CC1101与MSP430F5438的无线通信

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简介:本文主要讲以2个CC1101和一个MSP430F5438的一发一收通讯测试程序。

CC1101的功能强大远比于24L01。尤其通讯距离和低功耗。CC1101的数据手册网络上很多,找个搜索软件一搜一片一片的。。CC1101与MSP430F5438的无线通信CC1101与MSP430F5438的无线通信CC1101与MSP430F5438的无线通信不过我建议大家还是去ti的官网吧,那里的资料比较权威,也省得一些中文化的误解导致自己白花好几天的功夫。。

我在CC1101通讯的时候主要值得注意的,1、SPI的底层是个基础,包括单片机带的SPI接口也好,自己用IO口实现也好,怎么来实现和硬件之间的链接了。2、编程实现的时候注意时序问题。。SPI的时序都一样,但是操作芯片的时候可能有应答,可能没有应答。。3、花最大功夫研究里面的寄存器的配置。整个通讯成功与否,通讯效果好不好都在寄存器的配置上。。个人认为必须理解各个寄存器的作用及使用的目的及意义了。。4、GDO0等IO口的配置在整个系统中的运用非常重要。常见配置值0x01,0x02,0x03,0x06,0x07,其中配置值最为常用配置0x06了,但是了,对于各种需求可以相应修改了,具体手册上写的比较明白。。

以下为2个CC1101和一个MSP430F5438的一发一收通讯测试程序,实验证明通讯效果比,MC31213(xbee),2401AG,24L01都强,表现在1、通讯视距中有障碍物(如一般水泥墙壁)不影响通讯;2、整个系统电流消耗比较小大约电流在10D多个ma。具体代码如下。

//*****************************************************************************

//

// 【名称】:CC1101测试程序

// 【功能】:一个开发板实现两个CC1101模块间通讯

// 【版本】:V1.0

// 【作者】:刘

// 【日期】:2011-11-28 14:05:00

// 【说明】:软件版本定义为:V1.0为初始版本,以后改进完善的版本以此类推为V2.0,V3.0.......

//

//*****************************************************************************

//

// 【功能】:头文件定义

//

//*****************************************************************************

#include <msp430x54x.h>

//*****************************************************************************

// 常量定义

//*****************************************************************************

#define WRITE_BURST 0x40 //连续写入

#define READ_SINGLE 0x80 //读

#define READ_BURST 0xC0 //连续读

#define BYTES_IN_RXFIFO 0x7F //接收缓冲区的有效字节数

#define CRC_OK 0x80 //CRC校验通过位标志

//*****************************************************************************

#define Set_CC1101_GDO0_1 P1OUT |= BIT0;

#define Clr_CC1101_GDO0_1 P1OUT &= ~BIT0;

#define Set_CC1101_GDO2_1 P1OUT |= BIT2;

#define Clr_CC1101_GDO2_1 P1OUT &= ~BIT2;

#define Set_CC1101_MISO_1 P1OUT |= BIT4;

#define Clr_CC1101_MISO_1 P1OUT &= ~BIT4;

#define Set_CC1101_MOSI_1 P1OUT |= BIT6;

#define Clr_CC1101_MOSI_1 P1OUT &= ~BIT6;

#define Set_CC1101_SCK_1 P2OUT |= BIT0;

#define Clr_CC1101_SCK_1 P2OUT &= ~BIT0;

#define Set_CC1101_CSN_1 P2OUT |= BIT2;

#define Clr_CC1101_CSN_1 P2OUT &= ~BIT2;

#define Set_CC1101_GDO0_2 P3OUT |= BIT0;

#define Clr_CC1101_GDO0_2 P3OUT &= ~BIT0;

#define Set_CC1101_GDO2_2 P3OUT |= BIT2;

#define Clr_CC1101_GDO2_2 P3OUT &= ~BIT2;

#define Set_CC1101_MISO_2 P3OUT |= BIT4;

#define Clr_CC1101_MISO_2 P3OUT &= ~BIT4;

#define Set_CC1101_MOSI_2 P3OUT |= BIT6;

#define Clr_CC1101_MOSI_2 P3OUT &= ~BIT6;

#define Set_CC1101_SCK_2 P4OUT |= BIT0;

#define Clr_CC1101_SCK_2 P4OUT &= ~BIT0;

#define Set_CC1101_CSN_2 P4OUT |= BIT2;

#define Clr_CC1101_CSN_2 P4OUT &= ~BIT2;

//*****************************************************************************

unsigned char PaTabel[8] = {0x60 ,0x60 ,0x60 ,0x60 ,0x60 ,0x60 ,0x60 ,0x60};

//*****************************************************************************

unsigned char TxBuf[4]={0x01,0x02,0x03,0x00};

unsigned char RxBuf[4]={0x11,0x22,0x33,0x00};

//*****************************************************************************

void InitSys();

void delay(unsigned int s);

void IOinit(void);

void SpiInit(void);

void CpuInit(void);

void RESET_CC1100(unsigned char ch);

void POWER_UP_RESET_CC1100(void);

void halSpiWriteReg(unsigned char addr, unsigned char value,unsigned char ch);

void halSpiWriteBurstReg(unsigned char addr, unsigned char *buffer, unsigned char count,unsigned char ch);

void halSpiStrobe(unsigned char strobe,unsigned char ch);

unsigned char halSpiReadReg(unsigned char addr,unsigned char ch);

void halSpiReadBurstReg(unsigned char addr, unsigned char *buffer, unsigned char count,unsigned char ch);

unsigned char halSpiReadStatus(unsigned char addr,unsigned char ch);

void halRfWriteRfSettings(void);

void halRfSendPacket(unsigned char *txBuffer, unsigned char size,unsigned char ch);

unsigned char halRfReceivePacket(unsigned char *rxBuffer, unsigned char *length,unsigned char ch);

unsigned char SpiTxRxByte(unsigned char dat,unsigned char ch);

void setRxMode(void);

//*****************************************************************************

// CC1100 STROBE, CONTROL AND STATUS REGSITER

#define CCxxx0_IOCFG2 0x00 // GDO2 output pin configuration

#define CCxxx0_IOCFG1 0x01 // GDO1 output pin configuration

#define CCxxx0_IOCFG0 0x02 // GDO0 output pin configuration

#define CCxxx0_FIFOTHR 0x03 // RX FIFO and TX FIFO thresholds

#define CCxxx0_SYNC1 0x04 // Sync word, high INT8U

#define CCxxx0_SYNC0 0x05 // Sync word, low INT8U

#define CCxxx0_PKTLEN 0x06 // Packet length

#define CCxxx0_PKTCTRL1 0x07 // Packet automation control

#define CCxxx0_PKTCTRL0 0x08 // Packet automation control

#define CCxxx0_ADDR 0x09 // Device address

#define CCxxx0_CHANNR 0x0A // Channel number

#define CCxxx0_FSCTRL1 0x0B // Frequency synthesizer control

#define CCxxx0_FSCTRL0 0x0C // Frequency synthesizer control

#define CCxxx0_FREQ2 0x0D // Frequency control word, high INT8U

#define CCxxx0_FREQ1 0x0E // Frequency control word, middle INT8U

#define CCxxx0_FREQ0 0x0F // Frequency control word, low INT8U

#define CCxxx0_MDMCFG4 0x10 // Modem configuration

#define CCxxx0_MDMCFG3 0x11 // Modem configuration

#define CCxxx0_MDMCFG2 0x12 // Modem configuration

#define CCxxx0_MDMCFG1 0x13 // Modem configuration

#define CCxxx0_MDMCFG0 0x14 // Modem configuration

#define CCxxx0_DEVIATN 0x15 // Modem deviation setting

#define CCxxx0_MCSM2 0x16 // Main Radio Control State Machine configuration

#define CCxxx0_MCSM1 0x17 // Main Radio Control State Machine configuration

#define CCxxx0_MCSM0 0x18 // Main Radio Control State Machine configuration

#define CCxxx0_FOCCFG 0x19 // Frequency Offset Compensation configuration

#define CCxxx0_BSCFG 0x1A // Bit Synchronization configuration

#define CCxxx0_AGCCTRL2 0x1B // AGC control

#define CCxxx0_AGCCTRL1 0x1C // AGC control

#define CCxxx0_AGCCTRL0 0x1D // AGC control

#define CCxxx0_WOREVT1 0x1E // High INT8U Event 0 timeout

#define CCxxx0_WOREVT0 0x1F // Low INT8U Event 0 timeout

#define CCxxx0_WORCTRL 0x20 // Wake On Radio control

#define CCxxx0_FREND1 0x21 // Front end RX configuration

#define CCxxx0_FREND0 0x22 // Front end TX configuration

#define CCxxx0_FSCAL3 0x23 // Frequency synthesizer calibration

#define CCxxx0_FSCAL2 0x24 // Frequency synthesizer calibration

#define CCxxx0_FSCAL1 0x25 // Frequency synthesizer calibration

#define CCxxx0_FSCAL0 0x26 // Frequency synthesizer calibration

#define CCxxx0_RCCTRL1 0x27 // RC oscillator configuration

#define CCxxx0_RCCTRL0 0x28 // RC oscillator configuration

#define CCxxx0_FSTEST 0x29 // Frequency synthesizer calibration control

#define CCxxx0_PTEST 0x2A // Production test

#define CCxxx0_AGCTEST 0x2B // AGC test

#define CCxxx0_TEST2 0x2C // Various test settings

#define CCxxx0_TEST1 0x2D // Various test settings

#define CCxxx0_TEST0 0x2E // Various test settings

// Strobe commands

#define CCxxx0_SRES 0x30 // Reset chip.

#define CCxxx0_SFSTXON 0x31 // Enable and calibrate frequency synthesizer (if MCSM0.FS_AUTOCAL=1).

// If in RX/TX: Go to a wait state where only the synthesizer is

// running (for quick RX / TX turnaround).

#define CCxxx0_SXOFF 0x32 // Turn off crystal oscillator.

#define CCxxx0_SCAL 0x33 // Calibrate frequency synthesizer and turn it off

// (enables quick start).

#define CCxxx0_SRX 0x34 // Enable RX. Perform calibration first if coming from IDLE and

// MCSM0.FS_AUTOCAL=1.

#define CCxxx0_STX 0x35 // In IDLE state: Enable TX. Perform calibration first if

// MCSM0.FS_AUTOCAL=1. If in RX state and CCA is enabled:

// Only go to TX if channel is clear.

#define CCxxx0_SIDLE 0x36 // Exit RX / TX, turn off frequency synthesizer and exit

// Wake-On-Radio mode if applicable.

#define CCxxx0_SAFC 0x37 // Perform AFC adjustment of the frequency synthesizer

#define CCxxx0_SWOR 0x38 // Start automatic RX polling sequence (Wake-on-Radio)

#define CCxxx0_SPWD 0x39 // Enter power down mode when CSn goes high.

#define CCxxx0_SFRX 0x3A // Flush the RX FIFO buffer.

#define CCxxx0_SFTX 0x3B // Flush the TX FIFO buffer.

#define CCxxx0_SWORRST 0x3C // Reset real time clock.

#define CCxxx0_SNOP 0x3D // No operation. May be used to pad strobe commands to two

// INT8Us for simpler software.

#define CCxxx0_PARTNUM 0x30

#define CCxxx0_VERSION 0x31

#define CCxxx0_FREQEST 0x32

#define CCxxx0_LQI 0x33

#define CCxxx0_RSSI 0x34

#define CCxxx0_MARCSTATE 0x35

#define CCxxx0_WORTIME1 0x36

#define CCxxx0_WORTIME0 0x37

#define CCxxx0_PKTSTATUS 0x38

#define CCxxx0_VCO_VC_DAC 0x39

#define CCxxx0_TXBYTES 0x3A

#define CCxxx0_RXBYTES 0x3B

#define CCxxx0_PATABLE 0x3E

#define CCxxx0_TXFIFO 0x3F

#define CCxxx0_RXFIFO 0x3F

// RF_SETTINGS is a data structure which contains all relevant CCxxx0 registers

typedef struct S_RF_SETTINGS

{

unsigned char FSCTRL2; //自已加的

unsigned char FSCTRL1; // Frequency synthesizer control.

unsigned char FSCTRL0; // Frequency synthesizer control.

unsigned char FREQ2; // Frequency control word, high INT8U.

unsigned char FREQ1; // Frequency control word, middle INT8U.

unsigned char FREQ0; // Frequency control word, low INT8U.

unsigned char MDMCFG4; // Modem configuration.

unsigned char MDMCFG3; // Modem configuration.

unsigned char MDMCFG2; // Modem configuration.

unsigned char MDMCFG1; // Modem configuration.

unsigned char MDMCFG0; // Modem configuration.

unsigned char CHANNR; // Channel number.

unsigned char DEVIATN; // Modem deviation setting (when FSK modulation is enabled).

unsigned char FREND1; // Front end RX configuration.

unsigned char FREND0; // Front end RX configuration.

unsigned char MCSM0; // Main Radio Control State Machine configuration.

unsigned char FOCCFG; // Frequency Offset Compensation Configuration.

unsigned char BSCFG; // Bit synchronization Configuration.

unsigned char AGCCTRL2; // AGC control.

unsigned char AGCCTRL1; // AGC control.

unsigned char AGCCTRL0; // AGC control.

unsigned char FSCAL3; // Frequency synthesizer calibration.

unsigned char FSCAL2; // Frequency synthesizer calibration.

unsigned char FSCAL1; // Frequency synthesizer calibration.

unsigned char FSCAL0; // Frequency synthesizer calibration.

unsigned char FSTEST; // Frequency synthesizer calibration control

unsigned char TEST2; // Various test settings.

unsigned char TEST1; // Various test settings.

unsigned char TEST0; // Various test settings.

unsigned char IOCFG2; // GDO2 output pin configuration

unsigned char IOCFG0; // GDO0 output pin configuration

unsigned char PKTCTRL1; // Packet automation control.

unsigned char PKTCTRL0; // Packet automation control.

unsigned char ADDR; // Device address.

unsigned char PKTLEN; // Packet length.

} RF_SETTINGS;

const RF_SETTINGS rfSettings =

{

0x00,

0x08, // FSCTRL1 Frequency synthesizer control.

0x00, // FSCTRL0 Frequency synthesizer control.

0x10, // FREQ2 Frequency control word, high byte.

0xA7, // FREQ1 Frequency control word, middle byte.

0x62, // FREQ0 Frequency control word, low byte.

0x5B, // MDMCFG4 Modem configuration.

0xF8, // MDMCFG3 Modem configuration.

0x03, // MDMCFG2 Modem configuration.

0x22, // MDMCFG1 Modem configuration.

0xF8, // MDMCFG0 Modem configuration.

0xff, // CHANNR Channel number.

0x47, // DEVIATN Modem deviation setting (when FSK modulation is enabled).

0xB6, // FREND1 Front end RX configuration.

0x10, // FREND0 Front end RX configuration.

0x18, // MCSM0 Main Radio Control State Machine configuration.

0x1D, // FOCCFG Frequency Offset Compensation Configuration.

0x1C, // BSCFG Bit synchronization Configuration.

0xC7, // AGCCTRL2 AGC control.

0x00, // AGCCTRL1 AGC control.

0xB2, // AGCCTRL0 AGC control.

0xEA, // FSCAL3 Frequency synthesizer calibration.

0x2A, // FSCAL2 Frequency synthesizer calibration.

0x00, // FSCAL1 Frequency synthesizer calibration.

0x11, // FSCAL0 Frequency synthesizer calibration.

0x59, // FSTEST Frequency synthesizer calibration.

0x81, // TEST2 Various test settings.

0x35, // TEST1 Various test settings.

0x09, // TEST0 Various test settings.

0x0B, // IOCFG2 GDO2 output pin configuration.

0x06, // IOCFG0D GDO0 output pin configuration. Refer to SmartRF?Studio User Manual for detailed pseudo register explanation.

0x04, // PKTCTRL1 Packet automation control.

0x05, // PKTCTRL0 Packet automation control.

0xff, // ADDR Device address.

0x0c // PKTLEN Packet length.

};

//*****************************************************************************

//

// 【名称】 IOinit

// 【功能】 单片机IO口初始化

// 【参数】 无

// 【返回】 无

// 【说明】 无

//

//*****************************************************************************

void IOinit(void)

{

P1DIR &= ~(BIT0 + BIT2 + BIT4);

P1DIR |= BIT6;

P2DIR |= BIT0 + BIT2;

P3DIR &= ~(BIT0 + BIT2 + BIT4);

P3DIR |= BIT6;

P4DIR |= BIT0 + BIT2;

P10DIR |= BIT6 + BIT7;

}

//*****************************************************************************

//

// 【名称】 delay

// 【功能】 软件延时

// 【参数】 S:时间

// 【返回】 无

// 【说明】 无

//

//*****************************************************************************

void delay(unsigned int s)

{

while (s != 0)

{

s--;

}

}

//*****************************************************************************

//

// 【名称】 InitSys

// 【功能】 晶振初始化

// 【参数】 无

// 【返回】 无

// 【说明】 无

//

//*****************************************************************************

void InitSys()

{

int i;

WDTCTL = WDTPW + WDTHOLD;

P5SEL |= 0x0C;

UCSCTL6 &= ~XT2DRIVE_1;

UCSCTL4 |= SELS__XT2CLK;

for(i=0xFF;i>0;i--);

UCSCTL7 &= ~(XT2OFFG + DCOFFG);

SFRIFG1 &= ~OFIFG;

}

//*****************************************************************************

//

// 【名称】 halWait

// 【功能】 短延时

// 【参数】 timeout:时间

// 【返回】 无

// 【说明】 无

//

//*****************************************************************************

void halWait(unsigned int timeout)

{

do

{

_NOP();

_NOP();

_NOP();

_NOP();

_NOP();

_NOP();

_NOP();

_NOP();

_NOP();

_NOP();

_NOP();

_NOP();

_NOP();

_NOP();

_NOP();

_NOP();

}

while (--timeout);

}

//*****************************************************************************

//

// 【名称】 SpiInit

// 【功能】 无线通讯模块初始化

// 【参数】 无

// 【返回】 无

// 【说明】 无

//

//*****************************************************************************

void SpiInit(void)

{

Clr_CC1101_CSN_1;

Clr_CC1101_SCK_1;

Set_CC1101_CSN_1;

Clr_CC1101_CSN_2;

Clr_CC1101_SCK_2;

Set_CC1101_CSN_2;

}

//*****************************************************************************

//

// 【名称】 CpuInit

// 【功能】 单片机初始化

// 【参数】 无

// 【返回】 无

// 【说明】 无

//

//*****************************************************************************

void CpuInit(void)

{

InitSys();

IOinit();

SpiInit();

}

//*****************************************************************************

//

// 【名称】 SpiTxRxByte

// 【功能】 读写一字节

// 【参数】 dat:写入数据

// ch:通道

// 【返回】 状态值或读取值

// 【说明】 无

//

//*****************************************************************************

unsigned char SpiTxRxByte(unsigned char dat,unsigned char ch)

{

unsigned char i,temp;

temp = 0;

switch (ch)

{

case 1:

Clr_CC1101_SCK_1;

for(i=0; i<8; i++)

{

if(dat & 0x80)

{

Set_CC1101_MOSI_1;

}

else

{

Clr_CC1101_MOSI_1;

}

dat <<= 1;

Set_CC1101_SCK_1;

delay(20);

temp <<= 1;

if(P1IN&0x10)

{

temp++;

}

Clr_CC1101_SCK_1;

delay(20);

}

break;

case 2:

Clr_CC1101_SCK_2;

for(i=0; i<8; i++)

{

if(dat & 0x80)

{

Set_CC1101_MOSI_2;

}

else

{

Clr_CC1101_MOSI_2;

}

dat <<= 1;

Set_CC1101_SCK_2;

delay(20);

temp <<= 1;

if(P3IN&0x10)

{

temp++;

}

Clr_CC1101_SCK_2;

delay(10);

}

break;

}

return temp;

}

//*****************************************************************************

//

// 【名称】 RESET_CC1100

// 【功能】 复位芯片

// 【参数】 无

// 【返回】 无

// 【说明】 无

//

//*****************************************************************************

void RESET_CC1100(unsigned char ch)

{

switch (ch)

{

case 1:

Clr_CC1101_CSN_1;

while (P1IN & 0x10 );

SpiTxRxByte(CCxxx0_SRES,1);

while (P1IN & 0x10);

Set_CC1101_CSN_1;

break;

case 2:

Clr_CC1101_CSN_2;

while (P3IN & 0x10);

SpiTxRxByte(CCxxx0_SRES,2);

while (P3IN & 0x10);

Set_CC1101_CSN_2;

break;

}

}

//*****************************************************************************

//

// 【名称】 POWER_UP_RESET_CC1100

// 【功能】 上电复位

// 【参数】 无

// 【返回】 无

// 【说明】 无

//

//*****************************************************************************

void POWER_UP_RESET_CC1100(void)

{

Set_CC1101_CSN_1;

halWait(1);

Clr_CC1101_CSN_1;

halWait(1);

Set_CC1101_CSN_1;

halWait(41);

RESET_CC1100(1);

Set_CC1101_CSN_2;

halWait(1);

Clr_CC1101_CSN_2;

halWait(1);

Set_CC1101_CSN_2;

halWait(41);

RESET_CC1100(2);

}

//*****************************************************************************

//

// 【名称】 halSpiWriteReg

// 【功能】 写寄存器

// 【参数】 addr:地址

// value:值

// ch:模块通道

// 【返回】 无

// 【说明】 无

//

//*****************************************************************************

void halSpiWriteReg(unsigned char addr, unsigned char value,unsigned char ch)

{

switch (ch)

{

case 1:

Clr_CC1101_CSN_1;

while (P1IN & 0x10);

SpiTxRxByte(addr,1);

SpiTxRxByte(value,1);

Set_CC1101_CSN_1;

break;

case 2:

Clr_CC1101_CSN_2;

while (P3IN & 0x10);

SpiTxRxByte(addr,2);

SpiTxRxByte(value,2);

Set_CC1101_CSN_2;

break;

}

}

//*****************************************************************************

//

// 【名称】 halSpiWriteBurstReg

// 【功能】 连续写寄存器

// 【参数】 addr:地址

// *buffer:值

// count:个数

// ch:模块通道

// 【返回】 无

// 【说明】 无

//

//*****************************************************************************

void halSpiWriteBurstReg(unsigned char addr, unsigned char *buffer, unsigned char count,unsigned char ch)

{

unsigned char i, temp;

temp = addr | WRITE_BURST;

switch (ch)

{

case 1:

Clr_CC1101_CSN_1;

while (P1IN & 0x10);

SpiTxRxByte(temp,1);

for (i = 0; i < count; i++)

{

SpiTxRxByte(buffer[i],1);

}

Set_CC1101_CSN_1;

break;

case 2:

Clr_CC1101_CSN_2;

while (P3IN & 0x10);

SpiTxRxByte(temp,2);

for (i = 0; i < count; i++)

{

SpiTxRxByte(buffer[i],2);

}

Set_CC1101_CSN_2;

break;

}

}

//*****************************************************************************

//

// 【名称】 halSpiStrobe

// 【功能】 写命令

// 【参数】 strobe:命令

// ch:模块通道

// 【返回】 无

// 【说明】 无

//

//*****************************************************************************

void halSpiStrobe(unsigned char strobe,unsigned char ch)

{

switch (ch)

{

case 1:

Clr_CC1101_CSN_1;

while (P1IN & 0x10);

SpiTxRxByte(strobe,1);

Set_CC1101_CSN_1;

break;

case 2:

Clr_CC1101_CSN_2;

while (P3IN & 0x10);

SpiTxRxByte(strobe,2);

Set_CC1101_CSN_2;

break;

}

}

//*****************************************************************************

//

// 【名称】 halSpiReadReg

// 【功能】 读取状态

// 【参数】 addr:地址

// ch:模块通道

// 【返回】 状态值

// 【说明】 无

//

//*****************************************************************************

unsigned char halSpiReadReg(unsigned char addr,unsigned char ch)

{

unsigned char temp, value;

temp = addr|READ_SINGLE;

switch (ch)

{

case 1:

Clr_CC1101_CSN_1;

while (P1IN & 0x10);

SpiTxRxByte(temp,1);

value = SpiTxRxByte(0,1);

Set_CC1101_CSN_1;

break;

case 2:

Clr_CC1101_CSN_2;

while (P3IN & 0x10);

SpiTxRxByte(temp,2);

value = SpiTxRxByte(0,2);

Set_CC1101_CSN_2;

break;

}

return value;

}

//*****************************************************************************

//

// 【名称】 halSpiReadBurstReg

// 【功能】 读取状态

// 【参数】 addr:地址

// *buffer:返回值

// count:连续读取值

// ch:模块通道

// 【返回】 无

// 【说明】 无

//

//*****************************************************************************

void halSpiReadBurstReg(unsigned char addr, unsigned char *buffer, unsigned char count,unsigned char ch)

{

unsigned char i,temp;

temp = addr | READ_BURST;

switch (ch)

{

case 1:

Clr_CC1101_CSN_1;

while (P1IN & 0x10);

SpiTxRxByte(temp,1);

for (i = 0; i < count; i++)

{

buffer[i] = SpiTxRxByte(0,1);

}

Set_CC1101_CSN_1;

break;

case 2:

Clr_CC1101_CSN_2;

while (P3IN & 0x10);

SpiTxRxByte(temp,2);

for (i = 0; i < count; i++)

{

buffer[i] = SpiTxRxByte(0,2);

}

Set_CC1101_CSN_2;

break;

}

}

//*****************************************************************************

//

// 【名称】 halSpiReadStatus

// 【功能】 读取状态

// 【参数】 addr:地址

// ch:模块通道

// 【返回】 状态值

// 【说明】 无

//

//*****************************************************************************

unsigned char halSpiReadStatus(unsigned char addr,unsigned char ch)

{

unsigned char value,temp;

temp = addr | READ_BURST;

switch (ch)

{

case 1:

Clr_CC1101_CSN_1;

while (P1IN & 0x10);

SpiTxRxByte(temp,1);

value = SpiTxRxByte(0,1);

Set_CC1101_CSN_1;

break;

case 2:

Clr_CC1101_CSN_2;

while (P3IN & 0x10);

SpiTxRxByte(temp,2);

value = SpiTxRxByte(0,2);

Set_CC1101_CSN_2;

break;

}

return value;

}

//*****************************************************************************

//

// 【名称】 halRfWriteRfSettings

// 【功能】 寄存器设置

// 【参数】 无

// 【返回】 无

// 【说明】 无

//

//*****************************************************************************

void halRfWriteRfSettings(void)

{

halSpiWriteReg(CCxxx0_FSCTRL0, rfSettings.FSCTRL2,1);

halSpiWriteReg(CCxxx0_FSCTRL1, rfSettings.FSCTRL1,1);

halSpiWriteReg(CCxxx0_FSCTRL0, rfSettings.FSCTRL0,1);

halSpiWriteReg(CCxxx0_FREQ2, rfSettings.FREQ2,1);

halSpiWriteReg(CCxxx0_FREQ1, rfSettings.FREQ1,1);

halSpiWriteReg(CCxxx0_FREQ0, rfSettings.FREQ0,1);

halSpiWriteReg(CCxxx0_MDMCFG4, rfSettings.MDMCFG4,1);

halSpiWriteReg(CCxxx0_MDMCFG3, rfSettings.MDMCFG3,1);

halSpiWriteReg(CCxxx0_MDMCFG2, rfSettings.MDMCFG2,1);

halSpiWriteReg(CCxxx0_MDMCFG1, rfSettings.MDMCFG1,1);

halSpiWriteReg(CCxxx0_MDMCFG0, rfSettings.MDMCFG0,1);

halSpiWriteReg(CCxxx0_CHANNR, rfSettings.CHANNR,1);

halSpiWriteReg(CCxxx0_DEVIATN, rfSettings.DEVIATN,1);

halSpiWriteReg(CCxxx0_FREND1, rfSettings.FREND1,1);

halSpiWriteReg(CCxxx0_FREND0, rfSettings.FREND0,1);

halSpiWriteReg(CCxxx0_MCSM0 , rfSettings.MCSM0,1);

halSpiWriteReg(CCxxx0_FOCCFG, rfSettings.FOCCFG,1);

halSpiWriteReg(CCxxx0_BSCFG, rfSettings.BSCFG,1);

halSpiWriteReg(CCxxx0_AGCCTRL2, rfSettings.AGCCTRL2,1);

halSpiWriteReg(CCxxx0_AGCCTRL1, rfSettings.AGCCTRL1,1);

halSpiWriteReg(CCxxx0_AGCCTRL0, rfSettings.AGCCTRL0,1);

halSpiWriteReg(CCxxx0_FSCAL3, rfSettings.FSCAL3,1);

halSpiWriteReg(CCxxx0_FSCAL2, rfSettings.FSCAL2,1);

halSpiWriteReg(CCxxx0_FSCAL1, rfSettings.FSCAL1,1);

halSpiWriteReg(CCxxx0_FSCAL0, rfSettings.FSCAL0,1);

halSpiWriteReg(CCxxx0_FSTEST, rfSettings.FSTEST,1);

halSpiWriteReg(CCxxx0_TEST2, rfSettings.TEST2,1);

halSpiWriteReg(CCxxx0_TEST1, rfSettings.TEST1,1);

halSpiWriteReg(CCxxx0_TEST0, rfSettings.TEST0,1);

halSpiWriteReg(CCxxx0_IOCFG2, rfSettings.IOCFG2,1);

halSpiWriteReg(CCxxx0_IOCFG0, rfSettings.IOCFG0,1);

halSpiWriteReg(CCxxx0_PKTCTRL1, rfSettings.PKTCTRL1,1);

halSpiWriteReg(CCxxx0_PKTCTRL0, rfSettings.PKTCTRL0,1);

halSpiWriteReg(CCxxx0_ADDR, rfSettings.ADDR,1);

halSpiWriteReg(CCxxx0_PKTLEN, rfSettings.PKTLEN,1);

halSpiWriteReg(CCxxx0_FSCTRL0, rfSettings.FSCTRL2,2);

halSpiWriteReg(CCxxx0_FSCTRL1, rfSettings.FSCTRL1,2);

halSpiWriteReg(CCxxx0_FSCTRL0, rfSettings.FSCTRL0,2);

halSpiWriteReg(CCxxx0_FREQ2, rfSettings.FREQ2,2);

halSpiWriteReg(CCxxx0_FREQ1, rfSettings.FREQ1,2);

halSpiWriteReg(CCxxx0_FREQ0, rfSettings.FREQ0,2);

halSpiWriteReg(CCxxx0_MDMCFG4, rfSettings.MDMCFG4,2);

halSpiWriteReg(CCxxx0_MDMCFG3, rfSettings.MDMCFG3,2);

halSpiWriteReg(CCxxx0_MDMCFG2, rfSettings.MDMCFG2,2);

halSpiWriteReg(CCxxx0_MDMCFG1, rfSettings.MDMCFG1,2);

halSpiWriteReg(CCxxx0_MDMCFG0, rfSettings.MDMCFG0,2);

halSpiWriteReg(CCxxx0_CHANNR, rfSettings.CHANNR,2);

halSpiWriteReg(CCxxx0_DEVIATN, rfSettings.DEVIATN,2);

halSpiWriteReg(CCxxx0_FREND1, rfSettings.FREND1,2);

halSpiWriteReg(CCxxx0_FREND0, rfSettings.FREND0,2);

halSpiWriteReg(CCxxx0_MCSM0 , rfSettings.MCSM0,2);

halSpiWriteReg(CCxxx0_FOCCFG, rfSettings.FOCCFG,2);

halSpiWriteReg(CCxxx0_BSCFG, rfSettings.BSCFG,2);

halSpiWriteReg(CCxxx0_AGCCTRL2, rfSettings.AGCCTRL2,2);

halSpiWriteReg(CCxxx0_AGCCTRL1, rfSettings.AGCCTRL1,2);

halSpiWriteReg(CCxxx0_AGCCTRL0, rfSettings.AGCCTRL0,2);

halSpiWriteReg(CCxxx0_FSCAL3, rfSettings.FSCAL3,2);

halSpiWriteReg(CCxxx0_FSCAL2, rfSettings.FSCAL2,2);

halSpiWriteReg(CCxxx0_FSCAL1, rfSettings.FSCAL1,2);

halSpiWriteReg(CCxxx0_FSCAL0, rfSettings.FSCAL0,2);

halSpiWriteReg(CCxxx0_FSTEST, rfSettings.FSTEST,2);

halSpiWriteReg(CCxxx0_TEST2, rfSettings.TEST2,2);

halSpiWriteReg(CCxxx0_TEST1, rfSettings.TEST1,2);

halSpiWriteReg(CCxxx0_TEST0, rfSettings.TEST0,2);

halSpiWriteReg(CCxxx0_IOCFG2, rfSettings.IOCFG2,2);

halSpiWriteReg(CCxxx0_IOCFG0, rfSettings.IOCFG0,2);

halSpiWriteReg(CCxxx0_PKTCTRL1, rfSettings.PKTCTRL1,2);

halSpiWriteReg(CCxxx0_PKTCTRL0, rfSettings.PKTCTRL0,2);

halSpiWriteReg(CCxxx0_ADDR, rfSettings.ADDR,2);

halSpiWriteReg(CCxxx0_PKTLEN, rfSettings.PKTLEN,2);

}

//*****************************************************************************

//

// 【名称】 halRfSendPacket

// 【功能】 一数据包发送函数

// 【参数】 *txBuffer:发送指针

// size:数据长度

// ch:模块通道

// 【返回】 无

// 【说明】 无

//

//*****************************************************************************

void halRfSendPacket(unsigned char *txBuffer, unsigned char size,unsigned char ch)

{

switch (ch)

{

case 1:

halSpiWriteReg(CCxxx0_TXFIFO, size,1);

halSpiWriteBurstReg(CCxxx0_TXFIFO, txBuffer, size,1);

halSpiStrobe(CCxxx0_STX,1);

while (!(P1IN&0x01));

while (P1IN&0x01);

halSpiStrobe(CCxxx0_SFTX,1);

break;

case 2:

halSpiWriteReg(CCxxx0_TXFIFO, size,2);

halSpiWriteBurstReg(CCxxx0_TXFIFO, txBuffer, size,2);

halSpiStrobe(CCxxx0_STX,2);

while (!(P3IN&0x01));

while (P3IN&0x01);

halSpiStrobe(CCxxx0_SFTX,2);

break;

}

}

//*****************************************************************************

//

// 【名称】 halRfReceivePacket

// 【功能】 一数据包接收函数

// 【参数】 *rxBuffer:接收指针

// *length:数据长度

// ch:模块通道

// 【返回】 接收成功与否。

// 【说明】 无

//

//*****************************************************************************

unsigned char halRfReceivePacket(unsigned char *rxBuffer, unsigned char *length,unsigned char ch)

{

unsigned char status[2],a;

unsigned char packetLength;

unsigned char i=(*length)*4;

switch (ch)

{

case 1:

halSpiStrobe(CCxxx0_SRX,1);

delay(2);

while (P1IN&0x01)

{

delay(2);

--i;

if(i<1)

{

a=0;

}

}

if ((halSpiReadStatus(CCxxx0_RXBYTES,1) & BYTES_IN_RXFIFO))

{

packetLength = halSpiReadReg(CCxxx0_RXFIFO,1);

if (packetLength <= *length)

{

halSpiReadBurstReg(CCxxx0_RXFIFO, rxBuffer, packetLength,1);

*length = packetLength;

halSpiReadBurstReg(CCxxx0_RXFIFO, status,2,1);

halSpiStrobe(CCxxx0_SFRX,1);

a=status[1] & CRC_OK;

}

else

{

*length = packetLength;

halSpiStrobe(CCxxx0_SFRX,1);

a=0;

}

}

else

{

a=0;

}

break;

case 2:

halSpiStrobe(CCxxx0_SRX,2);

delay(2);

while (P3IN&0x01)

{

delay(2);

--i;

if(i<1)

{

a=0;

}

}

if ((halSpiReadStatus(CCxxx0_RXBYTES,2) & BYTES_IN_RXFIFO))

{

packetLength = halSpiReadReg(CCxxx0_RXFIFO,2);

if (packetLength <= *length)

{

halSpiReadBurstReg(CCxxx0_RXFIFO, rxBuffer, packetLength,2);

*length = packetLength;

halSpiReadBurstReg(CCxxx0_RXFIFO, status,2,2);

halSpiStrobe(CCxxx0_SFRX,2);

a=status[1] & CRC_OK;

}

else

{

*length = packetLength;

halSpiStrobe(CCxxx0_SFRX,2);

a=0;

}

}

else

{

a=0;

}

break;

}

return a;

}

//*****************************************************************************

//

// 【名称】 main

// 【功能】 主函数

// 【参数】 无

// 【返回】 无

// 【说明】 无

//

//*****************************************************************************

void main(void)

{

unsigned char leng = 4;

CpuInit();

POWER_UP_RESET_CC1100();

halRfWriteRfSettings();

halSpiWriteBurstReg(CCxxx0_PATABLE, PaTabel, 8,1);

halSpiWriteBurstReg(CCxxx0_PATABLE, PaTabel, 8,2);

for(;;)

{

TxBuf[0]=0x01;

TxBuf[1]=0x02;

TxBuf[2]=0x03;

TxBuf[3]=0x00;

halRfSendPacket(TxBuf,leng,1); // Transmit Tx buffer data

delay(10000);

if(halRfReceivePacket(RxBuf,&leng,2))

{

RxBuf[3]='';

P10OUT |= BIT6;

P10OUT &= ~BIT7;

RxBuf[0]=0x11;

RxBuf[1]=0x22;

RxBuf[2]=0x33;

RxBuf[3]=0x00;

&n

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