W39V040FB [WINBOND]
512K X 8 CMOS FLASH MEMORY WITH FWH INTERFACE; 512K ×8 CMOS闪光灯FWH接口存储器型号: | W39V040FB |
厂家: | WINBOND |
描述: | 512K X 8 CMOS FLASH MEMORY WITH FWH INTERFACE |
文件: | 总33页 (文件大小:363K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
W39V040FB Data Sheet
512K × 8 CMOS FLASH MEMORY
WITH FWH INTERFACE
Table of Contents-
1.
2.
3.
4.
5.
6.
GENERAL DESCRIPTION ......................................................................................................... 3
FEATURES................................................................................................................................. 3
PIN CONFIGURATIONS............................................................................................................. 4
BLOCK DIAGRAM ...................................................................................................................... 4
PIN DESCRIPTION..................................................................................................................... 4
FUNCTIONAL DESCRIPTION.................................................................................................... 5
6.1
6.2
6.3
6.4
6.5
6.6
6.7
6.8
Interface Mode Selection and Description..................................................................... 5
Read (Write) Mode ........................................................................................................ 5
Reset Operation............................................................................................................. 5
Boot Block Operation and Hardware Protection at Initial- #TBL & #WP....................... 5
Sector Erase Command ................................................................................................ 6
Program Operation ........................................................................................................ 6
Hardware Data Protection ............................................................................................. 6
WRITE OPERATION STATUS...................................................................................... 6
7.
REGISTER FOR FWH MODE .................................................................................................... 8
7.1
7.2
7.3
7.4
7.5
7.6
7.7
7.8
General Purpose Inputs Register for FWH Mode.......................................................... 8
Product Identification Registers..................................................................................... 8
Block Locking Registers ................................................................................................ 8
Register Based Block Locking Value Definitions Table................................................. 9
Read Lock.................................................................................................................... 10
Write Lock.................................................................................................................... 10
Lock Down ................................................................................................................... 10
Product Identification Registers................................................................................... 10
8.
9.
TABLE OF OPERATING MODES ............................................................................................ 10
8.1
8.2
8.3
Operating Mode Selection - Programmer Mode.......................................................... 10
Operating Mode Selection - FWH Mode...................................................................... 11
FWH Cycle Definition................................................................................................... 11
TABLE OF COMMAND DEFINITION ....................................................................................... 11
9.1
9.2
9.3
9.4
Embedded Programming Algorithm ............................................................................ 12
Embedded Erase Algorithm......................................................................................... 13
Embedded #Data Polling Algorithm............................................................................. 14
Embedded Toggle Bit Algorithm.................................................................................. 15
Publication Release Date: April 14, 2005
- 1 -
Revision A3
W39V040FB
9.5
Software Product Identification and Boot Block Lockout Detection Acquisition Flow . 16
10.
ELECTRICAL CHARACTERISTICS......................................................................................... 17
10.1
10.2
10.3
10.4
10.5
10.6
10.7
10.8
10.9
Absolute Maximum Ratings......................................................................................... 17
Programmer interface Mode DC Operating Characteristics........................................ 17
FWH Interface Mode DC Operating Characteristics ................................................... 18
Power-up Timing.......................................................................................................... 18
Capacitance................................................................................................................. 18
Programmer Interface Mode AC Characteristics......................................................... 19
Read Cycle Timing Parameters................................................................................... 20
Write Cycle Timing Parameters................................................................................... 20
Data Polling and Toggle Bit Timing Parameters ......................................................... 20
11.
TIMING WAVEFORMS FOR PROGRAMMER INTERFACE MODE ....................................... 21
11.1
11.2
11.3
11.4
11.5
11.6
Read Cycle Timing Diagram........................................................................................ 21
Write Cycle Timing Diagram........................................................................................ 21
Program Cycle Timing Diagram .................................................................................. 22
#DATA Polling Timing Diagram................................................................................... 22
Toggle Bit Timing Diagram.......................................................................................... 23
Sector Erase Timing Diagram ..................................................................................... 23
12.
13.
FWH INTERFACE MODE AC CHARACTERISTICS................................................................ 24
12.1
12.2
12.3
AC Test Conditions...................................................................................................... 24
Read/Write Cycle Timing Parameters ......................................................................... 24
Reset Timing Parameters............................................................................................ 24
TIMING WAVEFORMS FOR FWH INTERFACE MODE.......................................................... 25
13.1
13.2
13.3
13.4
13.5
13.6
13.7
Read Cycle Timing Diagram........................................................................................ 25
Write Cycle Timing Diagram........................................................................................ 25
Program Cycle Timing Diagram .................................................................................. 26
#DATA Polling Timing Diagram................................................................................... 27
Toggle Bit Timing Diagram.......................................................................................... 28
FGPI Register/Product ID Readout Timing Diagram................................................... 30
Reset Timing Diagram................................................................................................. 30
14.
15.
16.
ORDERING INFORMATION..................................................................................................... 31
HOW TO READ THE TOP MARKING...................................................................................... 31
PACKAGE DIMENSIONS......................................................................................................... 32
16.1
16.2
32L PLCC .................................................................................................................... 32
32L STSOP.................................................................................................................. 32
17.
VERSION HISTORY................................................................................................................. 33
- 2 -
W39V040FB
1. GENERAL DESCRIPTION
The W39V040FB is a 4-megabit, 3.3-volt only CMOS flash memory organized as 512K × 8 bits. For
flexible erase capability, the 4Mbits of data are divided into 8 uniform sectors of 64 Kbytes. The device
can be programmed and erased in-system with a standard 3.3V power supply. A 12-volt VPP is
required for accelerated program. The unique cell architecture of the W39V040FB results in fast
program/erase operations with extremely low current consumption. This device can operate at two
modes, Programmer bus interface mode, Firmware Hub (FWH) bus interface mode. As in the
Programmer interface mode, it acts like the traditional flash but with a multiplexed address inputs. But
in the FWH interface mode, this device complies with the Intel FWH specification. The device can also
be programmed and erased using standard EPROM programmers.
2. FEATURES
•
Single 3.3-volt operations:
− #TBL supports 64-Kbyte Boot Block
hardware protection
− 3.3-volt Read
− 3.3-volt Erase
− 3.3-volt Program
Fast Program operation:
− Byte-by-Byte programming: 9 µS (typ.)
(VPP = 12V)
− Byte-by-Byte programming: 12 µS (typ.)
(VPP = Vcc)
− #WP supports the whole chip except Boot
Block hardware protection
•
Low power consumption
•
− Active current: 15 mA (typ. for FWH read
mode)
•
•
Automatic program and erase timing with
internal VPP generation
End of program or erase detection
− Toggle bit
− Data polling
•
Fast Erase operation:
− Sector erase 0.6 Sec. (typ.)
•
•
•
•
•
•
Fast Read access time: Tkq 11 nS
Endurance: 10K cycles (typ.)
Twenty-year data retention
8 Even sectors with 64K bytes
Any individual sector can be erased
Hardware protection:
•
•
•
Latched address and data
TTL compatible I/O
Available packages: 32L PLCC, 32L STSOP
32L PLCC Lead free, 32L STSOP Lead free
Publication Release Date: April 14, 2005
Revision A3
- 3 -
W39V040FB
3. PIN CONFIGURATIONS
Firmware Hub (FWH) Mode
4. BLOCK DIAGRAM
#WP
7FFFF
#TBL
CLK
64K BYTES BLOCK 7
70000
FWH
Interface
FWH[3:0]
FWH4
6FFFF
64K BYTES BLOCK 6
60000
5FFFF
50000
IC
#INIT
#RESET
64K BYTES BLOCK 5
64K BYTES BLOCK 4
4FFFF
40000
3FFFF
64K BYTES BLOCK 3
64K BYTES BLOCK 2
R/#C
A[10:0]
DQ[7:0]
30000
2FFFF
Program-
mer
Interface
20000
1FFFF
10000
0FFFF
64K BYTES BLOCK 1
64K BYTES BLOCK 0
#OE
#WE
RY/#BY
00000
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
1
#OE(#INIT)
NC
NC
2
#WE(FWH4)
RY/#BY(RSV)
DQ7(RSV)
3
NC
SS
4
V
5
IC
DQ6(RSV)
6
A10(FGPI4)
R/#C(CLK)
DQ5(RSV)
7
5. PIN DESCRIPTION
DQ4(RSV)
8
DD
V
DQ3(FWH3)
32L STSOP
9
Vpp
SS
V
10
11
12
13
14
15
16
DQ2(FWH2)
DQ1(FWH1)
#RESET
A9(FGPI3)
A8(FGPI2)
INTERFACE
PGM FWH
SYM.
PIN NAME
DQ0(FWH0)
A0(ID0)
A7(FGPI1)
A6(FGPI0)
A5(#WP)
A1(ID1)
A2(ID2)
IC
#RESET
#INIT
#TBL
#WP
*
*
*
*
*
*
*
*
*
Interface Mode Selection
Reset
Initialize
Top Boot Block Lock
Write Protect
CLK Input
A3(ID3)
A4(#TBL)
A
1
0
^
A
8
^
R
/
A
9
^
#
C
^
#
F
G
P
I
F
G
P
I
F
G
P
I
R
E
S
E
T
C
L
K
v
V
P
P
V
D
D
2
v
3
v
4
v
CLK
FGPI[4:0]
4
3
2
1
32 31 30
General Purpose Inputs
A7(FGPI1)
A6(FGPI0)
A5(#WP)
A4(#TBL)
A3(ID3)
5
6
29
28
27
26
25
24
23
22
21
IC
Identification Inputs They
Are Internal Pull Down to
Vss
SS
V
7
8
NC
ID[3:0]
*
NC
9
DD
32L PLCC
V
10
11
12
13
A2(ID2)
A1(ID1)
#OE(#INIT)
#WE(FWH4)
RY/#BY(RSV)
DQ7(RSV)
FWH[3:0]
FWH4
R/#C
A[10:0]
DQ[7:0]
#OE
#WE
RY/#BY
VDD
*
*
Address/Data Inputs
FWH Cycle Initial
Row/Column Select
Address Inputs
Data Inputs/Outputs
Output Enable
Write Enable
Ready/ Busy
Power Supply
Ground
A0(ID0)
DQ0(FWH0)
*
*
*
*
*
*
*
*
14 15 16 17 18 19 20
D
Q
1
D
Q
2
D
Q
5
D
Q
3
D
Q
4
D
Q
6
V
S
S
^
^
^
^
^
^
F
F
R
S
V
v
F
R
S
V
v
R
S
V
v
W
H
1
W
H
2
W
H
3
v
v
v
*
*
VSS
Accelerate Program
VPP
*
*
Power Supply
RSV
NC
*
*
*
*
Reserved Pins
No Connection
- 4 -
W39V040FB
6. FUNCTIONAL DESCRIPTION
6.1 Interface Mode Selection and Description
This device can operate in two interface modes, one is Programmer interface mode, and the other is
FWH interface mode. The IC (Mode) pin of the device provides the control between these two
interface modes. These interface modes need to be configured before power up or return from
#RESET. When IC (Mode) pin is set to VDD, the device will be in the Programmer mode; while the IC
(Mode) pin is set to low state (or leaved no connection), it will be in the FWH mode. In Programmer
mode, this device just behaves like traditional flash parts with 8 data lines. But the row and column
address inputs are multiplexed. The row address are mapped to the higher internal address A[18:11].
And the column address are mapped to the lower internal address A[10:0]. For FWH mode, it
complies with the FWH Interface Specification, through the FWH[3:0] to communicate with the system
chipset .
6.2 Read (Write) Mode
In Programmer interface mode, the read (write) operation of the W39V040FB is controlled by #OE
(#WE). The #OE (#WE) is held low for the host to obtain (write) data from (to) the outputs (inputs).
#OE is the output control and is used to gate data from the output pins. The data bus is in high
impedance state when #OE is high. As for in the FWH interface mode, the read or write is determined
by the "bit 0 & bit 1 of START CYCLE ". Refer to the FWH cycle definition and timing waveforms for
further details.
6.3 Reset Operation
The #RESET input pin can be used in some application. When #RESET pin is at high state, the
device is in normal operation mode. When #RESET pin is at low state, it will halt the device and all
outputs will be at high impedance state. As the high state re-asserted to the #RESET pin, the device
will return to read or standby mode, it depends on the control signals.
6.4 Boot Block Operation and Hardware Protection at Initial- #TBL & #WP
There is a hardware method to protect the top boot block and other sectors. Before power on
programmer, tie the #TBL pin to low state and then the top boot block will not be programmed/erased.
If #WP pin is tied to low state before power on, the other sectors will not be programmed/erased.
In order to detect whether the boot block feature is set on or not, users can perform software
command sequence: enter the product identification mode (see Command Codes for
Identification/Boot Block Lockout Detection for specific code), and then read from address
7FFF2(hex). You can check the DQ2/DQ3 at the address 7FFF2 to see whether the #TBL/#WP pin is
in low or high state. If the DQ2 is “0”, it means the #TBL pin is tied to high state. In such condition,
whether boot block can be programmed/erased or not will depend on software setting. On the other
hand, if the DQ2 is “1”, it means the #TBL pin is tied to low state, then boot block is locked no matter
how the software is set. Like the DQ2, the DQ3 inversely mirrors the #WP state. If the DQ3 is “0”, it
means the #WP pin is in high state, then all the sectors except the boot block can be
programmed/erased. On the other hand, if the DQ3 is “1”, then all the sectors except the boot block
are programmed/erased inhibited.
To return to normal operation, perform a three-byte command sequence (or an alternate single-byte
command) to exit the identification mode. For the specific code, see Command Codes for
Identification/Boot Block Lockout Detection.
Publication Release Date: April 14, 2005
- 5 -
Revision A3
W39V040FB
6.5 Sector Erase Command
Sector erase is a six-bus cycles operation. There are two "unlock" write cycles, followed by writing the
"set-up" command. Two more "unlock" write cycles then follows by the Sector erase command. The
Sector address (any address location within the desired Sector) is latched on the rising edge of R/#C
in programmer mode, while the command (30H) is latched on the rising edge of #WE.
Sector erase does not require the user to program the device prior to erase. When erasing a Sector,
the remaining unselected sectors are not affected. The system is not required to provide any controls
or timings during these operations.
The automatic Sector erase begins after the erase command is completed, right from the rising edge
of the #WE pulse for the last Sector erase command pulse and terminates when the data on DQ7,
Data Polling, is "1" at which time the device returns to the read mode. Data Polling must be performed
at an address within any of the sectors being erased.
Refer to the Erase Command flow Chart using typical command strings and bus operations.
6.6 Program Operation
The W39V040FB is programmed on a byte-by-byte basis. Program operation can only change logical
data "1" to logical data "0." The erase operation, which changed entire data in main memory and/or
boot block from "0" to "1", is needed before programming.
The program operation is initiated by a 4-byte command cycle (see Command Codes for Byte
Programming). The device will internally enter the program operation immediately after the byte-
program command is entered. The internal program timer will automatically time-out (12µS typ. - TBP)
once it is completed and then return to normal read mode. Data polling and/or Toggle Bits can be
used to detect end of program cycle.
6.7 Hardware Data Protection
The integrity of the data stored in the W39V040FB is also hardware protected in the following ways:
(1) Noise/Glitch Protection: A #WE pulse of less than 5 nS in duration will not initiate a write cycle.
(2) VDD Power Up/Down Detection: The programming and read operation are inhibited when VDD is
less than 2.0V typical.
(3) Write Inhibit Mode: Forcing #OE low or #WE high will inhibit the write operation. This prevents
inadvertent writes during power-up or power-down periods.
6.8 WRITE OPERATION STATUS
The device provides several bits to determine the status of a program or erase operation: DQ5, DQ6,
and DQ7. Each of DQ7 and DQ6 provides a method for determining whether a program or erase
operation is complete or in progress. The device also offers a hardware-based output signal, RY/#BY
in programmer mode, to determine whether an Embedded Program or Erase operation is in progress
or has been completed.
DQ7: #Data Polling
The #Data Polling bit, DQ7, indicates whether an Embedded Program or Erase algorithm is in
progress or completed. Data Polling is valid after the rising edge of the final #WE pulse in the
command sequence.
- 6 -
W39V040FB
During the Embedded Program algorithm, the device outputs on DQ7 and the complement of the data
programmed to DQ7. Once the Embedded Program algorithm has completed, the device outputs the
data programmed to DQ7. The system must provide the program address to read valid status
information on DQ7. If a program address falls within a protected sector, #Data Polling on DQ7 is
active for about 1µS, and then the device returns to the read mode.
During the Embedded Erase algorithm, #Data Polling produces “0” on DQ7. Once the Embedded
Erase algorithm has completed, #Data Polling produces “1” on DQ7. An address within any of the
sectors selected for erasure must be provided to read valid status information on DQ7.
Just before the completion of an Embedded Program or Erase operation, DQ7 may change
asynchronously with DQ0-DQ6 while Output Enable (#OE) is set to low. That is, the device may
change from providing status information to valid data on DQ7. Depending on when it samples the
DQ7 output, the system may read the status or valid data. Even if the device has completed the
program or erase operation and DQ7 has valid data, the data outputs on DQ0-DQ6 may be still
invalid. Valid data on DQ7-DQ0 will appear on successive read cycles.
RY/#BY: Ready/#Busy
The RY/#BY is a dedicated, open-drain output pin which indicates whether an Embedded Algorithm is in
progress or complete. The RY/#BY status is valid after the rising edge of the final #WE pulse in the
command sequence. Since RY/#BY is an open-drain output, several RY/#BY pins can be tied together in
parallel with a pull-up resistor to VDD
.
When the output is low (Busy), the device is actively erasing or programming. When the output is high
(Ready), the device is in the read mode or standby mode.
DQ6: Toggle Bit
Toggle Bit on DQ6 indicates whether an Embedded Program or Erase algorithm is in progress or
complete. Toggle Bit I may be read at any address, and is valid after the rising edge of the final #WE
pulse in the command sequence (before the program or erase operation), and during the sector erase
time-out.
During an Embedded Program or Erase algorithm operation, successive read cycles to any address
cause DQ6 to toggle. The system may use either #OE or #CE to control the read cycles. Once the
operation has completed, DQ6 stops toggling.
The system can use DQ6 to determine whether a sector is actively erasing. If the device is actively
erasing (i.e., the Embedded Erase algorithm is in progress), DQ6 toggles. If a program address falls
within a protected sector, DQ6 toggles for about 1 µs after the program command sequence is written,
and then returns to reading array data.
DQ5: Exceeded Timing Limits
DQ5 indicates whether the program or erase time has exceeded a specified internal pulse count limit.
DQ5 produces “1” under these conditions which indicates that the program or erase cycle was not
successfully completed.
The device may output “1” on DQ5 if the system tries to program “1” to a location that was previously
programmed to “0.” Only the erase operation can change “0” back to “1.” Under this condition, the
device stops the operation, and while the timing limit has been exceeded, DQ5 produces “1.”
Under both these conditions, the system must write the reset command to return to the read mode.
Publication Release Date: April 14, 2005
- 7 -
Revision A3
W39V040FB
7. REGISTER FOR FWH MODE
There are three kinds of registers on this device, the General Purpose Input Registers, the Block Lock
Control Registers and Product Identification Registers. Users can access these registers through
respective address in the 4Gbytes memory map. There are detail descriptions in the sections below.
7.1 General Purpose Inputs Register for FWH Mode
This register reads the FGPI[4:0] pins on the W39V040FB.This is a pass-through register which can
read via memory address FFBC0100(hex). Since it is pass-through register, there is no default value.
GPI Register Table
BIT
FUNCTION
Reserved
7 − 5
4
3
2
1
0
Read FGPI4 pin status
Read FGPI3 pin status
Read FGPI2 pin status
Read FGPI1 pin status
Read FGPI0 pin status
7.2 Product Identification Registers
In the FWH interface mode, a read from FFBC, 0000(hex) can output the manufacturer code, DA(hex).
A read from FFBC, 0001(hex) can output the device code 54(hex).
There is an alternative software method to read out the Product Identification in both the Programmer
interface mode and the FWH interface mode. Thus, the programming equipment can automatically
matches the device with its proper erase and programming algorithms.
In the software access mode, a or JEDEC 3-byte command sequence can be used to access the
product ID for programmer interface mode. A read from address 0000(hex) outputs the manufacturer
code, DA(hex). A read from address 0001(hex) outputs the device code, 54(hex). The product ID
operation can be terminated by a three-byte command sequence or an alternate one-byte command
sequence (see Command Definition table for detail).
7.3 Block Locking Registers
This part provides 8 even 64Kbytes blocks, and each block can be locked by register control. These
control registers can be set or clear through memory address. Below is the detail description.
Please note that this feature is only can be applied on FWH mode.
- 8 -
W39V040FB
Block Locking Registers type and access memory map Table
REGISTERS
CONTROL
DEVICE PHYSICAL
4GBYTES SYSTEM
MEMORY ADDRESS
REGISTERS
TYPE
BLOCK
ADDRESS
BLR7
BLR6
BLR5
BLR4
BLR3
BLR2
BLR1
BLR0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
7
6
5
4
3
2
1
0
7FFFFh – 70000h
6FFFFh – 60000h
5FFFFh – 50000h
4FFFFh – 40000h
3FFFFh – 30000h
2FFFFh – 20000h
1FFFFh – 10000h
0FFFFh – 00000h
FFBF0002h
FFBE0002h
FFBD0002h
FFBC0002h
FFBB0002h
FFBA0002h
FFB90002h
FFB80002h
Block Locking Register Bits Function Table
BIT
FUNCTION
7 – 3
Reserved
Read Lock
1: Prohibit to read in the block where set
2
0: Normal read operation in the block where clear. This is default state.
Lock Down
1: Prohibit further to set or clear the Read Lock or Write Lock bits. This Lock Down
Bit can only be set not clear. Only the device is reset or re-powered, the Lock Down
Bit is cleared.
0: Normal operation for Read Lock or Write Lock. This is the default state.
Write Lock
1: Prohibited to write in the block where set. This is default state.
0: Normal programming/erase operation in the block where clear.
1
0
7.4 Register Based Block Locking Value Definitions Table
BIT [7:3]
00000
00000
00000
00000
00000
00000
00000
00000
BIT 2
BIT 1
BIT 0
RESULT
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
Full Access.
Write Lock. Default State.
Locked Open (Full Access, Lock Down).
Write Locked, Locked Down.
Read Locked.
Read & Write Locked.
Read Locked, Locked Down.
Read & Write Locked, Locked Down.
Publication Release Date: April 14, 2005
Revision A3
- 9 -
W39V040FB
7.5 Read Lock
Any attempt to read the data of read locked block will result in “00H.” The default state of any block is
unlocked upon power up. User can clear or set the write lock bit anytime as long as the lock down bit
is not set.
7.6 Write Lock
This is the default state of blocks upon power up. Before any program or erase to the specified block,
user should clear the write lock bit first. User can clear or set the write lock bit anytime as long as the
lock down bit is not set. The write lock function is in conjunction with the hardware protect pins, #WP &
TBL. When hardware protect pins are enabled, it will override the register block locking functions and
write lock the blocks no matter how the status of the register bits. Reading the register bit will not
reflect the status of the #WP or #TBL pins.
7.7 Lock Down
The default state of lock down bit for any block is unlocked. This bit can be set only once; any further
attempt to set or clear is ignored. Only the reset from #RESET or #INIT can clear the lock down bit.
Once the lock down bit is set for a block, then the write lock bit & read lock bit of that block will not be
set or cleared, and keep its current state.
7.8 Product Identification Registers
In the FWH interface mode, a read from FFBC, 0000(hex) can output the manufacturer code, DA(hex).
A read from FFBC,0001(hex) can output the device code 54(hex).
There is an alternative software method (six commands bytes) to read out the Product Identification in
both the Programmer interface mode and the FWH interface mode. Thus, the programming equipment
can automatically matches the device with its proper erase and programming algorithms.
In the software access mode, a six-byte (or JEDEC 3-byte) command sequence can be used to
access the product ID for programmer interface mode. A read from address 0000(hex) outputs the
manufacturer code, DA(hex). A read from address 0001(hex) outputs the device code, 54(hex). The
product ID operation can be terminated by a three-byte command sequence or an alternate one-byte
command sequence (see Command Definition table for detail).
8. TABLE OF OPERATING MODES
8.1 Operating Mode Selection - Programmer Mode
PINS
ADDRESS
MODE
#OE
VIL
VIH
X
#WE
VIH
VIL
X
#RESET
VIH
DQ.
Read
Write
AIN
AIN
X
Dout
Din
VIH
VIL
Standby
High Z
VIL
X
VIH
X
VIH
X
VIH
VIH
VIH
X
X
X
High Z/DOUT
High Z/DOUT
High Z
Write Inhibit
Output Disable
- 10 -
W39V040FB
8.2 Operating Mode Selection - FWH Mode
Operation modes in FWH interface mode are determined by "START Cycle" when it is selected.
When it is not selected, its outputs (FWH[3:0]) will be disable. Please reference to the "FWH Cycle
Definition".
8.3 FWH Cycle Definition
NO. OF
FIELD
DESCRIPTION
CLOCKS
"1101b" indicates FWH Memory Read cycle; while "1110b" indicates FWH
Memory Write cycle. 0000b" appears on FWH bus to indicate the initial
START
1
IDSEL
MSIZE
TAR
1
1
2
This one clock field indicates which FWH component is being selected.
Memory Size. There is always show “0000b” for single byte access.
Turned Around Time
Address Phase for Memory Cycle. FWH supports the 28 bits address
protocol. The addresses transfer most significant nibble first and least
significant nibble last. (i.e. Address[27:24] on FWH[3:0] first, and
Address[3:0] on FWH[3:0] last.)
ADDR
7
Synchronous to add wait state. "0000b" means Ready, "0101b" means
Short Wait, "0110b" means Long Wait, "1001b" for DMA only, "1010b"
means error, and other values are reserved.
Data Phase for Memory Cycle. The data transfer least significant nibble
first and most significant nibble last. (i.e. DQ[3:0] on FWH[3:0] first, then
DQ[7:4] on FWH[3:0] last.)
SYNC
DATA
N
2
9. TABLE OF COMMAND DEFINITION
COMMAND
DESCRIPTION
Read
Sector Erase
NO. OF
Cycles (1)
1ST CYCLE
Addr. Data
AIN DOUT
5555 AA
5555 AA
5555 AA
5555 AA
XXXX F0
2ND CYCLE 3RD CYCLE 4TH CYCLE 5TH CYCLE 6TH CYCLE
Addr. Data
Addr. Data
Addr. Data
Addr. Data
Addr. Data
1
6
4
3
3
1
2AAA 55
2AAA 55
2AAA 55
2AAA 55
5555 80
5555 A0
5555 90
5555 F0
5555 AA
2AAA 55
SA(5) 30
Byte Program
AIN
DIN
Product ID Entry
Product ID Exit (4)
Product ID Exit (4)
Notes: 1. The cycle means the write command cycle not the FWH clock cycle.
2. The Column Address / Row Address are mapped to the Low / High order Internal Address. i.e. Column Address
A[10:0] are mapped to the internal A[10:0], Row Address A[7:0] are mapped to the internal A[18:11]
3. Address Format: A14−A0 (Hex); Data Format: DQ7-DQ0 (Hex)
4. Either one of the two Product ID Exit commands can be used.
5. SA: Sector Address
SA = 7XXXXh for Unique Sector7 (Boot Sector)
SA = 6XXXXh for Unique Sector6
SA = 5XXXXh for Unique Sector5
SA = 3XXXXh for Unique Sector3
SA = 2XXXXh for Unique Sector2
SA = 1XXXXh for Unique Sector1
SA = 0XXXXh for Unique Sector0
SA = 4XXXXh for Unique Sector4
Publication Release Date: April 14, 2005
Revision A3
- 11 -
W39V040FB
9.1 Embedded Programming Algorithm
Start
Write Program Command Sequence
(see below)
#Data Polling/ Toggle bit
Programming Completed
Program Command Sequence (Address/Command):
5555H/AAH
2AAAH/55H
5555H/A0H
Program Address/Program Data
- 12 -
W39V040FB
9.2 Embedded Erase Algorithm
Start
Write Erase Command Sequence
(see below)
#Data Polling or Toggle Bit
Erasure Completed
Individual Sector Erase
Command Sequence
(Address/Command):
5555H/AAH
2AAAH/55H
5555H/80H
5555H/AAH
2AAAH/55H
Sector Address/30H
Publication Release Date: April 14, 2005
Revision A3
- 13 -
W39V040FB
9.3 Embedded #Data Polling Algorithm
Start
Read Byte
(DQ0 - DQ7)
Address = SA
Yes
DQ7 = Data
?
No
No
DQ5 = 1
Yes
Read Byte
(DQ0 - DQ7)
Address = SA
Yes
DQ7 = Data
No
Fail
Pass
Note: SA = Valid address for programming .During a sector erase
operation, a valid address is an address within any sector selected for
erasure.
- 14 -
W39V040FB
9.4 Embedded Toggle Bit Algorithm
Start
Read Byte
(DQ0-DQ7)
Read Byte
(DQ0-DQ7)
No
Toggle Bit
=Toggle ?
Yes
No
DQ5 = 1 ?
Yes
Read Byte
(DQ0-DQ7) Twin
No
Toggle Bit
=Toggle ?
Program/Erase
Operation complete
Program/Erase
Operation Not
Complete, Write
Reset Command
Note: Recheck toggle bit because it may stop toggling as DQ5 changes to “1”.
Publication Release Date: April 14, 2005
Revision A3
- 15 -
W39V040FB
9.5 Software Product Identification and Boot Block Lockout Detection Acquisition
Flow
Product
Product
Identification
Entry (1)
Product
Identification
and Boot Block
Lockout Detection
Mode (3)
Identification Exit(6)
Load data AA
to
Load data AA
to
address 5555
address 5555
(2)
(2)
(4)
Load data 55
to
Load data 55
to
Read address = 00000
data = DA
address 2AAA
address 2AAA
Load data 90
to
Load data F0
to
Read address = 00001
data = 54
address 5555
address 5555
Read address = 7FFF2
µ
S
Pause 10 S
µ
Pause 10
Check DQ[3:0] of data
outputs
(5)
Normal Mode
Notes for software product identification/boot block lockout detection:
(1) Data Format: DQ7−DQ0 (Hex); Address Format: A14−A0 (Hex)
(2) A1−A18 = VIL; manufacture code is read for A0 = VIL; device code is read for A0 = VIH.
(3) The device does not remain in identification and boot block lockout detection mode if power down.
(4) The DQ[3:2] to indicate the sectors protect status as below:
DQ2
DQ3
0
1
64Kbytes Boot Block Unlocked
Whole Chip Unlocked by #WP hardware
by #TBL hardware trapping
trapping Except Boot Block
64Kbytes Boot Block Locked by
#TBL hardware trapping
Whole Chip Locked by #WP hardware
trapping Except Boot Block
(5) The device returns to standard operation mode.
(6) Optional 1-write cycle (write F0 (hex.) at XXXX address) can be used to exit the product identification/boot block lockout
detection.
- 16 -
W39V040FB
10. ELECTRICAL CHARACTERISTICS
10.1 Absolute Maximum Ratings
PARAMETER
Operating Temperature
RATING
UNIT
°C
°C
V
V
V
0 to +70
-65 to +150
Storage Temperature
Power Supply Voltage to VSS Potential
D.C. Voltage on Any Pin to Ground Potential
VPP Voltage
-0.5 to +4.0
-0.5 to VDD +0.5
-0.5 to +13
Transient Voltage (<20 nS) on Any Pin to Ground Potential
-1.0 to VDD +0.5
V
Note: Exposure to conditions beyond those listed under Absolute Maximum Ratings May adversely affect the life and reliability
of the device.
10.2 Programmer interface Mode DC Operating Characteristics
(VDD = 3.3V ± 0.3V, VSS= 0V, TA = 0 to 70° C)
LIMITS
MIN. TYP.
PARAMETER
SYM.
TEST CONDITIONS
UNIT
MAX.
In Read or Write mode, all DQs open
Address inputs = 3.0V/0V, at f = 3 MHz
mA
Power Supply
ICC
ILI
-
15
30
Current
Input Leakage
Current
Output Leakage
Current
VIN = VSS to VDD
-
-
-
-
90
90
µA
µA
ILO VOUT = VSS to VDD
Input Low Voltage
Input High Voltage
Output Low Voltage
VIL
-
-
-0.5
2.0
-
-
-
-
-
0.8
VDD +0.5
0.45
V
V
V
V
VIH
VOL IOL = 2.1 mA
Output High Voltage VOH IOH = -0.1mA
2.4
-
Publication Release Date: April 14, 2005
Revision A3
- 17 -
W39V040FB
10.3 FWH Interface Mode DC Operating Characteristics
(VDD = 3.3V ± 0.3V, VSS= 0V, TA = 0 to 70° C)
LIMITS
PARAMETER
SYM.
ICC
TEST CONDITIONS
UNIT
mA
MIN.
TYP.
MAX.
Power Supply Current
Read
All Iout = 0A, CLK = 33 MHz,
in FWH mode operation.
-
15
25
Power Supply Current
Program/Erase
CLK = 33 MHz,
ICC
-
-
18
20
30
50
mA
in FWH mode operation.
FWH4 = 0.9 VDD, CLK = 33 MHz,
all inputs = 0.9 VDD / 0.1 VDD
no internal operation
FWH4 = 0.1 VDD, CLK = 33 MHz,
all inputs = 0.9 VDD /0.1 VDD
no internal operation.
Standby Current 1
Isb1
Isb2
uA
Standby Current 2
Input Low Voltage
Input Low Voltage of
#INIT
-
3
10
mA
VIL
VILI
VIH
VIHI
-
-
-
-
-0.5
-0.5
-
-
-
-
0.3 VDD
0.2 VDD
V
V
V
V
Input High Voltage
Input High Voltage of
#INIT Pin
0.5 VDD
1.35 V
VDD +0.5
VDD +0.5
Output Low Voltage
Output High Voltage
VOL IOL = 1.5 mA
VOH IOH = -0.5 mA
-
-
-
0.1 VDD
-
V
V
0.9 VDD
10.4 Power-up Timing
PARAMETER
Power-up to Read Operation
Power-up to Write Operation
SYMBOL
TPU. READ
TPU. WRITE
TYPICAL
UNIT
100
5
µS
mS
10.5 Capacitance
(VDD = 3.3V, TA = 25° C, f = 1 MHz)
PARAMETER
I/O Pin Capacitance
Input Capacitance
SYMBOL
CI/O
CONDITIONS
VI/O = 0V
MAX.
12
6
UNIT
pf
pf
CIN
VIN = 0V
- 18 -
W39V040FB
10.6 Programmer Interface Mode AC Characteristics
AC Test Conditions
PARAMETER
CONDITIONS
Input Pulse Levels
Input Rise/Fall Time
Input/Output Timing Level
Output Load
0V to 0.9 VDD
< 5 nS
1.5V/1.5V
1 TTL Gate and CL = 30 pF
AC Test Load and Waveform
+3.3V
1.8K
Ω
D
OUT
Input
Output
30 pF
0.9VDD
(Including Jig and
Scope)
1.3K
1.5V
Ω
1.5V
0V
Test Point
Test Point
Publication Release Date: April 14, 2005
Revision A3
- 19 -
W39V040FB
Programmer Interface Mode AC Characteristics, continued
10.7 Read Cycle Timing Parameters
(VDD = 3.3V ± 0.3V, VSS = 0V, TA = 0 to 70° C)
W39V040FB
MIN. MAX.
PARAMETER
Read Cycle Time
Row / Column Address Set Up Time
Row / Column Address Hold Time
Address Access Time
Output Enable Access Time
#OE Low to Active Output
#OE High to High-Z Output
Output Hold from Address Change
SYMBOL
UNIT
TRC
TAS
350
50
50
-
-
0
-
-
-
nS
nS
nS
nS
nS
nS
nS
nS
TAH
TAA
TOE
TOLZ
TOHZ
TOH
150
75
-
-
0
35
-
10.8 Write Cycle Timing Parameters
PARAMETER
Reset Time
Address Setup Time
Address Hold Time
R/#C to Write Enable High Time
#WE Pulse Width
#WE High Width
Data Setup Time
Data Hold Time
#OE Hold Time
SYMBOL
TRST
TAS
TAH
TCWH
TWP
TWPH
TDS
TDH
TOEH
TBP
TPEC
MIN.
TYP.
-
-
-
-
-
-
-
-
MAX.
-
-
-
-
-
-
UNIT
µS
nS
nS
nS
nS
nS
nS
nS
nS
µS
S
1
50
50
50
100
100
50
50
0
-
-
-
-
200
6
Byte programming Time
Sector Erase Cycle Time (Note 2)
Program/Erase Valid to RY/#BY Delay
-
-
90
12
0.6
-
TBUSY
-
nS
Notes: 1. All AC timing signals observe the following guidelines for determining setup and hold times:
(a) High level signal's reference level is input high and (b) low level signal's reference level is input low.
Ref. to the AC testing condition.
2. Exclude 00H pre-program prior to erasure. (In the pre-programming step of the embedded erase algorithm,
all bytes are programmed to 00H before erasure
10.9 Data Polling and Toggle Bit Timing Parameters
W39V040FB
PARAMETER
SYMBOL
UNIT
MIN.
MAX.
350
350
-
#OE to Data Polling Output Delay
#OE to Toggle Bit Output Delay
Toggle or Polling interval
TOEP
TOET
-
-
-
50
nS
nS
mS
- 20 -
W39V040FB
11. TIMING WAVEFORMS FOR PROGRAMMER INTERFACE MODE
11.1 Read Cycle Timing Diagram
#RESET
T
RST
TRC
Row Address
Column Address
Row Address
A[10:0]
R/#C
Column Address
T
AS
T
T
AS
T
AH
AH
VIH
#WE
#OE
T
AA
OH
T
TOE
TOHZ
T
OLZ
High-Z
High-Z
DQ[7:0]
Data Valid
11.2 Write Cycle Timing Diagram
T
RST
#RESET
A[10:0]
Column Address
Row Address
T
AS
T
AS
T
AH
T
AH
R/
#C
T
CWH
T
T
OEH
#OE
#WE
T
WP
WPH
T
DH
T
DS
DQ[7:0]
Data Valid
Publication Release Date: April 14, 2005
Revision A3
- 21 -
W39V040FB
Timing Waveforms for Programmer Interface Mode, continued
11.3 Program Cycle Timing Diagram
Byte Program Cycle
A[10:0]
2AAA
55
5555
Programmed Address
(Internal A[18:0])
DQ[7:0]
5555
A0
Data-In
AA
R/#C
#OE
#WE
TWPH
BP
T
WP
T
Internal Write Start
Byte 0
Byte 1
Byte 2
Byte 3
RY/#BY
TBUSY
Note: The internal address A[18:0] are converted from external Column/Row address.
Column/Row Address are mapped to the Low/High order internal address.
i.e. Column Address A[10:0] are mapped to the internal A[10:0],
Row Address A[7:0] are mapped to the internal A[18:11].
11.4 #DATA Polling Timing Diagram
A[10:0]
(Internal A[18:0])
An
An
An
An
R/#C
#WE
#OE
TOEP
X
X
DQ7
X
X
BP
T
RY/#BY
BUSY
T
- 22 -
W39V040FB
Timing Waveforms for Programmer Interface Mode, continued
11.5 Toggle Bit Timing Diagram
A[10:0]
R/#C
#WE
#OE
TOET
DQ6
TBP
RY/#BY
11.6 Sector Erase Timing Diagram
Six-byte code for 3.3V-only
Sector Erase
A[10:0]
5555
AA
2AAA
55
(Internal A[18:0])
DQ[7:0]
5555
80
5555
AA
2AAA
55
SA
30
R/#C
#OE
#WE
T
WP
T
PEC
T
WPH
Internal Erase starts
SB0
SB2
SB3
SB5
SB4
SB1
RY/#BY
Note: The internal address A[18:0] are converted from external Column/Row addres
Column/Row Address are mapped to the Low/High order internal address
i.e. Column Address A[10:0] are mapped to the internal A[10:0]
T
BUSY
Row Address A[7:0] are mapped to the internal A[18:11].
SA = Sector Address, Please ref. to the "Table of Command Definition"
Publication Release Date: April 14, 2005
Revision A3
- 23 -
W39V040FB
12. FWH INTERFACE MODE AC CHARACTERISTICS
12.1 AC Test Conditions
PARAMETER
Input Pulse Levels
Input Rise/Fall Slew Rate
Input/Output Timing Level
Output Load
CONDITIONS
0.6 VDD to 0.2 VDD
1 V/nS
0.4VDD / 0.4VDD
1 TTL Gate and CL = 10 pF
12.2 Read/Write Cycle Timing Parameters
(VDD = 3.3V ± 0.3V, VSS = 0V, TA = 0 to 70° C)
PARAMETER
SYMBOL
W39V040FB
MIN. MAX.
UNIT
Clock Cycle Time
Input Set Up Time
Input Hold Time
TCYC
TSU
THD
TKQ
30
7
0
-
-
-
nS
nS
nS
nS
Clock to Data Valid
2
11
Note: Minimum and Maximum time have different load. Please refer to PCI specification.
12.3 Reset Timing Parameters
PARAMETER
VDD stable to Reset Active
Clock Stable to Reset Active
Reset Pulse Width
Reset Active to Output Float
Reset Inactive to Input Active
SYMBOL
TPRST
TKRST
TRSTP
TRSTF
TRST
MIN.
1
100
100
-
TYP.
MAX.
-
-
-
50
-
UNIT
mS
µS
nS
nS
-
-
-
-
-
10
µS
Note: All AC timing signals observe the following guidelines for determining setup and hold times:
(a) High level signal's reference level is input high and (b) low level signal's reference level is input low.
Please refer to the AC testing condition.
- 24 -
W39V040FB
13. TIMING WAVEFORMS FOR FWH INTERFACE MODE
13.1 Read Cycle Timing Diagram
TCYC
CLK
#RESET
FWH4
T
SU THD
TSU THD
TKQ
Start
FWH
Read
M Size
IDSEL
Address
A[15:12] A[11:8] A[7:4]
TAR
0000b 1111b Tri-State 0000b
2 Clocks 1 Clock Data out 2 Clocks
Next Start
0000b
TAR
Sync
Data
A[18:16]
XA[22]XXb
D[3:0]
FWH[3:0]
XXXXb
A[3:0]
D[7:4]
1111b Tri-State
2 Clocks
1101b
0000b
Load Address in 7
Clocks
1 Clock
1 Clock
1 Clock
Note: When A22 = high, the host will read the BIOS code from the FWH device.
While A22 = low, the host will read the GPI (Add = FFBC0100) or
Product ID (Add = FFBC0000/FFBC0001) from the FWH device
13.2 Write Cycle Timing Diagram
T
CYC
CLK
#RESET
T
T
FWH4
SU HD
Start
FWH
Write
TAR
TAR
Sync
0000b
M Size
0000b
Address
Next Start
IDSEL
0000b
Data
D[7:4]
XXXXb XXXXb
A[15:12] A[11:8]
A[7:4]
1111b
2 Clocks
Tri-State
Tri-State 0000b
FWH[3:0]
1110b
A[18:16]
A[3:0]
D[3:0]
1111b
1 Clock
2 Clocks
Load Data in 2 Clocks
1 Clock
Load Address in 7 Clocks
1 Clock
1 Clock
Publication Release Date: April 14, 2005
Revision A3
- 25 -
W39V040FB
Timing Waveforms, for FWH Interface Mode, continued
13.3 Program Cycle Timing Diagram
CLK
#RESET
FWH4
Start next
command
Data
TAR
Sync
0000b
TAR
Address
M Size
IDSEL
1st Start
1110b
XXXXb
XXXXb
XXXXb
0101b
0101b
0101b
0000b
X101b
1111b
FWH[3:0
]
Tri-State
1111b
Tri-State
1010b
1010b
0000b
1 Clock
Load Data "AA" in 2 Clocks
2 Clocks
Load Address "5555" in 7 Clocks
1 Clock
1 Clock
2 Clocks
1 Clock
Write the 1st command to the device in FWH mode.
CLK
#RESET
FWH4
Start next
command
Address
X010b
Data
TAR
TAR
M
Size
Sync
0000b
IDSEL
2nd Start
1110b
XXXXb
1010b
1010b
1010b
0000b
XXXXb
FWH[3:0
]
1111b
2 Clocks
1111b
XXXXb
0101b
0101b
Tri-State
Tri-State
0000b
Load Data "55"
in 2 Clocks
1 Clock
Load Address "2AAA" in 7 Clocks
1 Clock
2 Clocks
1 Clock
1 Clock
Write the 2nd command to the device in FWH mode.
CLK
#RESET
FWH4
Start next
command
Data
TAR
TAR
Sync
0000b
IDSEL
Address
M Size
3rd Start
1110b
XXXXb
]
XXXXb
0000b
FWH[3:0
0101b
0101b
0101b
XXXXb
X101b
0000b
1010b
1111b
1111b
Tri-State
Tri-State
0000b
Load Data "A0"
in 2 Clocks
2 Clocks
1 Clock
Load Address "5555" in 7 Clocks
1 Clock
2 Clocks
1 Clock
1 Clock
Write the 3rd command to the device in FWH mode.
CLK
#RESET
FWH4
Internal
program start
Address
Data
TAR
TAR
IDSEL
Sync
M
Size
4th Start
1110b
XXXXb
]
XXXXb
A[18:16]
A[15:12]
A[11:8]
A[7:4]
FWH[3:0
A[3:0]
0000b
D[3:0]
D[7:4]
1111b
Tri-State
0000b
1111b
Tri-State
Internal
0000b
program start
Load Din in 2 Clocks
2 Clocks
1 Clock
2 Clocks
Load Ain in 7 Clocks
1 Clock
1 Clock
Write the 4th command(target location to be programmed) to the device in FWH mode.
- 26 -
W39V040FB
Timing Waveforms for FWH Interface Mode, continued
13.4 #DATA Polling Timing Diagram
CLK
#RESET
FWH4
Data
TAR
Sync
0000b
M Size
TAR
Next Start
1 Clock
Address
An[15:12]
Start
1110b
IDSEL
0000b
XXXXb
XXXXb
An[18:16]
Dn[3:0] Dn[7:4]
An[7:4]
An[3:0]
0000b
1111b
FWH[3:0]
An[11:8]
Tri-State
1111b
2 Clocks
Tri-State
Load Data "Dn"
in 2 Clocks
1 Clock
Load Address "An" in 7 Clocks
2 Clocks
1 Clock
1 Clock
Write the last command(program or erase) to the device in FWH mode.
CLK
#RESET
XXXXb
FWH4
M Size
TAR
Next Start
1 Clock
Address
TAR
Tri-State 0000b
2 Clocks 1 Clock
Read the DQ7 to see if the internal write complete or not.
Start
Sync
Data
IDSEL
0000b
XXXXb
XXXXb
An[18:16]
An[15:12]
An[11:8]
An[7:4]
An[3:0]
0000b
1111b
Tri-State
FWH[3:0]
1101b
1111b
XXXXb Dn7,xxx
1 Clock
2 Clocks
1 Clock
Load Address in 7 Clocks
Data out 2 Clocks
CLK
#RESET
FWH4
TAR
Next Start
1 Clock
Address
An[15:12]
TAR
Tri-State 0000b
1 Clock
IDSEL
0000b
M Size
Start
1101b
Sync
Data
XXXXb
XXXXb
An[18:16]
FWH[3:0]
An[11:8]
An[7:4]
An[3:0]
1111b
XXXXb
Dn7,xxx 1111b
Tri-State
0000b
2 Clocks
2 Clocks
Load Address in 7 Clocks
Data out 2 Clocks
1 Clock
1 Clock
When internal write complete, the DQ7 will equal to Dn7.
Publication Release Date: April 14, 2005
Revision A3
- 27 -
W39V040FB
Timing Waveforms for FWH Interface Mode, continued
13.5 Toggle Bit Timing Diagram
CLK
#RESET
FWH4
Data
D[7:4]
TAR
TAR
Next Start
1 Clock
Sync
0000b
Address
A[18:16] A[15:12]
M Size
Start
1110b
IDSEL
0000b
XXXXb
XXXXb
A[7:4]
A[3:0]
0000b
1111b
Tri-State
D[3:0]
1111b
2 Clocks
FWH[3:0]
A[11:8]
Tri-State
Load Data "Dn"
in 2 Clocks
2 Clocks
1 Clock
Load Address "An" in 7 Clocks
1 Clock
1 Clock
Write the last command(program or erase) to the device in FWH mode.
CLK
#RESET
FWH4
TAR
Next Start
1 Clock
Address
TAR
Tri-State 0000b
2 Clocks 1 Clock Data out 2 Clocks
Read the DQ6 to see if the internal write complete or not.
Start IDSEL
M Size
Sync
Data
0000b
XXXXb
XXXXb
XXXXb
XXXXb
XXXXb
XXXXb XXXXb
0000b
XXXXb
FWH[3:0]
1101b
1111b
1111b
2 Clocks
Tri-State
X,D6,XXb
1 Clock
1 Clock
Load Address in 7 Clocks
CLK
#RESET
FWH4
TAR
Next Start
1 Clock
Address
XXXXb
TAR
Tri-State 0000b
2 Clocks 1 Clock Data out 2 Clocks
Start
1101b
Sync
Data
IDSEL
0000b
M Size
XXXXb
XXXXb
0000b
1111b
1111b
2 Clocks
FWH[3:0]
XXXXb
XXXXb
XXXXb
XXXXb
Tri-State
XXXXb
X,D6,XXb
Load Address in 7 Clocks
1 Clock
1 Clock
When internal write complete, the DQ6 will stop toggle.
- 28 -
W39V040FB
Timing Waveforms for FWH Interface Mode, continued
Sector Erase Timing Diagram
CLK
#RESET
FWH4
Start next
Data
1010b 1010b
TAR
1111b
TAR
M
Size
Sync
Address
X101b
Load Address "5555" in 7 Clocks
1st Start IDSEL
command
XXXXb
0000b
XXXXb
FWH[3:0]
0000b
1110b
XXXXb
Tri-State
2 Clocks
0000b
0101b
0101b
0101b
1111b
Tri-State
Load Data "AA"
in 2 Clocks
1 Clock
2 Clocks
1 Clock 1 Clock
1 Clock
Write the 1st command to the device in FWH mode.
CLK
#RESET
FWH4
Start next
command
Address
X010b
Data
0101b
TAR
TAR
1111b
2 Clocks
Sync
0000b
IDSEL
0000b
M
2nd Start
1110b
Size
XXXXb
XXXXb
FWH[3:0]
XXXXb
0000b
1111b
Tri-State
1010b
1010b
1010b
0101b
Tri-State
Load Data "55"
in 2 Clocks
2 Clocks
1 Clock
1 Clock 1 Clock
Load Address "2AAA" in 7 Clocks
1 Clock
Write the 2nd command to the device in FWH mode.
CLK
#RESET
FWH4
Start next
command
Data
0000b 1000b
TAR
TAR
M
Size
Sync
Address
X101b
3rd Start IDSEL
1110b 0000b
XXXXb
XXXXb
0000b
FWH[3:0]
0000b
XXXXb
Tri-State
1111b
Tri-State
0101b
0101b
0101b
1111b
Load Data "80"
in 2 Clocks
2 Clocks
1 Clocks
2 Clocks
1 Clocks1 Clocks
Load Address "5555" in 7 Clocks
1 Clocks
Write the 3rd command to the device in FWH mode.
CLK
#RESET
FWH4
Start next
command
Address
X101b
M
Size
Data
1010b
TAR
TAR
1111b Tri-State
2 Clocks
Sync
IDSEL
0000b
4th Start
1110b
FWH[3:0]
XXXXb
0000b
XXXXb
XXXXb
0101b
0101b
0101b
1010b
1111b
Tri-State 0000b
Load Data "AA"
in 2 Clocks
1 Clock
2 Clocks
1 Clock
1 Clock
Load Address "5555" in 7 Clocks
1 Clock
Write the 4th command to the device in FWH mode.
CLK
#RESET
FWH4
Start next
command
Data
0101b
TAR
1111b
Tri-State 0000b
2 Clocks
TAR
1111b
Tri-State
2 Clocks
M
Size
Sync
Address
X010b
5th Start IDSEL
FWH[3:0]
XXXXb
XXXXb
XXXXb
1110b
0000b
1010b
1010b
1010b
0000b
0101b
Load Data "55"
in 2 Clocks
1 Clock
1 Clock 1 Clock
Load Address "2AAA" in 7 Clocks
1 Clock
Write the 5th command to the device in FWH mode.
CLK
#RESET
FWH4
Internal
erase start
Address
Data
0011b
TAR
TAR
Sync
0000b
M
Size
IDSEL
0000b
6th Start
1110b
FWH[3:0]
Internal
XXXXb
XXXXb
1111b
Tri-State
0000b
1111b
A[18:16]
XXXXb XXXXb XXXXb XXXXb
0000b
Tri-State
erase start
Load Din
2 Clocks
2 Clocks
1 Clock
1 Clock
Load Sector Address in 7 Clocks
1 Clock
in 2 Clocks
Write the 6th command(target sector to be erased) to the device in FWH mode.
Publication Release Date: April 14, 2005
Revision A3
- 29 -
W39V040FB
Timing Waveforms for FWH Interface Mode, continued
13.6 FGPI Register/Product ID Readout Timing Diagram
CLK
#RESET
FWH4
M Size
0000b
IDSEL
0000b
Address
0000b
TAR
Next Sta
1 Clock
TAR
Start
Data
Sync
FWH[3:0]
0001b
/0000b
0000b
/0001b
1101b
Tri-State 1111b
D[3:0]
D[7:4]
A[27:24]
Tri-State 1111b
A[23:20] A[19:16]
0000b
0000b
Load Address "FFBC0100(hex)" in 7 Clocks for GPI Register
& "FFBC0000(hex)/FFBC0001(hex) for Product ID
2 Clocks
1 Clock Data out 2 Clocks
1 Clock 1 Clock
2 Clocks
Note: During the GPI read out mode, the DQ[4:0] will capture the states(High or Low) of the FGPI[4:0] input pins. The DQ[7:5] are reserved pins
13.7 Reset Timing Diagram
VDD
CLK
T
PRST
T
KRST
T
RSTP
#RESET
FWH[3:0]
T
RST
TRSTF
FWH4
- 30 -
W39V040FB
14. ORDERING INFORMATION
ACCESS
POWER SUPPLY
STANDBY VDD
CURRENT MAX.
TIME
(nS)
11
CURRENT MAX.
PART NO.
PACKAGE
(mA)
30
30
(mA)
10
10
W39V040FBP
W39V040FBQ
32L PLCC
32L STSOP
11
32L PLCC
Lead free
32L STSOP
Lead free
W39V040FBPZ
W39V040FBQZ
11
11
30
30
10
10
Notes:
1. Winbond reserves the right to make changes to its products without prior notice.
2. Purchasers are responsible for performing appropriate quality assurance testing on products intended for use in
applications where personal injury might occur as a consequence of product failure.
15. HOW TO READ THE TOP MARKING
Example: The top marking of 32-pin STSOP W39V040FBQ
W39V040FBQ
2138977A-A12
345OBFA
1st line: Winbond logo
2nd line: the part number: W39V040FBQ
3rd line: the lot number
4th line: the tracking code: 345 O B FA
149: Packages made in ’03, week 45
O: Assembly house ID: A means ASE, O means OSE, ...etc.
B: IC revision; A means version A, B means version B, ...etc.
FA: Process code
Publication Release Date: April 14, 2005
- 31 -
Revision A3
W39V040FB
16. PACKAGE DIMENSIONS
16.1 32L PLCC
Dimension in Inches
Min. Nom. Max. Min. Nom. Max.
Dimension in mm
Symbol
H E
E
0.140
3.56
A
0.020
0.105
0.026
0.016
0.008
0.50
2.67
0.66
0.41
0.20
1
A
4
1
32
30
0.110
0.028
0.018
0.010
0.115
0.032
0.022
0.014
2.80
0.71
2.93
0.81
0.56
0.35
A
b
b
c
2
1
0.46
5
29
0.25
0.547
0.447
0.044
0.490
0.390
0.585
0.485
0.553
0.453
0.056
0.530
0.430
0.595
0.495
13.89
11.35
1.12
14.05
11.51
1.42
0.550
0.450
0.050
0.510
0.410
0.590
0.490
13.97
11.43
1.27
D
E
e
12.45
9.91
12.95
13.46
10.92
15.11
12.57
D
G
G
H
H
GD
10.41
14.99
12.45
2.29
E
D
E
D
HD
14.86
12.32
0.075
0.095
0.004
1.91
2.41
0.10
0.090
L
y
0
10
0
10
θ
21
13
Notes:
1. Dimensions D & E do not include interlead flash.
2. Dimension b1 does not include dambar protrusion/intrusio
3. Controlling dimension: Inches
14
20
c
4. General appearance spec. should be based on final
visual inspection sepc.
L
A2
A
A
θ
e
1
b
b1
Seating Plane
y
E
G
16.2 32L STSOP
HD
D
c
Dimension in Inches Dimension in mm
Symbol
Max.
1.20
Min. Nom. Max. Min. Nom.
e
0.047
A
0.002
0.035
0.006
0.041
0.05
0.95
0.17
0.10
0.15
1
A
E
2
0.040
1.00
0.22
-----
A
1.05
0.27
b
0.007 0.009 0.010
b
0.004
0.008
0.21
-----
0.488
c
12.40
8.00
D
E
H
0.315
0.551
0.020
14.00
D
0.50
0.60
0.80
e
0.50
0.70
0.020 0.024 0.028
0.031
L
θ
1
L
1 A
2
A
0.000
0.004
0.00
0
0.10
5
L
Y
Y
A
0
3
5
3
θ
L
1
- 32 -
W39V040FB
17. VERSION HISTORY
VERSION
DATE
PAGE
DESCRIPTION
A1
August 19, 2004
-
Initial Issued
Modify Isb1, Tbp, Tpec, Icc (read)
Add Icc (program/erase) and
Toggle or polling interval
Power supply voltage to Vss potential
Add important notice
A2
A3
October 4, 2004
April 14 ,2005
3, 17, 18, 20
33
Important Notice
Winbond products are not designed, intended, authorized or warranted for use as components in systems or
equipment intended for surgical implantation, atomic energy control instruments, airplane or spaceship instruments,
transportation instruments, traffic signal instruments, combustion control instruments, or for other applications
intended to support or sustain life. Further more, Winbond products are not intended for applications wherein failure
of Winbond products could result or lead to a situation wherein personal injury, death or severe property or
environmental damage could occur.
Winbond customers using or selling these products for use in such applications do so at their own risk and agree to
fully indemnify Winbond for any damages resulting from such improper use or sales.
Headquarters
Winbond Electronics Corporation America Winbond Electronics (Shanghai) Ltd.
27F, 2299 Yan An W. Rd. Shanghai,
200336 China
No. 4, Creation Rd. III,
Science-Based Industrial Park,
Hsinchu, Taiwan
2727 North First Street, San Jose,
CA 95134, U.S.A.
TEL: 1-408-9436666
TEL: 86-21-62365999
FAX: 86-21-62365998
TEL: 886-3-5770066
FAX: 1-408-5441798
FAX: 886-3-5665577
http://www.winbond.com.tw/
Taipei Office
Winbond Electronics Corporation Japan
7F Daini-ueno BLDG, 3-7-18
Shinyokohama Kohoku-ku,
Yokohama, 222-0033
Winbond Electronics (H.K.) Ltd.
Unit 9-15, 22F, Millennium City,
No. 378 Kwun Tong Rd.,
Kowloon, Hong Kong
9F, No.480, Rueiguang Rd.,
Neihu District, Taipei, 114,
Taiwan, R.O.C.
TEL: 886-2-8177-7168
FAX: 886-2-8751-3579
TEL: 81-45-4781881
TEL: 852-27513100
FAX: 81-45-4781800
FAX: 852-27552064
Please note that all data and specifications are subject to change without notice.
All the trade marks of products and companies mentioned in this data sheet belong to their respective owners.
Publication Release Date: April 14, 2005
Revision A3
- 33 -
相关型号:
©2020 ICPDF网 联系我们和版权申明