Athanassios Mavrogeorgiadis
/
CC1101_Transceiver
TI CC1101 Transceiver
Embed:
(wiki syntax)
Show/hide line numbers
CC1101.cpp
00001 00002 #include "CC1101.h" 00003 00004 #define RF_0db 00005 //#define RF_10db 00006 /////////////////////////////////////////////////////////////////////////////////////// 00007 CC1101::CC1101(PinName mosi, PinName miso, PinName clk, PinName csn, PinName RDmiso): 00008 _spi(mosi, miso, clk), _csn(csn), _RDmiso(RDmiso) 00009 { 00010 _csn = 1; 00011 00012 // Setup the spi for 8 bit data, high steady state clock, 00013 // second edge capture, with a 1MHz clock rate 00014 _spi.format(8,0); 00015 _spi.frequency(1000000); 00016 00017 POWER_UP_RESET_CCxxx0(); 00018 Strobe(CCxxx0_SRX); 00019 } 00020 /////////////////////////////////////////////////////////////////////////////////////// 00021 RF_SETTINGS rfSettings = // 433Mhz, 9600Bauds 00022 { 00023 0x06, // FSCTRL1 Frequency Synthesizer Control - IF:152.343Khz 00024 0x07, // IOCFG0 GDO0 Output Pin Configuration - Packet received and CRC OK 00025 0x00, // FSCTRL0 Frequency Synthesizer Control - Freq offset 00026 0x10, // FREQ2 Frequency Control Word, High Byte - 433.999 Mhz 00027 0xB1, // FREQ1 Frequency Control Word, Middle Byte 00028 0x3B, // FREQ0 Frequency Control Word, Low Byte 00029 0xF8, // MDMCFG4 Modem Configuration - BW: 58.035Khz 00030 0x83, // MDMCFG3 Modem Configuration - 9595 Baud 00031 0x13, // MDMCFG2 Modem Configuration - 30/32 sync word bits - Manchester disable - GFSK - Digital DC filter enable 00032 0x22, // MDMCFG1 Modem Configuration - num of preamble bytes:4 - FEC disable 00033 0xF8, // MDMCFG0 Modem Configuration - Channel spacing: 199.951Khz 00034 0x00, // CHANNR Channel Number 00035 0x15, // DEVIATN Modem Deviation Setting - 5.157Khz 00036 0x56, // FREND1 Front End RX Configuration 00037 0x10, // FREND0 Front End TX Configuration 00038 0x18, // MCSM0 Main Radio Control State Machine Configuration - PO timeout: 64(149-155us) - Auto calibrate from idle to rx/tx 00039 0x16, // FOCCFG Frequency Offset Compensation Configuration 00040 0x6C, // BSCFG Bit Synchronization Configuration 00041 0x03, // AGCCTRL2 AGC Control - target amplitude: 33dB - Maximum possible LNA + LNA 2 gain - All gain settings can be used 00042 0x40, // AGCCTRL1 AGC Control - LNA gain decreased first 00043 0x91, // AGCCTRL0 AGC Control - Medium hysterisis - Filter Samples: 16 - Normal AGC operation 00044 0xE9, // FSCAL3 Frequency Synthesizer Calibration 00045 0x2A, // FSCAL2 Frequency Synthesizer Calibration 00046 0x00, // FSCAL1 Frequency Synthesizer Calibration 00047 0x1F, // FSCAL0 Frequency Synthesizer Calibration 00048 0x59, // FSTEST Frequency Synthesizer Calibration Control 00049 0x88, // TEST2 Various Test Settings 00050 0x31, // TEST1 Various Test Settings 00051 0x09, // TEST0 Various Test Settings 00052 0x07, // FIFOTHR RX FIFO and TX FIFO Thresholds - Bytes in TX FIFO:33 - Bytes in RX FIFO:32 00053 0x06, // IOCFG2 GDO2 Output Pin Configuration - Sync word received/sent - end of packet 00054 0x04, // PKTCTRL1 Packet Automation Control - No address check - Automatic flush of RX FIFO is disable - sync word is always accepted 00055 0x05, // PKTCTRL0 Packet Automation Control - whitening is off - RX/TX data normal mode - CRC calculation in TX and CRC check in RX - Variable packet length 00056 0x00, // ADDR Device Address 00057 0xFF, // PKTLEN Packet Length 00058 0x3F, // MCSM1 Main Radio Control State Machine Configuration 00059 }; 00060 #ifdef RF_0db 00061 // PATABLE (0 dBm output power) 00062 char paTable[] = {0x60, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00}; 00063 #endif 00064 #ifdef RF_10db 00065 // PATABLE (10 dBm output power) 00066 char paTable[] = {0xC0, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00}; 00067 #endif 00068 /////////////////////////////////////////////////////////////////////////////////////// 00069 /////////////////////////////////////////////////////////////////////////////////////// 00070 // Macro to reset the CCxxx0 and wait for it to be ready 00071 void CC1101::RESET_CCxxx0(void) 00072 { 00073 // while (_RDmiso); 00074 _csn = 0; 00075 wait(0.000002); 00076 while (_RDmiso); 00077 _spi.write(CCxxx0_SRES); 00078 wait(0.000002); 00079 _csn = 1; 00080 } 00081 /////////////////////////////////////////////////////////////////////////////////////// 00082 // Macro to reset the CCxxx0 after power_on and wait for it to be ready 00083 // IMPORTANT NOTICE: 00084 // The file Wait.c must be included if this macro shall be used 00085 // The file is located under: ..\Lib\Chipcon\Hal\CCxx00 00086 // 00087 // min 40 us 00088 // <-----------------------> 00089 // CSn |--| |--------------------| |----------- 00090 // | | | | | 00091 // -- ---------- 00092 // 00093 // MISO |--------------- 00094 // - - - - - - - - - - - - - - - -| | 00095 // -- 00096 // Unknown / don't care 00097 // 00098 // MOSI - - - - - - - - - - - - - - - ---------- - - - - - 00099 // | SRES | 00100 // - - - - - - - - - - - - - - - ---------- - - - - - 00101 // 00102 void CC1101::POWER_UP_RESET_CCxxx0(void) 00103 { 00104 _csn = 1; 00105 wait(1e-6); 00106 _csn = 0; 00107 wait(1e-6); 00108 _csn = 1; 00109 wait(41e-6); 00110 RESET_CCxxx0(); 00111 } 00112 /////////////////////////////////////////////////////////////////////////////////////// 00113 // void Strobe(unsigned char strobe) 00114 // 00115 // DESCRIPTION: 00116 // Function for writing a strobe command to the CCxxx0 00117 // 00118 // ARGUMENTS: 00119 // unsigned char strobe 00120 // Strobe command 00121 /////////////////////////////////////////////////////////////////////////////////////// 00122 unsigned char CC1101::Strobe(unsigned char strobe) 00123 { 00124 unsigned char x; 00125 wait(0.000005); 00126 _csn = 0; 00127 wait(0.000002); 00128 while (_RDmiso); 00129 x = _spi.write(strobe); 00130 wait(0.000002); 00131 _csn = 1; 00132 return x; 00133 }// Strobe 00134 /////////////////////////////////////////////////////////////////////////////////////// 00135 // unsigned char ReadStatus(unsigned char addr) 00136 // 00137 // DESCRIPTION: 00138 // This function reads a CCxxx0 status register. 00139 // 00140 // ARGUMENTS: 00141 // unsigned char addr 00142 // Address of the CCxxx0 status register to be accessed. 00143 // 00144 // RETURN VALUE: 00145 // unsigned char 00146 // Value of the accessed CCxxx0 status register. 00147 /////////////////////////////////////////////////////////////////////////////////////// 00148 unsigned char CC1101::ReadStatus(unsigned char addr) 00149 { 00150 unsigned char x; 00151 wait(0.000005); 00152 _csn = 0; 00153 wait(0.000002); 00154 while (_RDmiso); 00155 _spi.write(addr | READ_BURST); 00156 x = _spi.write(0); 00157 wait(0.000002); 00158 _csn = 1; 00159 return x; 00160 }// ReadStatus 00161 /////////////////////////////////////////////////////////////////////////////////////// 00162 // void WriteRfSettings(RF_SETTINGS *pRfSettings) 00163 // 00164 // DESCRIPTION: 00165 // This function is used to configure the CCxxx0 based on a given rf setting 00166 // 00167 // ARGUMENTS: 00168 // RF_SETTINGS *pRfSettings 00169 // Pointer to a struct containing rf register settings 00170 /////////////////////////////////////////////////////////////////////////////////////// 00171 void CC1101::WriteRfSettings(RF_SETTINGS *pRfSettings) 00172 { 00173 // Write register settings 00174 WriteReg(CCxxx0_FSCTRL1, pRfSettings->FSCTRL1); 00175 WriteReg(CCxxx0_FSCTRL0, pRfSettings->FSCTRL0); 00176 WriteReg(CCxxx0_FREQ2, pRfSettings->FREQ2); 00177 WriteReg(CCxxx0_FREQ1, pRfSettings->FREQ1); 00178 WriteReg(CCxxx0_FREQ0, pRfSettings->FREQ0); 00179 WriteReg(CCxxx0_MDMCFG4, pRfSettings->MDMCFG4); 00180 WriteReg(CCxxx0_MDMCFG3, pRfSettings->MDMCFG3); 00181 WriteReg(CCxxx0_MDMCFG2, pRfSettings->MDMCFG2); 00182 WriteReg(CCxxx0_MDMCFG1, pRfSettings->MDMCFG1); 00183 WriteReg(CCxxx0_MDMCFG0, pRfSettings->MDMCFG0); 00184 WriteReg(CCxxx0_CHANNR, pRfSettings->CHANNR); 00185 WriteReg(CCxxx0_DEVIATN, pRfSettings->DEVIATN); 00186 WriteReg(CCxxx0_FREND1, pRfSettings->FREND1); 00187 WriteReg(CCxxx0_FREND0, pRfSettings->FREND0); 00188 WriteReg(CCxxx0_MCSM0 , pRfSettings->MCSM0 ); 00189 WriteReg(CCxxx0_FOCCFG, pRfSettings->FOCCFG); 00190 WriteReg(CCxxx0_BSCFG, pRfSettings->BSCFG); 00191 WriteReg(CCxxx0_AGCCTRL2, pRfSettings->AGCCTRL2); 00192 WriteReg(CCxxx0_AGCCTRL1, pRfSettings->AGCCTRL1); 00193 WriteReg(CCxxx0_AGCCTRL0, pRfSettings->AGCCTRL0); 00194 WriteReg(CCxxx0_FSCAL3, pRfSettings->FSCAL3); 00195 WriteReg(CCxxx0_FSCAL2, pRfSettings->FSCAL2); 00196 WriteReg(CCxxx0_FSCAL1, pRfSettings->FSCAL1); 00197 WriteReg(CCxxx0_FSCAL0, pRfSettings->FSCAL0); 00198 WriteReg(CCxxx0_FSTEST, pRfSettings->FSTEST); 00199 WriteReg(CCxxx0_TEST2, pRfSettings->TEST2); 00200 WriteReg(CCxxx0_TEST1, pRfSettings->TEST1); 00201 WriteReg(CCxxx0_TEST0, pRfSettings->TEST0); 00202 WriteReg(CCxxx0_FIFOTHR, pRfSettings->FIFOTHR); 00203 WriteReg(CCxxx0_IOCFG2, pRfSettings->IOCFG2); 00204 WriteReg(CCxxx0_IOCFG0, pRfSettings->IOCFG0); 00205 WriteReg(CCxxx0_PKTCTRL1, pRfSettings->PKTCTRL1); 00206 WriteReg(CCxxx0_PKTCTRL0, pRfSettings->PKTCTRL0); 00207 WriteReg(CCxxx0_ADDR, pRfSettings->ADDR); 00208 WriteReg(CCxxx0_PKTLEN, pRfSettings->PKTLEN); 00209 WriteReg(CCxxx0_MCSM1 , pRfSettings->MCSM1 ); 00210 RXMode(); 00211 00212 }// WriteRfSettings 00213 /////////////////////////////////////////////////////////////////////////////////////// 00214 void CC1101::init(void) 00215 { 00216 WriteRfSettings(&rfSettings); 00217 WriteReg(CCxxx0_PATABLE, paTable[0]); 00218 } 00219 /////////////////////////////////////////////////////////////////////////////////////// 00220 // unsigned char ReadReg(unsigned char addr) 00221 // 00222 // DESCRIPTION: 00223 // This function gets the value of a single specified CCxxx0 register. 00224 // 00225 // ARGUMENTS: 00226 // unsigned char addr 00227 // Address of the CCxxx0 register to be accessed. 00228 // 00229 // RETURN VALUE: 00230 // unsigned char 00231 // Value of the accessed CCxxx0 register. 00232 /////////////////////////////////////////////////////////////////////////////////////// 00233 unsigned char CC1101::ReadReg(unsigned char addr) 00234 { 00235 unsigned char x; 00236 wait(0.000005); 00237 _csn = 0; 00238 wait(0.000002); 00239 while (_RDmiso); 00240 _spi.write(addr | READ_SINGLE); 00241 x = _spi.write(0); 00242 wait(0.000002); 00243 _csn = 1; 00244 return x; 00245 }// ReadReg 00246 /////////////////////////////////////////////////////////////////////////////////////// 00247 // void ReadBurstReg(unsigned char addr, unsigned char *buffer, unsigned char count) 00248 // 00249 // DESCRIPTION: 00250 // This function reads multiple CCxxx0 register, using SPI burst access. 00251 // 00252 // ARGUMENTS: 00253 // unsigned char addr 00254 // Address of the first CCxxx0 register to be accessed. 00255 // unsigned char *buffer 00256 // Pointer to a byte array which stores the values read from a 00257 // corresponding range of CCxxx0 registers. 00258 // unsigned char count 00259 // Number of bytes to be read from the subsequent CCxxx0 registers. 00260 /////////////////////////////////////////////////////////////////////////////////////// 00261 void CC1101::ReadBurstReg(unsigned char addr, unsigned char *buffer, unsigned char count) 00262 { 00263 unsigned char i; 00264 wait(0.000005); 00265 _csn = 0; 00266 wait(0.000002); 00267 while (_RDmiso); 00268 _spi.write(addr | READ_BURST); 00269 for (i = 0; i < count; i++) 00270 { 00271 buffer[i] = _spi.write(0); 00272 } 00273 wait(0.000002); 00274 _csn = 1; 00275 }// ReadBurstReg 00276 /////////////////////////////////////////////////////////////////////////////////////// 00277 // void WriteReg(unsigned char addr, unsigned char value) 00278 // 00279 // DESCRIPTION: 00280 // Function for writing to a single CCxxx0 register 00281 // 00282 // ARGUMENTS: 00283 // unsigned char addr 00284 // Address of a specific CCxxx0 register to accessed. 00285 // unsigned char value 00286 // Value to be written to the specified CCxxx0 register. 00287 /////////////////////////////////////////////////////////////////////////////////////// 00288 void CC1101::WriteReg(unsigned char addr, unsigned char value) 00289 { 00290 wait(0.000005); 00291 _csn = 0; 00292 wait(0.000002); 00293 while (_RDmiso); 00294 _spi.write(addr); 00295 _spi.write(value); 00296 wait(0.000002); 00297 _csn = 1; 00298 }// WriteReg 00299 /////////////////////////////////////////////////////////////////////////////////////// 00300 // void WriteBurstReg(unsigned char addr, unsigned char *buffer, unsigned char count) 00301 // 00302 // DESCRIPTION: 00303 // This function writes to multiple CCxxx0 register, using SPI burst access. 00304 // 00305 // ARGUMENTS: 00306 // unsigned char addr 00307 // Address of the first CCxxx0 register to be accessed. 00308 // unsigned char *buffer 00309 // Array of bytes to be written into a corresponding range of 00310 // CCxx00 registers, starting by the address specified in _addr_. 00311 // unsigned char count 00312 // Number of bytes to be written to the subsequent CCxxx0 registers. 00313 /////////////////////////////////////////////////////////////////////////////////////// 00314 void CC1101::WriteBurstReg(unsigned char addr, unsigned char *buffer, unsigned char count) 00315 { 00316 unsigned char i; 00317 wait(0.000005); 00318 _csn = 0; 00319 wait(0.000002); 00320 while (_RDmiso); 00321 _spi.write(addr | WRITE_BURST); 00322 for (i = 0; i < count; i++) 00323 { 00324 _spi.write(buffer[i]); 00325 } 00326 wait(0.000002); 00327 _csn = 1; 00328 }// WriteBurstReg 00329 /////////////////////////////////////////////////////////////////////////////////////// 00330 unsigned char CC1101::RdRSSI(void) 00331 { 00332 unsigned char crssi; 00333 00334 00335 if (rssi >= 128) 00336 { 00337 crssi = 255 - rssi; 00338 crssi /= 2; 00339 crssi += 74; 00340 } 00341 else 00342 { 00343 crssi = rssi/2; 00344 crssi += 74; 00345 } 00346 return crssi; 00347 } 00348 /////////////////////////////////////////////////////////////////////////////////////// 00349 unsigned char CC1101::RdLQI(void) 00350 { 00351 unsigned char clqi; 00352 clqi = 0x3F - (lqi & 0x3F); 00353 00354 return clqi; 00355 } 00356 /////////////////////////////////////////////////////////////////////////////////////// 00357 unsigned char CC1101::RxFifoEmpty(void) 00358 { 00359 unsigned char RxFifoStatus; 00360 00361 Strobe(CCxxx0_SRX); 00362 RxFifoStatus = ReadStatus(CCxxx0_RXBYTES); 00363 00364 if (RxFifoStatus & 0x80) // check for RXFIFO overflow 00365 { 00366 // Make sure that the radio is in IDLE state before flushing the FIFO 00367 // (Unless RXOFF_MODE has been changed, the radio should be in IDLE state at this point) 00368 Strobe(CCxxx0_SIDLE); 00369 00370 // Flush RX FIFO 00371 Strobe(CCxxx0_SFRX); 00372 } 00373 if (RxFifoStatus & ~0x80) 00374 { 00375 return 0; 00376 } 00377 else 00378 return 1; 00379 } 00380 /////////////////////////////////////////////////////////////////////////////////////// 00381 //------------------------------------------------------------------------------------------------------- 00382 // BOOL ReceivePacket(unsigned char *rxBuffer, unsigned char *length) 00383 // 00384 // DESCRIPTION: 00385 // This function can be used to receive a packet of variable packet length (first byte in the packet 00386 // must be the length byte). The packet length should not exceed the RX FIFO size. 00387 // 00388 // ARGUMENTS: 00389 // unsigned char *rxBuffer 00390 // Pointer to the buffer where the incoming data should be stored 00391 // unsigned char *length 00392 // Pointer to a variable containing the size of the buffer where the incoming data should be 00393 // stored. After this function returns, that variable holds the packet length. 00394 // 00395 // RETURN VALUE: 00396 // BOOL 00397 // 1: CRC OK 00398 // 0: CRC NOT OK (or no packet was put in the RX FIFO due to filtering) 00399 /////////////////////////////////////////////////////////////////////////////////////// 00400 00401 int CC1101::ReceivePacket(unsigned char *rxBuffer, unsigned char *length) 00402 { 00403 unsigned char status[2]; 00404 unsigned char packetLength; 00405 00406 packetLength = ReadStatus(CCxxx0_RXBYTES); 00407 if (packetLength & BYTES_IN_RXFIFO) 00408 { 00409 // Read length byte 00410 packetLength = ReadReg(CCxxx0_RXFIFO); 00411 00412 // Read data from RX FIFO and store in rxBuffer 00413 if (packetLength <= *length) 00414 { 00415 ReadBurstReg(CCxxx0_RXFIFO, rxBuffer, packetLength); 00416 *length = packetLength; 00417 00418 // Read the 2 appended status bytes (status[0] = RSSI, status[1] = LQI) 00419 ReadBurstReg(CCxxx0_RXFIFO, status, 2); 00420 00421 rssi = status[RSSI]; 00422 lqi = status[LQI]; 00423 // MSB of LQI is the CRC_OK bit 00424 // return (status[LQI] & CRC_OK); 00425 if(status[LQI] & CRC_OK) 00426 { 00427 return 1; 00428 } 00429 } 00430 else 00431 { 00432 *length = packetLength; 00433 00434 // Make sure that the radio is in IDLE state before flushing the FIFO 00435 // (Unless RXOFF_MODE has been changed, the radio should be in IDLE state at this point) 00436 Strobe(CCxxx0_SIDLE); 00437 00438 // Flush RX FIFO 00439 Strobe(CCxxx0_SFRX); 00440 return 0; 00441 } 00442 } else 00443 return 0; 00444 return 0; 00445 }// halRfReceivePacket 00446 /////////////////////////////////////////////////////////////////////////////////////// 00447 unsigned char CC1101::TxFifoEmpty(void) 00448 { 00449 unsigned char TxFifoStatus; 00450 00451 Strobe(CCxxx0_STX); 00452 TxFifoStatus = ReadStatus(CCxxx0_TXBYTES); 00453 00454 if (TxFifoStatus & 0x80) // check for TXFIFO underflow 00455 { 00456 // Make sure that the radio is in IDLE state before flushing the FIFO 00457 Strobe(CCxxx0_SIDLE); 00458 00459 // Flush TX FIFO 00460 Strobe(CCxxx0_SFTX); 00461 } 00462 if (TxFifoStatus & ~0x80) 00463 { 00464 return 0; 00465 } 00466 else 00467 return 1; 00468 } 00469 /////////////////////////////////////////////////////////////////////////////////////// 00470 // void halRfSendPacket(unsigned char *txBuffer, unsigned char size) 00471 // 00472 // DESCRIPTION: 00473 // This function can be used to transmit a packet with packet length up to 63 bytes. 00474 // 00475 // ARGUMENTS: 00476 // unsigned char *txBuffer 00477 // Pointer to a buffer containing the data that are going to be transmitted 00478 // 00479 // unsigned char size 00480 // The size of the txBuffer 00481 /////////////////////////////////////////////////////////////////////////////////////// 00482 void CC1101::SendPacket(unsigned char *txBuffer, unsigned char size) 00483 { 00484 unsigned char i; 00485 00486 for (i = size; i > 0; i--) 00487 txBuffer[i] = txBuffer[i-1]; 00488 txBuffer[0] = size; 00489 00490 WriteBurstReg(CCxxx0_TXFIFO, txBuffer, size+1); 00491 Strobe(CCxxx0_SIDLE); 00492 Strobe(CCxxx0_STX); 00493 }// halRfSendPacket 00494 /////////////////////////////////////////////////////////////////////////////////////// 00495 unsigned char CC1101::ReadChipStatusTX(void) 00496 { 00497 unsigned char x; 00498 00499 x = Strobe(CCxxx0_SNOP); 00500 return x; 00501 } 00502 /////////////////////////////////////////////////////////////////////////////////////// 00503 unsigned char CC1101::ReadChipStatusRX(void) 00504 { 00505 unsigned char x; 00506 wait(0.000005); 00507 _csn = 0; 00508 wait(0.000002); 00509 while (_RDmiso); 00510 x = _spi.write(CCxxx0_PARTNUM | READ_BURST); 00511 wait(0.000002); 00512 _csn = 1; 00513 return x; 00514 } 00515 /////////////////////////////////////////////////////////////////////////////////////// 00516 void CC1101::FlushRX(void) 00517 { 00518 // Make sure that the radio is in IDLE state before flushing the FIFO 00519 Strobe(CCxxx0_SIDLE); 00520 00521 // Flush RX FIFO 00522 Strobe(CCxxx0_SFRX); 00523 } 00524 /////////////////////////////////////////////////////////////////////////////////////// 00525 void CC1101::FlushTX(void) 00526 { 00527 // Make sure that the radio is in IDLE state before flushing the FIFO 00528 Strobe(CCxxx0_SIDLE); 00529 00530 // Flush TX FIFO 00531 Strobe(CCxxx0_SFTX); 00532 } 00533 /////////////////////////////////////////////////////////////////////////////////////// 00534 void CC1101::RXMode(void) 00535 { 00536 Strobe(CCxxx0_SIDLE); 00537 Strobe(CCxxx0_SRX); 00538 } 00539 ///////////////////////////////////////////////////////////////////////////////////////
Generated on Tue Jul 12 2022 21:30:38 by 1.7.2