/**************************************************************************** * * Copyright (c) 2019 PX4 Development Team. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * 3. Neither the name PX4 nor the names of its contributors may be * used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. * ****************************************************************************/ #include "DPS310.hpp" using namespace Infineon_DPS310; namespace dps310 { template static void getTwosComplement(T &raw, uint8_t length) { if (raw & ((T)1 << (length - 1))) { raw -= (T)1 << length; } } DPS310::DPS310(I2CSPIBusOption bus_option, int bus, device::Device *interface) : I2CSPIDriver(MODULE_NAME, px4::device_bus_to_wq(interface->get_device_id()), bus_option, bus, interface->get_device_address()), _px4_barometer(interface->get_device_id()), _interface(interface), _sample_perf(perf_alloc(PC_ELAPSED, MODULE_NAME": read")), _comms_errors(perf_alloc(PC_COUNT, MODULE_NAME": comm errors")) { } DPS310::~DPS310() { perf_free(_sample_perf); perf_free(_comms_errors); delete _interface; } int DPS310::init() { if (RegisterRead(Register::ID) != Infineon_DPS310::REV_AND_PROD_ID) { PX4_ERR("Product_ID mismatch"); return PX4_ERROR; } if (reset() != OK) { PX4_DEBUG("reset failed"); return PX4_ERROR; } start(); return PX4_OK; } int DPS310::reset() { // Soft Reset RegisterSetBits(Register::RESET, RESET_BIT::SOFT_RST); usleep(40000); // 40 milliseconds const uint8_t mode_and_status = RegisterRead(Register::MEAS_CFG); bool coefficients_ready = mode_and_status & MEAS_CFG_BIT::COEF_RDY; bool sensor_ready = mode_and_status & MEAS_CFG_BIT::SENSOR_RDY; if (!coefficients_ready) { PX4_ERR("Coefficients are not available"); return PX4_ERROR; } if (!sensor_ready) { PX4_ERR("Sensor initialization not complete"); return PX4_ERROR; } // 1. Read the pressure calibration coefficients (c00, c10, c20, c30, c01, c11, and c21) from the Calibration Coefficient register. // Note: The coefficients read from the coefficient register are 2's complement numbers. uint8_t coef[18] {}; if (_interface->read((uint8_t)Register::COEF, coef, 18)) { return PX4_ERROR; } // first element of coef[18] corresponds to register 0x10 // 0x11 c0 [3:0] + 0x10 c0 [11:4] _calibration.c0 = ((uint32_t)coef[0] << 4) | (((uint32_t)coef[1] >> 4) & 0x0F); getTwosComplement(_calibration.c0, 12); // 0x11 c1 [11:8] + 0x12 c1 [7:0] _calibration.c1 = (((uint32_t)coef[1] & 0x0F) << 8) | (uint32_t)coef[2]; getTwosComplement(_calibration.c1, 12); // 0x13 c00 [19:12] + 0x14 c00 [11:4] + 0x15 c00 [3:0] _calibration.c00 = ((uint32_t)coef[3] << 12) | ((uint32_t)coef[4] << 4) | (((uint32_t)coef[5] >> 4) & 0x0F); getTwosComplement(_calibration.c00, 20); // 0x15 c10 [19:16] + 0x16 c10 [15:8] + 0x17 c10 [7:0] _calibration.c10 = (((uint32_t)coef[5] & 0x0F) << 16) | ((uint32_t)coef[6] << 8) | (uint32_t)coef[7]; getTwosComplement(_calibration.c10, 20); // 0x18 c01 [15:8] + 0x19 c01 [7:0] _calibration.c01 = ((uint32_t)coef[8] << 8) | (uint32_t)coef[9]; getTwosComplement(_calibration.c01, 16); // 0x1A c11 [15:8] + 0x1B c11 [7:0] _calibration.c11 = ((uint32_t)coef[8] << 8) | (uint32_t)coef[9]; getTwosComplement(_calibration.c11, 16); // 0x1C c20 [15:8] + 0x1D c20 [7:0] _calibration.c20 = ((uint32_t)coef[12] << 8) | (uint32_t)coef[13]; getTwosComplement(_calibration.c20, 16); // 0x1E c21 [15:8] + 0x1F c21 [7:0] _calibration.c21 = ((uint32_t)coef[14] << 8) | (uint32_t)coef[15]; getTwosComplement(_calibration.c21, 16); // 0x20 c30 [15:8] + 0x21 c30 [7:0] _calibration.c30 = ((uint32_t)coef[16] << 8) | (uint32_t)coef[17]; getTwosComplement(_calibration.c30, 16); // PRS_CFG: pressure measurement rate (32 Hz) and oversampling (16 time standard) RegisterSetBits(Register::PRS_CFG, PRS_CFG_BIT::PM_RATE_32HZ | PRS_CFG_BIT::PM_PRC_16); // TMP_CFG: temperature measurement rate (32 Hz) and oversampling (16 times) const uint8_t TMP_COEF_SRCE = RegisterRead(Register::COEF_SRCE) & COEF_SRCE_BIT::TMP_COEF_SRCE; RegisterSetBits(Register::TMP_CFG, TMP_CFG_BIT::TMP_RATE_32HZ | TMP_CFG_BIT::TMP_PRC_16 | TMP_COEF_SRCE); // CFG_REG: set pressure and temperature result bit-shift (required when the oversampling rate is >8 times) RegisterSetBits(Register::CFG_REG, CFG_REG_BIT::T_SHIFT | CFG_REG_BIT::P_SHIFT); // MEAS_CFG: Continous pressure and temperature measurement RegisterSetBits(Register::MEAS_CFG, MEAS_CFG_BIT::MEAS_CTRL_CONT); return PX4_OK; } void DPS310::start() { // run at twice the sample rate to capture all new data ScheduleOnInterval(1000000 / SAMPLE_RATE / 2); } void DPS310::RunImpl() { perf_begin(_sample_perf); // check if pressure ready bool pressure_ready = RegisterRead(Register::MEAS_CFG) & MEAS_CFG_BIT::PRS_RDY; if (!pressure_ready) { perf_end(_sample_perf); return; } // 2. Choose scaling factors kT (for temperature) and kP (for pressure) based on the chosen precision rate. The scaling factors are listed in Table 9. static constexpr float kT = 253952; // 16 times (Standard) static constexpr float kP = 253952; // 16 times (Standard) // 3. Read the pressure and temperature result from the registers // Read PSR_B2, PSR_B1, PSR_B0, TMP_B2, TMP_B1, TMP_B0 uint8_t buf[6] {}; const hrt_abstime timestamp_sample = hrt_absolute_time(); if (_interface->read((uint8_t)Register::PSR_B2, buf, 6) != PX4_OK) { perf_count(_comms_errors); perf_end(_sample_perf); return; } int32_t Praw = (buf[0] << 16) + (buf[1] << 8) + buf[2]; getTwosComplement(Praw, 24); int32_t Traw = (buf[3] << 16) + (buf[4] << 8) + buf[5]; getTwosComplement(Traw, 24); // 4. Calculate scaled measurement results. const float Praw_sc = Praw / kP; const float Traw_sc = Traw / kT; // 5. Calculate compensated measurement results. const auto &c00 = _calibration.c00; const auto &c01 = _calibration.c01; const auto &c10 = _calibration.c10; const auto &c11 = _calibration.c11; const auto &c20 = _calibration.c20; const auto &c21 = _calibration.c21; const auto &c30 = _calibration.c30; const float Pcomp = c00 + Praw_sc * (c10 + Praw_sc * (c20 + Praw_sc * c30)) + Traw_sc * c01 + Traw_sc * Praw_sc * (c11 + Praw_sc * c21); const auto &c0 = _calibration.c0; const auto &c1 = _calibration.c1; const float Tcomp = c0 * 0.5f + c1 * Traw_sc; _px4_barometer.set_error_count(perf_event_count(_comms_errors)); _px4_barometer.set_temperature(Tcomp); _px4_barometer.update(timestamp_sample, Pcomp / 100.0f); // Pascals -> Millibar perf_end(_sample_perf); } uint8_t DPS310::RegisterRead(Register reg) { uint8_t buf{}; _interface->read((uint8_t)reg, &buf, 1); return buf; } void DPS310::RegisterWrite(Register reg, uint8_t value) { _interface->write((uint8_t)reg, &value, 1); } void DPS310::RegisterSetBits(Register reg, uint8_t setbits) { uint8_t val = RegisterRead(reg); if (!(val & setbits)) { val |= setbits; RegisterWrite(reg, val); } } void DPS310::RegisterClearBits(Register reg, uint8_t clearbits) { uint8_t val = RegisterRead(reg); if (val & clearbits) { val &= !clearbits; RegisterWrite(reg, val); } } void DPS310::print_status() { I2CSPIDriverBase::print_status(); perf_print_counter(_sample_perf); perf_print_counter(_comms_errors); } } // namespace dps310