/* This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ /* backend driver for airspeed from a I2C SDP3X sensor with thanks to https://github.com/PX4/Firmware/blob/master/src/drivers/sdp3x_airspeed */ #include "AP_Airspeed_SDP3X.h" #include #include #include #define SDP3X_SCALE_TEMPERATURE 200.0f #define SDP3XD0_I2C_ADDR 0x21 #define SDP3XD1_I2C_ADDR 0x22 #define SDP3XD2_I2C_ADDR 0x23 #define SDP3X_CONT_MEAS_AVG_MODE 0x3615 #define SDP3X_CONT_MEAS_STOP 0x3FF9 #define SDP3X_SCALE_PRESSURE_SDP31 60 #define SDP3X_SCALE_PRESSURE_SDP32 240 #define SDP3X_SCALE_PRESSURE_SDP33 20 extern const AP_HAL::HAL &hal; AP_Airspeed_SDP3X::AP_Airspeed_SDP3X(AP_Airspeed &_frontend, uint8_t _instance) : AP_Airspeed_Backend(_frontend, _instance) { } /* send a 16 bit command code */ bool AP_Airspeed_SDP3X::_send_command(uint16_t cmd) { uint8_t b[2] {uint8_t(cmd >> 8), uint8_t(cmd & 0xFF)}; return _dev->transfer(b, 2, nullptr, 0); } // probe and initialise the sensor bool AP_Airspeed_SDP3X::init() { const uint8_t addresses[3] = { SDP3XD0_I2C_ADDR, SDP3XD1_I2C_ADDR, SDP3XD2_I2C_ADDR }; bool found = false; bool ret = false; for (uint8_t i=0; iget_device(get_bus(), addresses[i]); if (!_dev) { continue; } _dev->get_semaphore()->take_blocking(); // lots of retries during probe _dev->set_retries(10); // stop continuous average mode if (!_send_command(SDP3X_CONT_MEAS_STOP)) { _dev->get_semaphore()->give(); continue; } // these delays are needed for reliable operation _dev->get_semaphore()->give(); hal.scheduler->delay_microseconds(20000); _dev->get_semaphore()->take_blocking(); // start continuous average mode if (!_send_command(SDP3X_CONT_MEAS_AVG_MODE)) { _dev->get_semaphore()->give(); continue; } // these delays are needed for reliable operation _dev->get_semaphore()->give(); hal.scheduler->delay_microseconds(20000); _dev->get_semaphore()->take_blocking(); // step 3 - get scale uint8_t val[9]; ret = _dev->transfer(nullptr, 0, &val[0], sizeof(val)); if (!ret) { _dev->get_semaphore()->give(); continue; } // Check the CRC if (!_crc(&val[0], 2, val[2]) || !_crc(&val[3], 2, val[5]) || !_crc(&val[6], 2, val[8])) { _dev->get_semaphore()->give(); continue; } _scale = (((uint16_t)val[6]) << 8) | val[7]; _dev->get_semaphore()->give(); found = true; #ifndef HAL_NO_GCS char c = 'X'; switch (_scale) { case SDP3X_SCALE_PRESSURE_SDP31: c = '1'; break; case SDP3X_SCALE_PRESSURE_SDP32: c = '2'; break; case SDP3X_SCALE_PRESSURE_SDP33: c = '3'; break; } GCS_SEND_TEXT(MAV_SEVERITY_INFO, "SDP3%c[%u]: Found bus %u addr 0x%02x scale=%u", get_instance(), c, get_bus(), addresses[i], _scale); #endif } if (!found) { return false; } /* this sensor uses zero offset and skips cal */ set_use_zero_offset(); set_skip_cal(); set_offset(0); _dev->set_device_type(uint8_t(DevType::SDP3X)); set_bus_id(_dev->get_bus_id()); // drop to 2 retries for runtime _dev->set_retries(2); _dev->register_periodic_callback(20000, FUNCTOR_BIND_MEMBER(&AP_Airspeed_SDP3X::_timer, void)); return true; } // read the values from the sensor. Called at 50Hz void AP_Airspeed_SDP3X::_timer() { // read 6 bytes from the sensor uint8_t val[6]; int ret = _dev->transfer(nullptr, 0, &val[0], sizeof(val)); uint32_t now = AP_HAL::millis(); if (!ret) { if (now - _last_sample_time_ms > 200) { // try and re-connect _send_command(SDP3X_CONT_MEAS_AVG_MODE); } return; } // Check the CRC if (!_crc(&val[0], 2, val[2]) || !_crc(&val[3], 2, val[5])) { return; } int16_t P = (((int16_t)val[0]) << 8) | val[1]; int16_t temp = (((int16_t)val[3]) << 8) | val[4]; float diff_press_pa = float(P) / float(_scale); float temperature = float(temp) / SDP3X_SCALE_TEMPERATURE; WITH_SEMAPHORE(sem); _press_sum += diff_press_pa; _temp_sum += temperature; _press_count++; _temp_count++; _last_sample_time_ms = now; } /* correct pressure for barometric height With thanks to: https://github.com/PX4/Firmware/blob/master/Tools/models/sdp3x_pitot_model.py */ float AP_Airspeed_SDP3X::_correct_pressure(float press) { float sign = 1.0f; // fix for tube order AP_Airspeed::pitot_tube_order tube_order = get_tube_order(); switch (tube_order) { case AP_Airspeed::PITOT_TUBE_ORDER_NEGATIVE: press = -press; sign = -1.0f; break; case AP_Airspeed::PITOT_TUBE_ORDER_POSITIVE: break; case AP_Airspeed::PITOT_TUBE_ORDER_AUTO: default: if (press < 0.0f) { sign = -1.0f; press = -press; } break; } if (press <= 0.0f) { return 0.0f; } AP_Baro *baro = AP_Baro::get_singleton(); if (baro == nullptr) { return press; } float temperature; if (!get_temperature(temperature)) { return press; } float rho_air = baro->get_pressure() / (ISA_GAS_CONSTANT * (temperature + C_TO_KELVIN)); /* the constants in the code below come from a calibrated test of the drotek pitot tube by Sensiron. They are specific to the droktek pitot tube At 25m/s, the rough proportions of each pressure correction are: - dp_pitot: 5% - press_correction: 14% - press: 81% dp_tube has been removed from the Sensiron model as it is insignificant (less than 0.02% over the supported speed ranges) */ // flow through sensor float flow_SDP3X = (300.805f - 300.878f / (0.00344205f * (float)powf(press, 0.68698f) + 1.0f)) * 1.29f / rho_air; if (flow_SDP3X < 0.0f) { flow_SDP3X = 0.0f; } // diffential pressure through pitot tube float dp_pitot = 28557670.0f * (1.0f - 1.0f / (1.0f + (float)powf((flow_SDP3X / 5027611.0f), 1.227924f))); // uncorrected pressure float press_uncorrected = (press + dp_pitot) / SSL_AIR_DENSITY; // correction for speed at pitot-tube tip due to flow through sensor float dv = 0.0331582f * flow_SDP3X; // airspeed ratio float ratio = get_airspeed_ratio(); if (!is_positive(ratio)) { // cope with AP_Periph where ratio is 0 ratio = 2.0; } // calculate equivalent pressure correction. This formula comes // from turning the dv correction above into an equivalent // pressure correction. We need to do this so the airspeed ratio // calibrator can work, as it operates on pressure values float press_correction = sq(sqrtf(press_uncorrected*ratio)+dv)/ratio - press_uncorrected; return (press_uncorrected + press_correction) * sign; } // return the current differential_pressure in Pascal bool AP_Airspeed_SDP3X::get_differential_pressure(float &pressure) { WITH_SEMAPHORE(sem); if (AP_HAL::millis() - _last_sample_time_ms > 100) { return false; } if (_press_count > 0) { _press = _press_sum / _press_count; _press_count = 0; _press_sum = 0; } pressure = _correct_pressure(_press); return true; } // return the current temperature in degrees C, if available bool AP_Airspeed_SDP3X::get_temperature(float &temperature) { WITH_SEMAPHORE(sem); if ((AP_HAL::millis() - _last_sample_time_ms) > 100) { return false; } if (_temp_count > 0) { _temp = _temp_sum / _temp_count; _temp_count = 0; _temp_sum = 0; } temperature = _temp; return true; } /* check CRC for a set of bytes */ bool AP_Airspeed_SDP3X::_crc(const uint8_t data[], uint8_t size, uint8_t checksum) { uint8_t crc_value = 0xff; // calculate 8-bit checksum with polynomial 0x31 (x^8 + x^5 + x^4 + 1) for (uint8_t i = 0; i < size; i++) { crc_value ^= data[i]; for (uint8_t bit = 8; bit > 0; --bit) { if (crc_value & 0x80) { crc_value = (crc_value << 1) ^ 0x31; } else { crc_value = (crc_value << 1); } } } // verify checksum return (crc_value == checksum); }