#include "DFRobot_AS3935_I2c.h" DF_AS3935_I2C::DF_AS3935_I2C(uint8_t IRQx, uint8_t SIx, uint8_t DEVADDx) { _devadd = DEVADDx; _si = SIx; _irq = IRQx; // initalize the chip select pins pinMode(_si, OUTPUT); pinMode(_irq, INPUT); // set output pin initical condition digitalWrite(_si, HIGH); // set pin high for I2C mode } void DF_AS3935_I2C::AS3935_SetI2CAddress(uint8_t DEVADDx) { if (DEVADDx == AS3935_ADD1) { _devadd=DEVADDx; } else if (DEVADDx == AS3935_ADD2) { _devadd=DEVADDx; } else { _devadd=AS3935_ADD3; } } uint8_t DF_AS3935_I2C::_sing_reg_read(uint8_t RegAdd) { // I2C address Register address num bytes I2c.read((uint8_t)_devadd, (uint8_t)RegAdd, (uint8_t)0x01); // Use I2C library to read register uint8_t RegData = I2c.receive(); // receive the I2C data return RegData; } void DF_AS3935_I2C::_sing_reg_write(uint8_t RegAdd, uint8_t DataMask, uint8_t RegData) { // start by reading original register data (only modifying what we need to) uint8_t OrigRegData = _sing_reg_read(RegAdd); // calculate new register data... 'delete' old targeted data, replace with new data // note: 'DataMask' must be bits targeted for replacement // add'l note: this function does NOT shift values into the proper place... they need to be there already uint8_t NewRegData = ((OrigRegData & ~DataMask) | (RegData & DataMask)); // finally, write the data to the register I2c.write(_devadd, RegAdd, NewRegData); Serial.print("wrt: "); Serial.print(NewRegData,HEX); Serial.print(" Act: "); Serial.println(_sing_reg_read(RegAdd),HEX); } void DF_AS3935_I2C::AS3935_DefInit() { _AS3935_Reset(); // reset registers to default } void DF_AS3935_I2C::_AS3935_Reset() { // run PRESET_DEFAULT Direct Command to set all registers in default state I2c.write(_devadd, (uint8_t)0x3C, (uint8_t)0x96); delay(2); // wait 2ms to complete } void DF_AS3935_I2C::_CalRCO() { // run ALIB_RCO Direct Command to cal internal RCO I2c.write(_devadd, (uint8_t)0x3D, (uint8_t)0x96); delay(2); // wait 2ms to complete } void DF_AS3935_I2C::AS3935_PowerUp(void) { // power-up sequence based on datasheet, pg 23/27 // register 0x00, PWD bit: 0 (clears PWD) _sing_reg_write(0x00, 0x01, 0x00); _CalRCO(); // run RCO cal cmd _sing_reg_write(0x08, 0x20, 0x20); // set DISP_SRCO to 1 delay(2); _sing_reg_write(0x08, 0x20, 0x00); // set DISP_SRCO to 0 } void DF_AS3935_I2C::AS3935_PowerDown(void) { // register 0x00, PWD bit: 0 (sets PWD) _sing_reg_write(0x00, 0x01, 0x01); Serial.println("AS3935 powered down"); } void DF_AS3935_I2C::AS3935_DisturberEn(void) { // register 0x03, PWD bit: 5 (sets MASK_DIST) _sing_reg_write(0x03, 0x20, 0x00); Serial.println("disturber detection enabled"); } void DF_AS3935_I2C::AS3935_DisturberDis(void) { // register 0x03, PWD bit: 5 (sets MASK_DIST) _sing_reg_write(0x03, 0x20, 0x20); } void DF_AS3935_I2C::AS3935_SetIRQ_Output_Source(uint8_t irq_select) { // set interrupt source - what to display on IRQ pin // reg 0x08, bits 5 (TRCO), 6 (SRCO), 7 (LCO) // only one should be set at once, I think // 0 = NONE, 1 = TRCO, 2 = SRCO, 3 = LCO if(1 == irq_select) { _sing_reg_write(0x08, 0xE0, 0x20); // set only TRCO bit } else if(2 == irq_select) { _sing_reg_write(0x08, 0xE0, 0x40); // set only SRCO bit } else if(3 == irq_select) { _sing_reg_write(0x08, 0xE0, 0x80); // set only LCO bit } else // assume 0 { _sing_reg_write(0x08, 0xE0, 0x00); // clear IRQ pin display bits } } void DF_AS3935_I2C::AS3935_SetTuningCaps(uint8_t cap_val) { // Assume only numbers divisible by 8 (because that's all the chip supports) if(120 < cap_val) // cap_value out of range, assume highest capacitance { _sing_reg_write(0x08, 0x0F, 0x0F); // set capacitance bits to maximum } else { _sing_reg_write(0x08, 0x0F, (cap_val>>3)); // set capacitance bits } Serial.print("capacitance set to 8x"); Serial.println((_sing_reg_read(0x08) & 0x0F)); } uint8_t DF_AS3935_I2C::AS3935_GetInterruptSrc(void) { // definition of interrupt data on table 18 of datasheet // for this function: // 0 = unknown src, 1 = lightning detected, 2 = disturber, 3 = Noise level too high delay(10); // wait 3ms before reading (min 2ms per pg 22 of datasheet) uint8_t int_src = (_sing_reg_read(0x03) & 0x0F); // read register, get rid of non-interrupt data if(0x08 == int_src) { return 1; // lightning caused interrupt } else if(0x04 == int_src) { return 2; // disturber detected } else if(0x01 == int_src) { return 3; // Noise level too high } else{return 0;} // interrupt result not expected } uint8_t DF_AS3935_I2C::AS3935_GetLightningDistKm(void) { uint8_t strike_dist = (_sing_reg_read(0x07) & 0x3F); // read register, get rid of non-distance data return strike_dist; } uint32_t DF_AS3935_I2C::AS3935_GetStrikeEnergyRaw(void) { uint32_t nrgy_raw = ((_sing_reg_read(0x06) & 0x1F) << 8); // MMSB, shift 8 bits left, make room for MSB nrgy_raw |= _sing_reg_read(0x05); // read MSB nrgy_raw <<= 8; // shift 8 bits left, make room for LSB nrgy_raw |= _sing_reg_read(0x04); // read LSB, add to others return nrgy_raw/16777; } uint8_t DF_AS3935_I2C::AS3935_SetMinStrikes(uint8_t min_strk) { // This function sets min strikes to the closest available number, rounding to the floor, // where necessary, then returns the physical value that was set. Options are 1, 5, 9 or 16 strikes. // see pg 22 of the datasheet for more info (#strikes in 17 min) if(5 > min_strk) { _sing_reg_write(0x02, 0x30, 0x00); return 1; } else if(9 > min_strk) { _sing_reg_write(0x02, 0x30, 0x10); return 5; } else if(16 > min_strk) { _sing_reg_write(0x02, 0x30, 0x20); return 9; } else { _sing_reg_write(0x02, 0x30, 0x30); return 16; } } void DF_AS3935_I2C::AS3935_SetIndoors(void) { // AFE settings addres 0x00, bits 5:1 (10010, based on datasheet, pg 19, table 15) // this is the default setting at power-up (AS3935 datasheet, table 9) _sing_reg_write(0x00, 0x3E, 0x24); Serial.println("set up for indoor operation"); } void DF_AS3935_I2C::AS3935_SetOutdoors(void) { // AFE settings addres 0x00, bits 5:1 (01110, based on datasheet, pg 19, table 15) _sing_reg_write(0x00, 0x3E, 0x1C); Serial.println("set up for outdoor operation"); } void DF_AS3935_I2C::AS3935_ClearStatistics(void) { // clear is accomplished by toggling CL_STAT bit 'high-low-high' (then set low to move on) _sing_reg_write(0x02, 0x40, 0x40); // high _sing_reg_write(0x02, 0x40, 0x00); // low _sing_reg_write(0x02, 0x40, 0x40); // high } uint8_t DF_AS3935_I2C::AS3935_GetNoiseFloorLvl(void) { // NF settings addres 0x01, bits 6:4 // default setting of 010 at startup (datasheet, table 9) uint8_t reg_raw = _sing_reg_read(0x01); // read register 0x01 return ((reg_raw & 0x70)>>4); // should return value from 0-7, see table 16 for info } void DF_AS3935_I2C::AS3935_SetNoiseFloorLvl(uint8_t nf_sel) { // NF settings addres 0x01, bits 6:4 // default setting of 010 at startup (datasheet, table 9) if(7 >= nf_sel) // nf_sel within expected range { _sing_reg_write(0x01, 0x70, ((nf_sel & 0x07)<<4)); } else { // out of range, set to default (power-up value 010) _sing_reg_write(0x01, 0x70, 0x20); } } uint8_t DF_AS3935_I2C::AS3935_GetWatchdogThreshold(void) { // This function is used to read WDTH. It is used to increase robustness to disturbers, // though will make detection less efficient (see page 19, Fig 20 of datasheet) // WDTH register: add 0x01, bits 3:0 // default value of 0001 // values should only be between 0x00 and 0x0F (0 and 7) uint8_t reg_raw = _sing_reg_read(0x01); return (reg_raw & 0x0F); } void DF_AS3935_I2C::AS3935_SetWatchdogThreshold(uint8_t wdth) { // This function is used to modify WDTH. It is used to increase robustness to disturbers, // though will make detection less efficient (see page 19, Fig 20 of datasheet) // WDTH register: add 0x01, bits 3:0 // default value of 0001 // values should only be between 0x00 and 0x0F (0 and 7) _sing_reg_write(0x01, 0x0F, (wdth & 0x0F)); } uint8_t DF_AS3935_I2C::AS3935_GetSpikeRejection(void) { // This function is used to read SREJ (spike rejection). Similar to the Watchdog threshold, // it is used to make the system more robust to disturbers, though will make general detection // less efficient (see page 20-21, especially Fig 21 of datasheet) // SREJ register: add 0x02, bits 3:0 // default value of 0010 // values should only be between 0x00 and 0x0F (0 and 7) uint8_t reg_raw = _sing_reg_read(0x02); return (reg_raw & 0x0F); } void DF_AS3935_I2C::AS3935_SetSpikeRejection(uint8_t srej) { // This function is used to modify SREJ (spike rejection). Similar to the Watchdog threshold, // it is used to make the system more robust to disturbers, though will make general detection // less efficient (see page 20-21, especially Fig 21 of datasheet) // WDTH register: add 0x02, bits 3:0 // default value of 0010 // values should only be between 0x00 and 0x0F (0 and 7) _sing_reg_write(0x02, 0x0F, (srej & 0x0F)); } void DF_AS3935_I2C::AS3935_SetLCO_FDIV(uint8_t fdiv) { // This function sets LCO_FDIV register. This is useful in the tuning of the antenna // LCO_FDIV register: add 0x03, bits 7:6 // default value: 00 // set 0, 1, 2 or 3 for ratios of 16, 32, 64 and 128, respectively. // See pg 23, Table 20 for more info. _sing_reg_write(0x03, 0xC0, ((fdiv & 0x03) << 5)); } void DF_AS3935_I2C::AS3935_PrintAllRegs(void) { Serial.print("Reg 0x00: "); Serial.println(_sing_reg_read(0x00)); Serial.print("Reg 0x01: "); Serial.println(_sing_reg_read(0x01)); Serial.print("Reg 0x02: "); Serial.println(_sing_reg_read(0x02)); Serial.print("Reg 0x03: "); Serial.println(_sing_reg_read(0x03)); Serial.print("Reg 0x04: "); Serial.println(_sing_reg_read(0x04)); Serial.print("Reg 0x05: "); Serial.println(_sing_reg_read(0x05)); Serial.print("Reg 0x06: "); Serial.println(_sing_reg_read(0x06)); Serial.print("Reg 0x07: "); Serial.println(_sing_reg_read(0x07)); Serial.print("Reg 0x08: "); Serial.println(_sing_reg_read(0x08)); uint32_t nrgy_val = AS3935_GetStrikeEnergyRaw(); Serial.println(nrgy_val); } void DF_AS3935_I2C::AS3935_ManualCal(uint8_t capacitance, uint8_t location, uint8_t disturber) { // start by powering up AS3935_PowerUp(); // indoors/outdoors next... if(1 == location) // set outdoors if 1 { AS3935_SetOutdoors(); } else // set indoors if anything but 1 { AS3935_SetIndoors(); } // disturber cal if(0 == disturber) // disabled if 0 { AS3935_DisturberDis(); } else // enabled if anything but 0 { AS3935_DisturberEn(); } AS3935_SetIRQ_Output_Source(0); delay(500); // capacitance first... directly write value here AS3935_SetTuningCaps(capacitance); Serial.println("AS3935 manual cal complete"); } // a nice function would be to read the last 'x' strike data values....