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技術資料>51單片機

cc1101的詳解及單片機程序

發(fā)布時間:2018-03-26   瀏覽量:

1.初始化SPI,MCU各引腳。

    
        當有數據接收或發(fā)送狀態(tài)聲明時,有中斷和查詢兩種方式。GDO0與GDO2引腳輸出至MCU引腳,若要用中斷則要接至MCU外部中斷引腳,查詢時則可用GPIO。
 
    2.復位CC1101。
 
    3.初始化CC1101。(寫操作時可從SO中讀出CC1101狀態(tài))
 
        初始化后CC1100為IDLE狀態(tài).
    
    4.狀態(tài)機轉換,寫/讀FIFO數據。
 
        每次寫操作時SO返回的值為寫操作前的CC1100狀態(tài)值,具體值見Table20;讀狀態(tài)命令為當前CC1100狀態(tài)值,具體值見寄存器0X35說明;注意兩者區(qū)別。
 
快速認識Cc1100
 
             Cc1100可以工作在同步模式下,代價是:MCU自己控制前導碼。本系統(tǒng)中,Cc1100將工作在異步模式下。
  
知識點
 
             Head Byte:在 引腳 Cc1100.Csn 有效后,通過SPI總線寫入 Cc1100的第一個字節(jié)。
 
             Status Byte: 在寫入 HeadByte 的同時,MCU 得到 Status Byte。
 
             Burst Bit:在 Head Byte 中的一個 Bit, 有效值=="1",無效值=="0"
 
GDO0:
             GDO0可用作FIFO狀態(tài)輸出,載波感應(CS),時鐘輸出,GDO0 腳也能用作集成于芯片的模擬溫度傳感器(未用).配置寄存器為IOCFG0(0X02),現(xiàn)在配置為RX模式下數據狀態(tài)反應輸出.
 
GDO1:
             GDO1與SPI的SO共用引腳,默認狀態(tài)下為3態(tài),當CSn為低電平時,此引腳SPI的SO功能生效。配置寄存器為IOCFG0(0X01),現(xiàn)在配置為空閑狀態(tài)下3態(tài),SPI模式下SO.
 
GDO2:
 
             GDO2可用作FIFO狀態(tài)輸出,載波感應(CS),時鐘輸出,配置寄存器為IOCFG0(0X00),現(xiàn)在配置為載波感應(CS)輸出.
 
TXOFF_MODE/RXOFF_MODE:
 
             注意,此配置為在數據包被發(fā)送/接收后狀態(tài)機狀態(tài)決定位,僅是在發(fā)生發(fā)送或者接收后動作;當為IDLE時發(fā)SRX/STX后狀態(tài)機不按此配置運行。TX/RX后要校準。
 
功率放大控制(PATABLE):
 
             0X3E為功率寫入地址,0X22為為功率配置寄存器。PATABLE 是一個8字節(jié)表,定義了8個PA 功率值。這個表從最低位(0)到最高位(7)可讀和寫,一次一位。一個索引計數器用來控制對這個表的訪問。
 
             每讀出或寫入表中的一個字節(jié),計數器就加 1。當 CSn 為高時,計數值置為最小值。當達到最大值時,計數器由零重新開始計數。
    
             FREND0.PA_POWER(2:0)從8個功率值中選擇1個,且振幅為相應數等級。
 
 
異步模式:
             在此模式下,CC1101中的MCU的若干支持機制會停用,包括數據包硬件處理,F(xiàn)IFO 緩沖,數據白化,交錯(interleaver)和前向糾錯(FEC) ,曼徹斯特編碼(Manchester encoding);
 
             MSK不支持異步模式;
 
             PKTCTRL0.PKT_FORMAT == 3 使能異步模式,GDO0為input,GDO0, GDO1或GDO2為output 相應配置位為IOCFG0.GDO0_CFG, IOCFG1.GDO1_CFG IOCFG2.GDO2_CFG;
 
電磁波激活(WOR):
 
             在WOR濾波使用之前RC振蕩器必須啟用,RC振蕩器是 WOR 定時器的時鐘源.在WOR下,收到信號后會自動進入RX模式.
 
載波感應(CS)與RSSI:
 
             因此兩配置相互有連系,所以一起論述.
 
             RSSI 只能在RX模式下才能有效,作用為對當前信號質量評估,信號質量可從RSSI寄存器讀出.RSSI信號強度可從0X34取出.
 
             RSSI(信號強度)計算公式: 注:此為433M下,結果為負數,
 
                                            RSSI_dBm=(RSSI-256)/2-74 (RSSI>=128)
 
                                            RSSI_dBm= (RSSI/2)-74      (RSSI<128)
 
             CS 只在RX模式下才能有效,當信號質量高于設定門限值時,CS狀態(tài)將會被聲明。現(xiàn)在配置為GDO2輸出感應狀態(tài).
 
             CS門限值由以下4個寄存器決定
 
             ?? AGCCTRL2.MAX_LNA_GAIN  
             ?? AGCCTRL2.MAX_DVGA_GAIN
             ?? AGCCTRL1.CARRIER_SENSE_ABS_THR
             ?? AGCCTRL2.MAGN_TARGET
             
             CS門限值計算公式:     表默認門限值 + (MAGN_TARGET-33) + CARRIER_SENSE_ABS_THR.
 
                                           表默認門限值見table29,table30. 由AGCCTRL2.MAX_LNA_GAIN   AGCCTRL2.MAX_DVGA_GAIN 決定.
 
                                          默認門限值表只給了兩個數據速率下的值,其余由自己測.我們對此要求不是太高,可以參考用這個表.
 
                                           CARRIER_SENSE_ABS_THR為對應表中-7~7的值,最后單位為dBm.
 
                                           Example:
 
                                                         在250K下AGCCTRL2.MAX_LNA_GAIN = 00   AGCCTRL2.MAX_DVGA_GAIN = 00 得出表中為-90.5
 
                                                          MAGN_TARGET = 7(42), CARRIER_SENSE_ABS_THR = 1(1)
 
                                                         門限為-90.5 + (42-33) + 1= -82.5dBm            
 
清理信道訪問(CCA):

             清理信道訪問用來指示當前信號是空閑還是忙。當忙時是否丟棄當前數據,寄存器MCSM1.CCA_MODE決定是否丟棄.默認配置為保留當前寄存器中數據,丟棄下一步要處理數據.

 

數據FIFO:

          

 
             當TX操作時,由MCU控制,溢出時CC1101出錯;當RX操作時,讀空時CC1101出錯
 
             RX FIFO 和 TX FIFO 中的字節(jié)數也能分別從狀態(tài)寄存器 RXBYTES.NUM_RXBYTES和TXBYTES.NUM_TXBYTES 中讀出
 
             4 位 FIFOTHR.FIFO_THR 設置用來控制FIFO 門限點
 
             讀單字節(jié)時,,CSn繼續(xù)保持低;。突發(fā)訪問方式允許一地址字節(jié),然后是連續(xù)的數據字節(jié),直到通過設置 CSn 為高來斷訪問
            
             當寫操作時,最后一個字節(jié)被傳送至 SI 腳后, 被 SO腳接收的狀態(tài)位會表明在 TX FIFO中只有一個字節(jié)是空閑,
 
寄存器分類
         
  Configration Registers

共47個,可讀,可寫

0x00~0x2E

    
  Status Registers

共14個,只讀

0x30~0x3D

    
  Command Strobe

共14個,只寫

尋址空間:0x30~0x3D

 

14個地址,對相應的地址進行寫,

就相當于激活了對應的命令

本系統(tǒng)是用到的Strobe:

CC1100_STROBE_RESET
CC1100_STROBE_ENTER_RX_MODE
CC1100_STROBE_ENTER_TX_MODE
CC1100_COMMAND_STROBE_SIDLE
CC1100_COMMAND_STROBE_SFRX

  
  TX FIFO 共64個,只寫    
  RX FIFO 共64個,只讀    
         
 
 
Status(Command)Registers操作:
 
     當地址為0X30~0X3D時
 
     burst為1:對Status Registers的操作
 
                   Status Registers只可讀,且只能一次讀一個字節(jié),不可寫                 
     burst為0:對Command Registers操作
 
                 寄存器的訪問和一個寄存器的操作一樣,但沒有數據被傳輸.寫完畢后,CC1100便執(zhí)行相應操作.
 
 
 
 
     讀寫FIFO,有兩種模式:單字節(jié)讀寫;Burst讀寫。
         單字節(jié)讀寫時序:
             1 Cc1100.Csn有效。
             2 寫入Head Byte。
              3 讀、寫一個1字節(jié)。
             4 Cc1100.Csn無效。
#include 
#include 
#define  INT8U  unsigned char
#define  INT16U  unsigned int
#define  WRITE_BURST      0x40      //連續(xù)寫入
#define  READ_SINGLE      0x80      //讀
#define  READ_BURST       0xC0      //連續(xù)讀
#define  BYTES_IN_RXFIFO     0x7F        //接收緩沖區(qū)的有效字節(jié)數
#define  CRC_OK              0x80       //CRC校驗通過位標志
//*****************************************************************************************
sbit  GDO0 =P1^3;
sbit  GDO2 =P3^2;
sbit MISO =P1^6;
sbit MOSI =P1^5;
sbit SCK =P1^7;
sbit CSN =P1^2;
//*****************************************************************************************
sbit    LED2    =P3^4;
sbit    LED1    =P3^5;
sbit    KEY1    =P3^6;
sbit    KEY2    =P3^7;
//*****************************************************************************************
sbit led3=P2^3;
sbit led2=P2^2;
sbit led1=P2^1;
sbit led0=P2^0;
//*****************************************************************************************
//INT8U PaTabel[8] = {0x60 ,0x60 ,0x60 ,0x60 ,0x60 ,0x60 ,0x60 ,0x60};
INT8U PaTabel[8] = {0xc0 ,0xc0 ,0xc0 ,0xc0 ,0xc0 ,0xc0 ,0xc0 ,0xc0};//修改發(fā)射功率
//*****************************************************************************************
void SpiInit(void);
void CpuInit(void);
void RESET_CC1100(void);
void POWER_UP_RESET_CC1100(void);
void halSpiWriteReg(INT8U addr, INT8U value);
void halSpiWriteBurstReg(INT8U addr, INT8U *buffer, INT8U count);
void halSpiStrobe(INT8U strobe);
INT8U halSpiReadReg(INT8U addr);
void halSpiReadBurstReg(INT8U addr, INT8U *buffer, INT8U count);
INT8U halSpiReadStatus(INT8U addr);
void halRfWriteRfSettings(void);
void halRfSendPacket(INT8U *txBuffer, INT8U size);
INT8U halRfReceivePacket(INT8U *rxBuffer, INT8U *length); 
//*****************************************************************************************
// 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
{
    INT8U FSCTRL2;   //自已加的
    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;
/////////////////////////////////////////////////////////////////
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.
 //0xf6, // MDMCFG4 chang by allen
    0xF8,   // MDMCFG3   Modem configuration. 
 //0x83, // MDMCFG3 chang by allen   data rate = 2.398K
    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.
    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.
 0x01, //PKTCTRL0  crc disable chang by allen at 09.12.24
    0x00,   // ADDR      Device address.
    0x0c    // PKTLEN    Packet length.
};
//*****************************************************************************************
//函數名:delay(unsigned int s)
//輸入:時間
//輸出:無
//功能描述:普通廷時,內部用
//*****************************************************************************************  
static void delay(unsigned int s)
{
 unsigned int i;
 for(i=0; i sync transmitted
    while (!GDO0);
    // Wait for GDO0 to be cleared -> end of packet
    while (GDO0);
 halSpiStrobe(CCxxx0_SFTX);
 delay(20);
}

void setRxMode(void)
{
    halSpiStrobe(CCxxx0_SRX);  //進入接收狀態(tài)
}
/*
// Bit masks corresponding to STATE[2:0] in the status byte returned on MISO
#define CCxx00_STATE_BM                 0x70
#define CCxx00_FIFO_BYTES_AVAILABLE_BM  0x0F
#define CCxx00_STATE_TX_BM              0x20
#define CCxx00_STATE_TX_UNDERFLOW_BM    0x70
#define CCxx00_STATE_RX_BM              0x10
#define CCxx00_STATE_RX_OVERFLOW_BM     0x60
#define CCxx00_STATE_IDLE_BM            0x00
static INT8U RfGetRxStatus(void)
{
 INT8U temp, spiRxStatus1,spiRxStatus2;
 INT8U i=4;// 循環(huán)測試次數
    temp = CCxxx0_SNOP|READ_SINGLE;//讀寄存器命令
 CSN = 0;
 while (MISO);
 SpiTxRxByte(temp);
 spiRxStatus1 = SpiTxRxByte(0);
 do
 {
  SpiTxRxByte(temp);
  spiRxStatus2 = SpiTxRxByte(0);
  if(spiRxStatus1 == spiRxStatus2)
  {
   if( (spiRxStatus1 & CCxx00_STATE_BM) == CCxx00_STATE_RX_OVERFLOW_BM)
   {
               halSpiStrobe(CCxxx0_SFRX);
      return 0;
   }
      return 1;
  }
   spiRxStatus1=spiRxStatus2;
 }
 while(i--);
 CSN = 1;
    return 0; 
}
 */
INT8U halRfReceivePacket(INT8U *rxBuffer, INT8U *length)
{
    INT8U status[2];
    INT8U packetLength;
 INT8U i=(*length)*4;  // 具體多少要根據datarate和length來決定
    halSpiStrobe(CCxxx0_SRX);  //進入接收狀態(tài)
 //delay(5);
    //while (!GDO1);
    //while (GDO1);
 delay(2);
 while (GDO0)
 {
  delay(2);
  --i;
  if(i<1)
     return 0;     
 }
    if ((halSpiReadStatus(CCxxx0_RXBYTES) & BYTES_IN_RXFIFO)) //如果接的字節(jié)數不為0
 {
        //LED2 = 0;
  packetLength = halSpiReadReg(CCxxx0_RXFIFO);//讀出第一個字節(jié),此字節(jié)為該幀數據長度
        //if (packetLength <= *length)   //如果所要的有效數據長度小于等于接收到的數據包的長度
  if(packetLength == 0x08)
  {
            //halSpiReadBurstReg(CCxxx0_RXFIFO, rxBuffer, packetLength); //讀出所有接收到的數據
   halSpiReadBurstReg(CCxxx0_RXFIFO, rxBuffer, 8); //讀出所有接收到的數據
            *length = packetLength;    //把接收數據長度的修改為當前數據的長度
       
            // Read the 2 appended status bytes (status[0] = RSSI, status[1] = LQI)
            //halSpiReadBurstReg(CCxxx0_RXFIFO, status, 2);  //讀出CRC校驗位
   halSpiStrobe(CCxxx0_SFRX);  //清洗接收緩沖區(qū)
  // delay(2);
  // halSpiStrobe(CCxxx0_SRX);  //進入接收狀態(tài)
  // delay(20);
   //delay(200);
   return 1;
            //return (status[1] & CRC_OK);   //如果校驗成功返回接收成功
        }
   else
  {
            *length = packetLength;
            halSpiStrobe(CCxxx0_SFRX);  //清洗接收緩沖區(qū)
  // delay(2);
  // halSpiStrobe(CCxxx0_SRX);  //進入接收狀態(tài)
  // delay(20);
  // LED2 = 1;
            return 0;
        }
    }
  return 0;
}

void main(void)
{
 unsigned char key1_flag = 0;
 bit key2_flag = 0;
 unsigned int key1_scan_cnt = 400;
 unsigned int key2_scan_cnt = 300;
 INT8U i = 0;
 INT8U leng =0;
 INT8U tf =0;
 INT8U TxBuf[8]={1,2,3,4,5,6,7,8};  // 8字節(jié), 如果需要更長的數據包,請正確設置
 INT8U RxBuf[8]={0}; 
 CpuInit();
 POWER_UP_RESET_CC1100();
 halRfWriteRfSettings();
 halSpiWriteBurstReg(CCxxx0_PATABLE, PaTabel, 8);
 //halSpiStrobe(CCxxx0_SRX);  //進入接收狀態(tài)
 //setRxMode();
 while(1)
 {
     //setRxMode();
  delay(10);
     if(KEY1 == 0)
    {
   key1_scan_cnt--;
   if(!key1_scan_cnt)
   {   
    key1_scan_cnt = 300;
    if(key1_flag == 0)//判斷按鍵是否第1次按下
    {
     key1_flag = 1;//按鍵第1次按下標志位 
    }
   }
     }
  else
  {
   key1_scan_cnt = 300;
   if(key1_flag == 1)//判斷是否第一次按鍵動作松開
   {
    led1 = 0;
    led0 = 0;
    key1_flag = 2;
    key1_scan_cnt = 3;
    TxBuf[0] = 0x77;//第1個字節(jié)為0x77的數據幀,接收方收到后不需要返回應答
    while(1)
    {        
     halRfSendPacket(TxBuf,8); // Transmit Tx buffer data
     delay(100);    
     if(KEY1 == 0)//檢測按鍵是否第2次按下
     {
      key1_scan_cnt--;
      if(!key1_scan_cnt)
      {
       key1_flag = 3;//按鍵第2次按下
       key1_scan_cnt = 300;
       led1 = 1;
       led0 = 1;
       break;//當按鍵再次按下時退出長發(fā)狀態(tài)
      }
     }
     else//沒有第2次的按鍵動作
     {
      key1_scan_cnt = 3;
     }
    }
   }
   else if(key1_flag == 3)//是否為第2次的按鍵動作松開
   {
    key1_flag = 0;
   }
  }
 
     if(KEY2 == 0)
    {
   key2_scan_cnt--;
   if(!key2_scan_cnt)//確認按鍵正常按下
   {   
    key2_scan_cnt = 300;    
    key2_flag = 1;//按鍵第1次按下標志位   
   }
     }
  else
  {
   key2_scan_cnt = 300;
   if(key2_flag)//按鍵彈起
   {
    LED1 = 0;
    key2_flag = 0;
    delay(1000);
    TxBuf[0] = 0x88;        
    halRfSendPacket(TxBuf,8);// Transmit Tx buffer data    
    LED1 = 1;   
   }
    }
  leng =8; // 預計接受8 bytes
     if(halRfReceivePacket(RxBuf,&leng))
 // if(!GDO0)
  {      
  // leng =8; // 預計接受8 bytes
  // if(halRfReceivePacket(RxBuf,&leng))
   {
    if(RxBuf[0] == 0x77)//接收到的數據不需要返回應答
    {
     LED2 = ~LED2;
    }
    else if(RxBuf[0] == 0x88)//判斷接收到的數據是否需要返回應答
    {
     LED2 = 0;//接收數據正確,開接收指示燈
     LED1 = 0;//準備發(fā)送應答,開發(fā)送指示燈
     delay(1000);
     TxBuf[0] = 0x99;
     halRfSendPacket(TxBuf,8); // Transmit Tx buffer data  返回應答
     LED2 = 1;
     LED1 = 1;
    }
    else if(RxBuf[0] == 0x99)//應答數據
    {
     LED2 = 0;
     delay(1000);
     LED2 = 1;
    }
   }
  }
 } 
}