Fork of SX1276 library, with setLowDataRateOptimize() function added to configure "Low Datarate Optimize" setting of chip.
Dependents: SX1276_terminal SX1276_Semtech_GUI
Fork of SX127x by
sx127x_fsk.cpp
- Committer:
- modtronix
- Date:
- 2015-02-16
- Revision:
- 10:3d148697c0d3
- Parent:
- 4:d987ac2836bf
File content as of revision 10:3d148697c0d3:
#include "sx127x_fsk.h" /* SX127x driver * Copyright (c) 2013 Semtech * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ SX127x_fsk::SX127x_fsk(SX127x& r) : m_xcvr(r) { } SX127x_fsk::~SX127x_fsk() { } void SX127x_fsk::write_fifo(uint8_t len) { int i; m_xcvr.m_cs = 0; m_xcvr.m_spi.write(REG_FIFO | 0x80); // bit7 is high for writing to radio if (!m_xcvr.RegOpMode.bits.LongRangeMode && RegPktConfig1.bits.PacketFormatVariable) { m_xcvr.m_spi.write(len); } for (i = 0; i < len; i++) { m_xcvr.m_spi.write(m_xcvr.tx_buf[i]); } m_xcvr.m_cs = 1; } void SX127x_fsk::enable() { m_xcvr.set_opmode(RF_OPMODE_SLEEP); m_xcvr.RegOpMode.bits.LongRangeMode = 0; m_xcvr.write_reg(REG_OPMODE, m_xcvr.RegOpMode.octet); wait(0.01); RegPktConfig1.octet = m_xcvr.read_reg(REG_FSK_PACKETCONFIG1); RegPktConfig2.word = m_xcvr.read_u16(REG_FSK_PACKETCONFIG2); RegRxConfig.octet = m_xcvr.read_u16(REG_FSK_RXCONFIG); RegPreambleDetect.octet = m_xcvr.read_reg(REG_FSK_PREAMBLEDETECT); RegSyncConfig.octet = m_xcvr.read_reg(REG_FSK_SYNCCONFIG); RegFifoThreshold.octet = m_xcvr.read_reg(REG_FSK_FIFOTHRESH); RegAfcFei.octet = m_xcvr.read_reg(REG_FSK_AFCFEI); if (!RegFifoThreshold.bits.TxStartCondition) { RegFifoThreshold.bits.TxStartCondition = 1; // start TX on fifoEmpty==0 m_xcvr.write_reg(REG_FSK_FIFOTHRESH, RegFifoThreshold.octet); } if (RegSyncConfig.bits.AutoRestartRxMode != 1) { RegSyncConfig.bits.AutoRestartRxMode = 1; m_xcvr.write_reg(REG_FSK_SYNCCONFIG, RegSyncConfig.octet); } if (RegPreambleDetect.bits.PreambleDetectorTol != 10) { RegPreambleDetect.bits.PreambleDetectorTol = 10; m_xcvr.write_reg(REG_FSK_PREAMBLEDETECT, RegPreambleDetect.octet); } m_xcvr.set_opmode(RF_OPMODE_STANDBY); } void SX127x_fsk::init() { m_xcvr.set_opmode(RF_OPMODE_STANDBY); RegRxConfig.bits.RxTrigger = 6; // have RX restart (trigger) on preamble detection RegRxConfig.bits.AfcAutoOn = 1; // have AFC performed on RX restart (RX trigger) m_xcvr.write_reg(REG_FSK_RXCONFIG, RegRxConfig.octet); RegPreambleDetect.bits.PreambleDetectorOn = 1; // enable preamble detector m_xcvr.write_reg(REG_FSK_PREAMBLEDETECT, RegPreambleDetect.octet); m_xcvr.write_reg(REG_FSK_SYNCVALUE1, 0x55); m_xcvr.write_reg(REG_FSK_SYNCVALUE2, 0x6f); m_xcvr.write_reg(REG_FSK_SYNCVALUE3, 0x4e); RegSyncConfig.bits.SyncSize = 2; m_xcvr.write_reg(REG_FSK_SYNCCONFIG, RegSyncConfig.octet); // in case these were changed from default: set_bitrate(4800); set_tx_fdev_hz(5050); set_rx_dcc_bw_hz(10500, 0); // rxbw set_rx_dcc_bw_hz(50000, 1); // afcbw } uint32_t SX127x_fsk::get_bitrate() { uint16_t br = m_xcvr.read_u16(REG_FSK_BITRATEMSB); if (br == 0) return 0; else return XTAL_FREQ / br; } void SX127x_fsk::set_bitrate(uint32_t bps) { uint16_t tmpBitrate = XTAL_FREQ / bps; //printf("tmpBitrate:%d = %d / %d\r\n", tmpBitrate, XTAL_FREQ, bps); m_xcvr.write_u16(REG_FSK_BITRATEMSB, tmpBitrate); } void SX127x_fsk::set_tx_fdev_hz(uint32_t hz) { float tmpFdev = hz / FREQ_STEP_HZ; uint16_t v; //printf("tmpFdev:%f = %d / %f\r\n", tmpFdev, hz, FREQ_STEP_HZ); v = (uint16_t)tmpFdev; m_xcvr.write_u16(REG_FSK_FDEVMSB, v); } uint32_t SX127x_fsk::get_tx_fdev_hz(void) { uint16_t fdev = m_xcvr.read_u16(REG_FSK_FDEVMSB); return fdev * FREQ_STEP_HZ; } uint32_t SX127x_fsk::ComputeRxBw( uint8_t mantisse, uint8_t exponent ) { // rxBw if (m_xcvr.RegOpMode.bits.ModulationType == 0) return XTAL_FREQ / (mantisse * (1 << (exponent+2))); else return XTAL_FREQ / (mantisse * (1 << (exponent+3))); } void SX127x_fsk::ComputeRxBwMantExp( uint32_t rxBwValue, uint8_t* mantisse, uint8_t* exponent ) { uint8_t tmpExp, tmpMant; double tmpRxBw; double rxBwMin = 10e6; for( tmpExp = 0; tmpExp < 8; tmpExp++ ) { for( tmpMant = 16; tmpMant <= 24; tmpMant += 4 ) { tmpRxBw = ComputeRxBw(tmpMant, tmpExp); if( fabs( tmpRxBw - rxBwValue ) < rxBwMin ) { rxBwMin = fabs( tmpRxBw - rxBwValue ); *mantisse = tmpMant; *exponent = tmpExp; } } } } uint32_t SX127x_fsk::get_rx_bw_hz(uint8_t addr) { RegRxBw_t reg_bw; uint8_t mantissa; if (m_xcvr.RegOpMode.bits.LongRangeMode) return 0; reg_bw.octet = m_xcvr.read_reg(addr); switch (reg_bw.bits.Mantissa) { case 0: mantissa = 16; break; case 1: mantissa = 20; break; case 2: mantissa = 24; break; default: mantissa = 0; break; } if (addr == REG_FSK_RXBW) RegRxBw.octet = reg_bw.octet; else if (addr == REG_FSK_AFCBW) RegAfcBw.octet = reg_bw.octet; return ComputeRxBw(mantissa, reg_bw.bits.Exponent); } void SX127x_fsk::set_rx_dcc_bw_hz(uint32_t bw_hz, char afc) { uint8_t mantisse = 0; uint8_t exponent = 0; if (m_xcvr.RegOpMode.bits.LongRangeMode) return; ComputeRxBwMantExp( bw_hz, &mantisse, &exponent ); //printf("bw_hz:%d, mantisse:%d, exponent:%d\n", bw_hz, mantisse, exponent ); switch( mantisse ) { case 16: RegRxBw.bits.Mantissa = 0; break; case 20: RegRxBw.bits.Mantissa = 1; break; case 24: RegRxBw.bits.Mantissa = 2; break; default: // Something went terribely wrong printf("maintisse:%d\n", mantisse); break; } RegRxBw.bits.Exponent = exponent; if (afc) m_xcvr.write_reg(REG_FSK_AFCBW, RegRxBw.octet); else m_xcvr.write_reg(REG_FSK_RXBW, RegRxBw.octet); } void SX127x_fsk::start_tx(uint16_t arg_len) { uint16_t pkt_buf_len; RegIrqFlags2_t RegIrqFlags2; int maxlen = FSK_FIFO_SIZE-1; if (m_xcvr.RegOpMode.bits.Mode == RF_OPMODE_RECEIVER) { m_xcvr.set_opmode(RF_OPMODE_STANDBY); } if (m_xcvr.RegDioMapping1.bits.Dio0Mapping != 0) { m_xcvr.RegDioMapping1.bits.Dio0Mapping = 0; m_xcvr.write_reg(REG_DIOMAPPING1, m_xcvr.RegDioMapping1.octet); } if (RegPktConfig1.bits.PacketFormatVariable) { pkt_buf_len = arg_len; } else { pkt_buf_len = RegPktConfig2.bits.PayloadLength; printf("fixed-fmt %d\r\n", pkt_buf_len); } RegIrqFlags2.octet = m_xcvr.read_reg(REG_FSK_IRQFLAGS2); if (RegIrqFlags2.bits.FifoEmpty) { if (RegPktConfig1.bits.PacketFormatVariable) { --maxlen; // space for length byte if (pkt_buf_len > maxlen) { /*setup_FifoLevel(FALLING_EDGE); radio_write_fifo_(pkt_buf, maxlen, pkt_buf_len); remaining_ = pkt_buf_len - maxlen; printf("var-oversized %d R=%d\r\n", pkt_buf_len, remaining_);*/ printf("var-oversized %d\r\n", pkt_buf_len); } else { //setup_FifoLevel(NO_EDGE); // disable write_fifo(pkt_buf_len); //remaining_ = 0; // all was sent } } else { // fixed-length pkt format... pkt_buf_len = RegPktConfig2.bits.PayloadLength; if (RegPktConfig2.bits.PayloadLength > maxlen) { /*setup_FifoLevel(FALLING_EDGE); radio_write_fifo_(pkt_buf, maxlen, -1); remaining_ = SX1272FSK->RegPktConfig2.bits.PayloadLength - maxlen;*/ printf("todo: fsk large packet\r\n"); } else { //setup_FifoLevel(NO_EDGE); // disable printf("fixed-write-fifo %d\r\n", RegPktConfig2.bits.PayloadLength); write_fifo(RegPktConfig2.bits.PayloadLength); } } } else printf("fifo not empty %02x\r\n", RegIrqFlags2.octet); m_xcvr.set_opmode(RF_OPMODE_TRANSMITTER); } void SX127x_fsk::config_dio0_for_pktmode_rx() { if (RegPktConfig1.bits.CrcOn) { if (m_xcvr.RegDioMapping1.bits.Dio0Mapping != 1) { m_xcvr.RegDioMapping1.bits.Dio0Mapping = 1; // to CrcOk m_xcvr.write_reg(REG_DIOMAPPING1, m_xcvr.RegDioMapping1.octet); } } else { // Crc Off, use PayloadReady if (m_xcvr.RegDioMapping1.bits.Dio0Mapping != 0) { m_xcvr.RegDioMapping1.bits.Dio0Mapping = 0; // to PayloadReady m_xcvr.write_reg(REG_DIOMAPPING1, m_xcvr.RegDioMapping1.octet); } } } void SX127x_fsk::start_rx() { if (m_xcvr.RegOpMode.bits.LongRangeMode) return; if (m_xcvr.RegOpMode.bits.Mode == RF_OPMODE_RECEIVER) { // was already receiving, restart it m_xcvr.set_opmode(RF_OPMODE_STANDBY); wait(0.01); } config_dio0_for_pktmode_rx(); m_xcvr.set_opmode(RF_OPMODE_RECEIVER); } service_action_e SX127x_fsk::service() { int i; if (m_xcvr.RegOpMode.bits.Mode == RF_OPMODE_TRANSMITTER) { if (m_xcvr.dio0) { m_xcvr.set_opmode(RF_OPMODE_STANDBY); return SERVICE_TX_DONE; } } else if (m_xcvr.RegOpMode.bits.Mode == RF_OPMODE_RECEIVER && m_xcvr.dio0) { if (RegRxConfig.bits.AfcAutoOn) RegAfcValue = m_xcvr.read_s16(REG_FSK_AFCMSB); if (RegPktConfig1.bits.PacketFormatVariable) { rx_buf_length = m_xcvr.read_reg(REG_FIFO); } else { rx_buf_length = RegPktConfig2.bits.PayloadLength; } m_xcvr.m_cs = 0; m_xcvr.m_spi.write(REG_FIFO); // bit7 is low for reading from radio for (i = 0; i < rx_buf_length; i++) { m_xcvr.rx_buf[i] = m_xcvr.m_spi.write(0); } m_xcvr.m_cs = 1; return SERVICE_READ_FIFO; } return SERVICE_NONE; }