这是描述信息
兆易创新GD32-GigaDevice-兆易创新代理

兆易创新GD32F107VCT6-GD32 ARM Cortex-M3 Microcontroller

兆易创新GD32F107VCT6-GD32 ARM Cortex-M3 Microcontroller GigaDevice Semiconductor Inc. GD32F107xx ARM® Cortex™-M3 32-bit MCU Datasheet General description The GD32F107xx device belongs to the connectivity line of GD32 MCU Family. It is a 32-bit general-purpose microcontroller based on the ARM® Cortex™-M3 RISC core with enhanced connectivity performance and best ratio in terms of processing power, reduced power consumption and peripheral set. The Cortex™-M3 is a next generation processor core which is tightly coupled with a Nested Vectored Interrupt Controller (NVIC), SysTick timer and advanced debug support. The GD32F107xx device incorporates the ARM® Cortex™-M3 32-bit processor core operating at 108 MHz frequency with Flash accesses zero wait states to obtain maximum efficiency. It provides up to 1 MB on-chip Flash memory and 96 KB SRAM memory. An extensive range of enhanced I/Os and peripherals connected to two APB buses. The devices offer up to two 12-bit ADCs, up to two 12-bit DACs, up to four general-purpose 16-bit timers, two basic timers plus two PWM advanced-control timer, as well as standard and advanced communication interfaces: up to three SPIs, two I2Cs, three USARTs, two UARTs, two I2Ss, two CANs, an USBFS and an Ethernet MAC. The device operates from a 2.6 to 3.6 V power supply and available in –40 to +85 °C temperature range. Several power saving modes provide the flexibility for maximum optimization between wakeup latency and power consumption, an especially important consideration in low power applications. The above features make the GD32F107xx devices suitable for a wide range of interconnection applications, especially in areas such as industrial control, motor drives, power monitor and alarm systems, consumer and handheld equipment, POS, vehicle GPS, LED display and so on.   Device information Table 2-1. GD32F107xx devices features and peripheral list   Part Number GD32F107xx   RB RC RD RE RF RG VB VC Flash (KB) 128 256 384 512 768 1024 128 256 SRAM (KB) 96 96 96 96 96 96 96 96 Timers GPTM(16 bit) 4 (1-4) 4 (1-4) 4 (1-4) 4 (1-4) 4 (1-4) 4 (1-4) 4 (1-4) 4 (1-4)   Advanced TM(16 bit) 1 (0) 1 (0) 2 (0,7) 2 (0,7) 2 (0,7) 2 (0,7) 1 (0) 1 (0)   SysTick 1 1 1 1 1 1 1 1   Basic TM(16 bit) 2 (5-6) 2 (5-6) 2 (5-6) 2 (5-6) 2 (5-6) 2 (5-6) 2 (5-6) 2 (5-6)   Watchdog 2 2 2 2 2 2 2 2   RTC 1 1 1 1 1 1 1 1 Connectivity U(S)ART 5 5 5 5 5 5 5 5   I2C 1 (0) 1 (0) 2 (0-1) 2 (0-1) 2 (0-1) 2 (0-1) 1 (0) 1 (0)   SPI 3 (0-2) 3 (0-2) 3 (0-2) 3 (0-2) 3 (0-2) 3 (0-2) 3 (0-2) 3 (0-2)   I2S 2 (1-2) 2 (1-2) 2 (1-2) 2 (1-2) 2 (1-2) 2 (1-2) 2 (1-2) 2 (1-2)   CAN 2.0B 2 2 2 2 2 2 2 2   USBFS 1 1 1 1 1 1 1 1   Ethernet MAC 1 1 1 1 1 1 1 1 GPIO 51 51 51 51 51 51 80 80 EXMC 0 0 0 0 0 0 1 1
兆易创新GD32-GigaDevice-兆易创新代理
产品描述

兆易创新GD32F107VCT6-GD32 ARM Cortex-M3 Microcontroller

GigaDevice Semiconductor Inc.
GD32F107xx
ARM® Cortex™-M3 32-bit MCU
Datasheet

General description

The GD32F107xx device belongs to the connectivity line of GD32 MCU Family. It is a 32-bit general-purpose microcontroller based on the ARM® Cortex™-M3 RISC core with enhanced connectivity performance and best ratio in terms of processing power, reduced power consumption and peripheral set. The Cortex™-M3 is a next generation processor core which is tightly coupled with a Nested Vectored Interrupt Controller (NVIC), SysTick timer and advanced debug support.
The GD32F107xx device incorporates the ARM® Cortex™-M3 32-bit processor core operating at 108 MHz frequency with Flash accesses zero wait states to obtain maximum efficiency. It provides up to 1 MB on-chip Flash memory and 96 KB SRAM memory. An extensive range of enhanced I/Os and peripherals connected to two APB buses. The devices offer up to two 12-bit ADCs, up to two 12-bit DACs, up to four general-purpose 16-bit timers, two basic timers plus two PWM advanced-control timer, as well as standard and advanced communication interfaces: up to three SPIs, two I2Cs, three USARTs, two UARTs, two I2Ss, two CANs, an USBFS and an Ethernet MAC.
The device operates from a 2.6 to 3.6 V power supply and available in –40 to +85 °C temperature range. Several power saving modes provide the flexibility for maximum optimization between wakeup latency and power consumption, an especially important consideration in low power applications.
The above features make the GD32F107xx devices suitable for a wide range of interconnection applications, especially in areas such as industrial control, motor drives, power monitor and alarm systems, consumer and handheld equipment, POS, vehicle GPS, LED display and so on.
 

Device information

Table 2-1. GD32F107xx devices features and peripheral list

 

Part Number

GD32F107xx

 

RB

RC

RD

RE

RF

RG

VB

VC

Flash (KB)

128

256

384

512

768

1024

128

256

SRAM (KB)

96

96

96

96

96

96

96

96

Timers

GPTM(16

bit)

4

(1-4)

4

(1-4)

4

(1-4)

4

(1-4)

4

(1-4)

4

(1-4)

4

(1-4)

4

(1-4)

 

Advanced

TM(16 bit)

1

(0)

1

(0)

2

(0,7)

2

(0,7)

2

(0,7)

2

(0,7)

1

(0)

1

(0)

 

SysTick

1

1

1

1

1

1

1

1

 

Basic TM(16

bit)

2

(5-6)

2

(5-6)

2

(5-6)

2

(5-6)

2

(5-6)

2

(5-6)

2

(5-6)

2

(5-6)

 

Watchdog

2

2

2

2

2

2

2

2

 

RTC

1

1

1

1

1

1

1

1

Connectivity

U(S)ART

5

5

5

5

5

5

5

5

 

I2C

1

(0)

1

(0)

2

(0-1)

2

(0-1)

2

(0-1)

2

(0-1)

1

(0)

1

(0)

 

SPI

3

(0-2)

3

(0-2)

3

(0-2)

3

(0-2)

3

(0-2)

3

(0-2)

3

(0-2)

3

(0-2)

 

I2S

2

(1-2)

2

(1-2)

2

(1-2)

2

(1-2)

2

(1-2)

2

(1-2)

2

(1-2)

2

(1-2)

 

CAN 2.0B

2

2

2

2

2

2

2

2

 

USBFS

1

1

1

1

1

1

1

1

 

Ethernet

MAC

1

1

1

1

1

1

1

1

GPIO

51

51

51

51

51

51

80

80

EXMC

0

0

0

0

0

0

1

1

EXTI

16

16

16

16

16

16

16

16

ADC

Units

2

2

2

2

2

2

2

2

 

Channels

16

16

16

16

16

16

16

16

DAC

2

2

2

2

2

2

2

2

 

 

Part Number

GD32F107xx

 

VD

VE

VF

VG

ZC

ZD

ZE

ZF

ZG

Flash (KB)

384

512

768

1024

256

384

512

768

1024

SRAM (KB)

96

96

96

96

96

96

96

96

96

Timers

GPTM(16

bit)

4

(1-4)

4

(1-4)

4

(1-4)

4

(1-4)

4

(1-4)

4

(1-4)

4

(1-4)

4

(1-4)

4

(1-4)

 

Advanced

TM(16 bit)

2

(0,7)

2

(0,7)

2

(0,7)

2

(0,7)

2

(0,7)

2

(0,7)

2

(0,7)

2

(0,7)

2

(0,7)

 

SysTick

1

1

1

1

1

1

1

1

1

 

Basic TM(16

bit)

2

(5-6)

2

(5-6)

2

(5-6)

2

(5-6)

2

(5-6)

2

(5-6)

2

(5-6)

2

(5-6)

2

(5-6)

 

Watchdog

2

2

2

2

2

2

2

2

2

 

RTC

1

1

1

1

1

1

1

1

1

Connectivity

U(S)ART

5

5

5

5

5

5

5

5

5

 

I2C

2

2

2

2

2

2

2

2

2

 

SPI

3

(0-2)

3

(0-2)

3

(0-2)

3

(0-2)

3

(0-2)

3

(0-2)

3

(0-2)

3

(0-2)

3

(0-2)

 

 

I2S

2

(1-2)

2

(1-2)

2

(1-2)

2

(1-2)

2

(1-2)

2

(1-2)

2

(1-2)

2

(1-2)

2

(1-2)

 

CAN 2.0B

2

2

2

2

2

2

2

2

2

 

USBFS

1

1

1

1

1

1

1

1

1

 

Ethernet

MAC

1

1

1

1

1

1

1

1

1

GPIO

80

80

80

80

112

112

112

112

112

EXMC

1

1

1

1

1

1

1

1

1

EXTI

16

16

16

16

16

16

16

16

16

ADC

Units

2

2

2

2

2

2

2

2

2

 

Channels

16

16

16

16

16

16

16

16

16

DAC

2

2

2

2

2

2

2

2

2

Package

LQFP100

LQFP144

 

Memory map

Table 2-3. GD32F107xx memory map

Pre-defined

Regions

 

Bus

 

Address

 

Peripherals

External

device

 

 

 

 

AHB

 

0xA000 0000 - 0xA000 0FFF

 

EXMC - SWREG

 

 

 

External RAM

 

0x9000 0000 - 0x9FFF FFFF

EXMC - PC CARD

 

 

0x7000 0000 - 0x8FFF FFFF

EXMC - NAND

 

 

 

0x6000 0000 - 0x6FFF FFFF

EXMC -

NOR/PSRAM/SRA M

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Peripheral

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

AHB

0x5000 0000 - 0x5003 FFFF

USBFS

 

 

0x4008 0000 - 0x4FFF FFFF

Reserved

 

 

0x4004 0000 - 0x4007 FFFF

Reserved

 

 

0x4002 BC00 - 0x4003 FFFF

Reserved

 

 

0x4002 B000 - 0x4002 BBFF

Reserved

 

 

0x4002 A000 - 0x4002 AFFF

Reserved

 

 

0x4002 8000 - 0x4002 9FFF

ENET

 

 

0x4002 6800 - 0x4002 7FFF

Reserved

 

 

0x4002 6400 - 0x4002 67FF

Reserved

 

 

0x4002 6000 - 0x4002 63FF

Reserved

 

 

0x4002 5000 - 0x4002 5FFF

Reserved

 

 

0x4002 4000 - 0x4002 4FFF

Reserved

 

 

0x4002 3C00 - 0x4002 3FFF

Reserved

 

 

0x4002 3800 - 0x4002 3BFF

Reserved

 

 

0x4002 3400 - 0x4002 37FF

Reserved

 

 

0x4002 3000 - 0x4002 33FF

CRC

 

 

0x4002 2C00 - 0x4002 2FFF

Reserved

 

 

0x4002 2800 - 0x4002 2BFF

Reserved

 

 

0x4002 2400 - 0x4002 27FF

Reserved

 

 

0x4002 2000 - 0x4002 23FF

FMC

 

 

0x4002 1C00 - 0x4002 1FFF

Reserved

 

 

0x4002 1800 - 0x4002 1BFF

Reserved

 

 

0x4002 1400 - 0x4002 17FF

Reserved

 

 

0x4002 1000 - 0x4002 13FF

RCU

 

 

0x4002 0C00 - 0x4002 0FFF

Reserved

 

 

0x4002 0800 - 0x4002 0BFF

Reserved

 

 

0x4002 0400 - 0x4002 07FF

DMA1

 

 

0x4002 0000 - 0x4002 03FF

DMA0

 

 

0x4001 8400 - 0x4001 FFFF

Reserved

 

Pre-defined

Regions

 

Bus

 

Address

 

Peripherals

 

 

0x4001 8000 - 0x4001 83FF

Reserved

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

APB2

0x4001 7C00 - 0x4001 7FFF

Reserved

 

 

0x4001 7800 - 0x4001 7BFF

Reserved

 

 

0x4001 7400 - 0x4001 77FF

Reserved

 

 

0x4001 7000 - 0x4001 73FF

Reserved

 

 

0x4001 6C00 - 0x4001 6FFF

Reserved

 

 

0x4001 6800 - 0x4001 6BFF

Reserved

 

 

0x4001 5C00 - 0x4001 67FF

Reserved

 

 

0x4001 5800 - 0x4001 5BFF

Reserved

 

 

0x4001 5400 - 0x4001 57FF

Reserved

 

 

0x4001 5000 - 0x4001 53FF

Reserved

 

 

0x4001 4C00 - 0x4001 4FFF

Reserved

 

 

0x4001 4800 - 0x4001 4BFF

Reserved

 

 

0x4001 4400 - 0x4001 47FF

Reserved

 

 

0x4001 4000 - 0x4001 43FF

Reserved

 

 

0x4001 3C00 - 0x4001 3FFF

Reserved

 

 

0x4001 3800 - 0x4001 3BFF

USART0

 

 

0x4001 3400 - 0x4001 37FF

TIMER7

 

 

0x4001 3000 - 0x4001 33FF

SPI0

 

 

0x4001 2C00 - 0x4001 2FFF

TIMER0

 

 

0x4001 2800 - 0x4001 2BFF

ADC1

 

 

0x4001 2400 - 0x4001 27FF

ADC0

 

 

0x4001 2000 - 0x4001 23FF

GPIOG

 

 

0x4001 1C00 - 0x4001 1FFF

GPIOF

 

 

0x4001 1800 - 0x4001 1BFF

GPIOE

 

 

0x4001 1400 - 0x4001 17FF

GPIOD

 

 

0x4001 1000 - 0x4001 13FF

GPIOC

 

 

0x4001 0C00 - 0x4001 0FFF

GPIOB

 

 

0x4001 0800 - 0x4001 0BFF

GPIOA

 

 

0x4001 0400 - 0x4001 07FF

EXTI

 

 

0x4001 0000 - 0x4001 03FF

AFIO

 

 

 

 

 

 

 

APB1

0x4000 CC00 - 0x4000 FFFF

Reserved

 

 

0x4000 C800 - 0x4000 CBFF

Reserved

 

 

0x4000 C400 - 0x4000 C7FF

Reserved

 

 

0x4000 C000 - 0x4000 C3FF

Reserved

 

 

0x4000 8000 - 0x4000 BFFF

Reserved

 

 

0x4000 7C00 - 0x4000 7FFF

Reserved

 

 

0x4000 7800 - 0x4000 7BFF

Reserved

 

 

0x4000 7400 - 0x4000 77FF

DAC

 

 

0x4000 7000 - 0x4000 73FF

PMU

 

Pre-defined

Regions

 

Bus

 

Address

 

Peripherals

 

 

0x4000 6C00 - 0x4000 6FFF

BKP

 

 

0x4000 6800 - 0x4000 6BFF

CAN1

 

 

0x4000 6400 - 0x4000 67FF

CAN0

 

 

 

0x4000 6000 - 0x4000 63FF

Shared CAN SRAM

512 bytes

 

 

0x4000 5C00 - 0x4000 5FFF

Reserved

 

 

0x4000 5800 - 0x4000 5BFF

I2C1

 

 

0x4000 5400 - 0x4000 57FF

I2C0

 

 

0x4000 5000 - 0x4000 53FF

UART4

 

 

0x4000 4C00 - 0x4000 4FFF

UART3

 

 

0x4000 4800 - 0x4000 4BFF

USART2

 

 

0x4000 4400 - 0x4000 47FF

USART1

 

 

0x4000 4000 - 0x4000 43FF

Reserved

 

 

0x4000 3C00 - 0x4000 3FFF

SPI2/I2S2

 

 

0x4000 3800 - 0x4000 3BFF

SPI1/I2S1

 

 

0x4000 3400 - 0x4000 37FF

Reserved

 

 

0x4000 3000 - 0x4000 33FF

FWDGT

 

 

0x4000 2C00 - 0x4000 2FFF

WWDGT

 

 

0x4000 2800 - 0x4000 2BFF

RTC

 

 

0x4000 2400 - 0x4000 27FF

Reserved

 

 

0x4000 2000 - 0x4000 23FF

Reserved

 

 

0x4000 1C00 - 0x4000 1FFF

Reserved

 

 

0x4000 1800 - 0x4000 1BFF

Reserved

 

 

0x4000 1400 - 0x4000 17FF

TIMER6

 

 

0x4000 1000 - 0x4000 13FF

TIMER5

 

 

0x4000 0C00 - 0x4000 0FFF

TIMER4

 

 

0x4000 0800 - 0x4000 0BFF

TIMER3

 

 

0x4000 0400 - 0x4000 07FF

TIMER2

 

 

0x4000 0000 - 0x4000 03FF

TIMER1

 

 

 

 

 

SRAM

 

 

 

 

 

AHB

0x2007 0000 - 0x3FFF FFFF

Reserved

 

 

0x2006 0000 - 0x2006 FFFF

Reserved

 

 

0x2003 0000 - 0x2005 FFFF

Reserved

 

 

0x2002 0000 - 0x2002 FFFF

Reserved

 

 

0x2001 C000 - 0x2001 FFFF

Reserved

 

 

0x2001 8000 - 0x2001 BFFF

Reserved

 

 

0x2000 5000 - 0x2001 7FFF

 

SRAM

 

 

0x2000 0000 - 0x2000 4FFF

 

 

Code

 

AHB

0x1FFF F810 - 0x1FFF FFFF

Reserved

 

 

0x1FFF F800 - 0x1FFF F80F

Option Bytes

 

 

0x1FFF F000 - 0x1FFF F7FF

Boot loader

 

 

Pre-defined

Regions

 

Bus

 

Address

 

Peripherals

 

 

 

0x1FFF C010 - 0x1FFF EFFF

 

0x1FFF C000 - 0x1FFF C00F

0x1FFF B000 - 0x1FFF BFFF

0x1FFF 7A10 - 0x1FFF AFFF

Reserved

0x1FFF 7800 - 0x1FFF 7A0F

Reserved

0x1FFF 0000 - 0x1FFF 77FF

Reserved

0x1FFE C010 - 0x1FFE FFFF

Reserved

0x1FFE C000 - 0x1FFE C00F

Reserved

0x1001 0000 - 0x1FFE BFFF

Reserved

0x1000 0000 - 0x1000 FFFF

Reserved

0x083C 0000 - 0x0FFF FFFF

Reserved

0x0830 0000 - 0x083B FFFF

Reserved

0x0810 0000 - 0x082F FFFF

 

Main Flash

0x0802 0000 - 0x080F FFFF

0x0800 0000 - 0x0801 FFFF

0x0030 0000 - 0x07FF FFFF

Reserved

0x0010 0000 - 0x002F FFFF

 

Aliased to Main Flash or Boot loader

0x0002 0000 - 0x000F FFFF

0x0000 0000 - 0x0001 FFFF

 

GD32F107Zx LQFP144 pin definitions

Table 2-4. GD32F107Zx LQFP144 pin definitions

 

 

Pin Name

 

 

Pins

 

 

Pin Type(1)

 

 

I/O Level(2)

 

 

Functions description

 

PE2

 

1

 

I/O

 

5VT

Default: PE2

Alternate: TRACECK, EXMC_A23

 

PE3

 

2

 

I/O

 

5VT

Default: PE3

Alternate: TRACED0, EXMC_A19

 

PE4

 

3

 

I/O

 

5VT

Default: PE4 Alternate:TRACED1, EXMC_A20

 

PE5

 

4

 

I/O

 

5VT

Default: PE5 Alternate:TRACED2, EXMC_A21

 

PE6

 

5

 

I/O

 

5VT

Default: PE6

Alternate:TRACED3, EXMC_A22

VBAT

6

P

 

Default: VBAT

PC13-

TAMPER- RTC

 

7

 

I/O

 

 

Default: PC13

Alternate: TAMPER-RTC

PC14- OSC32IN

 

8

 

I/O

 

Default: PC14 Alternate: OSC32IN

PC15- OSC32OUT

 

9

 

I/O

 

Default: PC15 Alternate: OSC32OUT

 

PF0

 

10

 

I/O

 

5VT

Default: PF0 Alternate: EXMC_A0

 

PF1

 

11

 

I/O

 

5VT

Default: PF1

Alternate: EXMC_A1

 

PF2

 

12

 

I/O

 

5VT

Default: PF2

Alternate: EXMC_A2

 

PF3

 

13

 

I/O

 

5VT

Default: PF3

Alternate: EXMC_A3

 

PF4

 

14

 

I/O

 

5VT

Default: PF4

Alternate: EXMC_A4

 

PF5

 

15

 

I/O

 

5VT

Default: PF5 Alternate: EXMC_A5

VSS_5

16

P

 

Default: VSS_5

VDD_5

17

P

 

Default: VDD_5

PF6

18

I/O

 

Default: PF6

 

 

 

Pin Name

 

 

Pins

 

 

Pin Type(1)

 

 

I/O Level(2)

 

 

Functions description

 

 

 

 

Alternate: EXMC_NIORD

PF7

19

I/O

 

Default: PF7

 

 

 

 

Alternate: EXMC_NREG

PF8

20

I/O

 

Default: PF8

 

 

 

 

Alternate: EXMC_NIOWR

PF9

21

I/O

 

Default: PF9

 

 

 

 

Alternate: EXMC_CD

PF10

22

I/O

 

Default: PF10

 

 

 

 

Alternate: EXMC_INTR

OSCIN

23

I

 

Default: OSCIN

 

 

 

 

Remap: PD0

OSCOUT

24

O

 

Default: OSCOUT

 

 

 

 

Remap: PD1

NRST

25

I/O

 

Default: NRST

PC0

26

I/O

 

Default: PC0

 

 

 

 

Alternate: ADC01_IN10

 

 

 

 

Default: PC1

PC1

27

I/O

 

Alternate: ADC01_IN11, ETH_MII_MDC,

 

 

 

 

ETH_RMII_MDC

PC2

28

I/O

 

Default: PC2

 

 

 

 

Alternate: ADC01_IN12, ETH_MII_TXD2

PC3

29

I/O

 

Default: PC3

 

 

 

 

Alternate: ADC01_IN13, ETH_MII_TX_CLK

VSSA

30

P

 

Default: VSSA

VREF-

31

P

 

Default: VREF-

VREF+

32

P

 

Default: VREF+

VDDA

33

P

 

Default: VDDA

 

 

 

 

Default: PA0

PA0-WKUP

34

I/O

 

Alternate: WKUP, USART1_CTS, ADC01_IN0,

TIMER1_CH0, TIMER1_ETI, TIMER4_CH0,

 

 

 

 

TIMER7_ETI, ETH_MII_CRS

 

 

 

 

Default: PA1

PA1

35

I/O

 

Alternate: USART1_RTS, ADC01_IN1,

TIMER1_CH1, TIMER4_CH1,

 

 

 

 

ETH_MII_RX_CLK, ETH_RMII_REF_CLK

 

 

 

 

Default: PA2

PA2

36

I/O

 

Alternate: USART1_TX, ADC01_IN2,

TIMER1_CH2, TIMER4_CH2, ETH_MII_MDIO,

 

 

 

 

ETH_RMII_MDIO

 

 

 

Pin Name

 

 

Pins

 

 

Pin Type(1)

 

 

I/O Level(2)

 

 

Functions description

 

 

 

 

Default: PA3

PA3

37

I/O

 

Alternate: USART1_RX, ADC01_IN3,

 

 

 

 

TIMER1_CH3, TIMER4_CH3, ETH_MII_COL

VSS_4

38

P

 

Default: VSS_4

VDD_4

39

P

 

Default: VDD_4

 

 

 

 

Default: PA4

PA4

40

I/O

 

Alternate: SPI0_NSS, USART1_CK,

ADC01_IN4, DAC_OUT0

 

 

 

 

Remap:SPI2_NSS, I2S2_WS

PA5

41

I/O

 

Default: PA5

 

 

 

 

Alternate: SPI0_SCK, ADC01_IN5, DAC_OUT1

 

 

 

 

Default: PA6

PA6

42

I/O

 

Alternate: SPI0_MISO, ADC01_IN6,

TIMER2_CH0, TIMER7_BKIN

 

 

 

 

Remap: TIMER0_BKIN

 

 

 

 

Default: PA7

 

 

 

 

Alternate: SPI0_MOSI, ADC01_IN7,

PA7

43

I/O

 

TIMER2_CH1, TIMER7_CH0_ON,

 

 

 

 

ETH_MII_RX_DV, ETH_RMII_CRS_DV

 

 

 

 

Remap: TIMER0_CH0_ON

 

 

 

 

Default: PC4

PC4

44

I/O

 

Alternate: ADC01_IN14, ETH_MII_RXD0,

 

 

 

 

ETH_RMII_RXD0

 

 

 

 

Default: PC5

PC5

45

I/O

 

Alternate: ADC01_IN15, ETH_MII_RXD1,

 

 

 

 

ETH_RMII_RXD1

 

 

 

 

Default: PB0

PB0

46

I/O

 

Alternate: ADC01_IN8, TIMER2_CH2,

TIMER7_CH1_ON, ETH_MII_RXD2

 

 

 

 

Remap: TIMER0_CH1_ON

 

 

 

 

Default: PB1

PB1

47

I/O

 

Alternate: ADC01_IN9, TIMER2_CH3,

TIMER7_CH2_ON, ETH_MII_RXD3

 

 

 

 

Remap: TIMER0_CH2_ON

PB2

48

I/O

5VT

Default: PB2, BOOT1

PF11

49

I/O

5VT

Default: PF11

 

 

 

 

Alternate: EXMC_NIOS16

PF12

50

I/O

5VT

Default: PF12

 

 

 

 

Alternate: EXMC_A6

 

 

 

Pin Name

 

 

Pins

 

 

Pin Type(1)

 

 

I/O Level(2)

 

 

Functions description

VSS_6

51

P

 

Default: VSS_6

VDD_6

52

P

 

Default: VDD_6

 

PF13

 

53

 

I/O

 

5VT

Default: PF13 Alternate: EXMC_A7

 

PF14

 

54

 

I/O

 

5VT

Default: PF14

Alternate: EXMC_A8

 

PF15

 

55

 

I/O

 

5VT

Default: PF15 Alternate: EXMC_A9

 

PG0

 

56

 

I/O

 

5VT

Default: PG0 Alternate: EXMC_A10

 

PG1

 

57

 

I/O

 

5VT

Default: PG1

Alternate: EXMC_A11

 

PE7

 

58

 

I/O

 

5VT

Default: PE7 Alternate: EXMC_D4 Remap: TIMER0_ETI

 

PE8

 

59

 

I/O

 

5VT

Default: PE8 Alternate: EXMC_D5

Remap: TIMER0_CH0_ON

 

PE9

 

60

 

I/O

 

5VT

Default: PE9 Alternate: EXMC_D6 Remap: TIMER0_CH0

VSS_7

61

P

 

Default: VSS_7

VDD_7

62

P

 

Default: VDD_7

 

PE10

 

63

 

I/O

 

5VT

Default: PE10 Alternate: EXMC_D7

Remap: TIMER0_CH1_ON

 

PE11

 

64

 

I/O

 

5VT

Default: PE11 Alternate: EXMC_D8 Remap: TIMER0_CH1

 

PE12

 

65

 

I/O

 

5VT

Default: PE12 Alternate: EXMC_D9

Remap: TIMER0_CH2_ON

 

PE13

 

66

 

I/O

 

5VT

Default: PE13 Alternate: EXMC_D10

Remap: TIMER0_CH2

 

PE14

 

67

 

I/O

 

5VT

Default: PE14 Alternate: EXMC_D11

Remap: TIMER0_CH3

PE15

68

I/O

5VT

Default: PE15

 

 

 

Pin Name

 

 

Pins

 

 

Pin Type(1)

 

 

I/O Level(2)

 

 

Functions description

 

 

 

 

Alternate: EXMC_D12

Remap: TIMER0_BKIN

 

 

PB10

 

 

69

 

 

I/O

 

 

5VT

Default: PB10

Alternate: I2C1_SCL, USART2_TX, ETH_MII_RX_ER

Remap: TIMER1_CH2

 

 

PB11

 

 

70

 

 

I/O

 

 

5VT

Default: PB11

Alternate: I2C1_SDA, USART2_RX, ETH_MII_TX_EN, ETH_RMII_TX_EN

Remap: TIMER1_CH3

VSS_1

71

P

 

Default: VSS_1

VDD_1

72

P

 

Default: VDD_1

 

 

PB12

 

 

73

 

 

I/O

 

 

5VT

Default: PB12

Alternate: SPI1_NSS, I2C1_SMBA, USART2_CK, TIMER0_BKIN, I2S1_WS, CAN1_RX, ETH_MII_TXD0, ETH_RMII_TXD0

 

 

PB13

 

 

74

 

 

I/O

 

 

5VT

Default: PB13

Alternate: SPI1_SCK, USART2_CTS, TIMER0_CH0_ON, I2S1_CK, CAN1_TX, ETH_MII_TXD1, ETH_RMII_TXD1

 

PB14

 

75

 

I/O

 

5VT

Default: PB14

Alternate: SPI1_MISO, USART2_RTS, TIMER0_CH1_ON

 

PB15

 

76

 

I/O

 

5VT

Default: PB15

Alternate: SPI1_MOSI, TIMER0_CH2_ON, I2S1_SD

 

 

PD8

 

 

77

 

 

I/O

 

 

5VT

Default: PD8 Alternate: EXMC_D13

Remap: USART2_TX, ETH_MII_RX_DV,

ETH_RMII_CRS_DV

 

 

PD9

 

 

78

 

 

I/O

 

 

5VT

Default: PD9 Alternate: EXMC_D14

Remap: USART2_RX, ETH_MII_RXD0,

ETH_RMII_RXD0

 

 

PD10

 

 

79

 

 

I/O

 

 

5VT

Default: PD10 Alternate: EXMC_D15

Remap: USART2_CK, ETH_MII_RXD1,

ETH_RMII_RXD1

PD11

80

I/O

5VT

Default: PD11

 

 

 

Pin Name

 

 

Pins

 

 

Pin Type(1)

 

 

I/O Level(2)

 

 

Functions description

 

 

 

 

Alternate: EXMC_A16

Remap: USART2_CTS, ETH_MII_RXD2

 

 

PD12

 

 

81

 

 

I/O

 

 

5VT

Default: PD12 Alternate: EXMC_A17

Remap: TIMER3_CH0, USART2_RTS,

ETH_MII_RXD3

 

PD13

 

82

 

I/O

 

5VT

Default: PD13 Alternate: EXMC_A18 Remap: TIMER3_CH1

VSS_8

83

P

 

Default: VSS_8

VDD_8

84

P

 

Default: VDD_8

 

PD14

 

85

 

I/O

 

5VT

Default: PD14 Alternate: EXMC_D0

Remap: TIMER3_CH2

 

PD15

 

86

 

I/O

 

5VT

Default: PD15 Alternate: EXMC_D1 Remap: TIMER3_CH3

 

PG2

 

87

 

I/O

 

5VT

Default: PG2 Alternate: EXMC_A12

 

PG3

 

88

 

I/O

 

5VT

Default: PG3

Alternate: EXMC_A13

 

PG4

 

89

 

I/O

 

5VT

Default: PG4

Alternate: EXMC_A14

 

PG5

 

90

 

I/O

 

5VT

Default: PG5

Alternate: EXMC_A15

 

PG6

 

91

 

I/O

 

5VT

Default: PG6

Alternate: EXMC_INT1

 

PG7

 

92

 

I/O

 

5VT

Default: PG7 Alternate: EXMC_INT2

PG8

93

I/O

5VT

Default: PG8

VSS_9

94

P

 

Default: VSS_9

VDD_9

95

P

 

Default: VDD_9

 

PC6

 

96

 

I/O

 

5VT

Default: PC6

Alternate: I2S1_MCK, TIMER7_CH0 Remap: TIMER2_CH0

 

PC7

 

97

 

I/O

 

5VT

Default: PC7

Alternate: I2S2_MCK, TIMER7_CH1 Remap: TIMER2_CH1

PC8

98

I/O

5VT

Default: PC8

 

 

 

Pin Name

 

 

Pins

 

 

Pin Type(1)

 

 

I/O Level(2)

 

 

Functions description

 

 

 

 

Alternate: TIMER7_CH2

Remap: TIMER2_CH2

 

PC9

 

99

 

I/O

 

5VT

Default: PC9

Alternate: TIMER7_CH3 Remap: TIMER2_CH3

 

PA8

 

100

 

I/O

 

5VT

Default: PA8

Alternate: USART0_CK, TIMER0_CH0, CK_OUT0, USBFS_SOF

 

PA9

 

101

 

I/O

 

5VT

Default: PA9

Alternate: USART0_TX, TIMER0_CH1, USBFS_VBUS

 

PA10

 

102

 

I/O

 

5VT

Default: PA10

Alternate: USART0_RX, TIMER0_CH2, USBFS_ID

 

PA11

 

103

 

I/O

 

5VT

Default: PA11

Alternate: USART0_CTS, CAN0_RX, USBFS_DM, TIMER0_CH3

 

PA12

 

104

 

I/O

 

5VT

Default: PA12

Alternate: USART0_RTS, USBFS_DP, CAN0_TX, TIMER0_ETI

 

PA13

 

105

 

I/O

 

5VT

Default: JTMS, SWDIO Remap: PA13

NC

106

 

 

-

VSS_2

107

P

 

Default: VSS_2

VDD_2

108

P

 

Default: VDD_2

 

PA14

 

109

 

I/O

 

5VT

Default: JTCK, SWCLK

Remap: PA14

 

 

PA15

 

 

110

 

 

I/O

 

 

5VT

Default: JTDI

Alternate: SPI2_NSS, I2S2_WS

Remap: TIMER1_CH0, TIMER1_ETI, PA15, SPI0_NSS

 

PC10

 

111

 

I/O

 

5VT

Default: PC10 Alternate: UART3_TX

Remap: USART2_TX, SPI2_SCK, I2S2_CK

 

PC11

 

112

 

I/O

 

5VT

Default: PC11 Alternate: UART3_RX

Remap: USART2_RX, SPI2_MISO

 

PC12

 

113

 

I/O

 

5VT

Default: PC12 Alternate: UART4_TX

 

 

 

Pin Name

 

 

Pins

 

 

Pin Type(1)

 

 

I/O Level(2)

 

 

Functions description

 

 

 

 

Remap: USART2_CK, SPI2_MOSI, I2S2_SD

 

PD0

 

114

 

I/O

 

5VT

Default: PD0 Alternate: EXMC_D2 Remap: CAN0_RX

 

PD1

 

115

 

I/O

 

5VT

Default: PD1 Alternate: EXMC_D3

Remap: CAN0_TX

 

PD2

 

116

 

I/O

 

5VT

Default: PD2

Alternate: TIMER2_ETI, UART4_RX

 

PD3

 

117

 

I/O

 

5VT

Default: PD3 Alternate: EXMC_CLK

Remap: USART1_CTS

 

PD4

 

118

 

I/O

 

5VT

Default: PD4 Alternate: EXMC_NOE

Remap: USART1_RTS

 

PD5

 

119

 

I/O

 

5VT

Default: PD5

Alternate: EXMC_NWE Remap: USART1_TX

VSS_10

120

 

 

Default: VSS_10

VDD_10

121

 

 

Default: VDD_10

 

PD6

 

122

 

I/O

 

5VT

Default: PD6

Alternate: EXMC_NWAIT Remap: USART1_RX

 

PD7

 

123

 

I/O

 

5VT

Default: PD7

Alternate: EXMC_NE0, EXMC_NCE1 Remap: USART1_CK

 

PG9

 

124

 

I/O

 

5VT

Default: PG9

Alternate: EXMC_NE1, EXMC_NCE2

 

PG10

 

125

 

I/O

 

5VT

Default: PG10

Alternate: EXMC_NCE3_0, EXMC_NE2

 

PG11

 

126

 

I/O

 

5VT

Default: PG11

Alternate: EXMC_NCE3_1

 

PG12

 

127

 

I/O

 

5VT

Default: PG12 Alternate: EXMC_NE3

 

PG13

 

128

 

I/O

 

5VT

Default: PG13

Alternate: EXMC_A24

 

PG14

 

129

 

I/O

 

5VT

Default: PG14

Alternate: EXMC_A25

VSS_11

130

P

 

Default: VSS_11

 

 

 

Pin Name

 

 

Pins

 

 

Pin Type(1)

 

 

I/O Level(2)

 

 

Functions description

VDD_11

131

P

 

Default: VDD_11

PG15

132

I/O

5VT

Default: PG15

 

 

PB3

 

 

133

 

 

I/O

 

 

5VT

Default: JTDO Alternate:SPI2_SCK, I2S2_CK

Remap: PB3, TRACESWO, TIMER1_CH1,

SPI0_SCK

 

PB4

 

134

 

I/O

 

5VT

Default: NJTRST Alternate: SPI2_MISO

Remap: TIMER2_CH0, PB4, SPI0_MISO

 

 

PB5

 

 

135

 

 

I/O

 

Default: PB5

Alternate: I2C0_SMBA, SPI2_MOSI, I2S2_SD, ETH_PPS_OUT

Remap: TIMER2_CH1, SPI0_MOSI, CAN1_RX

 

PB6

 

136

 

I/O

 

5VT

Default: PB6

Alternate: I2C0_SCL, TIMER3_CH0 Remap: USART0_TX, CAN1_TX

 

 

PB7

 

 

137

 

 

I/O

 

 

5VT

Default: PB7

Alternate: I2C0_SDA , TIMER3_CH1, EXMC_NADV

Remap: USART0_RX

BOOT0

138

I

 

Default: BOOT0

 

PB8

 

139

 

I/O

 

5VT

Default: PB8

Alternate: TIMER3_CH2, ETH_MII_TXD3 Remap: I2C0_SCL, CAN0_RX

 

PB9

 

140

 

I/O

 

5VT

Default: PB9

Alternate: TIMER3_CH3 Remap: I2C0_SDA, CAN0_TX

PE0

141

I/O

5VT

Default: PE0

Alternate: TIMER3_ETI, EXMC_NBL0

PE1

142

I/O

5VT

Default: PE1

Alternate: EXMC_NBL1

VSS_3

143

P

 

Default: VSS_3

VDD_3

144

P

 

Default: VDD_3

Notes:
(1)Type: I = input, O = output, P = power.
(2)I/O Level: 5VT = 5 V tolerant.

ARM® Cortex™-M3 core

The Cortex™-M3 processor is the latest generation of ARM® processors for embedded systems. It has been developed to provide a low-cost platform that meets the needs of MCU implementation, with a reduced pin count and low-power consumption, while delivering outstanding computational performance and an advanced system response to interrupts.
32-bit ARM® Cortex™-M3 processor core
Up to 108 MHz operation frequency
Single-cycle multiplication and hardware divider
Integrated Nested Vectored Interrupt Controller (NVIC)
24-bit SysTick timer

The Cortex™-M3 processor is based on the ARMv7 architecture and supports both Thumb and Thumb-2 instruction sets. Some system peripherals listed below are also provided by Cortex™-M3:
Internal Bus Matrix connected with ICode bus, DCode bus, system bus, Private Peripheral Bus (PPB) and debug accesses (AHB-AP)
Nested Vectored Interrupt Controller (NVIC)
Flash Patch and Breakpoint (FPB)
Data Watchpoint and Trace (DWT)
Instrument Trace Macrocell (ITM)
Memory Protection Unit (MPU)
Serial Wire JTAG Debug Port (SWJ-DP)
Trace Port Interface Unit (TPIU)


On-chip memory

Up to 1024 Kbytes of Flash memory
96 Kbytes of SRAM

The ARM® Cortex™-M3 processor is structured in Harvard architecture which can use separate buses to fetch instructions and load/store data. 1024 Kbytes of inner Flash at most and 96 Kbytes of inner SRAM is available for storing programs and data, both accessed (R/W) at CPU clock speed with zero wait states. The Table 2-3. GD32F107xx memory map shows the memory map of the GD32F107xx series of devices, including code, SRAM, peripheral, and other pre-defined regions.

Clock, reset and supply management

Internal 8 MHz factory-trimmed RC and external 3 to 25 MHz crystal oscillator
Internal 40 KHz RC calibrated oscillator and external 32.768 KHz crystal oscillator
Integrated system clock PLL
2.6 to 3.6 V application supply and I/Os
Supply Supervisor: POR (Power On Reset), PDR (Power Down Reset), and low voltage detector (LVD)
The Clock Control Unit (CCU) provides a range of oscillator and clock functions. These include speed internal RC oscillator and external crystal oscillator, high speed and low speed two types. Several prescalers allow the configuration of the AHB frequency, the high-speed APB (APB2) and the low-speed APB (APB1) domains. The maximum frequency of the AHB and the high-speed APB domains is 108 MHz. The maximum allowed frequency of the low- speed APB domain is 54 MHz. See Figure 2-5. GD32F107xx clock tree for details on the clock tree.
The Reset Control Unit (RCU) controls three kinds of reset: system reset resets the processor core and peripheral IP components. Power-on reset (POR) and power-down reset (PDR) are always active, and ensures proper operation starting from/down to 2.6 V. The device remains in reset mode when VDD is below a specified threshold. The embedded low voltage detector (LVD) monitors the power supply, compares it to the voltage threshold and generates an interrupt as a warning message for leading the MCU into security.
Power supply schemes:
VDD range: 2.6 to 3.6 V, external power supply for I/Os and the internal regulator. Provided externally through VDD pins.
VSSA, VDDA range: 2.6 to 3.6 V, external analog power supplies for ADC, reset blocks, RCs and PLL. VDDA and VSSA must be connected to VDD and VSS, respectively.
VBAT range: 1.8 to 3.6 V, power supply for RTC, external clock 32 kHz oscillator and backup registers (through power switch) when VDD is not present.

Boot modes

At startup, boot pins are used to select one of three boot options:
Boot from main flash memory (default)
Boot from system memory
Boot from on-chip SRAM

The boot loader is located in the internal boot ROM memory (system memory). It is used to reprogram the Flash memory by using USART0 (PA9 and PA10), USART1 (PD5 and PD6), USBFS in device mode (PA9, PA11 and PA12). It also can be used to transfer and update the Flash memory code, the data and the vector table sections. In default condition, boot from bank 0 of Flash memory is selected. It also supports to boot from bank 1 of Flash memory by

setting a bit in option bytes.


Power saving modes

The MCU supports three kinds of power saving modes to achieve even lower power consumption. They are sleep mode, deep-sleep mode, and standby mode. These operating modes reduce the power consumption and allow the application to achieve the best balance between the CPU operating time, speed and power consumption.
Sleep mode
In sleep mode, only the clock of CPU core is off. All peripherals continue to operate and any interrupt/event can wake up the system.
Deep-sleep mode
In deep-sleep mode, all clocks in the 1.2V domain are off, and all of the high speed crystal oscillator (IRC8M, HXTAL) and PLL are disabled. Only the contents of SRAM and registers are retained. Any interrupt or wakeup event from EXTI lines can wake up the system from the deep-sleep mode including the 16 external lines, the RTC alarm, the LVD output, and USB wakeup. When exiting the Deep-sleep mode, the IRC8M is selected as the system clock.
Standby mode
In standby mode, the whole 1.2V domain is power off, the LDO is shut down, and all of IRC8M, HXTAL and PLL are disabled. The contents of SRAM and registers (except Backup registers) are lost. There are four wakeup sources for the standby mode, including the external reset from NRST pin, the RTC alarm, the FWDGT reset, and the rising edge on WKUP pin.

Analog to digital converter (ADC)

12-bit SAR ADC engine
Up to 1 MSPS conversion rate
Conversion range: VSSA to VDDA (2.6 to 3.6 V)
Temperature sensor

Up to two 12-bit 1 μs multi-channel ADCs are integrated in the device. Each is a total of up to 21 multiplexed external channels. An analog watchdog block can be used to detect the channels, which are required to remain within a specific threshold window. A configurable channel management block of analog inputs also can be used to perform conversions in single, continuous, scan or discontinuous mode to support more advanced usages.
The ADCs can be triggered from the events generated by the general-purpose timers (TIMERx) and the advanced-control timers (TIMER0 and TIMER7) with internal connection. The temperature sensor has to generate a voltage that varies linearly with temperature. The conversion range is between 2.6 V < VDDA < 3.6 V. The temperature sensor is internally connected to the ADC_IN16 input channel which is used to convert the sensor output voltage

into a digital value.


Digital to analog converter (DAC)

Two 12-bit DAC converters of independent output channel
8-bit or 12-bit mode in conjunction with the DMA controller

The two 12-bit buffered DAC channels are used to generate variable analog outputs. The DACs are designed with integrated resistor strings structure. The DAC channels can be triggered by the timer update outputs or EXTI with DMA support. In dual DAC channel operation, conversions could be done independently or simultaneously. The maximum output value of the DAC is VREF+.

DMA

7 channel DMA0 controller and 5 channel DMA1 controller
Peripherals supported: Timers, ADC, SPIs, I2Cs, USARTs, DAC, I2S
Dedicated DMA controller with the Ethernet application

The flexible general-purpose DMA controllers provide a hardware method of transferring data between peripherals and/or memory without intervention from the CPU, thereby freeing up bandwidth for other system functions. Four types of access method are supported: peripheral to peripheral, peripheral to memory, memory to peripheral, memory to memory
Each channel is connected to fixed hardware DMA requests. The priorities of DMA channel requests are determined by software configuration and hardware channel number. Transfer size of source and destination are independent and configurable.

General-purpose inputs/outputs (GPIOs)

Up to 112 fast GPIOs, all mappable on 16 external interrupt vectors (EXTI)
Analog input/output configurable
Alternate function input/output configurable

There are up to 112 general purpose I/O pins (GPIO) in GD32F107xx, named PA0 ~ PA15 and  PB0  ~ PB15,  PC0  ~  PC15,  PD0  ~ PD15,  PE0  ~  PE15,  PF0-PF15,  PG0-PG15 to
implement logic input/output functions. Each of the GPIO ports has related control and configuration registers to satisfy the requirements of specific applications. The external interrupts on the GPIO pins of the device have related control and configuration registers in the External Interrupt Control Unit (EXTI). The GPIO ports are pin-shared with other alternative functions (AFs) to obtain maximum flexibility on the package pins. Each of the GPIO pins can be configured by software as output (push-pull or open-drain), as input (with or without pull-up or pull-down) or as peripheral alternate function. Most of the GPIO pins are

shared with digital or analog alternate functions. All GPIOs are high-current capable except for analog inputs.

Timers and PWM generation

Up to two 16-bit advanced-control timer (TIMER0 & TIMER7), four 16-bit general-purpose timers (GPTM), and two 16-bit basic timer (TIMER5 & TIMER6)
Up to 4 independent channels of PWM, output compare or input capture for each GPTM and external trigger input
16-bit, motor control PWM advanced-control timer with programmable dead-time generation for output match
Encoder interface controller with two inputs using quadrature decoder
24-bit SysTick timer down counter
2 watchdog timers (Free watchdog timer and window watchdog timer)

The advanced-control timer (TIMER0 & TIMER7) can be seen as a three-phase PWM multiplexed on 6 channels. It has complementary PWM outputs with programmable dead- time generation. It can also be used as a complete general-purpose timer. The 4 independent channels can be used for
Input capture
Output compare
PWM generation (edge- or center-aligned counting modes)
Single pulse mode output

If configured as a general-purpose 16-bit timer, it has the same functions as the TIMER x timer. It can be synchronized with external signals or to interconnect with other GPTMs together which have the same architecture and features.
The general-purpose timer (GPTM), known as TIMER1 ~ TIMER4 can be used for a variety of purposes including general time, input signal pulse width measurement or output waveform generation such as a single pulse generation or PWM output, up to 4 independent channels for input capture/output compare. The GPTM also supports an encoder interface with two inputs using quadrature decoder.
The basic timer, known as TIMER5 and TIMER6 are mainly used for DAC trigger generation. They can also be used as a simple 16-bit time base.
The GD32F107xx have two watchdog peripherals, free watchdog timer and window watchdog timer. They offer a combination of high safety level, flexibility of use and timing accuracy.
The free watchdog timer includes a 12-bit down-counting counter and an 8-bit prescaler, It is clocked from an independent 40 kHz internal RC and as it operates independently of the main clock, it can operate in deep-sleep and standby modes. It can be used either as a watchdog to reset the device when a problem occurs, or as a free-running timer for application timeout management.

The window watchdog timer is based on a 7-bit down counter that can be set as free-running. It can be used as a watchdog to reset the device when a problem occurs. It is clocked from the main clock. It has an early warning interrupt capability and the counter can be frozen in debug mode.
The SysTick timer is dedicated for OS, but could also be used as a standard down counter. It features:
A 24-bit down counter
Auto reload capability
Maskable system interrupt generation when the counter reaches 0
Programmable clock source


Real time clock (RTC)

32-bit up-counter with a programmable 20-bit prescaler
Alarm function
Interrupt and wake-up event

The real time clock is an independent timer which provides a set of continuously running counters which can be used with suitable software to provide a clock calendar function, and provides an alarm interrupt and an expected interrupt. The RTC features a 32-bit programmable counter for long-term measurement using the compare register to generate an alarm. A 20-bit prescaler is used for the time base clock and is by default configured to generate a time base of 1 second from a clock at 32.768 kHz from external crystal oscillator.

Inter-integrated circuit (I2C)

Up to two I2C bus interfaces can support both master and slave mode with a frequency up to 400 kHz
Provide arbitration function, optional PEC (packet error checking) generation and checking
Supports 7-bit and 10-bit addressing mode and general call addressing mode

The I2C interface is an internal circuit allowing communication with an external I2C interface which is an industry standard two line serial interface used for connection to external hardware. These two serial lines are known as a serial data line (SDA) and a serial clock line (SCL). The I2C module provides transfer rate of up to 100 KHz in standard mode and up to 400 KHz in fast mode. The I2C module also has an arbitration detect function to prevent the situation where more than one master attempts to transmit data to the I2C bus at the same time. A CRC-8 calculator is also provided in I2C interface to perform packet error checking for I2C data.

Serial peripheral interface (SPI)

Up to three SPI interfaces with a frequency of up to 18 MHz
Support both master and slave mode
Hardware CRC calculation and transmit automatic CRC error checking

The SPI interface uses 4 pins, among which are the serial data input and output lines (MISO & MOSI), the clock line (SCK) and the slave select line (NSS). Both SPIs can be served by the DMA controller. The SPI interface may be used for a variety of purposes, including simplex synchronous transfers on two lines with a possible bidirectional data line or reliable communication using CRC checking.

Universal synchronous asynchronous receiver transmitter (USART)
Up to three USARTs and two UARTs with operating frequency up to 6.75 MHz
Supports both asynchronous and clocked synchronous serial communication modes
IrDA SIR encoder and decoder support
LIN break generation and detection
USARTs support ISO 7816-3 compliant smart card interface

The USART (USART0, USART1 and USART2) are used to translate data between parallel and serial interfaces, provides a flexible full duplex data exchange using synchronous or asynchronous transfer. It is also commonly used for RS-232 standard communication. The USART includes a programmable baud rate generator which is capable of dividing the system clock to produce a dedicated clock for the USART transmitter and receiver. The USART also supports DMA function for high speed data communication except UART4.

Inter-IC sound (I2S)

Two I2S bus Interfaces with sampling frequency from 8 kHz to 192 kHz
Support either master or slave mode

The Inter-IC sound (I2S) bus provides a standard communication interface for digital audio applications by 3-wire serial lines. GD32F107xx contain two I2S-bus interfaces that can be operated with 16/32 bit resolution in master or slave mode, pin multiplexed with SPI1 and SPI2. The audio sampling frequency from 8 kHz to 192 kHz is supported with less than 0.5% accuracy error.

Universal serial bus full-speed (USBFS)

One USB device/host/OTG full-speed Interface with frequency up to 12 Mbit/s
Internal main PLL for USB CLK compliantly

The Universal Serial Bus (USB) is a 4-wire bus with 4 bidirectional endpoints. The device controller enables 12 Mbit/s data exchange with integrated transceivers in device/host/OTG mode. Full-speed peripheral is compliant with the USB 2.0 specification. Transaction formatting is performed by the hardware, including CRC generation and checking. The status of a completed USB transfer or error condition is indicated by status registers. An interrupt is also generated if enabled. The dedicated 48 MHz clock is generated from the internal main PLL (the clock source must use a HXTAL crystal oscillator) and the operating frequency divided from APB1 should be 12 MHz above.

Controller area network (CAN)

Two CAN2.0B interface with communication frequency up to 1 Mbit/s
Internal main PLL for USB CLK compliantly

Controller area network (CAN) is a method for enabling serial communication in field bus. The CAN protocol has been used extensively in industrial automation and automotive applications. It can receive and transmit standard frames with 11-bit identifiers as well as extended frames with 29-bit identifiers. Each CAN has three mailboxes for transmission and two FIFOs of three message deep for reception. It also provides 14 scalable/configurable identifier filter banks for selecting the incoming messages needed and discarding the others.

Ethernet MAC interface

IEEE 802.3 compliant media access controller (MAC) for Ethernet LAN
10/100 Mbit/s rates with dedicated DMA controller and SRAM
Support hardware precision time protocol (PTP) with conformity to IEEE 1588

The Ethernet media access controller (MAC) conforms to IEEE 802.3 specifications and fully supports IEEE 1588 standards. The embedded MAC provides the interface to the required external network physical interface (PHY) for LAN bus connection via an internal media independent interface (MII) or a reduced media independent interface (RMII). The number of MII signals provided up to 17 with 25 MHz output and RMII up to 9 with 50 MHz output. The function of 32-bit CRC checking is also available.

External memory controller (EXMC)

Supported external memory: SRAM, PSRAM, ROM and NOR-Flash, NAND Flash and

CF card
Up to 16-bit data bus
Support to interface with Motorola 6800 and Intel 8080 type LCD directly

External memory controller (EXMC) is an abbreviation of external memory controller. It is divided in to several sub-banks for external device support, each sub-bank has its own chip selection signal but at one time, only one bank can be accessed. The EXMC support code execution from external memory except NAND Flash and CF card. The EXMC also can be configured to interface with the most common LCD module of Motorola 6800 and Intel 8080 series and reduce the system cost and complexity.

Debug mode

Serial wire JTAG debug port (SWJ-DP)

The ARM® SWJ-DP Interface is embedded and is a combined JTAG and serial wire debug port that enables either a serial wire debug or a JTAG probe to be connected to the target.

Package and operation temperature

LQFP144 (GD32F107Zx), LQFP100 (GD32F107Vx), LQFP64 (GD32F107Rx)
Operation temperature range: -40°C to +85°C (industrial level)

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uA级别智能门锁低功耗雷达模块让门锁更加智能省电节约功耗

发布时间: : 2022-02--18
uA级别智能门锁低功耗雷达模块让门锁更加智能省电节约功耗,指纹门锁并不是什么新鲜事,我相信每个人都很熟悉。随着近年来智能家居的逐步普及,指纹门锁也进入了成千上万的家庭。今天的功耗雷达模块指纹门锁不仅消除了繁琐的钥匙,而且还提供了各种智能功能,uA级别智能门锁低功耗雷达模块用在智能门锁上,可以实现门锁的智能感应屏幕,使电池寿命延长3-5倍,如与其他智能家居连接,成为智能场景的开关。所以今天的指纹门锁更被称为智能门锁。 今天,让我们来谈谈功耗雷达模块智能门锁的安全性。希望能让更多想知道智能门锁的朋友认识下。 指纹识别是智能门锁的核心 指纹识别技术在我们的智能手机上随处可见。从以前的实体指纹识别到屏幕下的指纹识别,可以说指纹识别技术已经相当成熟。指纹识别可以说是整个uA级低功耗雷达模块智能门锁的核心。 目前主要有三种常见的指纹识别方法,即光学指纹识别、半导体指纹识别和超声指纹识别。 光学指纹识别 让我们先谈谈光学指纹识别的原理实际上是光的反射。我们都知道指纹本身是不均匀的。当光照射到我们的指纹上时,它会反射,光接收器可以通过接收反射的光来绘制我们的指纹。就像激光雷达测绘一样。 光学指纹识别通常出现在打卡机上,手机上的屏幕指纹识别技术也使用光学指纹识别。今天的光学指纹识别已经达到了非常快的识别速度。 然而,光学指纹识别有一个缺点,即硬件上的活体识别无法实现,容易被指模破解。通常,活体识别是通过软件算法进行的。如果算法处理不当,很容易翻车。 此外,光学指纹识别也容易受到液体的影响,湿手解锁的成功率也会下降。 超声指纹识别 超声指纹识别也被称为射频指纹识别,其原理与光学类型相似,但超声波使用声波反射,实际上是声纳的缩小版本。因为使用声波,不要担心水折射会降低识别率,所以超声指纹识别可以湿手解锁。然而,超声指纹识别在防破解方面与光学类型一样,不能实现硬件,可以被指模破解,活体识别仍然依赖于算法。 半导体指纹识别 半导体指纹识别主要采用电容、电场(即我们所说的电感)、温度和压力原理来实现指纹图像的收集。当用户将手指放在前面时,皮肤形成电容阵列的极板,电容阵列的背面是绝缘极板。由于不同区域指纹的脊柱与谷物之间的距离也不同,因此每个单元的电容量随之变化,从而获得指纹图像。半导体指纹识别具有价格低、体积小、识别率高的优点,因此大多数uA级低功耗雷达模块智能门锁都采用了这种方案。半导体指纹识别的另一个功能是活体识别。传统的硅胶指模无法破解。 当然,这并不意味着半导体可以百分识别活体。所谓的半导体指纹识别活体检测不使用指纹活体体征。本质上,它取决于皮肤的材料特性,这意味着虽然传统的硅胶指模无法破解。 一般来说,无论哪种指纹识别,都有可能被破解,只是说破解的水平。然而,今天的指纹识别,无论是硬件生活识别还是算法生活识别,都相对成熟,很难破解。毕竟,都可以通过支付级别的认证,大大保证安全。 目前,市场上大多数智能门锁仍将保留钥匙孔。除了指纹解锁外,用户还可以用传统钥匙开门。留下钥匙孔的主要目的是在指纹识别故障或智能门锁耗尽时仍有开门的方法。但由于有钥匙孔,它表明它可以通过技术手段解锁。 目前市场上的锁等级可分为A、B、C三个等级,这三个等级主要是通过防暴开锁和防技术开锁的程度来区分的。A级锁要求技术解锁时间不少于1分钟,B级锁要求不少于5分钟。即使是高级别的C级锁也只要求技术解锁时间不少于10分钟。 也就是说,现在市场上大多数门锁,无论是什么级别,在专业的解锁大师面前都糊,只不过是时间长短。 安全是重要的,是否安全增加了人们对uA级别低功耗雷达模块智能门锁安全的担忧。事实上,现在到处都是摄像头,强大的人脸识别,以及移动支付的出现,使家庭现金减少,所有这些都使得入室盗窃的成本急剧上升,近年来各省市的入室盗窃几乎呈悬崖状下降。 换句话说,无论锁有多安全,无论锁有多难打开,都可能比在门口安装摄像头更具威慑力。 因此,担心uA级别低功耗雷达模块智能门锁是否不安全可能意义不大。毕竟,家里的防盗锁可能不安全。我们应该更加关注门锁能给我们带来多少便利。 我们要考虑的是智能门锁的兼容性和通用性。毕竟,智能门锁近年来才流行起来。大多数人在后期将普通机械门锁升级为智能门锁。因此,智能门锁能否与原门兼容是非常重要的。如果不兼容,发现无法安装是一件非常麻烦的事情。 uA级别低功耗雷达模块智能门锁主要是为了避免带钥匙的麻烦。因此,智能门锁的便利性尤为重要。便利性主要体现在指纹的识别率上。手指受伤导致指纹磨损或老年人指纹较浅。智能门锁能否识别是非常重要的。 当然,如果指纹真的失效,是否有其他解锁方案,如密码解锁或NFC解锁。还需要注意密码解锁是否有虚假密码等防窥镜措施。 当然,智能门锁的耐久性也是一个需要特别注意的地方。uA级别低功耗雷达模块智能门锁主要依靠内部电池供电,这就要求智能门锁的耐久性尽可能好,否则经常充电或更换电池会非常麻烦。 智能门锁低功耗雷达模块:让门锁更加智能省电节约功耗 在当今信息化时代,智能门锁已经成为人们生活中不可或缺的一部分。对于门锁制造商来说,如何提高门锁的安全性、实用性和便利性,成为他们面对的重要课题。随着人们对门锁智能化的需求越来越高,门锁的能耗问题也成为了门锁制造商需要重视的问题。为此,越来越多的门锁制造商开始推出以低功耗为主题的系列产品。在这样的背景下,智能门锁低功耗雷达模块应运而生。 智能门锁低功耗雷达模块是一种新型技术,其采取雷达技术对门锁周围的物体进行探测,一旦发现门锁附近有人靠近,便会将门锁自动解锁,无需使用钥匙。同时,在保持智能控制的前提下,实现了门锁省电、节约功耗,延长门锁使用寿命。 在使用智能门锁低功耗雷达模块的门锁中,控制电路和自动解锁机制是关键的部件。控制电路采用先进的芯片技术,通过优秀的功耗控制以实现模块化管理。而自动解锁机制不仅可以通过微波信号控制实现门锁的无钥匙解锁,还能够在门锁未处理的情况下自动锁定,保障门锁的安全。 智能门锁低功耗雷达模块的主要特点是:低功耗、高灵敏度和高可靠性。该模块在进行人体检测时,可以远距离探测到距离为5-7米远处的人体信号,目标检测速度极快,而且对门锁周围的环境要求不高。同时,该模块采用了自适应自动补偿技术,能够根据不同环境的变化自动调整信号发射和接收参数,减小误检率。 在使用智能门锁低功耗雷达模块的门锁中,其功耗可以做到非常低,一组电池能够支持门锁持续使用几年左右。而且这样的智能门锁除了具有自动解锁的功能,还可与APP相互匹配,实现了远程操作的便捷性。 总的来说,智能门锁低功耗雷达模块的问世,解决了门锁安全性和省电节省方面的问题,是智能门锁材料不可或缺的一部分。作为门锁制造商,只有不断创新,利用这种新型技术,将会在行业中占据重要的地位。 除了上文所述的主要特点和优势,智能门锁低功耗雷达模块还具有以下几点: 1. 实时监测门锁周围环境变化,通过物体的距离体积和运动来确定是否有人靠近门锁,并控制门锁的开启或关闭,使得门锁更加智能化。 2. 可对门锁附件进行检测,如门挂、门应急照明灯以及紧急呼叫按钮等,并及时给出响应,确保门锁能够正常运作。这样,门锁在不受干扰的情况下,能够 保持安全通道。 3. 通过智能学习技术,能够自适应网站多种环境的变化,让智能门锁低功耗雷达模块更加准确和精细的控制门锁的开关,节约能耗并延长使用寿命。 4. 能够与其他智能电器相连,如智能家居系统、电视等,形成智能家居生态圈,更好地控制家庭访客进出,让生活更加方便。 综上所述,智能门锁低功耗雷达模块的出现,对提升门锁能耗管理和智能化有着重要作用。门锁制造商只有将这些新型技术运用到门锁产品中,才能更加贴合用户需求,满足消费市场的日益增长的智能化需求。
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14
2022-01

微波雷达传感器雷达感应浴室镜上的应用

发布时间: : 2022-01--14
微波雷达传感器雷达感应浴室镜上的应用,如今,家用电器的智能化已成为一种常态,越来越多的人开始在自己的浴室里安装智能浴室镜。但是还有很多人对智能浴镜的理解还不够深入,今天就来说说这个话题。 什么是智能浴室镜?智慧型浴室镜,顾名思义,就是卫浴镜子智能化升级,入门级产品基本具备了彩灯和镜面触摸功能,更高档次的产品安装有微波雷达传感器智能感应,当感应到有人接近到一定距离即可开启亮灯或者亮屏操作,也可三色无极调,智能除雾,语音交互,日程安排备忘,甚至在镜子上看电视,听音乐,气象预报,问题查询,智能控制,健康管理等。 智能化雷达感应浴室镜与普通镜的区别,为什么要选TA?,就功能而言,普通浴镜价格用它没有什么压力!而且雷达感应智能浴镜会让人犹豫不决是否“值得一看”。就功能和应用而言,普通浴镜功能单一,而微波雷达传感器智能浴室镜功能创新:镜子灯光色温和亮度可以自由调节,镜面还可以湿手触控,智能除雾,既环保又健康! 尽管智能浴镜比较新颖,但功能丰富,体验感更好,特别是入门级的智能浴镜,具有基础智能化功能,真的适合想体验下智能化的小伙伴们。 给卫生间安装微波雷达传感器浴室镜安装注意什么? ①确定智能浴室镜的安装位置,因为是安装时在墙壁上打孔,一旦安装后一般无法移动位置。 ②在选购雷达感应智能浴室镜时,根据安装位置确定镜子的形状和尺寸。 ③确定智能浴镜的安装位置后,在布线时为镜子预留好电源线。 ④确定微波雷达传感器智能浴镜的安装高度,一般智能浴镜的标准安装高度约85cm(从地砖到镜子底),具体安装高度要根据家庭成员的身高及使用习惯来决定。 ⑤镜面遇到污渍,可用酒精或30%清洁稀释液擦洗,平时可用干毛巾养护,注意多通风。
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14
2024-09

超宽带通信车载UWB芯片:创新车载通信新时代

发布时间: : 2024-09--14
随着汽车智能化、网联化的不断演进,车载通信技术的发展也日益成为汽车科技创新的焦点。近年来,超宽带(Ultra-Wideband,简称UWB)通信技术的崛起,为车载通信领域带来了创新性的创新。本文将深入探讨超宽带通信车载UWB芯片的技术原理、应用优势、市场前景,以及当前的发展现状与趋势。 一、超宽带通信技术概述 超宽带通信技术是一种无线通信技术,它利用纳秒至微秒级的非正弦波窄脉冲传输数据,具有高速率、低功耗、高精度定位等特点。与传统的无线通信技术相比,UWB技术具有更高的数据传输速率和更低的功耗,同时能够实现厘米级的准确定位,因此在车载通信领域具有广阔的应用前景。 二、超宽带通信车载UWB芯片的技术原理 超宽带通信车载UWB芯片是实现车载UWB通信的核心部件。它采用先进的脉冲无线电技术,通过发射和接收纳秒级脉冲信号来传输数据。这些脉冲信号具有极宽的频谱范围,能够在短时间内传输大量数据,从而实现高速、高效的车载通信。 UWB芯片还具备高精度定位能力。通过测量脉冲信号从发射到接收的时间差,可以准确计算出信号传输的距离,进而实现厘米级的定位精度。这一特性使得UWB芯片在车载导航、自动驾驶等领域具有独特的优势。 三、超宽带通信车载UWB芯片的应用优势 高速数据传输:UWB芯片能够实现高达数百兆比特每秒的数据传输速率,满足车载多媒体、车载娱乐等应用对高速数据传输的需求。 低功耗特性:UWB技术采用短脉冲信号进行通信,功耗极低,有助于延长车载设备的续航时间。 高精度定位:UWB芯片能够实现厘米级的定位精度,为车载导航、自动驾驶等应用提供精准的位置信息。 抗干扰能力强:UWB信号具有较高的频率和极短的脉冲宽度,能够有效抵抗多径效应和干扰信号,提高通信的可靠性。 安全性高:UWB通信具有极强的安全性,信号传输距离短、难以被截获,能够有效保护车载通信的安全性。 四、超宽带通信车载UWB芯片的市场前景 随着汽车智能化、网联化的加速发展,车载通信技术的需求日益旺盛。超宽带通信车载UWB芯片作为一种具有高速、低功耗、高精度定位等优势的新型通信技术,将在未来车载通信市场中占据重要地位。 目前,国内外众多汽车厂商和科技公司已经开始关注并投入研发超宽带通信车载UWB芯片。预计未来几年,随着技术的不断进步和成本的不断降低,UWB芯片将广泛应用于汽车领域,推动车载通信技术的发展。 同时,随着5G、物联网等技术的深度融合,车载UWB芯片将与其他车载通信技术形成互补,共同构建智能、安全、高效的车载通信网络。这将为自动驾驶、智能交通等领域的发展提供有力支撑,推动汽车产业向更加智能化、网联化的方向发展。 五、超宽带通信车载UWB芯片的发展现状与趋势 目前,超宽带通信车载UWB芯片的研发和应用尚处于起步阶段,但已经展现出强大的潜力和广阔的应用前景。未来,UWB芯片将呈现以下发展趋势: 技术不断创新:随着研究的深入和技术的进步,UWB芯片的性能将不断提升,数据传输速率、定位精度等方面将进一步优化。 成本逐渐降低:随着生产工艺的改进和市场规模的扩大,UWB芯片的生产成本将逐渐降低,推动其在车载通信领域的广泛应用。 应用场景不断拓展:除了传统的车载导航、自动驾驶等领域外,UWB芯片还将应用于车载支付、车载安全监控等更多场景,为汽车智能化提供更多可能性。 与其他技术深度融合:UWB芯片将与5G、物联网等技术深度融合,共同构建更加智能、高效的车载通信网络。 六、结论 超宽带通信车载UWB芯片作为一种具有高速、低功耗、高精度定位等优势的新型通信技术,将在未来车载通信市场中发挥重要作用。随着技术的不断进步和应用场景的不断拓展,UWB芯片将成为推动汽车智能化、网联化发展的重要力量。我们期待在未来看到更多创新性的UWB芯片产品问世,为汽车产业的发展注入新的活力。
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13
2024-09

高精定位UWB通讯芯片:未来定位技术的创新者

发布时间: : 2024-09--13
随着物联网、自动驾驶、智能机器人等技术的飞速发展,高精度定位技术逐渐成为这些领域的核心需求。超宽带(Ultra-Wideband,简称UWB)通讯技术作为一种新兴的无线通信技术,以其高精度、高速度、低功耗等特性,正在成为高精度定位领域的热门选择。本文将深入探讨高精定位UWB通讯芯片的工作原理、技术优势、应用领域以及未来发展趋势,为您揭示这一技术的无限可能。 一、高精定位UWB通讯芯片的工作原理 UWB通讯技术是一种利用纳秒至微秒级的非正弦波窄脉冲传输数据的无线通讯技术。其工作原理基于极短的脉冲信号,在极宽的频带范围内进行信息传输。这些脉冲信号具有极短的持续时间和高带宽,使得UWB技术能够实现厘米级甚至毫米级的高精度定位。 高精定位UWB通讯芯片是实现UWB定位的核心部件。它集成了发射器、接收器、信号处理器等多个功能模块,能够发射和接收UWB脉冲信号,并通过复杂的算法对信号进行处理,从而实现对目标物体的精确定位。 二、高精定位UWB通讯芯片的技术优势 高精度定位:UWB技术通过测量信号传输时间差来确定目标物体的位置,其定位精度可达到厘米级甚至毫米级,远超传统的GPS、Wi-Fi等定位技术。 高速度传输:UWB技术采用极短的脉冲信号进行数据传输,因此具有极高的传输速度,适用于需要实时响应的应用场景。 低功耗设计:高精定位UWB通讯芯片采用先进的低功耗设计,使得设备在长时间运行过程中能够保持较低的能耗,延长使用寿命。 强抗干扰能力:UWB技术采用宽带信号传输,具有较强的抗干扰能力,能够在复杂环境中稳定工作。 三、高精定位UWB通讯芯片的应用领域 物联网领域:在物联网场景中,高精定位UWB通讯芯片可以用于实现设备间的精确位置感知,提升物联网系统的智能化水平。例如,在智能家居系统中,通过UWB定位技术可以实现对家电设备的精准控制,提升用户的使用体验。 自动驾驶领域:自动驾驶汽车需要精确感知周围环境中的障碍物和其他车辆的位置。高精定位UWB通讯芯片能够提供厘米级的定位精度,为自动驾驶系统提供可靠的位置信息,保障行车安全。 智能机器人领域:智能机器人需要在复杂的环境中进行导航和定位。高精定位UWB通讯芯片可以帮助机器人实现精确的位置感知和路径规划,提高机器人的工作效率和自主性。 室内定位领域:传统的GPS定位技术在室内环境中往往无法正常工作。而高精定位UWB通讯芯片则能够在室内环境中实现精确的定位功能,为商场、医院、机场等公共场所提供便捷的导航服务。 四、高精定位UWB通讯芯片的未来发展趋势 技术不断创新:随着芯片制造工艺和算法的不断进步,高精定位UWB通讯芯片的性能将进一步提升,定位精度、传输速度、功耗等方面都将得到优化。 应用场景不断拓展:随着物联网、人工智能等技术的不断发展,高精定位UWB通讯芯片的应用场景将不断拓展,涉及到更多领域和行业。 标准化与互操作性提升:未来,高精定位UWB通讯芯片将更加注重标准化和互操作性,不同厂商的产品将能够实现无缝对接和协同工作,推动整个产业的健康发展。 安全与隐私保护加强:随着高精定位UWB通讯芯片应用的普及,安全和隐私保护问题将受到更多关注。未来的芯片设计将更加注重数据加密、身份验证等安全措施,保障用户数据的安全和隐私。 高精定位UWB通讯芯片作为未来定位技术的领跑者,具有广阔的应用前景和巨大的市场潜力。随着技术的不断创新和应用场景的不断拓展,我们有理由相信,这一技术将在未来发挥更加重要的作用,为人们的生活带来更多便利和可能性。同时,我们也应关注到安全和隐私保护等问题,确保技术的健康发展并造福人类。 五、高精定位UWB通讯芯片在智能制造领域的应用 智能制造是工业4.0的核心内容,它要求实现生产过程中的高度自动化、信息化和智能化。高精定位UWB通讯芯片凭借其高精度、高速度、低功耗等特性,在智能制造领域有着广泛的应用前景。 在生产线上,高精定位UWB通讯芯片可以用于实现物料、零部件和机器人的精确位置感知。通过实时监测和定位生产线上的各个元素,可以优化生产流程,提高生产效率。同时,它还可以用于实现设备的自动化巡检和维护,降低人工干预的成本和风险。 此外,高精定位UWB通讯芯片还可以与物联网、云计算等技术相结合,构建智能工厂的数据采集和分析系统。通过对生产数据的实时收集和分析,可以实现生产过程的可视化和智能化管理,提高生产质量和效率。 六、高精定位UWB通讯芯片在医疗领域的应用 医疗领域对定位技术的精度和稳定性有着极高的要求。高精定位UWB通讯芯片可以为医疗领域提供精确、可靠的定位服务。在手术室中,高精定位UWB通讯芯片可以用于实现手术器械和医疗设备的精确追踪和管理。医生可以实时了解手术器械的位置和状态,提高手术的准确性和安全性。此外,它还可以用于实现患者的精确定位,为精准医疗提供有力支持。 在养老院和康复中心,高精定位UWB通讯芯片可以帮助医护人员实时监测老年人的位置和行动轨迹,及时发现异常情况并采取相应措施。同时,它还可以用于实现老年人的智能定位服务,提供便捷的导航和求助功能,提高老年人的生活质量。 七、高精定位UWB通讯芯片在安防领域的应用 安防领域对定位技术的需求日益增长,高精定位UWB通讯芯片在这一领域也有着广泛的应用。 在公共安全领域,高精定位UWB通讯芯片可以用于实现警察、消防员等应急人员的精确定位。在紧急情况下,指挥中心可以实时了解应急人员的位置和状态,实现快速响应和高效调度。 在智能安防系统中,高精定位UWB通讯芯片可以用于实现人员和车辆的精确追踪和管理。通过对人员和车辆的实时定位,可以及时发现异常情况并采取相应的安全措施,提高安防系统的可靠性和有效性。 八、结论 高精定位UWB通讯芯片以其高精度、高速度、低功耗等特性,正在成为未来定位技术的领跑者。它在物联网、自动驾驶、智能机器人、室内定位、智能制造、医疗和安防等领域都有着广泛的应用前景。随着技术的不断创新和应用场景的不断拓展,我们有理由相信,高精定位UWB通讯芯片将在未来发挥更加重要的作用,为人们的生活带来更多便利和安全性。 然而,我们也应看到,高精定位UWB通讯芯片的发展仍面临一些挑战,如成本、标准化、互操作性以及安全和隐私保护等问题。为了推动这一技术的健康发展,我们需要加强技术研发和创新,推动产业标准化和规范化,加强安全和隐私保护措施的研究和应用。 总之,高精定位UWB通讯芯片是一项具有巨大潜力和广阔应用前景的技术。我们有理由相信,在未来的发展中,它将成为推动物联网、智能制造、医疗和安防等领域进步的重要力量,为我们的生活带来更多的便利和安全。
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12
2024-09

厘米级定位UWB定位芯片:未来位置感知技术

发布时间: : 2024-09--12
在科技飞速发展的今天,位置感知技术已成为众多领域不可或缺的关键技术之一。其中,超宽带(Ultra-Wideband,简称UWB)定位技术以其独特的优势,逐渐成为高精度定位领域的佼佼者。厘米级定位UWB定位芯片作为这一技术的核心,正以其卓越的性能和广泛的应用前景,创新着位置感知技术的创新。 一、UWB定位技术概述 超宽带(UWB)定位技术是一种利用纳秒至微秒级的非正弦波窄脉冲传输数据的无线通信技术。它具有传输速率高、功耗低、抗多径干扰能力强等特点,特别适用于短距离无线通信和精确定位。与传统的无线定位技术相比,UWB定位技术在定位精度、实时性和稳定性等方面有着显著的优势。 二、厘米级定位UWB定位芯片的特点 厘米级定位UWB定位芯片作为UWB定位技术的核心组件,具有以下几个显著特点: 高精度定位:厘米级定位UWB定位芯片采用先进的信号处理算法和定位算法,能够实现厘米级的定位精度。这使得它在需要高精度位置信息的场景中有着广泛的应用,如工业自动化、智能仓储、机器人导航等。 低功耗设计:为了满足长时间稳定运行的需求,厘米级定位UWB定位芯片采用了低功耗设计。通过优化电路设计和电源管理策略,芯片在保证定位精度的同时,有效降低了功耗,延长了设备的使用寿命。 抗干扰能力强:UWB信号具有较宽的频谱范围和较高的时间分辨率,这使得厘米级定位UWB定位芯片在复杂环境中具有较强的抗干扰能力。无论是室内还是室外,无论是静止还是运动状态,芯片都能保持稳定的定位性能。 易于集成:厘米级定位UWB定位芯片采用了标准的封装和接口设计,方便与其他硬件设备进行集成。这使得它能够轻松融入各种应用场景中,为各类设备提供高精度定位服务。 三、厘米级定位UWB定位芯片的应用领域 由于其卓越的性能和广泛的应用前景,厘米级定位UWB定位芯片在众多领域都有着重要的应用价值。以下是几个典型的应用领域: 智能物流:在智能仓储和物流领域,厘米级定位UWB定位芯片可以实现货物和设备的精确跟踪和定位。通过实时监测货物的位置和状态,提高物流效率和准确性,降低运营成本。 自动驾驶:在自动驾驶领域,厘米级定位UWB定位芯片可以为车辆提供高精度的位置信息,帮助车辆实现精确导航和避障。这对于提高自动驾驶系统的安全性和可靠性具有重要意义。 工业自动化:在工业自动化领域,厘米级定位UWB定位芯片可以用于机器人导航和生产线监控。通过实时监测机器人和设备的位置和状态,实现生产流程的自动化和智能化,提高生产效率和质量。 医疗健康:在医疗健康领域,厘米级定位UWB定位芯片可以用于实时监测患者的位置和活动状态。这有助于医护人员更好地了解患者的健康状况,提供个性化的医疗服务。 四、厘米级定位UWB定位芯片的未来发展趋势 随着物联网、人工智能等技术的不断发展,位置感知技术在各个领域的应用将更加广泛和深入。厘米级定位UWB定位芯片作为高精度定位技术的代表,其未来发展将呈现以下几个趋势: 更高的定位精度:随着算法和硬件技术的不断进步,厘米级定位UWB定位芯片的定位精度将进一步提高。未来,我们有望看到毫米级甚至更高精度的定位芯片问世。 更低的功耗和成本:为了满足更广泛的应用需求,厘米级定位UWB定位芯片将不断优化功耗和成本。通过采用更先进的制造工艺和电源管理技术,降低芯片的功耗和成本,使其更具市场竞争力。 更强的抗干扰能力和稳定性:在复杂多变的应用环境中,厘米级定位UWB定位芯片需要具备更强的抗干扰能力和稳定性。未来,芯片设计将更加注重对环境的适应性和稳定性,确保在各种场景下都能保持稳定的定位性能。 更广泛的应用场景:随着技术的不断进步和应用需求的不断拓展,厘米级定位UWB定位芯片将应用于更多领域。除了现有的智能物流、自动驾驶、工业自动化和医疗健康等领域外,未来还可能涉及智能家居、智慧城市等更多领域。 五、结语 厘米级定位UWB定位芯片作为未来位置感知技术的创新者,正以其卓越的性能和广泛的应用前景创新着技术的发展潮流。我们有理由相信,在未来的科技发展中,厘米级定位UWB定位芯片将发挥更加重要的作用,为我们的生活带来更多便利和可能性。
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