#include "LR1110.h" #include #if !RADIOLIB_EXCLUDE_LR11X0 LR1110::LR1110(Module* mod) : LR11x0(mod) { chipType = RADIOLIB_LR11X0_DEVICE_LR1110; } int16_t LR1110::begin(float freq, float bw, uint8_t sf, uint8_t cr, uint8_t syncWord, int8_t power, uint16_t preambleLength, float tcxoVoltage) { // execute common part int16_t state = LR11x0::begin(bw, sf, cr, syncWord, preambleLength, tcxoVoltage); RADIOLIB_ASSERT(state); // configure publicly accessible settings state = setFrequency(freq); RADIOLIB_ASSERT(state); state = setOutputPower(power); return(state); } int16_t LR1110::beginGFSK(float freq, float br, float freqDev, float rxBw, int8_t power, uint16_t preambleLength, float tcxoVoltage) { // execute common part int16_t state = LR11x0::beginGFSK(br, freqDev, rxBw, preambleLength, tcxoVoltage); RADIOLIB_ASSERT(state); // configure publicly accessible settings state = setFrequency(freq); RADIOLIB_ASSERT(state); state = setOutputPower(power); return(state); } int16_t LR1110::beginLRFHSS(float freq, uint8_t bw, uint8_t cr, bool narrowGrid, int8_t power, float tcxoVoltage) { // execute common part int16_t state = LR11x0::beginLRFHSS(bw, cr, narrowGrid, tcxoVoltage); RADIOLIB_ASSERT(state); // configure publicly accessible settings state = setFrequency(freq); RADIOLIB_ASSERT(state); state = setOutputPower(power); return(state); } int16_t LR1110::setFrequency(float freq) { return(this->setFrequency(freq, false)); } int16_t LR1110::setFrequency(float freq, bool skipCalibration, float band) { RADIOLIB_CHECK_RANGE(freq, 150.0, 960.0, RADIOLIB_ERR_INVALID_FREQUENCY); // check if we need to recalibrate image int16_t state; if(!skipCalibration && (fabsf(freq - this->freqMHz) >= RADIOLIB_LR11X0_CAL_IMG_FREQ_TRIG_MHZ)) { state = LR11x0::calibrateImageRejection(freq - band, freq + band); RADIOLIB_ASSERT(state); } // set frequency state = LR11x0::setRfFrequency((uint32_t)(freq*1000000.0f)); RADIOLIB_ASSERT(state); this->freqMHz = freq; return(state); } int16_t LR1110::setOutputPower(int8_t power) { return(this->setOutputPower(power, false)); } int16_t LR1110::setOutputPower(int8_t power, bool forceHighPower) { // check if power value is configurable int16_t state = this->checkOutputPower(power, NULL, forceHighPower); RADIOLIB_ASSERT(state); // determine whether to use HP or LP PA and check range accordingly bool useHp = forceHighPower || (power > 14); // TODO how and when to configure OCP? // update PA config - always use VBAT for high-power PA state = setPaConfig((uint8_t)useHp, (uint8_t)useHp, 0x04, 0x07); RADIOLIB_ASSERT(state); // set output power state = setTxParams(power, RADIOLIB_LR11X0_PA_RAMP_48U); return(state); } int16_t LR1110::checkOutputPower(int8_t power, int8_t* clipped) { return(checkOutputPower(power, clipped, false)); } int16_t LR1110::checkOutputPower(int8_t power, int8_t* clipped, bool forceHighPower) { if(forceHighPower || (power > 14)) { if(clipped) { *clipped = RADIOLIB_MAX(-9, RADIOLIB_MIN(22, power)); } RADIOLIB_CHECK_RANGE(power, -9, 22, RADIOLIB_ERR_INVALID_OUTPUT_POWER); } else { if(clipped) { *clipped = RADIOLIB_MAX(-17, RADIOLIB_MIN(14, power)); } RADIOLIB_CHECK_RANGE(power, -17, 14, RADIOLIB_ERR_INVALID_OUTPUT_POWER); } return(RADIOLIB_ERR_NONE); } int16_t LR1110::setModem(ModemType_t modem) { switch(modem) { case(ModemType_t::LoRa): { return(this->begin()); } break; case(ModemType_t::FSK): { return(this->beginGFSK()); } break; case(ModemType_t::LRFHSS): { return(this->beginLRFHSS()); } break; } return(RADIOLIB_ERR_WRONG_MODEM); } #endif