KB
Count = 65280 KB/256 = 261120, value = count -1 = 261120 -1 = 261119 = 3FBFFh
Bits 7:4 = RFU = Fh
Erase Type not supported = 0/ supported = 1
JEDEC Sector Map
Parameter Dword-10
Config-1 Region-2
Bit 3 = Erase Type 4 support = 0b
--- Erase Type 4 is not defined
Bit 2 = Erase Type 3 support = 1b
--- Erase Type 3 is 256-KB erase and is supported in the 64-KB sector region
Bit 1 = Erase Type 2 support = 0b
03h(512
Mb
71h
6Fh
--- Erase Type 2 is 64-KB erase and is not supported in the 64-KB sector region
Bit 0 = Erase Type 1 support = 0b
--- Erase Type 1 is 4-KB erase and is not supported in the 64-KB sector region
72h
73h
74h
70h
71h
72h
FEh
03h
02h
Bits 31:24 = RFU = FFh
Bits 23:16 = Region count (Dwords -1) = 02h: Three regions
Bits 15:8 = Configuration ID = 03h: 4 KB sectors at top with remainder 256 KB
sectors
JEDEC Sector Map
Parameter Dword-11
Config-3 Header
Bits 7:2 = RFU = 111111b
Bit 1 = Map Descriptor = 1
75h
73h
FFh
Bit 0 = not the end descriptor = 0
76h
77h
78h
74h
75h
76h
F4h
FFh
FBh
Bits 31:8 = 512 Mb device Region size = 03FBFFh:
Region size as count-1 of 256 Byte units = 255 x 256 KB sectors = 65280 KB
Count = 65280 KB/256 = 261120, value = count -1 = 261120 -1 = 261119 = 3FBFFh
Bits 7:4 = RFU = Fh
Erase Type not supported = 0/ supported = 1
JEDEC Sector Map
Parameter Dword-12
Config-3 Region-0
Bit 3 = Erase Type 4 support = 0b
--- Erase Type 4 is not defined
Bit 2 = Erase Type 3 support = 1b
--- Erase Type 3 is 256-KB erase and is supported in the 64-KB sector region
Bit 1 = Erase Type 2 support = 0b
03h(512
Mb
79h
77h
--- Erase Type 2 is 64-KB erase and is not supported in the 64-KB sector region
Bit 0 = Erase Type 1 support = 0b
--- Erase Type 1 is 4-KB erase and is not supported in the 64-KB sector region
7Ah
7Bh
7Ch
78h
79h
7Ah
F4h
7Fh
03h
Bits 31:8 = Region size = 00037Fh:
Region size as count-1 of 256 Byte units = 1 x 224 KB sectors = 224 KB
Count = 224 KB/256 = 896, value = count -1 = 896 -1 = 895 = 37Fh
Bits 7:4 = RFU = Fh
Erase Type not supported = 0/ supported = 1
Bit 3 = Erase Type 4 support = 0b
JEDEC Sector Map
Parameter Dword-13
Config-3 Region-1
--- Erase Type 4 is not defined
Bit 2 = Erase Type 3 support = 1b
--- Erase Type 3 is 256-KB erase and is supported in the 224-KB sector region
Bit 1 = Erase Type 2 support = 0b
7Dh
7Bh
00h
--- Erase Type 2 is 64-KB erase and is not supported in the 224-KB sector region
Bit 0 = Erase Type 1 support = 0b
--- Erase Type 1 is 4-KB erase and is not supported in the 224-KB sector region
Datasheet
151 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Device identification
Table 71
CFI alternate vendor-specific extended query parameter A5h, JEDEC SFDP Rev B,
section 2, sector map parameter table, 512 Mb (continued)
CFI parameter SFDP parameter
relative byte
relative byte
SFDP D word name
Data
Description
address offset
address offset
7Eh
7Fh
80h
7C
7D
7E
F1h
7Fh
00h
Bits 31:8 = Region size = 00007Fh:
Region size as count-1 of 256 Byte units = 8 x 4 KB sectors = 32 KB
Count = 32 KB/256 = 128, value = count -1 = 128 -1 = 127 = 7Fh
Bits 7:4 = RFU = Fh
Erase Type not supported = 0/ supported = 1
Bit 3 = Erase Type 4 support = 0b
JEDEC Sector Map
Parameter Dword-14
Config-3 Region-2
--- Erase Type 4 is not defined
Bit 2 = Erase Type 3 support = 0b
--- Erase Type 3 is 256-KB erase and is not supported in the 4-KB sector region
Bit 1 = Erase Type 2 support = 0b
81h
7F
00h
--- Erase Type 2 is 64-KB erase and is not supported in the 4-KB sector region
Bit 0 = Erase Type 1 support = 1b
--- Erase Type 1 is 4-KB erase and is supported in the 4-KB sector region
82h
83h
84h
85h
86h
87h
88h
80h
81h
82h
83h
84h
85h
86h
FFh
05h
00h
FFh
F4h
FFh
FFh
Bits 31:24 = RFU = FFh
Bits 23:16 = Region count (Dwords -1) = 00h: One region
Bits 15:8 = Configuration ID = 05h: Uniform 256-KB sectors
Bits 7:2 = RFU = 111111b
JEDEC Sector Map
Parameter Dword-15
Config-4 Header
Bit 1 = Map Descriptor = 1
Bit 0 = The end descriptor = 1
Bits 31:8 = 512 Mb device Region size = 03FFFFh:
Region size as count-1 of 256 Byte units = 256 x 256 KB sectors = 65536 KB
Count = 65536 KB/256 = 262144, value = count -1 = 262144 -1 = 262143 = 3FFFFh
Bits 7:4 = RFU = Fh
Erase Type not supported = 0/ supported = 1
JEDEC Sector Map
Parameter Dword-16
Config-4 Region-0
Bit 3 = Erase Type 4 support = 0b
--- Erase Type 4 is not defined
Bit 2 = Erase Type 3 support = 1b
--- Erase Type 3 is 256-KB erase and is supported in the 256-KB sector region
Bit 1 = Erase Type 2 support = 0b
89h
87h
03h
--- Erase Type 2 is 64-KB erase and is not supported in the 256-KB sector region
Bit 0 = Erase Type 1 support = 0b
--- Erase Type 1 is 4-KB erase and is not supported in the 256-KB sector region
Datasheet
152 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Initial delivery state
13
Initial delivery state
The device is shipped from Infineon with non-volatile bits set as follows:
• The entire memory array is erased: i.e., all bits are set to ‘1’ (each byte contains FFh).
• The OTP address space has the first 16 bytes programmed to a random number. All other bytes are erased to FFh.
• The SFDP address space contains the values as defined in the description of the SFDP address space.
• The ID-CFI address space contains the values as defined in the description of the ID-CFI address space.
• The Status Register 1 non-volatile contains 00h (all SR1NV bits are cleared to 0’s).
• The Configuration Register 1 non-volatile contains 00h.
• The Configuration Register 2 non-volatile contains 08h.
• The Configuration Register 3 non-volatile contains 00h.
• The Configuration Register 4 non-volatile contains 10h.
• The Password Register contains FFFFFFFF-FFFFFFFFh.
• All PPB bits are 1.
• The ASP Register bits are FFFFh.
Datasheet
153 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Package diagrams
14
Package diagrams
A-B
C
0.20
0.10
C
D
2X
0.33
C
0.25
0.10
M
C A-B D
C
0.10
C
DIMENSIONS
NOTES:
SYMBOL
MIN.
NOM.
MAX.
2.65
1. ALL DIMENSIONS ARE IN MILLIMETERS.
2. DIMENSIONING AND TOLERANCING PER ASME Y14.5M - 1994.
A
A1
A2
b
2.35
0.10
2.05
-
3. DIMENSION D DOES NOT INCLUDE MOLD FLASH, PROTRUSIONS OR GATE BURRS.
MOLD FLASH, PROTRUSIONS OR GATE BURRS SHALL NOT EXCEED 0.15 mm PER
END. DIMENSION E1 DOES NOT INCLUDE INTERLEAD FLASH OR PROTRUSION.
INTERLEAD FLASH OR PROTRUSION SHALL NOT EXCEED 0.25 mm PER SIDE.
D AND E1 DIMENSIONS ARE DETERMINED AT DATUM H.
4. THE PACKAGE TOP MAY BE SMALLER THAN THE PACKAGE BOTTOM. DIMENSIONS
D AND E1 ARE DETERMINED AT THE OUTMOST EXTREMES OF THE PLASTIC BODY
EXCLUSIVE OF MOLD FLASH, TIE BAR BURRS, GATE BURRS AND INTERLEAD
FLASH, BUT INCLUSIVE OF ANY MISMATCH BETWEEN THE TOP AND BOTTOM OF
THE PLASTIC BODY.
-
0.30
2.55
0.51
0.48
-
0.31
0.27
0.20
0.20
-
b1
c
-
0.33
0.30
-
-
c1
5. DATUMS A AND B TO BE DETERMINED AT DATUM H.
6. "N" IS THE MAXIMUM NUMBER OF TERMINAL POSITIONS FOR THE SPECIFIED
PACKAGE LENGTH.
7. THE DIMENSIONS APPLY TO THE FLAT SECTION OF THE LEAD BETWEEN 0.10 TO
0.25 mm FROM THE LEAD TIP.
8. DIMENSION "b" DOES NOT INCLUDE DAMBAR PROTRUSION. ALLOWABLE DAMBAR
PROTRUSION SHALL BE 0.10 mm TOTAL IN EXCESS OF THE "b" DIMENSION AT
MAXIMUM MATERIAL CONDITION. THE DAMBAR CANNOT BE LOCATED ON THE
LOWER RADIUS OF THE LEAD FOOT.
D
E
10.30 BSC
10.30 BSC
7.50 BSC
E1
e
1.27 BSC
-
L
1.27
0.40
L1
L2
N
9. THIS CHAMFER FEATURE IS OPTIONAL. IF IT IS NOT PRESENT, THEN A PIN 1
IDENTIFIER MUST BE LOCATED WITHIN THE INDEX AREA INDICATED.
10. LEAD COPLANARITY SHALL BE WITHIN 0.10 mm AS MEASURED FROM THE
SEATING PLANE.
1.40 REF
0.25 BSC
16
h
0.25
0°
-
-
-
-
0.75
8°
0
0 1
0 2
5°
15°
-
0°
002-15547 *A
Figure 117
SOIC 16-lead, 10.30 7.50 2.65 mm (SO3016)
Datasheet
154 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Package diagrams
NOTES:
DIMENSIONS
SYMBOL
MIN.
NOM.
MAX.
0.55
1. ALL DIMENSIONS ARE IN MILLIMETERS.
2. N IS THE TOTAL NUMBER OF TERMINALS.
e
1.27 BSC.
8
N
3
DIMENSION "b" APPLIES TO METALLIZED TERMINAL AND IS MEASURED
BETWEEN 0.15 AND 0.30mm FROM TERMINAL TIP. IF THE TERMINAL HAS
THE OPTIONAL RADIUS ON THE OTHER END OF THE TERMINAL, THE
DIMENSION "b" SHOULD NOT BE MEASURED IN THAT RADIUS AREA.
ND REFERS TO THE NUMBER OF TERMINALS ON D SIDE.
ND
4
0.45
0.50
L
b
D2
E2
D
0.35
3.90
3.30
0.40
4.00
0.45
4.10
3.50
4
3.40
6.00 BSC
PIN #1 ID ON TOP WILL BE LOCATED WITHIN THE INDICATED ZONE.
COPLANARITY ZONE APPLIES TO THE EXPOSED HEAT SINK
SLUG AS WELL AS THE TERMINALS.
5
6
E
8.00 BSC
0.70
0.00
0.75
-
0.80
0.05
A
A1
7. JEDEC SPECIFICATION NO. REF. : N/A
0.20 REF
-
A3
K
-
0.20
002-15552 *A
Figure 118
WSON 8-Lead DFN 6.0 8.0 0.8 mm (WNH008) WNH008 4.0 3.4 mm E-Pad (SAWN)
Datasheet
155 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Package diagrams
NOTES:
DIMENSIONS
SYMBOL
MIN.
NOM.
MAX.
1.
2.
3.
DIMENSIONING AND TOLERANCING METHODS PER ASME Y14.5M-1994.
A
A1
D
-
-
-
1.20
-
ALL DIMENSIONS ARE IN MILLIMETERS.
0.20
BALL POSITION DESIGNATION PER JEP95, SECTION 3, SPP-020.
8.00 BSC
4.
5.
e REPRESENTS THE SOLDER BALL GRID PITCH.
E
6.00 BSC
4.00 BSC
4.00 BSC
5
D1
E1
MD
ME
N
SYMBOL "MD" IS THE BALL MATRIX SIZE IN THE "D" DIRECTION.
SYMBOL "ME" IS THE BALL MATRIX SIZE IN THE "E" DIRECTION.
N IS THE NUMBER OF POPULATED SOLDER BALL POSITIONS FOR MATRIX SIZE MD X ME.
5
6
7
DIMENSION "b" IS MEASURED AT THE MAXIMUM BALL DIAMETER IN A PLANE
PARALLEL TO DATUM C.
24
0.40
b
0.35
0.45
"SD" AND "SE" ARE MEASURED WITH RESPECT TO DATUMS A AND B AND DEFINE THE
POSITION OF THE CENTER SOLDER BALL IN THE OUTER ROW.
eE
eD
SD
SE
1.00 BSC
1.00 BSC
0.00 BSC
0.00 BSC
WHEN THERE IS AN ODD NUMBER OF SOLDER BALLS IN THE OUTER ROW, "SD" OR "SE" = 0.
WHEN THERE IS AN EVEN NUMBER OF SOLDER BALLS IN THE OUTER ROW, "SD" = eD/2 AND
"SE" = eE/2.
8.
9.
"+" INDICATES THE THEORETICAL CENTER OF DEPOPULATED BALLS.
A1 CORNER TO BE IDENTIFIED BY CHAMFER, LASER OR INK MARK,
METALLIZED MARK INDENTATION OR OTHER MEANS.
002-15534 **
Figure 119
Ball grid array 24-ball FBGA 8.0 6.0 1.2 mm (FAB024)
14.1
Special handling instructions for FBGA packages
Flash memory devices in BGA packages may be damaged if exposed to ultrasonic cleaning methods. The package
and/or data integrity may be compromised if the package body is exposed to temperatures above 150°C for
prolonged periods of time.
Datasheet
156 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Ordering information
15
Ordering information
15.1
Ordering part number
The ordering part number is formed by a valid combination of the following:
S25FS 512
S
AG
M
F
I
01
1
Packing type
0 = Tray
1 = Tube
3 = 13” Tape and reel
Model number (Additional ordering options)
01 = SOIC16 / WSON 6 x 8 footprint, 256-KB Physical Sector
21 = 5 x 5 ball BGA footprint, 256-KB Physical Sector
Temperature range / Grade
I = Industrial (-40°C to +85°C)
V = Industrial Plus (-40°C to +105°C)
A = Automotive, AEC-Q100 grade 3 (-40°C to +85°C)
B = Automotive, AEC-Q100 grade 2 (-40°C to +105°C)
M = Automotive, AEC-Q100 grade 1 (-40°C to +125°C)
[81]
Package materials
F = Halogen-free, Lead (Pb)-free
H = Halogen-free, Lead (Pb)-free
Package type
M = 16-pin SOIC
N = 8-contact WSON 6 x 8 mm
B = 24-ball BGA 6 x 8 mm package, 1.00 mm pitch
Speed
AG = 133 MHz
DS = 80 MHz DDR
Device technology
S = 65-nm MIRRORBIT™ Process technology
Density
512 = 512 Mb
Device family
S25FS Memory 1.8 V-only, Serial Peripheral Interface (SPI) Flash Memory
Note
81. Halogen free definition is in accordance with IE 61249-2-21 specification.
Datasheet
157 of 160
002-00488 Rev. *N
2022-05-02
512 Mb (64 MB) FS-S Flash
SPI Multi-I/O, 1.8 V
Ordering information
15.2
Valid combinations — standard
Valid combinations list configurations planned to be supported in volume for this device. Contact the local sales
office to confirm availability of specific valid combinations and to check on newly released combinations.
Table 72
Valid combinations — standard
Base ordering
part number
Speed
option
Package and
temperature
Model number Packing type
Package marking
MFI, MFV
NFI, NFV
BHI, BHV
MFI, MFV
NFI, NFV
BHI, BHV
01
21
01
21
0, 1, 3
0, 3
FS512S + A +(Temp) + F + (Model Number)
FS512S + A +(Temp) + H + (Model Number)
FS512S + D +(Temp) + F + (Model Number)
FS512S + D +(Temp) + H + (Model Number)
AG
DS
S25FS512S
0, 1, 3
0, 3
15.3
Valid combinations — automotive grade / AEC-Q100
Table 73 lists configurations that are automotive grade / AEC-Q100 qualified and are planned to be available in
volume. The table will be updated as new combinations are released. Consult your local sales representative to
confirm availability of specific combinations and to check on newly released combinations.
Production Part Approval Process (PPAP) support is only provided for AEC-Q100 grade products.
Products to be used in end-use applications that require ISO/TS-16949 compliance must be AEC-Q100 grade
products in combination with PPAP. Non–AEC-Q100 grade products are not manufactured or documented in full
compliance with
ISO/TS-16949 requirements.
AEC-Q100 grade products are also offered without PPAP support for end-use applications that do not require
ISO/TS-16949 compliance.
Table 73
Valid combinations — automotive grade / AEC-Q100
Base ordering Speed
Package and
temperature
Model number Packing type
Package marking
part number
option
MFA, MFB, MFM
NFA, NFB, NFM
BHA, BHB, BHM
MFA, MFB, MFM
NFA, NFB, NFM
BHA, BHB, BHM
01
21
01
21
0, 1, 3
0, 3
FS512S + A + (Temp) + F + (Model Number)
FS512S + A + (Temp) + H + (Model Number)
FS512S + D + (Temp) + F + (Model Number)
FS512S + D + (Temp) + H + (Model Number)
AG
S25FS512S
0, 1, 3
0, 3
DS
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