NUC930-YA2E [NUVOTON]
ARM Cortexâ¢-M0 32-BIT MICROCONTROLLER;型号: | NUC930-YA2E |
厂家: | NUVOTON |
描述: | ARM Cortexâ¢-M0 32-BIT MICROCONTROLLER |
文件: | 总89页 (文件大小:2245K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
NuMicro™ NUC120 Data Sheet
ARM Cortex™-M0
32-BIT MICROCONTROLLER
NuMicro™ Family
NUC120 Data Sheet
The information described in this document is the exclusive intellectual property of
Nuvoton Technology Corporation and shall not be reproduced without permission from Nuvoton.
Nuvoton is providing this document only for reference purposes of NuMicro microcontroller based
system design. Nuvoton assumes no responsibility for errors or omissions.
All data and specifications are subject to change without notice.
For additional information or questions, please contact: Nuvoton Technology Corporation.
Publication Release Date: Jan. 2, 2012
- 1 -
Revision V2.03
NuMicro™ NUC120 Data Sheet
Contents
1
2
GENERAL DESCRIPTION ......................................................................................................... 7
FEATURES................................................................................................................................. 8
2.1
NuMicro™ NUC120 Features – USB Line ...................................................................... 8
3
PARTS INFORMATION LIST AND PIN CONFIGURATION .................................................... 12
3.1
3.2
NuMicro™ NUC120 Products Selection Guide............................................................. 12
3.1.1 NuMicro™ NUC120 Medium Density USB Line Selection Guide....................................12
3.1.2 NuMicro™ NUC120 Low Density USB Line Selection Guide..........................................12
Pin Configuration .......................................................................................................... 14
3.2.1 NuMicro™ NUC120 Medium Density Pin Diagram .........................................................14
3.2.2 NuMicro™ NUC120 Low Density Pin Diagram ...............................................................17
4
5
BLOCK DIAGRAM .................................................................................................................... 19
4.1
4.2
NuMicro™ NUC120 Medium Density Block Diagram ................................................... 19
NuMicro™ NUC120 Low Density Block Diagram.......................................................... 20
FUNCTIONAL DESCRIPTION.................................................................................................. 21
5.1
5.2
ARM® Cortex™-M0 Core.............................................................................................. 21
System Manager........................................................................................................... 23
5.2.1 Overview ........................................................................................................................23
5.2.2 System Reset.................................................................................................................23
5.2.3 System Power Distribution .............................................................................................24
5.2.4 System Memory Map......................................................................................................25
5.2.5 System Timer (SysTick) .................................................................................................27
5.2.6 Nested Vectored Interrupt Controller (NVIC)..................................................................28
Clock Controller ............................................................................................................ 32
5.3
5.3.1 Overview ........................................................................................................................32
5.3.2 Clock Generator .............................................................................................................34
5.3.3 System Clock and SysTick Clock ...................................................................................35
5.3.4 Peripherals Clock ...........................................................................................................36
5.3.5 Power Down Mode Clock ...............................................................................................36
5.3.6 Frequency Divider Output...............................................................................................37
USB Device Controller (USB)....................................................................................... 38
5.4
5.5
5.6
5.7
5.4.1 Overview ........................................................................................................................38
5.4.2 Features .........................................................................................................................38
General Purpose I/O (GPIO) ........................................................................................ 39
5.5.1 Overview ........................................................................................................................39
5.5.2 Features .........................................................................................................................39
I2C Serial Interface Controller (Master/Slave) (I2C) ...................................................... 40
5.6.1 Overview ........................................................................................................................40
5.6.2 Features .........................................................................................................................41
PWM Generator and Capture Timer (PWM) ................................................................ 42
5.7.1 Overview ........................................................................................................................42
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NuMicro™ NUC120 Data Sheet
5.7.2 Features .........................................................................................................................43
Real Time Clock (RTC)................................................................................................. 44
5.8
5.9
5.8.1 Overview ........................................................................................................................44
5.8.2 Features .........................................................................................................................44
Serial Peripheral Interface (SPI)................................................................................... 45
5.9.1 Overview ........................................................................................................................45
5.9.2 Features .........................................................................................................................45
5.10 Timer Controller (TMR)................................................................................................. 46
5.10.1 Overview ......................................................................................................................46
5.10.2 Features .......................................................................................................................46
5.11 Watchdog Timer (WDT)................................................................................................ 47
5.11.1 Overview ......................................................................................................................47
5.11.2 Features .......................................................................................................................49
5.12 UART Interface Controller (UART) ............................................................................... 49
5.12.1 Overview ......................................................................................................................49
5.12.2 Features .......................................................................................................................51
5.13 PS/2 Device Controller (PS2D)..................................................................................... 52
5.13.1 Overview ......................................................................................................................52
5.13.2 Features .......................................................................................................................52
5.14 I2S Controller (I2S)......................................................................................................... 53
5.14.1 Overview ......................................................................................................................53
5.14.2 Features .......................................................................................................................53
5.15 Analog-to-Digital Converter (ADC) ............................................................................... 54
5.15.1 Overview ......................................................................................................................54
5.15.2 Features .......................................................................................................................54
5.16 Analog Comparator (CMP) ........................................................................................... 55
5.16.1 Overview ......................................................................................................................55
5.16.2 Features .......................................................................................................................55
5.17 PDMA Controller (PDMA)............................................................................................. 56
5.17.1 Overview ......................................................................................................................56
5.17.2 Features .......................................................................................................................56
5.18 External Bus Interface (EBI) ......................................................................................... 57
5.18.1 Overview ......................................................................................................................57
5.18.2 Features .......................................................................................................................57
FLASH MEMORY CONTROLLER (FMC) ................................................................................ 58
6
7
6.1
6.2
Overview....................................................................................................................... 58
Features........................................................................................................................ 58
ELECTRICAL CHARACTERISTICS......................................................................................... 59
7.1
7.2
Absolute Maximum Ratings.......................................................................................... 59
DC Electrical Characteristics ........................................................................................ 60
7.2.1 NuMicro™ NUC100/NUC120 Medium Density DC Electrical Characteristics.................60
7.2.2 NuMicro™ NUC100/NUC120 Low Density DC Electrical Characteristics .......................65
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NuMicro™ NUC120 Data Sheet
7.2.3 Operating Current Curve (Test condition: run NOP).......................................................70
7.2.4 Idle Current Curve..........................................................................................................72
7.2.5 Power Down Current Curve............................................................................................74
AC Electrical Characteristics ........................................................................................ 75
7.3
7.4
7.3.1 External 4~24 MHz High Speed Crystal.........................................................................75
7.3.2 External 32.768 kHz Low Speed Crystal ........................................................................76
7.3.3 Internal 22.1184 MHz High Speed Oscillator..................................................................76
7.3.4 Internal 10 kHz Low Speed Oscillator.............................................................................76
Analog Characteristics.................................................................................................. 77
7.4.1 Specification of 12-bit SARADC .....................................................................................77
7.4.2 Specification of LDO and Power management...............................................................78
7.4.3 Specification of Low Voltage Reset ................................................................................79
7.4.4 Specification of Brown-Out Detector...............................................................................79
7.4.5 Specification of Power-On Reset (5 V)...........................................................................79
7.4.6 Specification of Temperature Sensor .............................................................................80
7.4.7 Specification of Comparator ...........................................................................................80
7.4.8 Specification of USB PHY ..............................................................................................81
Flash DC Electrical Characteristics .............................................................................. 82
7.5
7.6
SPI Dynamic Characteristics ........................................................................................ 83
8
9
PACKAGE DIMENSIONS......................................................................................................... 85
8.1
8.2
8.3
100L LQFP (14x14x1.4 mm footprint 2.0mm) .............................................................. 85
64L LQFP (10x10x1.4mm footprint 2.0 mm) ................................................................ 86
48L LQFP (7x7x1.4mm footprint 2.0mm) ..................................................................... 87
REVISION HISTORY................................................................................................................ 88
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NuMicro™ NUC120 Data Sheet
Figures
Figure 3-1 NuMicro™ NUC100 Series selection code ................................................................... 13
Figure 3-2 NuMicro™ NUC120 Medium Density LQFP 100-pin Pin Diagram ............................... 14
Figure 3-3 NuMicro™ NUC120 Medium Density LQFP 64-pin Pin Diagram ................................. 15
Figure 3-4 NuMicro™ NUC120 Medium Density LQFP 48-pin Pin Diagram ................................. 16
Figure 3-5 NuMicro™ NUC120 Low Density LQFP 64-pin Pin Diagram........................................ 17
Figure 3-6 NuMicro™ NUC120 Low Density LQFP 48-pin Pin Diagram........................................ 18
Figure 4-1 NuMicro™ NUC120 Medium Density Block Diagram ................................................... 19
Figure 4-2 NuMicro™ NUC120 Low Density Block Diagram ......................................................... 20
Figure 5-1 Functional Controller Diagram...................................................................................... 21
Figure 5-2 NuMicro™ NUC120 Power Distribution Diagram.......................................................... 24
Figure 5-4 Clock generator global view diagram ........................................................................... 33
Figure 5-5 Clock generator block diagram..................................................................................... 34
Figure 5-6 System Clock Block Diagram ....................................................................................... 35
Figure 5-7 SysTick Clock Control Block Diagram.......................................................................... 35
Figure 5-8 Clock Source of Frequency Divider.............................................................................. 37
Figure 5-9 Block Diagram of Frequency Divider............................................................................ 37
Figure 5-10 I2C Bus Timing............................................................................................................ 40
Figure 5-11 Timing of Interrupt and Reset Signal.......................................................................... 48
Figure 7-1 Typical Crystal Application Circuit ................................................................................ 76
Figure 7-2 SPI Master dynamic characteristics timing................................................................... 84
Figure 7-3 SPI Slave dynamic characteristics timing..................................................................... 84
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NuMicro™ NUC120 Data Sheet
Tables
Table 1-1 Connectivity Supported Table.......................................................................................... 7
Table 5-1 Address Space Assignments for On-Chip Controllers................................................... 26
Table 5-2 Exception Model ............................................................................................................ 29
Table 5-3 System Interrupt Map..................................................................................................... 30
Table 5-4 Vector Table Format ...................................................................................................... 31
Table 5-5 Watchdog Timeout Interval Selection............................................................................ 47
Table 5-6 UART Baud Rate Equation............................................................................................ 49
Table 5-7 UART Baud Rate Setting Table..................................................................................... 50
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NuMicro™ NUC120 Data Sheet
1
GENERAL DESCRIPTION
The NuMicro™ NUC100 Series is 32-bit microcontrollers with embedded ARM® Cortex™-M0 core
for industrial control and applications which need rich communication interfaces. The Cortex™-M0
is the newest ARM® embedded processor with 32-bit performance and at a cost equivalent to
traditional 8-bit microcontroller. NuMicro™ NUC100 Series includes NUC100, NUC120, NUC130
and NUC140 product line.
The NuMicro™ NUC120 USB Line with USB 2.0 full-speed function embeds Cortex™-M0 core
running up to 50 MHz with 32K/64K/128K-byte embedded flash, 4K/8K/16K-byte embedded
SRAM, and 4K-byte loader ROM for the ISP. It also equips with plenty of peripheral devices, such
as Timers, Watchdog Timer, RTC, PDMA, UART, SPI, I2C, I2S, PWM Timer, GPIO, PS/2, USB
2.0 FS Device, 12-bit ADC, Analog Comparator, Low Voltage Reset Controller and Brown-Out
Detector.
Product Line
NUC100
UART
SPI
●
I2C
●
USB
●
LIN
CAN
PS/2
I2S
●
●
●
●
●
●
●
●
●
NUC120
●
●
●
NUC130
●
●
●
●
●
●
●
NUC140
●
●
●
●
Table 1-1 Connectivity Supported Table
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NuMicro™ NUC120 Data Sheet
2
FEATURES
The equipped features are dependent on the product line and their sub products.
2.1 NuMicro™ NUC120 Features – USB Line
•Core
–
–
–
–
–
–
ARM® Cortex™-M0 core runs up to 50 MHz
One 24-bit system timer
Supports low power sleep mode
Single-cycle 32-bit hardware multiplier
NVIC for the 32 interrupt inputs, each with 4-levels of priority
Serial Wire Debug supports with 2 watchpoints/4 breakpoints
•Build-in LDO for wide operating voltage ranges from 2.5 V to 5.5 V
•Flash Memory
–
32K/64K/128K bytes Flash for program code (128KB only support in NuMicro™
NUC100/NUC120 Medium Density)
–
–
–
–
4KB flash for ISP loader
Support In-system program (ISP) application code update
512 byte page erase for flash
Configurable data flash address and size for 128KB system, fixed 4KB data flash for
the 32KB and 64KB system
–
–
Support 2 wire ICP update through SWD/ICE interface
Support fast parallel programming mode by external programmer
•SRAM Memory
–
4K/8K/16K bytes embedded SRAM (16KB only support in NuMicro™ NUC100/NUC120
Medium Density)
–
Support PDMA mode
•PDMA (Peripheral DMA)
Support 9 channels PDMA for automatic data transfer between SRAM and peripherals
(Only support 1 channel in NuMicro™ NUC100/NUC120 Low Density)
•Clock Control
–
–
–
Flexible selection for different applications
Built-in 22.1184 MHz high speed OSC for system operation
Trimmed to
Trimmed to
1 % at +25 ℃ and VDD = 5 V
3 % at -40 ℃ ~ +85 ℃ and VDD = 2.5 V ~ 5.5 V
–
–
–
–
Built-in 10 KHz low speed OSC for Watchdog Timer and Wake-up operation
Support one PLL, up to 50 MHz, for high performance system operation
External 4~24 MHz high speed crystal input for USB and precise timing operation
External 32.768 kHz low speed crystal input for RTC function and low power system
operation
•GPIO
–
Four I/O modes:
Quasi bi-direction
Push-Pull output
Open-Drain output
Input only with high impendence
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NuMicro™ NUC120 Data Sheet
–
–
–
TTL/Schmitt trigger input selectable
I/O pin can be configured as interrupt source with edge/level setting
High driver and high sink IO mode support
•Timer
–
–
–
Support 4 sets of 32-bit timers with 24-bit up-timer and one 8-bit pre-scale counter
Independent clock source for each timer
Provides one-shot, periodic, toggle and continuous counting operation modes
(NuMicro™ NUC100/NUC120 Medium Density only support one-shot and periodic
mode)
–
Support event counting function (NuMicro™ NUC100/NUC120 Low Density only)
•Watchdog Timer
–
–
–
–
Multiple clock sources
8 selectable time out period from 1.6ms ~ 26.0sec (depends on clock source)
WDT can wake-up from power down or idle mode
Interrupt or reset selectable on watchdog time-out
•RTC
–
–
–
–
–
–
Support software compensation by setting frequency compensate register (FCR)
Support RTC counter (second, minute, hour) and calendar counter (day, month, year)
Support Alarm registers (second, minute, hour, day, month, year)
Selectable 12-hour or 24-hour mode
Automatic leap year recognition
Support periodic time tick interrupt with 8 period options 1/128, 1/64, 1/32, 1/16, 1/8,
1/4, 1/2 and 1 second
–
Support wake-up function
•PWM/Capture
–
–
–
Built-in up to four 16-bit PWM generators provide eight PWM outputs or four
complementary paired PWM outputs
Each PWM generator equipped with one clock source selector, one clock divider, one
8-bit prescaler and one Dead-Zone generator for complementary paired PWM
Up to eight 16-bit digital Capture timers (shared with PWM timers) provide eight
rising/falling capture inputs
–
Support Capture interrupt
•UART
–
Up to three UART controllers (NuMicro™ NUC100/NUC120 Low Density only support 2
UART controllers)
–
–
–
–
–
UART ports with flow control (TXD, RXD, CTS and RTS)
UART0 with 63-byte FIFO is for high speed
UART1/2(optional) with 15-byte FIFO for standard device
Support IrDA (SIR) function
Support RS-485 9-bit mode and direction control. (NuMicro™ NUC100/NUC120 Low
Density Only)
–
–
Programmable baud-rate generator up to 1/16 system clock
Support PDMA mode
•SPI
–
Up to four sets of SPI controller (NuMicro™ NUC100/NUC120 Low Density only
support 2 SPI controllers)
–
–
Master up to 16 MHz, and Slave up to 10 MHz (chip working @ 5V)
Support SPI master/slave mode
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NuMicro™ NUC120 Data Sheet
–
–
–
–
–
Full duplex synchronous serial data transfer
Variable length of transfer data from 1 to 32 bits
MSB or LSB first data transfer
Rx and Tx on both rising or falling edge of serial clock independently
2 slave/device select lines when it is as the master, and 1 slave/device select line
when it is as the slave
–
–
Support byte suspend mode in 32-bit transmission
Support PDMA mode
•I2C
–
–
–
–
–
Up to two sets of I2C device
Master/Slave mode
Bidirectional data transfer between masters and slaves
Multi-master bus (no central master)
Arbitration between simultaneously transmitting masters without corruption of serial
data on the bus
–
–
Serial clock synchronization allows devices with different bit rates to communicate via
one serial bus
Serial clock synchronization can be used as a handshake mechanism to suspend and
resume serial transfer
–
–
Programmable clocks allow versatile rate control
Support multiple address recognition (four slave address with mask option)
•I2S
–
–
–
–
–
–
–
–
Interface with external audio CODEC
Operate as either master or slave mode
Capable of handling 8-, 16-, 24- and 32-bit word sizes
Mono and stereo audio data supported
I2S and MSB justified data format supported
Two 8 word FIFO data buffers are provided, one for transmit and one for receive
Generates interrupt requests when buffer levels cross a programmable boundary
Support two DMA requests, one for transmit and one for receive
•PS/2 Device Controller
–
–
–
–
–
Host communication inhibit and request to send detection
Reception frame error detection
Programmable 1 to 16 bytes transmit buffer to reduce CPU intervention
Double buffer for data reception
S/W override bus
•USB 2.0 Full-Speed Device
–
–
–
–
–
–
–
–
One set of USB 2.0 FS Device 12Mbps
On-chip USB Transceiver
Provide 1 interrupt source with 4 interrupt events
Support Control, Bulk In/Out, Interrupt and Isochronous transfers
Auto suspend function when no bus signaling for 3 ms
Provide 6 programmable endpoints
Include 512 Bytes internal SRAM as USB buffer
Provide remote wake-up capability
•EBI (External bus interface) support (NuMicro™ NUC100/NUC120 Low Density 64-pin
Package Only)
–
–
–
Accessible space: 64KB in 8-bit mode or 128KB in 16-bit mode
Support 8-/16-bit data width
Support byte write in 16-bit data width mode
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NuMicro™ NUC120 Data Sheet
•ADC
–
–
–
–
–
–
–
–
12-bit SAR ADC with 600K SPS
Up to 8-ch single-end input or 4-ch differential input
Single scan/single cycle scan/continuous scan
Each channel with individual result register
Scan on enabled channels
Threshold voltage detection
Conversion start by software programming or external input
Support PDMA mode
•Analog Comparator
–
–
–
–
Up to two analog comparators
External input or internal bandgap voltage selectable at negative node
Interrupt when compare result change
Power down wake-up
•One built-in temperature sensor with 1℃ resolution
•Brown-Out detector
–
–
With 4 levels: 4.5 V/3.8 V/2.7 V/2.2 V
Support Brown-Out Interrupt and Reset option
•Low Voltage Reset
–
Threshold voltage levels: 2.0 V
•Operating Temperature: -40℃~85℃
•Packages:
–
–
All Green package (RoHS)
LQFP 100-pin / 64-pin / 48-pin (100-pin for NuMicro™ NUC100/NUC120 Medium
Density Only)
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NuMicro™ NUC120 Data Sheet
3
PARTS INFORMATION LIST AND PIN CONFIGURATION
3.1 NuMicro™ NUC120 Products Selection Guide
3.1.1 NuMicro™ NUC120 Medium Density USB Line Selection Guide
Connectivity
ISP
Loader
ROM
Data
Flash
ISP
ICP
Part number APROM RAM
I/O
Timer
I2S Comp. PWM ADC RTC EBI
Package
UART SPI I2C USB LIN CAN
NUC120LD3AN 64 KB 16 KB
4 KB
4 KB up to 31 4x32-bit
2
2
2
2
3
3
3
1
1
2
2
4
4
4
2
2
2
2
2
2
2
1
1
1
1
1
1
1
-
-
-
-
-
-
-
-
-
-
-
-
-
-
1
1
1
1
1
1
1
1
1
2
2
2
2
2
4
4
6
6
8
8
8
8x12-bit
8x12-bit
8x12-bit
8x12-bit
8x12-bit
8x12-bit
8x12-bit
v
v
v
v
v
v
v
-
-
-
-
-
-
-
v
v
v
v
v
v
v
LQFP48
LQFP48
LQFP64
LQFP64
LQFP100
LQFP100
LQFP100
NUC120LE3AN 128 KB 16 KB Definable 4 KB up to 31 4x32-bit
NUC120RD3AN 64 KB 16 KB 4 KB 4 KB up to 45 4x32-bit
NUC120RE3AN 128 KB 16 KB Definable 4 KB up to 45 4x32-bit
NUC120VD2AN 64 KB 8 KB
NUC120VD3AN 64 KB 16 KB
4 KB
4 KB
4 KB up to 76 4x32-bit
4 KB up to 76 4x32-bit
NUC120VE3AN 128 KB 16 KB Definable 4 KB up to 76 4x32-bit
3.1.2 NuMicro™ NUC120 Low Density USB Line Selection Guide
Connectivity
ISP
Loader
ROM
Data
Flash
ISP
ICP
Part number APROM RAM
I/O
Timer
I2S Comp. PWM ADC RTC EBI
Package
UART SPI I2C USB LIN CAN
NUC120LC1BN 32 KB 4 KB
NUC120LD1BN 64 KB 4 KB
NUC120LD2BN 64 KB 8 KB
NUC120RC1BN 32 KB 4 KB
NUC120RD1BN 64 KB 4 KB
NUC120RD2BN 64 KB 8 KB
4 KB
4 KB
4 KB
4 KB
4 KB
4 KB
4 KB up to 31 4x32-bit
4 KB up to 31 4x32-bit
4 KB up to 31 4x32-bit
4 KB up to 45 4x32-bit
4 KB up to 45 4x32-bit
4 KB up to 45 4x32-bit
2
2
2
2
2
2
1
1
1
2
2
2
2
2
2
2
2
2
1
1
1
1
1
1
-
-
-
-
-
-
-
-
-
-
-
-
1
1
1
1
1
1
1
1
1
2
2
2
4
4
4
4
4
4
8x12-bit
8x12-bit
8x12-bit
8x12-bit
8x12-bit
8x12-bit
v
v
v
v
v
v
-
-
v
v
v
v
v
v
LQFP48
LQFP48
LQFP48
LQFP64
LQFP64
LQFP64
-
v
v
v
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NuMicro™ NUC120 Data Sheet
NUC 1 0 0 - X X X X X
ARM-Based
32-bit Microcontroller
Temperature
N: -40 ~ +85
E: -40 ~ +105
C: -40 ~ +125
CPU core
1: Cortex-M0
5/7: ARM7
9: ARM9
Reserve
RAM Size
1: 4K
2: 8K
Function
0: Advance Line
2: USB Line
3: Automotive Line
4: Connectivity Line
3: 16K
APROM Size
A: 8K
Package Type
Y: QFN 36
L: LQFP 48
R: LQFP 64
V: LQFP 100
B: 16K
C: 32K
D: 64K
E: 128K
Figure 3-1 NuMicro™ NUC100 Series selection code
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NuMicro™ NUC120 Data Sheet
3.2 Pin Configuration
3.2.1 NuMicro™ NUC120 Medium Density Pin Diagram
3.2.1.1 NuMicro™ NUC120 Medium Density LQFP 100 pin
ADC5/PA.5
ADC6/PA.6
ADC7/SPISS21/PA.7
VREF
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
PB.9/SPISS11
PB.10/SPISS01
PB.11/PWM4
PE.5/PWM5
PE.6
AVDD
SPISS20/PD.0
SPICLK2/PD.1
MISO20/PD.2
MOSI20/PD.3
MISO21/PD.4
MOSI21/PD.5
CPN0/PC.7
CPP0/PC.6
CPN1/PC.15
CPP1/PC.14
INT1/PB.15
XT1_OUT
XT1_IN
PC.0/SPISS00/I2SLRCLK
PC.1/SPICLK0/I2SBCLK
PC.2/MISO00/I2SDI
PC.3/MOSI00/I2SDO
PC.4/MISO01
PC.5/MOSI01
PD.15/TXD2
PD.14/RXD2
PD.7
NUC120VxxAN
Medium Density
LQFP 100-pin
PD.6
PB.3/CTS0
PB.2/RTS0
PB.1/TXD0
PB.0/RXD0
D+
/RESET
VSS
VDD
D-
PS2DAT
VDD33
PS2CLK
VBUS
PVSS
PE.7
STADC/PB.8
PE.8
Figure 3-2 NuMicro™ NUC120 Medium Density LQFP 100-pin Pin Diagram
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NuMicro™ NUC120 Data Sheet
3.2.1.2 NuMicro™ NUC120 Medium Density LQFP 64 pin
ADC5/PA.5
ADC6/PA.6
ADC7/PA.7
AVDD
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
PB.9
PB.10
PB.11/PWM4
PE.5/PWM5
PC.0/SPISS00/I2SLRCLK
PC.1/SPICLK0/I2SBCLK
PC.2/MISO00/I2SDI
PC.3/MOSI00/I2SDO
PB.3/CTS0
PB.2/RTS0
PB.1/TXD0
PB.0/RXD0
D+
CPN0/PC.7
CPP0/PC.6
CPN1/PC.15
CPP1/PC.14
INT1/PB.15
XT1_OUT
XT1_IN
NUC120RxxAN
Medium Density
LQFP 64-pin
/RESET
VSS
VDD
D-
PVSS
VDD33
STADC/PB.8
VBUS
Figure 3-3 NuMicro™ NUC120 Medium Density LQFP 64-pin Pin Diagram
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Revision V2.03
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NuMicro™ NUC120 Data Sheet
3.2.1.3 NuMicro™ NUC120 Medium Density LQFP 48 pin
Figure 3-4 NuMicro™ NUC120 Medium Density LQFP 48-pin Pin Diagram
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Revision V2.03
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NuMicro™ NUC120 Data Sheet
3.2.2 NuMicro™ NUC120 Low Density Pin Diagram
3.2.2.1 NuMicro™ NUC120 Low Density LQFP 64 pin
AD8/ADC5/PA.5
AD7/ADC6/PA.6
AD6/ADC7/PA.7
AVDD
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
32
31
30
29
28
27
26
25
24
23
22
21
20
19
18
17
PB.9/TM1
PB.10/TM2
PB.11/TM3
PE.5
AD5/CPN0/PC.7
AD4/CPP0/PC.6
AD3/CPN1/PC.15
AD2/CPP1/PC.14
INT1/PB.15
XT1_OUT
PC.0/SPISS00/I2SLRCLK
PC.1/SPICLK0/I2SBCLK
PC.2/MISO00/I2SDI
PC.3/MOSI00/I2SDO
PB.3/CTS0/nWRH
PB.2/RTS0/nWRL
PB.1/TXD0
NUC120RxxBN
Low Density
LQFP 64-pin
XT1_IN
/RESET
PB.0/RXD0
VSS
D+
VDD
D-
PVSS
VDD33
STADC/TM0/PB.8
VBUS
Figure 3-5 NuMicro™ NUC120 Low Density LQFP 64-pin Pin Diagram
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Revision V2.03
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NuMicro™ NUC120 Data Sheet
3.2.2.2 NuMicro™ NUC120 Low Density LQFP 48 pin
Figure 3-6 NuMicro™ NUC120 Low Density LQFP 48-pin Pin Diagram
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NuMicro™ NUC120 Data Sheet
4
BLOCK DIAGRAM
4.1 NuMicro™ NUC120 Medium Density Block Diagram
Cortex-M0
50MHz
FLASH
128KB
PDMA
10 kHz
P
L
L
32.768 kHz
22.1184 MHz
4~24 MHz
SRAM
16KB
GPIO
A,B,C,D,E
CLK_CTL
ISP 4KB
2.5V~
5.5V
LDO
PS2
SPI 2/3
RTC
12-bit ADC
WDT
SPI 0/1
Analog
I2C 1
Timer 0/1/
Timer 2/3
PWM 4~7
I2C 0
UART 0 -3M
Comparator
POR
Brown-out
LVR
UART 1 -115K
UART 2 -115K
I2S
PWM 0~3
USB-FS
512BRAM
USBPHY
Peripherals with PDMA
Figure 4-1 NuMicro™ NUC120 Medium Density Block Diagram
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NuMicro™ NUC120 Data Sheet
4.2 NuMicro™ NUC120 Low Density Block Diagram
Cortex-M0
50MHz
FLASH
64KB
PDMA
10 kHz
P
L
L
32.768 kHz
22.1184 MHz
4~24 MHz
SRAM
8KB
GPIO
A,B,C,D,E
CLK_CTL
ISP 4KB
2.5V~
5.5V
LDO
RTC
12-bit ADC
WDT
SPI 0/1
Analog
I2C 1
Timer 0/1/
Timer 2/3
UART 0 -3M
Comparator
POR
Brown-out
LVR
UART 1 -115K
PWM 0~3
USB-FS
512BRAM
I2S
I2C 0
USBPHY
Peripherals with PDMA
Figure 4-2 NuMicro™ NUC120 Low Density Block Diagram
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
5
FUNCTIONAL DESCRIPTION
5.1 ARM® Cortex™-M0 Core
The Cortex™-M0 processor is a configurable, multistage, 32-bit RISC processor. It has an AMBA
AHB-Lite interface and includes an NVIC component. It also has optional hardware debug
functionality. The processor can execute Thumb code and is compatible with other Cortex-M
profile processor. The profile supports two modes -Thread mode and Handler mode. Handler
mode is entered as a result of an exception. An exception return can only be issued in Handler
mode. Thread mode is entered on Reset, and can be entered as a result of an exception return.
Figure 5-1 shows the functional controller of processor.
Cortex-M0 components
Cortex-M0 processor
Debug
Nested
Vectored
Interrupt
Controller
(NVIC)
Interrupts
Breakpoint
and
Watchpoint
Unit
Cortex-M0
Processor
Core
Debug
Access
Port
Wakeup
Interrupt
Controller
(WIC)
Debugger
interface
Bus Matrix
(DAP)
AHB-Lite
interface
Serial Wire or
JTAG debug port
Figure 5-1 Functional Controller Diagram
The implemented device provides:
A low gate count processor that features:
z
The ARMv6-M Thumb® instruction set
Thumb-2 technology
ARMv6-M compliant 24-bit SysTick timer
A 32-bit hardware multiplier
The system interface supports little-endian data accesses
The ability to have deterministic, fixed-latency, interrupt handling
Load/store-multiples and multicycle-multiplies that can be abandoned and
restarted to facilitate rapid interrupt handling
C Application Binary Interface compliant exception model. This is the ARMv6-M,
C Application Binary Interface (C-ABI) compliant exception model that enables
the use of pure C functions as interrupt handlers
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NuMicro™ NUC120 Data Sheet
Low power sleep mode entry using Wait For Interrupt (WFI), Wait For Event
(WFE) instructions, or the return from interrupt sleep-on-exit feature
z
NVIC that features:
32 external interrupt inputs, each with four levels of priority
Dedicated Non-Maskable Interrupt (NMI) input.
Support for both level-sensitive and pulse-sensitive interrupt lines
Wake-up Interrupt Controller (WIC), providing ultra-low power sleep mode
support.
z
z
Debug support
Four hardware breakpoints.
Two watchpoints.
Program Counter Sampling Register (PCSR) for non-intrusive code profiling.
Single step and vector catch capabilities.
Bus interfaces:
Single 32-bit AMBA-3 AHB-Lite system interface that provides simple integration
to all system peripherals and memory.
Single 32-bit slave port that supports the DAP (Debug Access Port).
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Revision V2.03
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NuMicro™ NUC120 Data Sheet
5.2 System Manager
5.2.1 Overview
System management includes these following sections:
z
z
z
System Resets
System Memory Map
System management registers for Part Number ID, chip reset and on-chip controllers
reset , multi-functional pin control
z
z
z
System Timer (SysTick)
Nested Vectored Interrupt Controller (NVIC)
System Control registers
5.2.2 System Reset
The system reset can be issued by one of the below listed events. For these reset event flags can
be read by RSTSRC register.
z
z
z
z
z
z
z
The Power-On Reset
The low level on the /RESET pin
Watchdog Time Out Reset
Low Voltage Reset
Brown-Out Detector Reset
CPU Reset
System Reset
System Reset and Power-On Reset all reset the whole chip including all peripherals. The
difference between System Reset and Power-On Reset is external crystal circuit and ISPCON.BS
bit. System Reset doesn’t reset external crystal circuit and ISPCON.BS bit, but Power-On Reset
does.
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NuMicro™ NUC120 Data Sheet
5.2.3 System Power Distribution
In this chip, the power distribution is divided into three segments.
z
z
z
Analog power from AVDD and AVSS provides the power for analog components
operation.
Digital power from VDD and VSS supplies the power to the internal regulator which
provides a fixed 2.5 V power for digital operation and I/O pins.
USB transceiver power from VBUS offers the power for operating the USB transceiver.
The outputs of internal voltage regulators, LDO and VDD33, require an external capacitor which
should be located close to the corresponding pin. Analog power (AVDD) should be the same
voltage level of the digital power (VDD). Figure 5-2 shows the power distribution of NuMicro™
NUC120.
Figure 5-2 NuMicro™ NUC120 Power Distribution Diagram
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NuMicro™ NUC120 Data Sheet
5.2.4 System Memory Map
NuMicro™ NUC100 Series provides 4G-byte addressing space. The memory locations assigned
to each on-chip controllers are shown in the following table. The detailed register definition,
memory space, and programming detailed will be described in the following sections for each on-
chip peripherals. NuMicro™ NUC100 Series only supports little-endian data format.
Address Space
Token
Controllers
Flash and SRAM Memory Space
0x0000_0000 – 0x0001_FFFF FLASH_BA
0x2000_0000 – 0x2000_3FFF SRAM_BA
FLASH Memory Space (128KB)
SRAM Memory Space (16KB)
External Memory Space (128KB)
0x6000_0000 – 0x6001_FFFF EXTMEM_BA
(NuMicro™ NUC100/NUC120 Low Density 64-pin Only)
AHB Controllers Space (0x5000_0000 – 0x501F_FFFF)
0x5000_0000 – 0x5000_01FF GCR_BA
0x5000_0200 – 0x5000_02FF CLK_BA
0x5000_0300 – 0x5000_03FF INT_BA
0x5000_4000 – 0x5000_7FFF GPIO_BA
0x5000_8000 – 0x5000_BFFF PDMA_BA
0x5000_C000 – 0x5000_FFFF FMC_BA
System Global Control Registers
Clock Control Registers
Interrupt Multiplexer Control Registers
GPIO Control Registers
Peripheral DMA Control Registers
Flash Memory Control Registers
External Bus Interface Control Registers
0x5001_0000 – 0x5001_03FF EBI_BA
(NuMicro™ NUC100/NUC120 Low Density 64-pin Only)
APB1 Controllers Space (0x4000_0000 ~ 0x400F_FFFF)
0x4000_4000 – 0x4000_7FFF WDT_BA
0x4000_8000 – 0x4000_BFFF RTC_BA
0x4001_0000 – 0x4001_3FFF TMR01_BA
0x4002_0000 – 0x4002_3FFF I2C0_BA
0x4003_0000 – 0x4003_3FFF SPI0_BA
0x4003_4000 – 0x4003_7FFF SPI1_BA
0x4004_0000 – 0x4004_3FFF PWMA_BA
0x4005_0000 – 0x4005_3FFF UART0_BA
0x4006_0000 – 0x4006_3FFF USBD_BA
0x400D_0000 – 0x400D_3FFF ACMP_BA
Watchdog Timer Control Registers
Real Time Clock (RTC) Control Register
Timer0/Timer1 Control Registers
I2C0 Interface Control Registers
SPI0 with master/slave function Control Registers
SPI1 with master/slave function Control Registers
PWM0/1/2/3 Control Registers
UART0 Control Registers
USB 2.0 FS device Controller Registers
Analog Comparator Control Registers
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NuMicro™ NUC120 Data Sheet
Address Space
0x400E_0000 – 0x400E_FFFF ADC_BA
APB2 Controllers Space (0x4010_0000 ~ 0x401F_FFFF)
Token
Controllers
Analog-Digital-Converter (ADC) Control Registers
0x4010_0000 – 0x4010_3FFF PS2_BA
0x4011_0000 – 0x4011_3FFF TMR23_BA
0x4012_0000 – 0x4012_3FFF I2C1_BA
PS/2 Interface Control Registers
Timer2/Timer3 Control Registers
I2C1 Interface Control Registers
SPI2 with master/slave function Control Registers
0x4013_0000 – 0x4013_3FFF SPI2_BA
0x4013_4000 – 0x4013_7FFF SPI3_BA
(NuMicro™ NUC100/NUC120 Medium Density Only)
SPI3 with master/slave function Control Registers
(NuMicro™ NUC100/NUC120 Medium Density Only)
PWM4/5/6/7 Control Registers
0x4014_0000 – 0x4014_3FFF PWMB_BA
0x4015_0000 – 0x4015_3FFF UART1_BA
0x4015_4000 – 0x4015_7FFF UART2_BA
0x401A_0000 – 0x401A_3FFF I2S_BA
(NuMicro™ NUC100/NUC120 Medium Density Only)
UART1 Control Registers
UART2 Control Registers
(NuMicro™ NUC100/NUC120 Medium Density Only)
I2S Interface Control Registers
System Controllers Space (0xE000_E000 ~ 0xE000_EFFF)
0xE000_E010 – 0xE000_E0FF SCS_BA
0xE000_E100 – 0xE000_ECFF SCS_BA
0xE000_ED00 – 0xE000_ED8F SCS_BA
System Timer Control Registers
External Interrupt Controller Control Registers
System Control Registers
Table 5-1 Address Space Assignments for On-Chip Controllers
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NuMicro™ NUC120 Data Sheet
5.2.5 System Timer (SysTick)
The Cortex-M0 includes an integrated system timer, SysTick. SysTick provides a simple, 24-bit
clear-on-write, decrementing, wrap-on-zero counter with a flexible control mechanism. The
counter can be used as a Real Time Operating System (RTOS) tick timer or as a simple counter.
When system timer is enabled, it will count down from the value in the SysTick Current Value
Register (SYST_CVR) to zero, and reload (wrap) to the value in the SysTick Reload Value
Register (SYST_RVR) on the next clock cycle, then decrement on subsequent clocks. When the
counter transitions to zero, the COUNTFLAG status bit is set. The COUNTFLAG bit clears on
reads.
The SYST_CVR value is UNKNOWN on reset. Software should write to the register to clear it to
zero before enabling the feature. This ensures the timer will count from the SYST_RVR value
rather than an arbitrary value when it is enabled.
If the SYST_RVR is zero, the timer will be maintained with a current value of zero after it is
reloaded with this value. This mechanism can be used to disable the feature independently from
the timer enable bit.
For more detailed information, please refer to the documents “ARM® Cortex™-M0 Technical
Reference Manual” and “ARM® v6-M Architecture Reference Manual”.
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NuMicro™ NUC120 Data Sheet
5.2.6 Nested Vectored Interrupt Controller (NVIC)
Cortex-M0 provides an interrupt controller as an integral part of the exception mode, named as
“Nested Vectored Interrupt Controller (NVIC)”. It is closely coupled to the processor kernel and
provides following features:
z
z
z
Nested and Vectored interrupt support
Automatic processor state saving and restoration
Reduced and deterministic interrupt latency
The NVIC prioritizes and handles all supported exceptions. All exceptions are handled in “Handler
Mode”. This NVIC architecture supports 32 (IRQ[31:0]) discrete interrupts with 4 levels of priority.
All of the interrupts and most of the system exceptions can be configured to different priority
levels. When an interrupt occurs, the NVIC will compare the priority of the new interrupt to the
current running one’s priority. If the priority of the new interrupt is higher than the current one, the
new interrupt handler will override the current handler.
When any interrupts is accepted, the starting address of the interrupt service routine (ISR) is
fetched from a vector table in memory. There is no need to determine which interrupt is accepted
and branch to the starting address of the correlated ISR by software. While the starting address is
fetched, NVIC will also automatically save processor state including the registers “PC, PSR, LR,
R0~R3, R12” to the stack. At the end of the ISR, the NVIC will restore the mentioned registers
from stack and resume the normal execution. Thus it will take less and deterministic time to
process the interrupt request.
The NVIC supports “Tail Chaining” which handles back-to-back interrupts efficiently without the
overhead of states saving and restoration and therefore reduces delay time in switching to
pending ISR at the end of current ISR. The NVIC also supports “Late Arrival” which improves the
efficiency of concurrent ISRs. When a higher priority interrupt request occurs before the current
ISR starts to execute (at the stage of state saving and starting address fetching), the NVIC will
give priority to the higher one without delay penalty. Thus it advances the real-time capability.
For more detailed information, please refer to the documents “ARM® Cortex™-M0 Technical
Reference Manual” and “ARM® v6-M Architecture Reference Manual”.
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NuMicro™ NUC120 Data Sheet
5.2.6.1 Exception Model and System Interrupt Map
Table 5-2 lists the exception model supported by NuMicro™ NUC100 Series. Software can set
four levels of priority on some of these exceptions as well as on all interrupts. The highest user-
configurable priority is denoted as “0” and the lowest priority is denoted as “3”. The default priority
of all the user-configurable interrupts is “0”. Note that priority “0” is treated as the fourth priority on
the system, after three system exceptions “Reset”, “NMI” and “Hard Fault”.
Exception Name
Reset
Vector Number
Priority
-3
1
2
NMI
-2
Hard Fault
Reserved
3
-1
4 ~ 10
11
Reserved
Configurable
Reserved
Configurable
Configurable
Configurable
SVCall
Reserved
12 ~ 13
14
PendSV
SysTick
15
Interrupt (IRQ0 ~ IRQ31)
16 ~ 47
Table 5-2 Exception Model
Interrupt
Number
Vector
Number
Interrupt
Name
Source IP Interrupt description
(Bit in Interrupt
Registers)
0 ~ 15
16
-
-
-
System exceptions
0
1
2
3
4
5
6
7
8
9
BOD_OUT Brown-Out Brown-Out low voltage detected interrupt
17
WDT_INT
EINT0
WDT
GPIO
GPIO
GPIO
GPIO
Watchdog Timer interrupt
18
External signal interrupt from PB.14 pin
External signal interrupt from PB.15 pin
External signal interrupt from PA[15:0]/PB[13:0]
External interrupt from PC[15:0]/PD[15:0]/PE[15:0]
19
EINT1
20
GPAB_INT
GPCDE_INT
21
22
PWMA_INT PWM0~3 PWM0, PWM1, PWM2 and PWM3 interrupt
PWMB_INT PWM4~7 PWM4, PWM5, PWM6 and PWM7 interrupt
23
24
TMR0_INT
TMR1_INT
TMR0
TMR1
Timer 0 interrupt
Timer 1 interrupt
25
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NuMicro™ NUC120 Data Sheet
Interrupt
Number
Vector
Number
Interrupt
Name
Source IP Interrupt description
(Bit in Interrupt
Registers)
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
TMR2_INT
TMR3_INT
TMR2
TMR3
Timer 2 interrupt
Timer 3 interrupt
UART02_INT UART0/2 UART0 and UART2 interrupt
UART1 UART1 interrupt
UART1_INT
SPI0_INT
SPI1_INT
SPI2_INT
SPI3_INT
I2C0_INT
I2C1_INT
Reserved
Reserved
Reserved
USB_INT
PS2_INT
SPI0
SPI1
SPI2
SPI3
I2C0
I2C1
SPI0 interrupt
SPI1 interrupt
SPI2 interrupt
SPI3 interrupt
I2C0 interrupt
I2C1 interrupt
Reserved Reserved
Reserved Reserved
Reserved Reserved
USBD
PS/2
USB 2.0 FS Device interrupt
PS/2 interrupt
ACMP_INT
PDMA_INT
I2S_INT
ACMP
PDMA
I2S
Analog Comparator-0 or Comaprator-1 interrupt
PDMA interrupt
I2S interrupt
Clock controller interrupt for chip wake-up from
power down state
44
28
PWRWU_INT
CLKC
ADC
45
46
47
29
30
31
ADC_INT
Reserved
RTC_INT
ADC interrupt
Reserved Reserved
RTC Real time clock interrupt
Table 5-3 System Interrupt Map
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NuMicro™ NUC120 Data Sheet
5.2.6.2 Vector Table
When any interrupts is accepted, the processor will automatically fetch the starting address of the
interrupt service routine (ISR) from a vector table in memory. For ARMv6-M, the vector table base
address is fixed at 0x00000000. The vector table contains the initialization value for the stack
pointer on reset, and the entry point addresses for all exception handlers. The vector number on
previous page defines the order of entries in the vector table associated with exception handler
entry as illustrated in previous section.
Vector Table Word Offset Description
0
SP_main – The Main stack pointer
Vector Number
Exception Entry Pointer using that Vector Number
Table 5-4 Vector Table Format
5.2.6.3 Operation Description
NVIC interrupts can be enabled and disabled by writing to their corresponding Interrupt Set-
Enable or Interrupt Clear-Enable register bit-field. The registers use a write-1-to-enable and write-
1-to-clear policy, both registers reading back the current enabled state of the corresponding
interrupts. When an interrupt is disabled, interrupt assertion will cause the interrupt to become
Pending, however, the interrupt will not activate. If an interrupt is Active when it is disabled, it
remains in its Active state until cleared by reset or an exception return. Clearing the enable bit
prevents new activations of the associated interrupt.
NVIC interrupts can be pended/un-pended using a complementary pair of registers to those used
to enable/disable the interrupts, named the Set-Pending Register and Clear-Pending Register
respectively. The registers use a write-1-to-enable and write-1-to-clear policy, both registers
reading back the current pended state of the corresponding interrupts. The Clear-Pending
Register has no effect on the execution status of an Active interrupt.
NVIC interrupts are prioritized by updating an 8-bit field within a 32-bit register (each register
supporting four interrupts).
The general registers associated with the NVIC are all accessible from a block of memory in the
System Control Space and will be described in next section.
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NuMicro™ NUC120 Data Sheet
5.3 Clock Controller
5.3.1 Overview
The clock controller generates the clocks for the whole chip, including system clocks and all
peripheral clocks. The clock controller also implements the power control function with the
individually clock ON/OFF control, clock source selection and a clock divider. The chip will not
enter power down mode until CPU sets the power down enable bit (PWR_DOWN_EN) and
Cortex-M0 core executes the WFI instruction. After that, chip enter power down mode and wait for
wake-up interrupt source triggered to leave power down mode. In the power down mode, the
clock controller turns off the external 4~24 MHz high speed crystal and internal 22.1184 MHz high
speed oscillator to reduce the overall system power consumption.
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NuMicro™ NUC120 Data Sheet
22.1184
MHz
22.1184 MHz
10 kHz
111
011
010
001
000
CPUCLK
HCLK
CPU
EBI
4~12
MHz
PLLFOUT
32.768 kHz
4~24 MHz
1/(HCLK_N+1)
PDMA
ACMP
I2C 0~1
SPI 0-3
32.768
kHz
PCLK
22.1184 MHz
HCLK
10 kHz
111
010
001
000
CLKSEL0[2:0]
TMR 0
TMR 1
TMR 2
TMR 3
22.1184 MHz
4~24 MHz
32.768 kHz
4~24 MHz
1
PLLFOUT
0
22.1184 MHz
PLLCON[19]
CLKSEL1[22:20]
CLKSEL1[18:16]
CLKSEL1[14:12]
CLKSEL1[10:8]
PS2
FMC
22.1184 MHz
HCLK
1/2
1/2
1/2
111
011
010
001
000
CPUCLK
1
0
SysTick
4~24 MHz
32.768 kHz
4~24 MHz
SYST_CSR[2]
22.1184 MHz
HCLK
11
10
01
00
FDIV
PWM 6-7
PWM 4-5
PWM 2-3
PWM 0-1
CLKSEL0[5:3]
32.768 kHz
4~24 MHz
22.1184 MHz
HCLK
11
10
01
00
32.768 kHz
CLKSEL2[7:2]
CLKSEL1[31:28]
RTC
I2S
PLLFOUT
4~24 MHz
10 kHz
BOD
11
10
WDT
CLKSEL2[1:0]
HCLK
1/2048
22.1184 MHz
PLLFOUT
CLKSEL1[1:0]
11
01
00
1/(ADC_N+1)
1/(UART_N+1)
1/(USB_N+1)
ADC
UART 0-2
USB
4~24 MHz
CLKSEL1[3:2]
CLKSEL1[25:24]
PLLFOUT
Figure 5-3 Clock generator global view diagram
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NuMicro™ NUC120 Data Sheet
5.3.2 Clock Generator
The clock generator consists of 5 clock sources which are listed below:
z
z
z
One external 32.768 kHz low speed crystal
One external 4~24 MHz high speed crystal
One programmable PLL FOUT(PLL source consists of external 4~24 MHz high speed
crystal and internal 22.1184 MHz high speed oscillator)
z
z
One internal 22.1184 MHz high speed oscillator
One internal 10 kHz low speed oscillator
XTL32K_EN (PWRCON[1])
X32I
External
32.768 kHz
32.768 kHz
Crystal
X32O
XTL12M_EN (PWRCON[0])
4~24 MHz
XT_IN
External
4~24 MHz
PLL_SRC (PLLCON[19])
Crystal
XT_OUT
0
1
PLL FOUT
PLL
OSC22M_EN (PWRCON[2])
Internal
22.1184 MHz
Oscillator
22.1184 MHz
10 kHz
OSC10K_EN(PWRCON[3])
Internal
10 kHz
Oscillator
Figure 5-4 Clock generator block diagram
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NuMicro™ NUC120 Data Sheet
5.3.3 System Clock and SysTick Clock
The system clock has 5 clock sources which were generated from clock generator block. The
clock source switch depends on the register HCLK_S (CLKSEL0[2:0]). The block diagram is
showed in Figure 5-5.
HCLK_S (CLKSEL0[2:0])
22.1184 MHz
111
10 kHz
011
010
001
000
CPUCLK
HCLK
CPU
AHB
APB
PLLFOUT
32.768 kHz
4~24 MHz
1/(HCLK_N+1)
PCLK
HCLK_N (CLKDIV[3:0])
CPU in Power Down Mode
Figure 5-5 System Clock Block Diagram
The clock source of SysTick in Cortex-M0 core can use CPU clock or external clock
(SYST_CSR[2]). If using external clock, the SysTick clock (STCLK) has 5 clock sources. The
clock source switch depends on the setting of the register STCLK_S (CLKSEL0[5:3]). The block
diagram is showed in Figure 5-6.
Figure 5-6 SysTick Clock Control Block Diagram
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NuMicro™ NUC120 Data Sheet
5.3.4 Peripherals Clock
The peripherals clock had different clock source switch setting which depends on the different
peripheral. Please refer the CLKSEL1 and CLKSEL2 register description in 5.3.7.
5.3.5 Power Down Mode Clock
When chip enters into power down mode, system clocks, some clock sources, and some
peripheral clocks will be disabled. Some clock sources and peripherals clock are still active in
power down mode.
For theses clocks which still keep active list below:
z
Clock Generator
Internal 10 kHz low speed oscillator clock
External 32.768 kHz low speed crystal clock
z
Peripherals Clock (When WDT adopt internal 10 kHz low speed oscillator as clock
source and RTC adopt external 32.768 kHz low speed crystal as clock source)
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5.3.6 Frequency Divider Output
This device is equipped a power-of-2 frequency divider which is composed by16 chained divide-
by-2 shift registers. One of the 16 shift register outputs selected by a sixteen to one multiplexer is
reflected to CLKO function pin. Therefore there are 16 options of power-of-2 divided clocks with
the frequency from Fin/21 to Fin/216 where Fin is input clock frequency to the clock divider.
The output formula is Fout = Fin/2(N+1), where Fin is the input clock frequency, Fout is the clock
divider output frequency and N is the 4-bit value in FSEL (FRQDIV[3:0]).
When write 1 to DIVIDER_EN (FRQDIV[4]), the chained counter starts to count. When write 0 to
DIVIDER_EN (FRQDIV[4]), the chained counter continuously runs till divided clock reaches low
state and stay in low state.
Figure 5-7 Clock Source of Frequency Divider
Figure 5-8 Block Diagram of Frequency Divider
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NuMicro™ NUC120 Data Sheet
5.4 USB Device Controller (USB)
5.4.1 Overview
There is one set of USB 2.0 full-speed device controller and transceiver in this device. It is
compliant with USB 2.0 full-speed device specification and support control/bulk/interrupt/
isochronous transfer types.
In this device controller, there are two main interfaces: the APB bus and USB bus which comes
from the USB PHY transceiver. For the APB bus, the CPU can program control registers through
it. There are 512 bytes internal SRAM as data buffer in this controller. For IN or OUT transfer, it is
necessary to write data to SRAM or read data from SRAM through the APB interface or SIE.
Users need to set the effective starting address of SRAM for each endpoint buffer through “buffer
segmentation register (USB_BUFSEGx)”.
There are 6 endpoints in this controller. Each of the endpoint can be configured as IN or OUT
endpoint. All the operations including Control, Bulk, Interrupt and Isochronous transfer are
implemented in this block. The block of ENDPOINT CONTROL is also used to manage the data
sequential synchronization, endpoint states, current start address, transaction status, and data
buffer status for each endpoint.
There are four different interrupt events in this controller. They are the wake-up function, device
plug-in or plug-out event, USB events, like IN ACK, OUT ACK etc, and BUS events, like suspend
and resume, etc. Any event will cause an interrupt, and users just need to check the related event
flags in interrupt event status register (USB_INTSTS) to acknowledge what kind of interrupt
occurring, and then check the related USB Endpoint Status Register (USB_EPSTS) to
acknowledge what kind of event occurring in this endpoint.
A software-disable function is also supported for this USB controller. It is used to simulate the
disconnection of this device from the host. If user enables DRVSE0 bit (USB_DRVSE0), the USB
controller will force the output of USB_DP and USB_DM to level low and its function is disabled.
After disable the DRVSE0 bit, host will enumerate the USB device again.
Reference: Universal Serial Bus Specification Revision 1.1
5.4.2 Features
This Universal Serial Bus (USB) performs a serial interface with a single connector type for
attaching all USB peripherals to the host system. Following is the feature listing of this USB.
z
z
Compliant with USB 2.0 Full-Speed specification
Provide 1 interrupt vector with 4 different interrupt events (WAKEUP, FLDET, USB
and BUS)
z
z
z
Support Control/Bulk/Interrupt/Isochronous transfer type
Support suspend function when no bus activity existing for 3 ms
Provide 6 endpoints for configurable Control/Bulk/Interrupt/Isochronous transfer types
and maximum 512 bytes buffer size
z
Provide remote wake-up capability
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NuMicro™ NUC120 Data Sheet
5.5 General Purpose I/O (GPIO)
5.5.1 Overview
NuMicro™ NUC100/NUC120 Medium Density has up to 80 General Purpose I/O pins can be
shared with other function pins; it depends on the chip configuration. These 80 pins are arranged
in 5 ports named with GPIOA, GPIOB, GPIOC, GPIOD and GPIOE. Each port equips maximum
16 pins. Each one of the 80 pins is independent and has the corresponding register bits to control
the pin mode function and data.
NuMicro™ NUC100/NUC120 Low Density has up to 65 General Purpose I/O pins can be shared
with other function pins; it depends on the chip configuration and package. These 65 pins are
arranged in 4 ports named with GPIOA, GPIOB, GPIOC and GPIOD with each port equips
maximum 16 pins and another port named GPIOE with 1 pins PE.5.
The I/O type of each of I/O pins can be configured by software individually as input, output, open-
drain or quasi-bidirectional mode. After reset, the I/O type of all pins stay in quasi-bidirectional
mode and port data register GPIOx_DOUT[15:0] resets to 0x0000_FFFF. Each I/O pin equips a
very weakly individual pull-up resistor which is about 110KΩ~300KΩ for VDD is from 5.0 V to 2.5
V.
5.5.2 Features
Four I/O modes:
z
Quasi bi-direction
Push-Pull output
Open-Drain output
Input only with high impendence
z
z
z
TTL/Schmitt trigger input selectable
I/O pin can be configured as interrupt source with edge/level setting
High driver and high sink IO mode support
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NuMicro™ NUC120 Data Sheet
5.6 I2C Serial Interface Controller (Master/Slave) (I2C)
5.6.1 Overview
I2C is a two-wire, bi-directional serial bus that provides a simple and efficient method of data
exchange between devices. The I2C standard is a true multi-master bus including collision
detection and arbitration that prevents data corruption if two or more masters attempt to control
the bus simultaneously.
Data is transferred between a Master and a Slave synchronously to SCL on the SDA line on a
byte-by-byte basis. Each data byte is 8-bit long. There is one SCL clock pulse for each data bit
with the MSB being transmitted first. An acknowledge bit follows each transferred byte. Each bit is
sampled during the high period of SCL; therefore, the SDA line may be changed only during the
low period of SCL and must be held stable during the high period of SCL. A transition on the SDA
line while SCL is high is interpreted as a command (START or STOP). Please refer to the Figure
5-9 for more detail I2C BUS Timing.
Figure 5-9 I2C Bus Timing
The device’s on-chip I2C logic provides the serial interface that meets the I2C bus standard mode
specification. The I2C port handles byte transfers autonomously. To enable this port, the bit ENS1
in I2CON should be set to '1'. The I2C H/W interfaces to the I2C bus via two pins: SDA and SCL.
Pull up resistor is needed for I2C operation as these are open drain pins. When the I/O pins are
used as I2C port, user must set the pins function to I2C in advance.
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NuMicro™ NUC120 Data Sheet
5.6.2 Features
The I2C bus uses two wires (SDA and SCL) to transfer information between devices connected to
the bus. The main features of the bus are:
z
z
z
z
Master/Slave mode
Bidirectional data transfer between masters and slaves
Multi-master bus (no central master)
Arbitration between simultaneously transmitting masters without corruption of serial
data on the bus
z
z
z
Serial clock synchronization allows devices with different bit rates to communicate via
one serial bus
Serial clock synchronization can be used as a handshake mechanism to suspend and
resume serial transfer
Built-in a 14-bit time-out counter will request the I2C interrupt if the I2C bus hangs up
and timer-out counter overflows.
z
z
z
z
External pull-up are needed for high output
Programmable clocks allow versatile rate control
Supports 7-bit addressing mode
I2C-bus controllers support multiple address recognition ( Four slave address with
mask option)
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5.7 PWM Generator and Capture Timer (PWM)
5.7.1 Overview
NuMicro™ NUC100/NUC120 Medium Density has 2 sets of PWM group supports total 4 sets of
PWM Generators which can be configured as 8 independent PWM outputs, PWM0~PWM7, or as
4 complementary PWM pairs, (PWM0, PWM1), (PWM2, PWM3), (PWM4, PWM5) and (PWM6,
PWM7) with 4 programmable dead-zone generators. NuMicro™ NUC100/NUC120 Low Density
only support 1 set of PWM group supports total 2 sets of PWM Generators which can be
configured as 4 independent PWM outputs, PWM0~PWM3, or as 2 complementary PWM pairs,
(PWM0, PWM1) and (PWM2, PWM3) with 2 programmable dead-zone generators.
Each PWM Generator has one 8-bit prescaler, one clock divider with 5 divided frequencies (1,
1/2, 1/4, 1/8, 1/16), two PWM Timers including two clock selectors, two 16-bit PWM down-
counters for PWM period control, two 16-bit comparators for PWM duty control and one dead-
zone generator. The 4 sets of PWM Generators provide eight independent PWM interrupt flags
which are set by hardware when the corresponding PWM period down counter reaches zero.
Each PWM interrupt source with its corresponding enable bit can cause CPU to request PWM
interrupt. The PWM generators can be configured as one-shot mode to produce only one PWM
cycle signal or auto-reload mode to output PWM waveform continuously.
When PCR.DZEN01 is set, PWM0 and PWM1 perform complementary PWM paired function; the
paired PWM period, duty and dead-time are determined by PWM0 timer and Dead-zone
generator 0. Similarly, the complementary PWM pairs of (PWM2, PWM3), (PWM4, PWM5) and
(PWM6, PWM7) are controlled by PWM2, PWM4 and PWM6 timers and Dead-zone generator 2,
4 and 6, respectively.
To prevent PWM driving output pin with unsteady waveform, the 16-bit period down counter and
16-bit comparator are implemented with double buffer. When user writes data to
counter/comparator buffer registers the updated value will be load into the 16-bit down counter/
comparator at the time down counter reaching zero. The double buffering feature avoids glitch at
PWM outputs.
When the 16-bit period down counter reaches zero, the interrupt request is generated. If PWM-
timer is set as auto-reload mode, when the down counter reaches zero, it is reloaded with PWM
Counter Register (CNRx) automatically then start decreasing, repeatedly. If the PWM-timer is set
as one-shot mode, the down counter will stop and generate one interrupt request when it reaches
zero.
The value of PWM counter comparator is used for pulse high width modulation. The counter
control logic changes the output to high level when down-counter value matches the value of
compare register.
The alternate feature of the PWM-timer is digital input Capture function. If Capture function is
enabled the PWM output pin is switched as capture input mode. The Capture0 and PWM0 share
one timer which is included in PWM0 and the Capture1 and PWM1 share PWM1 timer, and etc.
Therefore user must setup the PWM-timer before enable Capture feature. After capture feature is
enabled, the capture always latched PWM-counter to Capture Rising Latch Register (CRLR)
when input channel has a rising transition and latched PWM-counter to Capture Falling Latch
Register (CFLR) when input channel has a falling transition. Capture channel 0 interrupt is
programmable by setting CCR0.CRL_IE0[1] (Rising latch Interrupt enable) and
CCR0.CFL_IE0[2]] (Falling latch Interrupt enable) to decide the condition of interrupt occur.
Capture channel 1 has the same feature by setting CCR0.CRL_IE1[17] and CCR0.CFL_IE1[18].
And capture channel 2 to channel 3 on each group have the same feature by setting the
corresponding control bits in CCR2. For each group, whenever Capture issues Interrupt 0/1/2/3,
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the PWM counter 0/1/2/3 will be reload at this moment.
The maximum captured frequency that PWM can capture is confined by the capture interrupt
latency. When capture interrupt occurred, software will do at least three steps, they are: Read
PIIR to get interrupt source and Read CRLRx/CFLRx(x=0~3) to get capture value and finally write
1 to clear PIIR to zero. If interrupt latency will take time T0 to finish, the capture signal mustn’t
transition during this interval (T0). In this case, the maximum capture frequency will be 1/T0. For
example:
HCLK = 50 MHz, PWM_CLK = 25 MHz, Interrupt latency is 900 ns
So the maximum capture frequency will is 1/900ns ≈ 1000 kHz
5.7.2 Features
5.7.2.1 PWM function features:
z
PWM group has two PWM generators. Each PWM generator supports one 8-bit
prescaler, one clock divider, two PWM-timers (down counter), one dead-zone
generator and two PWM outputs.
z
z
z
z
Up to 16-bit resolution
PWM Interrupt request synchronized with PWM period
One-shot or Auto-reload mode PWM
Up to 2 PWM group (PWMA/PWMB) to support 8 PWM channels or 4 PWM paired
channels (only 1 PWM group support for NuMicro™ NUC100/NUC120 Low Density)
5.7.2.2 Capture Function Features:
z
z
Timing control logic shared with PWM Generators
Support 8 Capture input channels shared with 8 PWM output channels (NuMicro™
NUC100/NUC120 Low Density only support 4 Capture input channels shared with 4
PWM output channels)
z
Each channel supports one rising latch register (CRLR), one falling latch register
(CFLR) and Capture interrupt flag (CAPIFx)
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NuMicro™ NUC120 Data Sheet
5.8 Real Time Clock (RTC)
5.8.1 Overview
Real Time Clock (RTC) controller provides user the real time and calendar message. The clock
source of RTC is from an external 32.768 kHz low speed crystal connected at pins X32I and
X32O (reference to pin descriptions) or from an external 32.768 kHz low speed oscillator output
fed at pin X32I. The RTC controller provides the time message (second, minute, hour) in Time
Loading Register (TLR) as well as calendar message (day, month, year) in Calendar Loading
Register (CLR). The data message is expressed in BCD format. It also offers alarm function that
user can preset the alarm time in Time Alarm Register (TAR) and alarm calendar in Calendar
Alarm Register (CAR).
The RTC controller supports periodic Time Tick and Alarm Match interrupts. The periodic interrupt
has 8 period options 1/128, 1/64, 1/32, 1/16, 1/8, 1/4, 1/2 and 1 second which are selected by
TTR (TTR[2:0]). When RTC counter in TLR and CLR is equal to alarm setting time registers TAR
and CAR, the alarm interrupt flag (RIIR.AIF) is set and the alarm interrupt is requested if the alarm
interrupt is enabled (RIER.AIER=1). Both RTC Time Tick and Alarm Match can cause chip wake-
up from power down mode if wake-up function is enabled (TWKE (TTR[3])=1).
5.8.2 Features
z
There is a time counter (second, minute, hour) and calendar counter (day, month, year) for
user to check the time
z
z
z
z
z
z
z
Alarm register (second, minute, hour, day, month, year)
12-hour or 24-hour mode is selectable
Leap year compensation automatically
Day of week counter
Frequency compensate register (FCR)
All time and calendar message is expressed in BCD code
Support periodic time tick interrupt with 8 period options 1/128, 1/64, 1/32, 1/16, 1/8, 1/4, 1/2
and 1 second
z
z
Support RTC Time Tick and Alarm Match interrupt
Support wake-up chip from power down mode
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NuMicro™ NUC120 Data Sheet
5.9 Serial Peripheral Interface (SPI)
5.9.1 Overview
The Serial Peripheral Interface (SPI) is a synchronous serial data communication protocol which
operates in full duplex mode. Devices communicate in master/slave mode with 4-wire bi-direction
interface. The NuMicro™ NUC100/NUC120 Medium Density contains up to four sets of SPI
controller performing a serial-to-parallel conversion on data received from a peripheral device,
and a parallel-to-serial conversion on data transmitted to a peripheral device. Each set of SPI
controller can be set as a master that can drive up to 2 external peripheral slave devices; it also
can be configured as a slave device controlled by an off-chip master device. NuMicro™
NUC100/NUC120 Low Density contains two sets of SPI controller only.
This controller supports a variable serial clock for special application and it also supports 2-bit
transfer mode to connect 2 off-chip slave devices at the same time. The SPI controller also
supports PDMA function to access the data buffer.
5.9.2 Features
z
z
z
z
z
Up to four sets of SPI controller for NuMicro™ NUC100/NUC120 Medium Density
Up to two sets of SPI controller for NuMicro™ NUC100/NUC120 Low Density
Support master or slave mode operation
Support 1-bit or 2-bit transfer mode
Configurable bit length up to 32-bit of a transfer word and configurable word numbers up to 2
of a transaction, so the maximum bit length is 64-bit for each data transfer
z
Provide burst mode operation, transmit/receive can be transferred up to two times word
transaction in one transfer
z
z
z
z
z
z
z
Support MSB or LSB first transfer
2 device/slave select lines in master mode, but 1 device/slave select line in slave mode
Support byte reorder function
Support byte or word suspend mode
Variable output serial clock frequency in master mode
Support two programmable serial clock frequencies in master mode
Support two channel PDMA request, one for transmitter and another for receiver
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NuMicro™ NUC120 Data Sheet
5.10 Timer Controller (TMR)
5.10.1 Overview
The timer controller includes four 32-bit timers, TIMER0~TIMER3, which allows user to easily
implement a timer control for applications. The timer can perform functions like frequency
measurement, event counting, interval measurement, clock generation, delay timing, and so on.
The timer can generates an interrupt signal upon timeout, or provide the current value during
operation. Note: toggle mode, continuous counting mode and event counting function only
support in NuMicro™ NUC100/NUC120 Low Density.
5.10.2 Features
4 sets of 32-bit timers with 24-bit up-timer and one 8-bit pre-scale counter
z
z
z
Independent clock source for each timer
Provides one-shot, periodic, toggle and continuous counting operation modes (NuMicro™
NUC100/NUC120 Medium Density only support one-shot and periodic mode)
z
z
z
z
Time out period = (Period of timer clock input) * (8-bit pre-scale counter + 1) * (24-bit TCMP)
Maximum counting cycle time = (1 / T MHz) * (28) * (224), T is the period of timer clock
24-bit timer value is readable through TDR (Timer Data Register)
Support event counting function to count the event from external pin (NuMicro™
NUC100/NUC120 Low Density only)
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5.11 Watchdog Timer (WDT)
5.11.1 Overview
The purpose of Watchdog Timer is to perform a system reset when system runs into an unknown
state. This prevents system from hanging for an infinite period of time. Besides, this Watchdog
Timer supports another function to wake-up chip from power down mode. The watchdog timer
includes an 18-bit free running counter with programmable time-out intervals. Table 5-5 show the
watchdog timeout interval selection and Figure 5-64 shows the timing of watchdog interrupt signal
and reset signal.
Setting WTE (WDTCR [7]) enables the watchdog timer and the WDT counter starts counting up.
When the counter reaches the selected time-out interval, Watchdog timer interrupt flag WTIF will
be set immediately to request a WDT interrupt if the watchdog timer interrupt enable bit WTIE is
set, in the meanwhile, a specified delay time (1024 * TWDT) follows the time-out event. User must
set WTR (WDTCR [0]) (Watchdog timer reset) high to reset the 18-bit WDT counter to avoid chip
from Watchdog timer reset before the delay time expires. WTR bit is cleared automatically by
hardware after WDT counter is reset. There are eight time-out intervals with specific delay time
which are selected by Watchdog timer interval select bits WTIS (WDTCR [10:8]). If the WDT
counter has not been cleared after the specific delay time expires, the watchdog timer will set
Watchdog Timer Reset Flag (WTRF) high and reset chip. This reset will last 63 WDT clocks (TRST
)
then chip restarts executing program from reset vector (0x0000_0000). WTRF will not be cleared
by Watchdog reset. User may poll WTRF by software to recognize the reset source. WDT also
provides wake-up function. When chip is powered down and the Watchdog Timer Wake-up
Function Enable bit (WDTR[4]) is set, if the WDT counter reaches the specific time interval
defined by WTIS (WDTCR [10:8]) , the chip is waken up from power down state. First example, if
WTIS is set as 000, the specific time interval for chip to wake up from power down state is 24 *
TWDT. When power down command is set by software, then, chip enters power down state. After
24 * TWDT time is elapsed, chip is waken up from power down state. Second example, if WTIS
(WDTCR [10:8]) is set as 111, the specific time interval for chip to wake up from power down
state is 218 * TWDT. If power down command is set by software, then, chip enters power down
state. After 218 * TWDT time is elapsed, chip is waken up from power down state. Notice if WTRE
(WDTCR [1]) is set to 1, after chip is waken up, software should clear the Watchdog Timer
counter by setting WTR(WDTCR [0]) to 1 as soon as possible. Otherwise, if the Watchdog Timer
counter is not cleared by setting WTR (WDTCR [0]) to 1 before time starting from waking up to
software clearing Watchdog Timer counter is over 1024 * TWDT , the chip is reset by Watchdog
Timer.
Timeout Interval
Selection
WTR Timeout Interval
(WDT_CLK=10 kHz)
Interrupt Period
TINT
WTIS
TTIS
Min. TWTR ~ Max. TWTR
1.6 ms ~ 104 ms
000
001
010
011
100
101
110
111
24 * TWDT
26 * TWDT
28 * TWDT
210 * TWDT
212 * TWDT
214 * TWDT
216 * TWDT
218 * TWDT
1024 * TWDT
1024 * TWDT
1024 * TWDT
1024 * TWDT
1024 * TWDT
1024 * TWDT
1024 * TWDT
1024 * TWDT
6.4 ms ~ 108.8 ms
25.6 ms ~ 128 ms
102.4 ms ~ 204.8 ms
409.6 ms ~ 512 ms
1.6384 s ~ 1.7408 s
6.5536 s ~ 6.656 s
26.2144 s ~ 26.3168 s
Table 5-5 Watchdog Timeout Interval Selection
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TWDT
TTIS
TINT
1024 * TWDT
INT
TRST
RST
Minimum TWTR
Maximum TWTR
63 * TWDT
TWDT : Watchdog Engine Clock Time Period
TTIS : Watchdog Timeout Interval Selection Period
TINT : Watchdog Interrupt Period
TRST : Watchdog Reset Period
TWTR : Watchdog Timeout Interval Period
Figure 5-10 Timing of Interrupt and Reset Signal
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NuMicro™ NUC120 Data Sheet
5.11.2 Features
z
z
z
18-bit free running counter to avoid chip from Watchdog timer reset before the delay time
expires.
Selectable time-out interval (24 ~ 218) and the time out interval is 104 ms ~ 26.3168 s (if
WDT_CLK = 10 kHz).
Reset period = (1 / 10 kHz) * 63, if WDT_CLK = 10 kHz.
5.12 UART Interface Controller (UART)
NuMicro™ NUC100/NUC120 Medium Density provides up to three channels of Universal
Asynchronous Receiver/Transmitters (UART). UART0 supports High Speed UART and UART1~2
perform Normal Speed UART, besides, only UART0 and UART1 support flow control function.
NuMicro™ NUC100/NUC120 Low Density only supports UART0 and UART1.
5.12.1 Overview
The Universal Asynchronous Receiver/Transmitter (UART) performs a serial-to-parallel
conversion on data received from the peripheral, and a parallel-to-serial conversion on data
transmitted from the CPU. The UART controller also supports IrDA SIR Function and RS-485
mode functions. Each UART channel supports seven types of interrupts including transmitter
FIFO empty interrupt (INT_THRE), receiver threshold level reaching interrupt (INT_RDA), line
status interrupt (parity error or framing error or break interrupt) (INT_RLS), receiver buffer time out
interrupt (INT_TOUT), MODEM/Wake-up status interrupt (INT_MODEM) and Buffer error interrupt
(INT_BUF_ERR). Interrupts of UART0 and UART2 share the interrupt number 12 (vector number
is 28); Interrupt number 13 (vector number is 29) only supports UART1 interrupt. Refer to Nested
Vectored Interrupt Controller chapter for System Interrupt Map.
The UART0 is built-in with a 64-byte transmitter FIFO (TX_FIFO) and a 64-byte receiver FIFO
(RX_FIFO) that reduces the number of interrupts presented to the CPU and the UART1~2 are
equipped 16-byte transmitter FIFO (TX_FIFO) and 16-byte receiver FIFO (RX_FIFO). The CPU
can read the status of the UART at any time during the operation. The reported status information
includes the type and condition of the transfer operations being performed by the UART, as well
as 4 error conditions (parity error, framing error, break interrupt and buffer error) probably occur
while receiving data. The UART includes a programmable baud rate generator that is capable of
dividing clock input by divisors to produce the serial clock that transmitter and receiver need. The
baud rate equation is Baud Rate = UART_CLK / M * [BRD + 2], where M and BRD are defined in
Baud Rate Divider Register (UA_BAUD). Table 5-6 lists the equations in the various conditions
and Table 5-7 list the UART baud rate setting table.
Mode
DIV_X_EN DIV_X_ONE
Divider X
BRD Baud rate equation
0
1
2
0
1
1
0
0
1
B
B
A
A
A
UART_CLK / [16 * (A+2)]
UART_CLK / [(B+1) * (A+2)] , B must >= 8
UART_CLK / (A+2), A must >=3
Don’t care
Table 5-6 UART Baud Rate Equation
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NuMicro™ NUC120 Data Sheet
System clock = Internal 22.1184 MHz high speed oscillator
Mode0 Mode1
Parameter Register
Mode2
Register
Baud rate
Register
x
Parameter
A=0,B=11
Parameter
A=22
921600
460800
x
0x3000_0016
0x3000_002E
0x2B00_0000
A=1,B=15
A=2,B=11
0x2F00_0001
0x2B00_0002
A=1
0x0000_0001
0x0000_0004
0x0000_000A
0x0000_0016
A=46
A=94
A=4,B=15
A=6,B=11
0x2F00_0004
0x2B00_0006
230400
115200
57600
A=4
A=10
A=22
0x3000_005E
0x3000_00BE
0x3000_017E
A=10,B=15
A=14,B=11
0x2F00_000A
0x2B00_000E
A=190
A=382
A=22,B=15
A=30,B=11
0x2F00_0016
0x2B00_001E
A=62,B=8
0x0000_0022 A=46,B=11
A=34,B=15
0x2800_003E
0x2B00_002E
0x2F00_0022
38400
19200
9600
A=34
A=70
A=574
A=1150
A=2302
A=4606
0x3000_023E
0x3000_047E
0x3000_08FE
0x3000_11FE
A=126,B=8
0x0000_0046 A=94,B=11
A=70,B=15
0x2800_007E
0x2B00_005E
0x2F00_0046
A=254,B=8
0x0000_008E A=190,B=11
A=142,B=15
0x2800_00FE
0x2B00_00BE
0x2F00_008E
A=142
A=286
A=510,B=8
0x0000_011E A=382,B=11
A=286,B=15
0x2800_01FE
0x2B00_017E
0x2F00_011E
4800
Table 5-7 UART Baud Rate Setting Table
The UART0 and UART1 controllers support auto-flow control function that uses two low-level
signals, /CTS (clear-to-send) and /RTS (request-to-send), to control the flow of data transfer
between the UART and external devices (ex: Modem). When auto-flow is enabled, the UART is
not allowed to receive data until the UART asserts /RTS to external device. When the number of
bytes in the RX FIFO equals the value of RTS_TRI_LEV (UA_FCR [19:16]), the /RTS is de-
asserted. The UART sends data out when UART controller detects /CTS is asserted from external
device. If a valid asserted /CTS is not detected the UART controller will not send data out.
The UART controllers also provides Serial IrDA (SIR, Serial Infrared) function (User must set
IrDA_EN (UA_FUN_SEL [1]) to enable IrDA function). The SIR specification defines a short-range
infrared asynchronous serial transmission mode with one start bit, 8 data bits, and 1 stop bit. The
maximum data rate is 115.2 Kbps (half duplex). The IrDA SIR block contains an IrDA SIR
Protocol encoder/decoder. The IrDA SIR protocol is half-duplex only. So it cannot transmit and
receive data at the same time. The IrDA SIR physical layer specifies a minimum 10ms transfer
delay between transmission and reception. This delay feature must be implemented by software.
For NuMicro™ NUC100/NUC120 Low Density, another alternate function of UART controllers is
RS-485 9-bit mode function, and direction control provided by RTS pin or can program GPIO
(PB.2 for RTS0 and PB.6 for RTS1) to implement the function by software. The RS-485 mode is
selected by setting the UA_FUN_SEL register to select RS-485 function. The RS-485 driver
control is implemented using the RTS control signal from an asynchronous serial port to enable
the RS-485 driver. In RS-485 mode, many characteristics of the RX and TX are same as UART.
Publication Release Date: Jan. 2, 2012
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Revision V2.03
NuMicro™ NUC120 Data Sheet
5.12.2 Features
z
Full duplex, asynchronous communications
z
Separate receive / transmit 64/16/16 bytes (UART0/UART1/UART2) entry FIFO for data
payloads
z
Support hardware auto flow control/flow control function (CTS, RTS) and programmable
RTS flow control trigger level (UART0 and UART1 support)
z
z
z
z
z
z
Programmable receiver buffer trigger level
Support programmable baud-rate generator for each channel individually
Support CTS wake-up function (UART0 and UART1 support)
Support 7-bit receiver buffer time out detection function
UART0/UART1 can be served by the DMA controller
Programmable transmitting data delay time between the last stop and the next start bit by
setting UA_TOR [DLY] register
z
z
Support break error, frame error, parity error and receive / transmit buffer overflow detect
function
Fully programmable serial-interface characteristics
Programmable number of data bit, 5-, 6-, 7-, 8-bit character
Programmable parity bit, even, odd, no parity or stick parity bit generation and
detection
Programmable stop bit, 1, 1.5, or 2 stop bit generation
z
z
Support IrDA SIR function mode
Support for 3-/16-bit duration for normal mode
Support RS-485 function mode. (NuMicro™ NUC100/NUC120 Low Density only)
Support RS-485 9-bit mode
Support hardware or software direct enable control provided by RTS pin
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
5.13 PS/2 Device Controller (PS2D)
5.13.1 Overview
PS/2 device controller provides basic timing control for PS/2 communication. All communication
between the device and the host is managed through the CLK and DATA pins. Unlike PS/2
keyboard or mouse device controller, the received/transmit code needs to be translated as
meaningful code by firmware. The device controller generates the CLK signal after receiving a
request to send, but host has ultimate control over communication. DATA sent from the host to
the device is read on the rising edge and DATA sent from device to the host is change after rising
edge. A 16 bytes FIFO is used to reduce CPU intervention. S/W can select 1 to 16 bytes for a
continuous transmission.
5.13.2 Features
Host communication inhibit and request to send detection
z
z
z
z
z
Reception frame error detection
Programmable 1 to 16 bytes transmit buffer to reduce CPU intervention
Double buffer for data reception
S/W override bus
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
5.14 I2S Controller (I2S)
5.14.1 Overview
The I2S controller consists of IIS protocol to interface with external audio CODEC. Two 8 word
deep FIFO for read path and write path respectively and is capable of handling 8 ~ 32 bit word
sizes. DMA controller handles the data movement between FIFO and memory.
5.14.2 Features
I2S can operate as either master or slave
z
z
z
z
z
z
z
Capable of handling 8-, 16-, 24- and 32-bit word sizes
Mono and stereo audio data supported
I2S and MSB justified data format supported
Two 8 word FIFO data buffers are provided, one for transmit and one for receive
Generates interrupt requests when buffer levels cross a programmable boundary
Two DMA requests, one for transmit and one for receive
Publication Release Date: Jan. 2, 2012
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Revision V2.03
NuMicro™ NUC120 Data Sheet
5.15 Analog-to-Digital Converter (ADC)
5.15.1 Overview
NuMicro™ NUC100 Series contains one 12-bit successive approximation analog-to-digital
converters (SAR A/D converter) with 8 input channels. The A/D converter supports three
operation modes: single, single-cycle scan and continuous scan mode. The A/D converters can
be started by software and external STADC pin.
5.15.2 Features
Analog input voltage range: 0~VREF
z
z
z
z
z
z
12-bit resolution and 10-bit accuracy is guaranteed
Up to 8 single-end analog input channels or 4 differential analog input channels
Maximum ADC clock frequency is 16 MHz
Up to 600K SPS conversion rate
Three operating modes
Single mode: A/D conversion is performed one time on a specified channel
Single-cycle scan mode: A/D conversion is performed one cycle on all specified
channels with the sequence from the lowest numbered channel to the highest
numbered channel
Continuous scan mode: A/D converter continuously performs Single-cycle scan mode
until software stops A/D conversion
z
An A/D conversion can be started by
Software write 1 to ADST bit
External pin STADC
z
z
z
z
Conversion results are held in data registers for each channel with valid and overrun
indicators
Conversion result can be compared with specify value and user can select whether to
generate an interrupt when conversion result is equal to the compare register setting
Channel 7 supports 3 input sources: external analog voltage, internal bandgap voltage,
and internal temperature sensor output
Support Self-calibration to minimize conversion error
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
5.16 Analog Comparator (CMP)
5.16.1 Overview
NuMicro™ NUC100 Series contains two comparators. The comparators can be used in a number
of different configurations. The comparator output is a logical one when positive input greater than
negative input, otherwise the output is a zero. Each comparator can be configured to cause an
interrupt when the comparator output value changes. The block diagram is shown in Error!
Reference source not found..
5.16.2 Features
Analog input voltage range: 0~5.0 V
z
z
z
z
Hysteresis function supported
Two analog comparators with optional internal reference voltage input at negative end
One interrupt vector for both comparators
Publication Release Date: Jan. 2, 2012
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Revision V2.03
NuMicro™ NUC120 Data Sheet
5.17 PDMA Controller (PDMA)
5.17.1 Overview
NuMicro™ NUC100/NUC120 Medium Density contains a peripheral direct memory access
(PDMA) controller that transfers data to and from memory or transfer data to and from APB
devices. The PDMA has nine channels of DMA (Peripheral-to-Memory or Memory-to-Peripheral
or Memory-to-Memory). For each PDMA channel (PDMA CH0~CH8), there is one word buffer as
transfer buffer between the Peripherals APB devices and Memory.
Software can stop the PDMA operation by disable PDMA [PDMACEN]. The CPU can recognize
the completion of a PDMA operation by software polling or when it receives an internal PDMA
interrupt. The PDMA controller can increase source or destination address or fixed them as well.
Notice: NuMicro™ NUC100/NUC120 Low Density only has 1 PDMA channel (channel 0).
5.17.2 Features
z
Up to nine DMA channels. Each channel can support a unidirectional transfer (NuMicro™
NUC100/NUC120 Low Density only has 1 PDMA channel)
z
z
z
AMBA AHB master/slave interface compatible, for data transfer and register read/write
Support source and destination address increased mode or fixed mode
Hardware channel priority. DMA channel 0 has the highest priority and channel 8 has the
lowest priority
Publication Release Date: Jan. 2, 2012
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Revision V2.03
NuMicro™ NUC120 Data Sheet
5.18 External Bus Interface (EBI)
5.18.1 Overview
The NuMicro™ NUC100/NUC120 Low Density LQFP-64 package equips an external bus interface
(EBI) for external device used.
To save the connections between external device and this chip, EBI support address bus and
data bus multiplex mode. And, address latch enable (ALE) signal supported differentiate the
address and data cycle.
5.18.2 Features
External Bus Interface has the following functions:
z
External devices with max. 64K-byte size (8-bit data width)/128K-byte (16-bit data width)
supported
z
z
z
Variable external bus base clock (MCLK) supported
8-bit or 16-bit data width supported
Variable data access time (tACC), address latch enable time (tALE) and address hold
time (tAHD) supported
z
z
Address bus and data bus multiplex mode supported to save the address pins
Configurable idle cycle supported for different access condition: Write command finish
(W2X), Read-to-Read (R2R)
Publication Release Date: Jan. 2, 2012
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Revision V2.03
NuMicro™ NUC120 Data Sheet
6
FLASH MEMORY CONTROLLER (FMC)
6.1 Overview
NuMicro™ NUC100 Series equips with 128/64/32K bytes on chip embedded Flash for application
program memory (APROM) that can be updated through ISP procedure. In System Programming
(ISP) function enables user to update program memory when chip is soldered on PCB. After chip
power on, Cortex-M0 CPU fetches code from APROM or LDROM decided by boot select (CBS) in
Config0. By the way, NuMicro™ NUC100 Series also provides additional DATA Flash for user, to
store some application dependent data before chip power off. For 128K bytes APROM device, the
data flash is shared with original 128K program memory and its start address is configurable and
defined by user application request in Config1. For 64K/32K bytes APROM device, the data flash
is fixed at 4K.
6.2 Features
z
Run up to 50 MHz with zero wait state for continuous address read access
z
128/64/32KB application program memory (APROM) (NuMicro™ NUC100/NUC120 Low
Density only support up to 64KB size)
z
z
z
z
4KB in system programming (ISP) loader program memory (LDROM)
Configurable or fixed 4KB data flash with 512 bytes page erase unit
Programmable data flash start address for 128K APROM device
In System Program (ISP) to update on chip Flash
Publication Release Date: Jan. 2, 2012
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Revision V2.03
NuMicro™ NUC120 Data Sheet
7
ELECTRICAL CHARACTERISTICS
7.1 Absolute Maximum Ratings
SYMBOL
PARAMETER
VDD−VSS
VIN
MIN
-0.3
VSS-0.3
4
MAX
+7.0
VDD+0.3
24
UNIT
V
DC Power Supply
Input Voltage
V
Oscillator Frequency
Operating Temperature
1/tCLCL
TA
MHz
°C
-40
+85
Storage Temperature
TST
-55
+150
120
°C
Maximum Current into VDD
-
mA
mA
mA
mA
mA
mA
Maximum Current out of VSS
120
Maximum Current sunk by a I/O pin
Maximum Current sourced by a I/O pin
Maximum Current sunk by total I/O pins
Maximum Current sourced by total I/O pins
35
35
100
100
Note: Exposure to conditions beyond those listed under absolute maximum ratings may adversely affects the lift and
reliability of the device.
Publication Release Date: Jan. 2, 2012
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Revision V2.03
NuMicro™ NUC120 Data Sheet
7.2 DC Electrical Characteristics
7.2.1 NuMicro™ NUC100/NUC120 Medium Density DC Electrical Characteristics
(VDD-VSS=3.3 V, TA = 25°C, FOSC = 50 MHz unless otherwise specified.)
SPECIFICATION
PARAMETER
SYM.
TEST CONDITIONS
MIN.
TYP.
MAX. UNIT
Operation voltage
VDD
2.5
5.5
V
V
V
V
V
VDD =2.5 V ~ 5.5 V up to 50 MHz
VSS
Power Ground
-0.3
-10%
0
AVSS
LDO Output Voltage
Analog Operating Voltage
Analog Reference Voltage
VLDO
AVDD
Vref
2.5
+10%
VDD
VDD > 2.7 V
0
AVDD
VDD = 5.5 V@50 MHz,
IDD1
IDD2
IDD3
IDD4
IDD5
IDD6
IDD7
54
31
51
28
22
14
20
mA
mA
mA
mA
mA
mA
mA
enable all IP and PLL, XTAL=12
MHz
VDD = 5.5 V@ 50 MHz,
disable all IP and enable PLL,
XTAL=12 MHz
Operating Current
Normal Run Mode
@ 50 MHz
VDD = 3 V@50 MHz,
enable all IP and PLL, XTAL=12
MHz
VDD = 3 V@50 MHz,
disable all IP and enable PLL,
XTAL=12 MHz
Operating Current
Normal Run Mode
@ 12 MHz
VDD = 5.5 V@12 MHz,
enable all IP and disable PLL,
XTAL=12 MHz
VDD = 5.5 V@12 MHz,
disable all IP and disable PLL,
XTAL=12 MHz
VDD = 3 V@12MHz,
enable all IP and disable PLL,
XTAL=12 MHz
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
SPECIFICATION
PARAMETER
SYM.
TEST CONDITIONS
MIN.
TYP.
MAX. UNIT
VDD = 3 V@12 MHz,
IDD8
12
mA
disable all IP and disable PLL,
XTAL=12 MHz
VDD = 5 V@4 MHz,
IDD9
15
11
13
9
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
enable all IP and disable PLL,
XTAL=4 MHz
VDD = 5 V@4 MHz,
IDD10
IDD11
IDD12
IIDLE1
IIDLE2
IIDLE3
IIDLE4
IIDLE5
IIDLE6
IIDLE7
disable all IP and disable PLL,
XTAL=4 MHz
Operating Current
Normal Run Mode
@ 4 MHz
V
DD = 3 V@4 MHz,
enable all IP and disable PLL,
XTAL=4 MHz
VDD = 3 V@4 MHz,
disable all IP and disable PLL,
XTAL=4 MHz
VDD= 5.5 V@50 MHz,
38
15
35
13
13
5.5
12
enable all IP and PLL, XTAL=12
MHz
VDD=5.5 V@50 MHz,
disable all IP and enable PLL,
XTAL=12 MHz
Operating Current
Idle Mode
V
DD = 3 V@50 MHz,
@ 50 MHz
enable all IP and PLL, XTAL=12
MHz
V
DD = 3 V@50 MHz,
disable all IP and enable PLL,
XTAL=12 MHz
Operating Current
Idle Mode
VDD = 5.5 V@12 MHz,
enable all IP and disable PLL,
XTAL=12 MHz
@ 12 MHz
VDD = 5.5 V@12 MHz,
disable all IP and disable PLL,
XTAL=12 MHz
VDD = 3 V@12 MHz,
enable all IP and disable PLL,
XTAL=12 MHz
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
SPECIFICATION
PARAMETER
SYM.
TEST CONDITIONS
MIN.
TYP.
MAX. UNIT
VDD = 3 V@12 MHz,
IIDLE8
4
mA
disable all IP and disable PLL,
XTAL=12 MHz
V
DD = 5 V@4 MHz,
IIDLE9
IIDLE10
IIDLE11
IIDLE12
8.5
3.5
7
mA
mA
mA
mA
enable all IP and disable PLL,
XTAL=4 MHz
V
DD = 5 V@4 MHz,
disable all IP and disable PLL,
XTAL=4 MHz
Operating Current
Idle Mode
@ 4 MHz
VDD = 3 V@4 MHz,
enable all IP and disable PLL,
XTAL=4 MHz
V
DD = 3 V@4 MHz,
2.5
disable all IP and disable PLL,
XTAL=4 MHz
VDD = 5.5 V, RTC OFF, No load
@ Disable BOV function
IPWD1
IPWD2
IPWD3
IPWD4
23
18
28
22
μA
μA
μA
μA
VDD = 3.3 V, RTC OFF, No load
@ Disable BOV function
Standby Current
Power down Mode
VDD = 5.5 V, RTC run , No load
@ Disable BOV function
VDD = 3.3 V, RTC run , No load
@ Disable BOV function
Input Current PA, PB, PC,
PD, PE (Quasi-bidirectional
mode)
VDD = 5.5 V, VIN = 0 V or VIN=VDD
IIN1
-50
-60
μA
Input Current at /RESET[1]
VDD = 3.3 V, VIN = 0.45 V
VDD = 5.5 V, 0<VIN<VDD
IIN2
ILK
-55
-2
-45
-
-30
+2
μA
μA
Input Leakage Current PA,
PB, PC, PD, PE
Logic 1 to 0 Transition Current
PA~PE (Quasi-bidirectional
mode)
[3]
VDD = 5.5 V, VIN<2.0 V
ITL
-650
-
-200
μA
VDD = 4.5 V
VDD = 2.5 V
-0.3
-0.3
-
-
0.8
0.6
Input Low Voltage PA, PB,
PC, PD, PE (TTL input)
VIL1
V
VDD
+0.2
V
DD = 5.5 V
DD =3.0 V
2.0
1.5
-
-
Input High Voltage PA, PB,
PC, PD, PE (TTL input)
VIH1
V
V
VDD
+0.2
V
Input Low Voltage PA, PB,
PC, PD, PE (Schmitt input)
VIL2
-0.5
-
0.2 VDD
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
SPECIFICATION
PARAMETER
SYM.
TEST CONDITIONS
MIN.
TYP.
MAX. UNIT
Input High Voltage PA, PB,
PC, PD, PE (Schmitt input)
VIH2 0.4 VDD
-
VDD+0.5
V
V
Hysteresis voltage of PA~PE
(Schmitt input)
0.2 VDD
VHY
VDD = 4.5 V
DD = 3.0 V
VDD = 5.5 V
DD = 3.0 V
0
-
-
0.8
0.4
Input Low Voltage XT1[*2]
VIL3
V
V
V
0
3.5
VDD
+0.2
-
Input High Voltage XT1[*2]
VIH3
VDD
+0.2
V
2.4
-
-
Input Low Voltage X32I[*2]
Input High Voltage X32I[*2]
VIL4
VIH4
0
0.4
2.5
V
V
1.7
Negative going threshold
(Schmitt input), /RESET
VILS
-0.5
-
-
0.3 VDD
VDD+0.5
V
V
Positive going threshold
(Schmitt input), /RESET
VIHS 0.7 VDD
VDD = 4.5 V, VS = 2.4 V
VDD = 2.7 V, VS = 2.2 V
ISR11
ISR12
ISR13
ISR21
ISR22
ISR23
ISK11
ISK12
ISK13
-300
-50
-40
-20
-4
-370
-70
-60
-24
-6
-450
-90
-80
-28
-8
μA
μA
Source Current PA, PB, PC,
PD, PE (Quasi-bidirectional
Mode)
V
DD = 2.5 V, VS = 2.0 V
μA
VDD = 4.5 V, VS = 2.4 V
VDD = 2.7 V, VS = 2.2 V
mA
mA
mA
mA
mA
mA
Source Current PA, PB, PC,
PD, PE (Push-pull Mode)
V
DD = 2.5 V, VS = 2.0 V
-3
-5
-7
VDD = 4.5 V, VS = 0.45 V
VDD = 2.7 V, VS = 0.45 V
10
7
16
10
9
20
Sink Current PA, PB, PC, PD,
PE (Quasi-bidirectional and
Push-pull Mode)
13
VDD = 2.5 V, VS = 0.45 V
6
12
Brown-Out voltage with
BOV_VL [1:0] =00b
VBO2.2
VBO2.7
VBO3.8
VBO4.5
VBH
2.1
2.6
3.6
4.3
30
2.2
2.7
3.8
4.5
-
2.3
2.8
4.0
4.7
150
V
V
Brown-Out voltage with
BOV_VL [1:0] =01b
Brown-Out voltage with
BOV_VL [1:0] =10b
V
Brown-Out voltage with
BOV_VL [1:0] =11b
V
Hysteresis range of BOD
voltage
VDD = 2.5 V~5.5 V
mV
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
Note:
1. /RESET pin is a Schmitt trigger input.
2. Crystal Input is a CMOS input.
3. Pins of PA, PB, PC, PD and PE can source a transition current when they are being externally driven from 1 to 0. In the
condition of VDD=5.5 V, 5he transition current reaches its maximum value when VIN approximates to 2 V.
Publication Release Date: Jan. 2, 2012
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Revision V2.03
NuMicro™ NUC120 Data Sheet
7.2.2 NuMicro™ NUC100/NUC120 Low Density DC Electrical Characteristics
(VDD-VSS=3.3 V, TA = 25°C, FOSC = 50 MHz unless otherwise specified.)
SPECIFICATION
PARAMETER
SYM.
TEST CONDITIONS
MIN.
TYP.
MAX. UNIT
Operation voltage
VDD
2.5
5.5
V
V
V
V
V
VDD =2.5 V ~ 5.5 V up to 50 MHz
VSS
Power Ground
-0.3
-10%
0
AVSS
LDO Output Voltage
Analog Operating Voltage
Analog Reference Voltage
VLDO
AVDD
Vref
2.5
+10%
VDD
VDD > 2.7 V
0
AVDD
VDD = 5.5 V@50 MHz,
IDD1
IDD2
IDD3
IDD4
IDD5
IDD6
IDD7
mA
mA
mA
mA
mA
mA
mA
46
30
44
28
19
13
17
enable all IP and PLL, XTAL=12
MHz
VDD = 5.5 V@50 MHz,
disable all IP and enable PLL,
XTAL=12 MHz
Operating Current
Normal Run Mode
@ 50 MHz
VDD = 3 V@50 MHz,
enable all IP and PLL, XTAL=12
MHz
VDD = 3 V@50 MHz,
disable all IP and enable PLL,
XTAL=12 MHz
Operating Current
Normal Run Mode
@ 12 MHz
VDD = 5.5 V@12 MHz,
enable all IP and disable PLL,
XTAL=12 MHz
VDD = 5.5 V@12 MHz,
disable all IP and disable PLL,
XTAL=12 MHz
VDD = 3 V@12 MHz,
enable all IP and disable PLL,
XTAL=12 MHz
Publication Release Date: Jan. 2, 2012
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NuMicro™ NUC120 Data Sheet
SPECIFICATION
PARAMETER
SYM.
TEST CONDITIONS
MIN.
TYP.
MAX. UNIT
V
DD = 3 V@12 MHz,
IDD8
mA
11.5
disable all IP and disable PLL,
XTAL=12 MHz
VDD = 5 V@4 MHz,
IDD9
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
mA
13.5
10
12
8
enable all IP and disable PLL,
XTAL=4 MHz
VDD = 5 V@4 MHz,
IDD10
IDD11
IDD12
IIDLE1
IIDLE2
IIDLE3
IIDLE4
IIDLE5
IIDLE6
IIDLE7
disable all IP and disable PLL,
XTAL=4 MHz
Operating Current
Normal Run Mode
@ 4 MHz
VDD = 3 V@4 MHz,
enable all IP and disable PLL,
XTAL=4 MHz
VDD = 3 V@4 MHz,
disable all IP and disable PLL,
XTAL=4 MHz
VDD= 5.5 V@50 MHz,
30
13
28
12
11
5
enable all IP and PLL, XTAL=12
MHz
VDD=5.5 V@50 MHz,
disable all IP and enable PLL,
XTAL=12 MHz
Operating Current
Idle Mode
VDD = 3 V@50 MHz,
@ 50 MHz
enable all IP and PLL, XTAL=12
MHz
VDD = 3 V@50 MHz,
disable all IP and enable PLL,
XTAL=12 MHz
Operating Current
Idle Mode
VDD = 5.5 V@12 MHz,
enable all IP and disable PLL,
XTAL=12 MHz
@ 12 MHz
VDD = 5.5 V@12 MHz,
disable all IP and disable PLL,
XTAL=12 MHz
VDD = 3 V@12 MHz,
10
enable all IP and disable PLL,
XTAL=12 MHz
Publication Release Date: Jan. 2, 2012
Revision V2.03
- 66 -
NuMicro™ NUC120 Data Sheet
SPECIFICATION
PARAMETER
SYM.
TEST CONDITIONS
MIN.
TYP.
MAX. UNIT
VDD = 3 V@12 MHz,
IIDLE8
mA
4
disable all IP and disable PLL,
XTAL=12 MHz
VDD = 5 V@4 MHz,
IIDLE9
IIDLE10
IIDLE11
IIDLE12
mA
mA
mA
mA
7
enable all IP and disable PLL,
XTAL=4 MHz
VDD = 5 V@4 MHz,
3.5
6
disable all IP and disable PLL,
XTAL=4 MHz
Operating Current
Idle Mode
@ 4 MHz
VDD = 3 V@4 MHz,
enable all IP and disable PLL,
XTAL=4 MHz
VDD = 3 V@4 MHz,
2.5
disable all IP and disable PLL,
XTAL=4 MHz
VDD = 5.5 V, RTC OFF, No load
@ Disable BOV function
IPWD1
IPWD2
IPWD3
IPWD4
17
14.5
20
μA
μA
μA
μA
VDD = 3.3 V, RTC OFF, No load
@ Disable BOV function
Standby Current
Power down Mode
VDD = 5.5 V, RTC run , No load
@ Disable BOV function
VDD = 3.3 V, RTC run , No load
@ Disable BOV function
17
Input Current PA, PB, PC,
PD, PE (Quasi-bidirectional
mode)
VDD = 5.5 V, VIN = 0 V or VIN=VDD
IIN1
-50
-60
μA
Input Current at /RESET[1]
VDD = 3.3 V, VIN = 0.45 V
VDD = 5.5 V, 0<VIN<VDD
IIN2
ILK
-55
-2
-45
-
-30
+2
μA
μA
Input Leakage Current PA,
PB, PC, PD, PE
Logic 1 to 0 Transition Current
PA~PE (Quasi-bidirectional
mode)
[3]
VDD = 5.5 V, VIN<2.0 V
ITL
-650
-
-200
μA
VDD = 4.5 V
VDD = 2.5 V
-0.3
-0.3
-
-
0.8
0.6
Input Low Voltage PA, PB,
PC, PD, PE (TTL input)
VIL1
V
VDD
+0.2
V
DD = 5.5 V
DD =3.0 V
2.0
1.5
-
-
Input High Voltage PA, PB,
PC, PD, PE (TTL input)
VIH1
V
V
VDD
+0.2
V
Input Low Voltage PA, PB,
PC, PD, PE (Schmitt input)
0.2
VDD
VIL2
-0.5
-
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
SPECIFICATION
PARAMETER
SYM.
TEST CONDITIONS
MIN.
TYP.
MAX. UNIT
Input High Voltage PA, PB,
PC, PD, PE (Schmitt input)
VDD
+0.5
0.4
VDD
VIH2
-
V
Hysteresis voltage of PA~PE
(Schmitt input)
0.2 VDD
VHY
V
VDD = 4.5 V
DD = 3.0 V
VDD = 5.5 V
DD = 3.0 V
0
0
-
-
0.8
V
0.4
Input Low Voltage XT1[*2]
VIL3
V
VDD
+0.2
3.5
2.4
-
V
Input High Voltage XT1[*2]
VIH3
VDD
+0.2
V
-
-
Input Low Voltage X32I[*2]
Input High Voltage X32I[*2]
VIL4
VIH4
0
0.4
2.5
v
1.7
V
Negative going threshold
(Schmitt input), /RESET
VILS
-0.5
-
-
0.3 VDD
VDD+0.5
V
V
Positive going threshold
(Schmitt input), /RESET
VIHS 0.7 VDD
VDD = 4.5 V, VS = 2.4 V
VDD = 2.7 V, VS = 2.2 V
ISR11
ISR12
ISR12
ISR21
ISR22
ISR22
ISK1
-300
-50
-40
-20
-4
-370
-70
-60
-24
-6
-450
-90
-80
-28
-8
μA
μA
Source Current PA, PB, PC,
PD, PE (Quasi-bidirectional
Mode)
V
DD = 2.5 V, VS = 2.0 V
μA
VDD = 4.5 V, VS = 2.4 V
VDD = 2.7 V, VS = 2.2 V
mA
mA
mA
mA
mA
mA
Source Current PA, PB, PC,
PD, PE (Push-pull Mode)
V
DD = 2.5 V, VS = 2.0 V
-3
-5
-7
VDD = 4.5 V, VS = 0.45 V
VDD = 2.7 V, VS = 0.45 V
10
7
16
10
9
20
Sink Current PA, PB, PC, PD,
PE (Quasi-bidirectional and
Push-pull Mode)
ISK1
13
V
DD = 2.5 V, VS = 0.45 V
ISK1
6
12
Brown-Out voltage with
BOV_VL [1:0] =00b
VBO2.2
VBO2.7
VBO3.8
VBO4.5
VBH
2.1
2.6
3.6
4.3
30
2.2
2.7
3.8
4.5
-
2.3
2.8
4.0
4.7
150
V
V
Brown-Out voltage with
BOV_VL [1:0] =01b
Brown-Out voltage with
BOV_VL [1:0] =10b
V
Brown-Out voltage with
BOV_VL [1:0] =11b
V
Hysteresis range of BOD
voltage
VDD = 2.5 V~5.5 V
mV
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
SPECIFICATION
PARAMETER
SYM.
TEST CONDITIONS
MIN.
TYP.
MAX. UNIT
Bandgap voltage
VDD = 2.5 V~5.5 V
VBG
1.20
1.26
1.32
V
Note:
1. /RESET pin is a Schmitt trigger input.
2. Crystal Input is a CMOS input.
3. Pins of PA, PB, PC, PD and PE can source a transition current when they are being externally driven from 1 to 0. In the
condition of VDD=5.5 V, 5he transition current reaches its maximum value when VIN approximates to 2 V.
Publication Release Date: Jan. 2, 2012
- 69 -
Revision V2.03
NuMicro™ NUC120 Data Sheet
7.2.3 Operating Current Curve (Test condition: run NOP)
1. XTAL clock = 12 MHz, PLL disable, all-IP disable:
Unit: mA
2.
XTAL clock = 12 MHz, PLL disable, all-IP enable
Unit: mA
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
3.
XTAL clock = 12 MHz, PLL enable, all-IP disable
Unit: mA
4.
XTAL clock = 12 MHz, PLL enable, all-IP enable
Unit: mA
Publication Release Date: Jan. 2, 2012
Revision V2.03
- 71 -
NuMicro™ NUC120 Data Sheet
7.2.4 Idle Current Curve
1.
XTAL clock = 12 MHz, PLL disable, all-IP disable
Unit: mA
2.
XTAL clock = 12 MHz, PLL disable, all-IP enable
Unit: mA
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
3.
XTAL clock = 12 MHz, PLL enable, all-IP disable
Unit: mA
4.
XTAL clock = 12 MHz, PLL enable, all-IP enable
Unit: mA
Publication Release Date: Jan. 2, 2012
Revision V2.03
- 73 -
NuMicro™ NUC120 Data Sheet
7.2.5 Power Down Current Curve
XTAL clock = 12 MHz, PLL Disable
Unit: mA
Publication Release Date: Jan. 2, 2012
Revision V2.03
- 74 -
NuMicro™ NUC120 Data Sheet
7.3 AC Electrical Characteristics
t
CLCL
t
t
CLCH
CLCX
t
t
CHCX
CHCL
Note: Duty cycle is 50%.
SYMBOL
tCHCX
PARAMETER
Clock High Time
Clock Low Time
Clock Rise Time
Clock Fall Time
CONDITION
MIN.
TYP.
MAX. UNIT
20
20
-
-
-
-
-
-
nS
nS
nS
nS
tCLCX
-
tCLCH
10
10
tCHCL
-
7.3.1 External 4~24 MHz High Speed Crystal
PARAMETER
Input clock frequency
Temperature
CONDITION
MIN.
4
TYP.
MAX. UNIT
External crystal
12
-
24
85
5.5
-
MHz
℃
-
-
-40
2.5
-
VDD
5
V
Operating current
12 MHz@ VDD = 5V
1
mA
7.3.1.1 Typical Crystal Application Circuits
CRYSTAL
C1
C2
R
4 MHz ~ 24 MHz
without
without
without
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
Figure 7-1 Typical Crystal Application Circuit
7.3.2 External 32.768 kHz Low Speed Crystal
PARAMETER
Input clock frequency
CONDITION
MIN.
-
TYP.
MAX. UNIT
External crystal
32.768
-
kHz
℃
Temperature
VDD
-
-
-40
2.5
-
-
85
5.5
V
7.3.3 Internal 22.1184 MHz High Speed Oscillator
PARAMETER
Supply voltage[1]
CONDITION
MIN.
2.5
-
TYP.
MAX. UNIT
-
-
5.5
V
MHz
%
Center Frequency
-
22.1184
-
-
+25℃; VDD =5 V
-1
+1
Calibrated Internal Oscillator Frequency
Operation Current
-40℃~+85℃;
-3
-
-
+3
-
%
VDD=2.5 V~5.5 V
VDD =5 V
500
uA
7.3.4 Internal 10 kHz Low Speed Oscillator
PARAMETER
CONDITION
MIN.
2.5
-
TYP.
MAX. UNIT
Supply voltage[1]
-
-
10
-
5.5
-
V
kHz
%
Center Frequency
-
+25℃; VDD =5 V
-30
+30
Calibrated Internal Oscillator Frequency
-40℃~+85℃;
-50
-
+50
%
VDD=2.5 V~5.5 V
Note: Internal operation voltage comes from LDO.
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
7.4 Analog Characteristics
7.4.1 Specification of 12-bit SARADC
SYMBOL
-
PARAMETER
MIN.
TYP.
MAX. UNIT
Resolution
Differential nonlinearity error
Integral nonlinearity error
Offset error
-
-
-
-
-
-
12
Bit
LSB
LSB
LSB
-
DNL
INL
EO
±3
-
-
±4
±1
10
EG
Gain error (Transfer gain)
Monotonic
1
1.005
-
Guaranteed
FADC
FS
ADC clock frequency (AVDD=5V/3V)
Sample rate
-
-
-
-
16/8
MHz
K SPS
V
600
VDDA
IDD
Supply voltage
3
-
-
5.5
0.5
1.5
VDDA
1
-
mA
mA
V
Supply current (Avg.)
IDDA
VREF
IREF
VIN
-
-
Reference voltage
Reference current (Avg.)
Input voltage
-
-
-
-
mA
V
0
-
VREF
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
7.4.2 Specification of LDO and Power management
PARAMETER
Input Voltage
Output Voltage
MIN.
2.7
TYP.
5
MAX. UNIT
NOTE
5.5
V
V
VDD input voltage
VDD > 2.7 V
-10%
2.5
+10%
Temperature
Cbp
-40
-
25
1
85
-
℃
uF
Resr=1ohm
Note:
1. It is recommended that a 10uF or higher capacitor and a 100nF bypass capacitor are connected between VDD and the
closest VSS pin of the device.
2. For ensuring power stability, a 1uF or higher capacitor must be connected between LDO pin and the closest VSS pin of
the device.
Publication Release Date: Jan. 2, 2012
- 78 -
Revision V2.03
NuMicro™ NUC120 Data Sheet
7.4.3 Specification of Low Voltage Reset
PARAMETER
Operation voltage
Quiescent current
Temperature
CONDITION
MIN.
1.7
-
TYP.
MAX.
5.5
5
UNIT
V
-
-
-
VDD=5.5 V
-
uA
℃
-40
25
85
Temperature=25℃
Temperature=-40℃
1.7
-
2.0
2.4
2.3
-
V
V
Threshold voltage
Hysteresis
Temperature=85℃
-
1.6
0
-
V
V
-
0
0
7.4.4 Specification of Brown-Out Detector
PARAMETER
Operation voltage
Quiescent current
Temperature
CONDITION
MIN.
2.5
-
TYP.
-
MAX.
5.5
UNIT
V
-
AVDD=5.5 V
-
-
125
85
μA
℃
V
-40
4.3
3.6
2.6
2.1
30
25
4.5
3.8
2.7
2.2
-
BOV_VL[1:0]=11
BOV_VL [1:0]=10
BOV_VL [1:0]=01
BOV_VL [1:0]=00
-
4.7
4.0
V
Brown-Out voltage
Hysteresis
2.8
V
2.3
V
150
mV
7.4.5 Specification of Power-On Reset (5 V)
PARAMETER
Temperature
CONDITION
MIN.
TYP.
25
2
MAX.
UNIT
℃
-
V+
-40
85
-
Reset voltage
-
-
V
Quiescent current
Vin>reset voltage
1
-
nA
Publication Release Date: Jan. 2, 2012
Revision V2.03
- 79 -
NuMicro™ NUC120 Data Sheet
7.4.6 Specification of Temperature Sensor
PARAMETER
Supply voltage[1]
Temperature
Current consumption
Gain
CONDITIONS
MIN.
2.5
TYP.
MAX.
5.5
UNIT
V
-
-
-40
125
℃
6.4
-
10.5
uA
-1.76
720
mV/℃
mV
Offset
Temp=0 ℃
Note: Internal operation voltage comes from LDO.
7.4.7 Specification of Comparator
PARAMETER
Temperature
CONDITION
MIN.
TYP.
MAX. UNIT
-
-40
2.4
-
25
3
85
5.5
℃
V
VDD
-
VDD current
20 uA@VDD=3 V
20
5
40
uA
mV
V
Input offset voltage
Output swing
-
-
-
-
-
15
0.1
0.1
-
-
VDD-0.1
VDD-1.2
-
Input common mode range
DC gain
-
V
70
dB
@VCM=1.2 V and
VDIFF=0.1 V
Propagation delay
-
200
20
-
ns
20 mV@VCM=1 V
50 mV@VCM=0.1 V
50 mV@VCM=VDD-1.2
Comparison voltage
10
-
mV
@10 mV for non-
hysteresis
One bit control
Hysteresis
W/O and W. hysteresis
@VCM=0.4 V ~ VDD-1.2 V
-
-
±10
-
-
mV
us
@CINP=1.3 V
CINN=1.2 V
Wake-up time
2
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
7.4.8 Specification of USB PHY
7.4.8.1 USB DC Electrical Characteristics
SYMBOL
PARAMETER
Input high (driven)
CONDITIONS
MIN.
TYP.
MAX. UNIT
VIH
VIL
VDI
2.0
V
Input low
0.8
V
V
Differential input sensitivity
|PADP-PADM|
0.2
0.8
0.8
Differential
VCM
VSE
Includes VDI range
2.5
2.0
V
common-mode range
Single-ended receiver threshold
Receiver hysteresis
V
mV
V
200
VOL
Output low (driven)
0
0.3
3.6
VOH
VCRS
RPU
Output high (driven)
2.8
V
Output signal cross voltage
Pull-up resistor
1.3
2.0
V
1.425
1.575
kΩ
Termination
Voltage
for
VTRM
3.0
3.6
V
upstream port pull up (RPU)
Driver output resistance
Transceiver capacitance
ZDRV
CIN
Steady state drive*
Pin to GND
10
Ω
20
pF
*Driver output resistance doesn’t include series resistor resistance.
7.4.8.2 USB Full-Speed Driver Electrical Characteristics
SYMBOL
TFR
PARAMETER
Rise Time
CONDITIONS
CL=50p
MIN.
4
TYP.
MAX. UNIT
20
20
ns
ns
%
TFF
Fall Time
CL=50p
4
TFRFF
Rise and fall time matching
TFRFF=TFR/TFF
90
111.11
7.4.8.3 USB Power Dissipation
SYMBOL
PARAMETER
CONDITIONS
MIN.
TYP.
MAX. UNIT
Standby
50
uA
uA
uA
IVDDREG
VDDD and VDDREG Supply
Current (Steady State)
Input mode
(Full
Speed)
Output mode
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
7.5 Flash DC Electrical Characteristics
SYMBOL
Nendu
Tret
PARAMETER
Endurance
CONDITIONS
MIN.
10000
100
20
TYP. MAX. UNIT
cycles[1]
Temp=25 ℃
Retention time
year
Terase
Tmass
Tprog
Vdd
Page erase time
Mass erase time
Program time
40
60
55
2.75
14
7
ms
ms
us
40
50
40
35
Supply voltage
2.25
2.5
V[2]
mA
mA
uA
Idd1
Read current
Idd2
Program/Erase current
Power down current
Ipd
10
1. Number of program/erase cycles.
2. Vdd is source from chip LDO output voltage.
3. This table is guaranteed by design, not test in production.
Publication Release Date: Jan. 2, 2012
Revision V2.03
- 82 -
NuMicro™ NUC120 Data Sheet
7.6 SPI Dynamic Characteristics
SYMBOL
PARAMETER
MIN.
TYP.
MAX.
UNIT
SPI master mode (VDD = 4.5V ~ 5.5V, 30pF loading Capacitor)
tDS
tDH
tV
Data setup time
26
0
18
-
-
-
ns
ns
ns
Data hold time
Data output valid time
-
4
6
SPI master mode (VDD = 3.0V ~ 3.6V, 30pF loading Capacitor)
tDS
tDH
tV
Data setup time
39
0
26
-
-
-
ns
ns
ns
Data hold time
Data output valid time
-
6
10
SPI slave mode (VDD = 4.5V ~ 5.5V, 30pF loading Capacitor)
tDS
tDH
tV
Data setup time
Data hold time
0
-
-
ns
ns
ns
2*PCLK+4
-
-
-
Data output valid time
2*PCLK+19
2*PCLK+27
SPI slave mode (VDD = 3.0V ~ 3.6V, 30pF loading Capacitor)
tDS
tDH
tV
Data setup time
Data hold time
0
-
-
ns
ns
ns
2*PCLK+8
-
-
-
Data output valid time
2*PCLK+27
2*PCLK+40
Publication Release Date: Jan. 2, 2012
Revision V2.03
- 83 -
NuMicro™ NUC120 Data Sheet
Figure 7-2 SPI Master dynamic characteristics timing
Figure 7-3 SPI Slave dynamic characteristics timing
Publication Release Date: Jan. 2, 2012
Revision V2.03
- 84 -
NuMicro™ NUC120 Data Sheet
8
PACKAGE DIMENSIONS
8.1 100L LQFP (14x14x1.4 mm footprint 2.0mm)
H
D
D
A
A2
A1
7
51
7
50
H
E
E
100
26
L1
L
1
25
c
e
b
θ
Y
Controlling Dimension : Millimeters
Dimension in inch
Dimension in mm
Symbol
A
Nom
Nom
Min
Max
Min
Max
1.60
0.063
A1
A
0.002
0.05
1.35
0.17
0.10
1.45
0.27
0.053 0.055 0.057
1.40
0.22
b
0.011
0.008
0.009
0.006
0.007
0.004
0.547
0.547
c
0.15
0.20
D
E
14.00
0.551
0.551
0.020
14.10
13.90
13.90
0.556
0.556
14.00 14.10
0.50
e
H D
16.00
16.20
16.20
16.00
15.80
15.80
0.45
0.622
0.622
0.018
0.638
0.638
0.030
0.630
0.630
0.024
0.039
H E
L
0.60
1.00
0.75
L1
y
0.10
7
0.004
7
θ
0
0
Publication Release Date: Jan. 2, 2012
Revision V2.03
- 85 -
NuMicro™ NUC120 Data Sheet
8.2 64L LQFP (10x10x1.4mm footprint 2.0 mm)
Dimension in inch
Dimension in mm
Symbol
Nom
Nom
Min
Max
Min
Max
0.063
1.60
A
A
A
b
c
0.002
0.053
0.007
0.004
1
0.05
1.35
0.17
0.09
0.15
1.45
0.27
0.20
0.006
0.057
2
0.055
0.008
1.40
0.20
0.011
0.008
10.00
10.00
0.50
0.393
0.393
0.020
D
E
e
H
H
L
L
y
D
12.00
12.00
0.60
0.472
0.472
0.024
0.039
E
0.030
7
0.75
7
0.45
0
0.018
0
1.00
1
0.10
3.5
0.004
3.5
0
Publication Release Date: Jan. 2, 2012
Revision V2.03
- 86 -
NuMicro™ NUC120 Data Sheet
8.3 48L LQFP (7x7x1.4mm footprint 2.0mm)
Publication Release Date: Jan. 2, 2012
Revision V2.03
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NuMicro™ NUC120 Data Sheet
9
REVISION HISTORY
PAGE/
CHAP.
VERSION
DATE
DESCRIPTION
V1.00
V1.01
V1.02
V1.03
March 1, 2010
April 9, 2010
May 31, 2010
July 27, 2010
-
Preliminary version initial issued
Ch4
7.2
Modify the block diagram
Add operation current of DC characteristics
Modify LQFP 48 Pin Description
3.3.1
1. Modify LQFP 48 Pin Description
V1.04
V2.00
Aug. 23, 2010
Nov. 11 2010
7.2
-
2. Modify operation current of DC characteristics
Update low density and selection table
Remove NUC130/NUC140
Add SPI Dynamic Characteristics
Remove TM0~3 of medium density
Remove word “MICROWIRE” in all document
V2.01
May 6, 2011
-
Modify temperature sensor spec
Revise Pin description position for multi-function T2EX, T3EX,
nRD, nWR
V2.02
V2.03
June 20, 2011
Jan. 2, 2012
-
-
Update title of SPI Dynamic Characteristics
Update BOD spec
1. Remove feature “Dynamic priority changing” for NVIC
2. Modify ADC analog characteristic spec
Publication Release Date: Jan. 2, 2012
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Revision V2.03
NuMicro™ NUC120 Data Sheet
Important Notice
Nuvoton Products are neither intended nor warranted for usage in systems or equipment, any
malfunction or failure of which may cause loss of human life, bodily injury or severe property
damage. Such applications are deemed, “Insecure Usage”.
Insecure usage includes, but is not limited to: equipment for surgical implementation, atomic
energy control instruments, airplane or spaceship instruments, the control or operation of
dynamic, brake or safety systems designed for vehicular use, traffic signal instruments, all
types of safety devices, and other applications intended to support or sustain life.
All Insecure Usage shall be made at customer’s risk, and in the event that third parties lay
claims to Nuvoton as a result of customer’s Insecure Usage, customer shall indemnify the
damages and liabilities thus incurred by Nuvoton.
Publication Release Date: Jan. 2, 2012
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Revision V2.03
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