STM32F103和CC1101通信

只看该作者 · 2016-6-25 17:32

STM32连接CC1101模块连接的时候，程序一直死在
// Wait for GDO0 to be set -> sync transmitted
while (!GD0_BIT);
// Wait for GDO0 to be cleared -> end of packet
while (GD0_BIT);

；我想请教一下，CS, SI, SO, SCLK, GD0， GD2，这几个引脚是不是都要加上拉电阻？？

3万 · 2016-6-25 20:12

不用加，使用STM32内部上拉即可；

只看该作者 · 2016-6-26 08:48

有谁帮我看看源代码有没有问题？

只看该作者 · 2016-6-26 08:50

/************************************
* 文件名  ：rf1100se.c
* 描述 :
* 实验平台 :
* 硬件连接：
* 库版本  ：

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

#include "stm32f10x.h"
#include "stm32f10x_it.h"
#include "stm32f10x_rcc.h"
#include "misc.h"

#define  INT8U unsigned char
#define  INT16U unsigned int
#define  uclong unsigned long

//==================================主出从入====================================
#define  MOSI_0    GPIO_ResetBits(GPIOB, GPIO_Pin_3)
#define  MOSI_1    GPIO_SetBits(GPIOB, GPIO_Pin_3)
//===================================SPI时钟端口================================
#define  SCK_0    GPIO_ResetBits(GPIOA, GPIO_Pin_11)
#define  SCK_1    GPIO_SetBits(GPIOA, GPIO_Pin_11)
//==================================SPI使能端口=================================
#define  CSN_0    GPIO_ResetBits(GPIOA, GPIO_Pin_12)
#define  CSN_1    GPIO_SetBits(GPIOA, GPIO_Pin_12)

#define  MOSO_BIT GPIO_ReadInputDataBit(GPIOB,GPIO_Pin_15)
#define  GD0_BIT GPIO_ReadInputDataBit(GPIOB,GPIO_Pin_14)

//==============================================================================
#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
//*****************************************************************************************
// CC1100-CC1101  所有相关寄存器映射
#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
//******************************************************************************
//*****更多功率参数设置可详细参考DATACC1100英文文档中第48-49页的参数表**********
//INT8U PaTabel[8] = {0x04 ,0x04 ,0x04 ,0x04 ,0x04 ,0x04 ,0x04 ,0x04};  //-30dBm 功率最小
INT8U PaTabel[8] = {0x60 ,0x60 ,0x60 ,0x60 ,0x60 ,0x60 ,0x60 ,0x60};  //0dBm
//INT8U PaTabel[8] = {0xC0 ,0xC0 ,0xC0 ,0xC0 ,0xC0 ,0xC0 ,0xC0 ,0xC0}; //10dBm    功率最大
//=======================定义RF1100-1101寄存器结构体数组 =================================
typedef struct S_RF_SETTINGS
{
INT8U FSCTRL2;
INT8U FSCTRL1; // Frequency synthesizer control.
INT8U FSCTRL0; // Frequency synthesizer control.
INT8U FREQ2;    // Frequency control word, high INT8U.
INT8U FREQ1;    // Frequency control word, middle INT8U.
INT8U FREQ0;    // Frequency control word, low INT8U.
INT8U MDMCFG4; // Modem configuration.
INT8U MDMCFG3; // Modem configuration.
INT8U MDMCFG2; // Modem configuration.
INT8U MDMCFG1; // Modem configuration.
INT8U MDMCFG0; // Modem configuration.
INT8U CHANNR; // Channel number.
INT8U DEVIATN; // Modem deviation setting (when FSK modulation is enabled).
INT8U FREND1; // Front end RX configuration.
INT8U FREND0; // Front end RX configuration.
INT8U MCSM0;    // Main Radio Control State Machine configuration.
INT8U FOCCFG; // Frequency Offset Compensation Configuration.
INT8U BSCFG;    // Bit synchronization Configuration.
INT8U AGCCTRL2;  // AGC control.
INT8U AGCCTRL1;  // AGC control.
INT8U AGCCTRL0;  // AGC control.
INT8U FSCAL3; // Frequency synthesizer calibration.
INT8U FSCAL2; // Frequency synthesizer calibration.
INT8U FSCAL1; // Frequency synthesizer calibration.
INT8U FSCAL0; // Frequency synthesizer calibration.
INT8U FSTEST; // Frequency synthesizer calibration control
INT8U TEST2;    // Various test settings.
INT8U TEST1;    // Various test settings.
INT8U TEST0;    // Various test settings.
INT8U IOCFG2; // GDO2 output pin configuration
INT8U IOCFG0; // GDO0 output pin configuration
INT8U PKTCTRL1;  // Packet automation control.
INT8U PKTCTRL0;  // Packet automation control.
INT8U ADDR;    // Device address.
INT8U PKTLEN; // Packet length.
} RF_SETTINGS;
//==========================CC1100-1101寄存器配置===============================
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.

0x00, // 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. 0x0B
0x06, // IOCFG0D GDO0 output pin configuration. Refer to SmartRF?Studio User Manual for detailed pseudo register explanation. 0x06

0x04, // PKTCTRL1  Packet automation control.
0x05, // PKTCTRL0  Packet automation control.
0x00, // ADDR    Device address.
0xff // PKTLEN Packet length.最大
};

void RF1100_IO_set(void)
{
GPIO_InitTypeDef GPIO_InitStructure;

  RCC_APB2PeriphClockCmd(RCC_APB2Periph_GPIOA,ENABLE);
RCC_APB2PeriphClockCmd(RCC_APB2Periph_GPIOB,ENABLE);

//SO
GPIO_InitStructure.GPIO_Pin = GPIO_Pin_15;
GPIO_InitStructure.GPIO_Speed = GPIO_Speed_50MHz;
GPIO_InitStructure.GPIO_Mode = GPIO_Mode_IPU;
GPIO_Init(GPIOB, &GPIO_InitStructure);

//GD0
GPIO_InitStructure.GPIO_Pin = GPIO_Pin_14;
GPIO_InitStructure.GPIO_Speed = GPIO_Speed_50MHz;
GPIO_InitStructure.GPIO_Mode = GPIO_Mode_IPU;
GPIO_Init(GPIOB, &GPIO_InitStructure);

//SI
GPIO_InitStructure.GPIO_Pin = GPIO_Pin_3;
  GPIO_InitStructure.GPIO_Mode = GPIO_Mode_Out_PP;
  GPIO_InitStructure.GPIO_Speed = GPIO_Speed_50MHz;
  GPIO_Init(GPIOB, &GPIO_InitStructure);

//SCLK
GPIO_InitStructure.GPIO_Pin = GPIO_Pin_11;
  GPIO_InitStructure.GPIO_Mode = GPIO_Mode_Out_PP;
  GPIO_InitStructure.GPIO_Speed = GPIO_Speed_50MHz;
  GPIO_Init(GPIOA, &GPIO_InitStructure);

//CS
GPIO_InitStructure.GPIO_Pin = GPIO_Pin_12;
  GPIO_InitStructure.GPIO_Mode = GPIO_Mode_Out_PP;
  GPIO_InitStructure.GPIO_Speed = GPIO_Speed_50MHz;
  GPIO_Init(GPIOA, &GPIO_InitStructure);

}

//==============================================================================
//******************************************************************************
//函数名：delay(unsigned int s)
//输入：时间
//输出：无
//功能描述：普通廷时,内部用
//******************************************************************************
void delay(unsigned int s)
{
unsigned int i;
for(i=0; i<s; i++);
for(i=0; i<s; i++);
}
//========================延时约5ms=============================================
void Delay5ms(void)
{
INT16U i=40000;
while (i != 0)
{
      i--;
}
}
//******************************************************************************
void halWait(INT16U timeout)
{
char i;
do {
   for(i=0; i<20; i++);
} while (--timeout);
}
//******************************************************************************
//函数名：SpisendByte(INT8U dat)
//输入：发送的数据
//输出：无
//功能描述：SPI发送一个字节
//******************************************************************************
INT8U SpiTxRxByte(INT8U dat)
{
//----------------------以下是模拟SPI时序方式-----------------------------------
INT8U i,temp;
temp = 0;
SCK_0 ;
for(i=0; i<8; i++)
{
if(dat & 0x80)
{
            MOSI_1;
}
else
{
   MOSI_0;
}
dat <<= 1;
         SCK_1;
temp <<= 1;
if(MOSO_BIT)temp++;  //读取MISO状态
SCK_0 ;
}
return temp;
}
//******************************************************************************
//函数名：void RESET_CC1100(void)
//输入：无
//输出：无
//功能描述：复位CC1100
//******************************************************************************
void RESET_CC1100(void)
{
CSN_0 ;
while(MOSO_BIT); // (P1IN & 0x40);
SpiTxRxByte(CCxxx0_SRES); //写入复位命令
while(MOSO_BIT); // (P1IN & 0x40);
      CSN_1;
}
//******************************************************************************
//函数名：void POWER_UP_RESET_CC1100(void)
//输入：无
//输出：无
//功能描述：上电复位CC1100
//******************************************************************************
void POWER_UP_RESET_CC1100(void)
{
CSN_1;
halWait(1);
CSN_0 ;
halWait(1);
CSN_1;
halWait(41);
RESET_CC1100();    //复位CC1100
}
//******************************************************************************
//函数名：void halSpiWriteReg(INT8U addr, INT8U value)
//输入：地址和配置字
//输出：无
//功能描述：SPI写寄存器
//******************************************************************************
void halSpiWriteReg(INT8U addr, INT8U value)
{
CSN_0;
while(MOSO_BIT); // (P1IN& 0x40);
SpiTxRxByte(addr); //写地址
SpiTxRxByte(value); //写入配置
CSN_1;
}
//******************************************************************************
//函数名：void halSpiWriteBurstReg(INT8U addr, INT8U *buffer, INT8U count)
//输入：地址，写入缓冲区，写入个数
//输出：无
//功能描述：SPI连续写配置寄存器
//******************************************************************************
void halSpiWriteBurstReg(INT8U addr, INT8U *buffer, INT8U count)
{
INT8U i, temp;
temp = addr | WRITE_BURST;
CSN_0;
while(MOSO_BIT); // (P1IN & 0x40);
SpiTxRxByte(temp);
for (i = 0; i < count; i++)
{
      SpiTxRxByte(buffer[i]);
}
CSN_1;
}
//******************************************************************************
//函数名：void halSpiStrobe(INT8U strobe)
//输入：命令
//输出：无
//功能描述：SPI写命令
//******************************************************************************
void halSpiStrobe(INT8U strobe)
{
CSN_0;
while(MOSO_BIT); // (P1IN & 0x40);
SpiTxRxByte(strobe); //写入命令
CSN_1;
}
//******************************************************************************
//函数名：INT8U halSpiReadReg(INT8U addr)
//输入：地址
//输出：该寄存器的配置字
//功能描述：SPI读寄存器
//******************************************************************************
INT8U halSpiReadReg(INT8U addr)
{
INT8U temp, value;
temp = addr|READ_SINGLE;//读寄存器命令
CSN_0;
while(MOSO_BIT); //(P1IN & 0x40);
SpiTxRxByte(temp);
value = SpiTxRxByte(0);
CSN_1;
return value;
}
//***************************************************************************
//函数名：void halSpiReadBurstReg(INT8U addr, INT8U *buffer, INT8U count)
//输入：地址，读出数据后暂存的缓冲区，读出配置个数
//输出：无
//功能描述：SPI连续写配置寄存器
//******************************************************************************
void halSpiReadBurstReg(INT8U addr, INT8U *buffer, INT8U count)
{
INT8U i,temp;
temp = addr | READ_BURST; //写入要读的配置寄存器地址和读命令
CSN_0;
while(MOSO_BIT); //  (P1IN & 0x40);
SpiTxRxByte(temp);
for (i = 0; i < count; i++)
{
      buffer[i] = SpiTxRxByte(0);
}
CSN_1;
}
//******************************************************************************
//函数名：INT8U halSpiReadReg(INT8U addr)
//输入：地址
//输出：该状态寄存器当前值
//功能描述：SPI读状态寄存器
//******************************************************************************
INT8U halSpiReadStatus(INT8U addr)
{
INT8U value,temp;
temp = addr | READ_BURST; //写入要读的状态寄存器的地址同时写入读命令
CSN_0;
while(MOSO_BIT);  // (P1IN & 0x40);
SpiTxRxByte(temp);
value = SpiTxRxByte(0);
CSN_1;
return value;
}

只看该作者 · 2016-6-26 08:58

//******************************************************************************
//函数名：void halRfWriteRfSettings(RF_SETTINGS *pRfSettings)
//输入：无
//输出：无
//功能描述：配置CC1100的寄存器
//******************************************************************************
void halRfWriteRfSettings(void)
{
halSpiWriteReg(CCxxx0_FSCTRL0,  rfSettings.FSCTRL2);//自已加的
halSpiWriteReg(CCxxx0_FSCTRL1,  rfSettings.FSCTRL1);
halSpiWriteReg(CCxxx0_FSCTRL0,  rfSettings.FSCTRL0);
halSpiWriteReg(CCxxx0_FREQ2, rfSettings.FREQ2);
halSpiWriteReg(CCxxx0_FREQ1, rfSettings.FREQ1);
halSpiWriteReg(CCxxx0_FREQ0, rfSettings.FREQ0);
halSpiWriteReg(CCxxx0_MDMCFG4,  rfSettings.MDMCFG4);
halSpiWriteReg(CCxxx0_MDMCFG3,  rfSettings.MDMCFG3);
halSpiWriteReg(CCxxx0_MDMCFG2,  rfSettings.MDMCFG2);
halSpiWriteReg(CCxxx0_MDMCFG1,  rfSettings.MDMCFG1);
halSpiWriteReg(CCxxx0_MDMCFG0,  rfSettings.MDMCFG0);
halSpiWriteReg(CCxxx0_CHANNR, rfSettings.CHANNR);
halSpiWriteReg(CCxxx0_DEVIATN,  rfSettings.DEVIATN);
halSpiWriteReg(CCxxx0_FREND1, rfSettings.FREND1);
halSpiWriteReg(CCxxx0_FREND0, rfSettings.FREND0);
halSpiWriteReg(CCxxx0_MCSM0 , rfSettings.MCSM0 );
halSpiWriteReg(CCxxx0_FOCCFG, rfSettings.FOCCFG);
halSpiWriteReg(CCxxx0_BSCFG, rfSettings.BSCFG);
halSpiWriteReg(CCxxx0_AGCCTRL2, rfSettings.AGCCTRL2);
halSpiWriteReg(CCxxx0_AGCCTRL1, rfSettings.AGCCTRL1);
halSpiWriteReg(CCxxx0_AGCCTRL0, rfSettings.AGCCTRL0);
halSpiWriteReg(CCxxx0_FSCAL3, rfSettings.FSCAL3);
halSpiWriteReg(CCxxx0_FSCAL2, rfSettings.FSCAL2);
halSpiWriteReg(CCxxx0_FSCAL1, rfSettings.FSCAL1);
halSpiWriteReg(CCxxx0_FSCAL0, rfSettings.FSCAL0);
halSpiWriteReg(CCxxx0_FSTEST, rfSettings.FSTEST);
halSpiWriteReg(CCxxx0_TEST2, rfSettings.TEST2);
halSpiWriteReg(CCxxx0_TEST1, rfSettings.TEST1);
halSpiWriteReg(CCxxx0_TEST0, rfSettings.TEST0);
halSpiWriteReg(CCxxx0_IOCFG2, rfSettings.IOCFG2);
halSpiWriteReg(CCxxx0_IOCFG0, rfSettings.IOCFG0);
halSpiWriteReg(CCxxx0_PKTCTRL1, rfSettings.PKTCTRL1);
halSpiWriteReg(CCxxx0_PKTCTRL0, rfSettings.PKTCTRL0);
halSpiWriteReg(CCxxx0_ADDR,    rfSettings.ADDR);
halSpiWriteReg(CCxxx0_PKTLEN, rfSettings.PKTLEN);
}
//******************************************************************************
//函数名：void halRfSendPacket(INT8U *txBuffer, INT8U size)
//输入：发送的缓冲区，发送数据个数
//输出：无
//功能描述：CC1100发送一组数据
//******************************************************************************
void halRfSendPacket(INT8U *txBuffer, INT8U size)
{
halSpiWriteReg(CCxxx0_TXFIFO, size);
halSpiWriteBurstReg(CCxxx0_TXFIFO, txBuffer, size); //写入要发送的数据
halSpiStrobe(CCxxx0_STX); //进入发送模式发送数据
// Wait for GDO0 to be set -> sync transmitted
while (!GD0_BIT);
// Wait for GDO0 to be cleared -> end of packet
while (GD0_BIT);
halSpiStrobe(CCxxx0_SFTX);
}
//------------------------------------------------------------------------------
void setRxMode(void)
{
halSpiStrobe(CCxxx0_SRX); //进入接收状态
}
//------------------------------------------------------------------------------
INT8U halRfReceivePacket(INT8U *rxBuffer, INT8U *length)
{
INT8U status[2];
INT8U packetLength;
INT8U i=(*length)*4;  // 具体多少要根据datarate和length来决定
halSpiStrobe(CCxxx0_SRX); //进入接收状态
delay(580);
//while (P2IN & 0x80)
{
delay(100);
--i;
if(i<1)
   return 0;
}
if ((halSpiReadStatus(CCxxx0_RXBYTES) & BYTES_IN_RXFIFO)) //如果接的字节数不为0
{
      packetLength = halSpiReadReg(CCxxx0_RXFIFO);//读出第一个字节，此字节为该帧数据长度
      if (packetLength <= *length) //如果所要的有效数据长度小于等于接收到的数据包的长度
{
         halSpiReadBurstReg(CCxxx0_RXFIFO, rxBuffer, packetLength); //读出所有接收到的数据
         *length = packetLength; //把接收数据长度的修改为当前数据的长度
         // Read the 2 appended status bytes (status[0] = RSSI, status[1] = LQI)
         halSpiReadBurstReg(CCxxx0_RXFIFO, status, 2); //读出CRC校验位
halSpiStrobe(CCxxx0_SFRX); //清洗接收缓冲区
         return (status[1] & CRC_OK); //如果校验成功返回接收成功
      }
   else
{
         *length = packetLength;
         halSpiStrobe(CCxxx0_SFRX); //清洗接收缓冲区
         return 0;
      }
}
else
return 0;
}
//=============================================================================

void RF110SE_Init(void)
{
RF1100_IO_set();
POWER_UP_RESET_CC1100();
halRfWriteRfSettings();
halSpiWriteBurstReg(CCxxx0_PATABLE, PaTabel, 8);
delay(2000);

}

int main(void)
{
unsigned char leng =8;       // 8字节, 如果需要更长的数据包,请正确设置
unsigned char TxBuf[8];

  SystemInit(); //配置系统时钟为 72M
  RF110SE_Init();

TxBuf[0] = 0x01; TxBuf[1] = 0x02; TxBuf[2] = 0x03; TxBuf[3] = 0x04;
TxBuf[4] = 0x05; TxBuf[5] = 0x06; TxBuf[6] = 0x07; TxBuf[3] = 0x08;
leng = 8;
  while (1)
  {
halRfSendPacket(TxBuf,leng); // Transmit Tx buffer data
delay(2000);
  }
}

只看该作者 · 2016-6-26 08:59

我用芯片是STM32F103C8，请各位高手帮我看看

只看该作者 · 2016-6-26 09:51

STM32连接CC1101模块连接的时候，程序一直死在
// Wait for GDO0 to be set -> sync transmitted
while (!GD0_BIT);
// Wait for GDO0 to be cleared -> end of packet
while (GD0_BIT);
这两个代码改为延时10ms即可，用上面的代码很容易死机，我的程序就是这样做的