mirror of https://github.com/ArduPilot/ardupilot
660 lines
19 KiB
C++
660 lines
19 KiB
C++
/*
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* This file is free software: you can redistribute it and/or modify it
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* under the terms of the GNU General Public License as published by the
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* Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* This file is distributed in the hope that it will be useful, but
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* WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
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* See the GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License along
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* with this program. If not, see <http://www.gnu.org/licenses/>.
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*
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* Code by Andrew Tridgell and Siddharth Bharat Purohit
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*/
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#include <AP_HAL/AP_HAL.h>
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#include "ch.h"
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#include "hal.h"
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#if HAL_USE_ADC == TRUE && !defined(HAL_DISABLE_ADC_DRIVER)
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#include "AnalogIn.h"
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#if HAL_WITH_IO_MCU
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#include <AP_IOMCU/AP_IOMCU.h>
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extern AP_IOMCU iomcu;
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#endif
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#include "hwdef/common/stm32_util.h"
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// MAVLink is included as we send a mavlink message as part of debug,
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// and also use the MAV_POWER flags below in update_power_flags
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#include <GCS_MAVLink/GCS_MAVLink.h>
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#define ANLOGIN_DEBUGGING 0
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// base voltage scaling for 12 bit 3.3V ADC
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#define VOLTAGE_SCALING (3.3f / ((1 << 12) - 1))
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// voltage divider is usually 1/(10/(20+10))
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#ifndef HAL_IOMCU_VSERVO_SCALAR
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#define HAL_IOMCU_VSERVO_SCALAR 3
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#endif
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// voltage divider is usually not present
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#ifndef HAL_IOMCU_VRSSI_SCALAR
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#define HAL_IOMCU_VRSSI_SCALAR 1
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#endif
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#if ANLOGIN_DEBUGGING
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# define Debug(fmt, args ...) do {printf("%s:%d: " fmt "\n", __FUNCTION__, __LINE__, ## args); } while(0)
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#else
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# define Debug(fmt, args ...)
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#endif
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extern const AP_HAL::HAL& hal;
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using namespace ChibiOS;
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// special pins
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#define ANALOG_SERVO_VRSSI_PIN 103
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/*
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scaling table between ADC count and actual input voltage, to account
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for voltage dividers on the board.
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*/
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const AnalogIn::pin_info AnalogIn::pin_config[] = HAL_ANALOG_PINS;
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#define ADC_GRP1_NUM_CHANNELS ARRAY_SIZE(AnalogIn::pin_config)
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#if defined(ADC_CFGR_RES_16BITS)
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// on H7 we use 16 bit ADC transfers, giving us more resolution. We
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// need to scale by 1/16 to match the 12 bit scale factors in hwdef.dat
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#define ADC_BOARD_SCALING (1.0/16)
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#else
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#define ADC_BOARD_SCALING 1
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#endif
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// samples filled in by ADC DMA engine
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adcsample_t *AnalogIn::samples;
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uint32_t AnalogIn::sample_sum[ADC_GRP1_NUM_CHANNELS];
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uint32_t AnalogIn::sample_count;
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AnalogSource::AnalogSource(int16_t pin) :
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_pin(pin)
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{
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}
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float AnalogSource::read_average()
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{
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WITH_SEMAPHORE(_semaphore);
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if (_sum_count == 0) {
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return _value;
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}
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_value = _sum_value / _sum_count;
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_value_ratiometric = _sum_ratiometric / _sum_count;
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_sum_value = 0;
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_sum_ratiometric = 0;
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_sum_count = 0;
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return _value;
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}
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float AnalogSource::read_latest()
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{
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return _latest_value;
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}
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/*
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return scaling from ADC count to Volts
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*/
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float AnalogSource::_pin_scaler(void)
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{
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float scaling = VOLTAGE_SCALING;
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for (uint8_t i=0; i<ADC_GRP1_NUM_CHANNELS; i++) {
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if (AnalogIn::pin_config[i].channel == _pin) {
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scaling = AnalogIn::pin_config[i].scaling;
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break;
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}
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}
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return scaling;
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}
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/*
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return voltage in Volts
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*/
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float AnalogSource::voltage_average()
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{
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return _pin_scaler() * read_average();
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}
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/*
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return voltage in Volts, assuming a ratiometric sensor powered by
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the 5V rail
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*/
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float AnalogSource::voltage_average_ratiometric()
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{
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voltage_average();
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return _pin_scaler() * _value_ratiometric;
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}
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/*
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return voltage in Volts
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*/
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float AnalogSource::voltage_latest()
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{
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return _pin_scaler() * read_latest();
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}
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bool AnalogSource::set_pin(uint8_t pin)
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{
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if (_pin == pin) {
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return true;
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}
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bool found_pin = false;
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if (pin == ANALOG_SERVO_VRSSI_PIN) {
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found_pin = true;
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} else {
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for (uint8_t i=0; i<ADC_GRP1_NUM_CHANNELS; i++) {
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if (AnalogIn::pin_config[i].channel == pin) {
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found_pin = true;
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break;
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}
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}
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}
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if (!found_pin) {
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return false;
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}
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WITH_SEMAPHORE(_semaphore);
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_pin = pin;
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_sum_value = 0;
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_sum_ratiometric = 0;
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_sum_count = 0;
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_latest_value = 0;
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_value = 0;
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_value_ratiometric = 0;
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return true;
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}
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/*
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apply a reading in ADC counts
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*/
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void AnalogSource::_add_value(float v, float vcc5V)
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{
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WITH_SEMAPHORE(_semaphore);
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_latest_value = v;
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_sum_value += v;
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if (vcc5V < 3.0f) {
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_sum_ratiometric += v;
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} else {
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// this compensates for changes in the 5V rail relative to the
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// 3.3V reference used by the ADC.
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_sum_ratiometric += v * 5.0f / vcc5V;
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}
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_sum_count++;
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if (_sum_count == 254) {
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_sum_value /= 2;
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_sum_ratiometric /= 2;
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_sum_count /= 2;
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}
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}
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/*
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callback from ADC driver when sample buffer is filled
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*/
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void AnalogIn::adccallback(ADCDriver *adcp)
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{
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const adcsample_t *buffer = samples;
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stm32_cacheBufferInvalidate(buffer, sizeof(adcsample_t)*ADC_DMA_BUF_DEPTH*ADC_GRP1_NUM_CHANNELS);
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for (uint8_t i = 0; i < ADC_DMA_BUF_DEPTH; i++) {
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for (uint8_t j = 0; j < ADC_GRP1_NUM_CHANNELS; j++) {
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sample_sum[j] += *buffer++;
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}
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}
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sample_count += ADC_DMA_BUF_DEPTH;
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}
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/*
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setup adc peripheral to capture samples with DMA into a buffer
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*/
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void AnalogIn::init()
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{
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static_assert(sizeof(uint16_t) == sizeof(adcsample_t), "adcsample_t must be uint16_t");
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if (ADC_GRP1_NUM_CHANNELS == 0) {
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return;
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}
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samples = (adcsample_t *)hal.util->malloc_type(sizeof(adcsample_t)*ADC_DMA_BUF_DEPTH*ADC_GRP1_NUM_CHANNELS, AP_HAL::Util::MEM_DMA_SAFE);
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adcStart(&ADCD1, NULL);
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memset(&adcgrpcfg, 0, sizeof(adcgrpcfg));
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adcgrpcfg.circular = true;
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adcgrpcfg.num_channels = ADC_GRP1_NUM_CHANNELS;
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adcgrpcfg.end_cb = adccallback;
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#if defined(ADC_CFGR_RES_16BITS)
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// use 16 bit resolution
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adcgrpcfg.cfgr = ADC_CFGR_CONT | ADC_CFGR_RES_16BITS;
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#elif defined(ADC_CFGR_RES_12BITS)
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// use 12 bit resolution
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adcgrpcfg.cfgr = ADC_CFGR_CONT | ADC_CFGR_RES_12BITS;
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#else
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// use 12 bit resolution with ADCv1 or ADCv2
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adcgrpcfg.sqr1 = ADC_SQR1_NUM_CH(ADC_GRP1_NUM_CHANNELS);
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adcgrpcfg.cr2 = ADC_CR2_SWSTART;
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#endif
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for (uint8_t i=0; i<ADC_GRP1_NUM_CHANNELS; i++) {
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uint8_t chan = pin_config[i].channel;
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// setup cycles per sample for the channel
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#if defined(STM32H7)
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adcgrpcfg.pcsel |= (1<<chan);
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adcgrpcfg.smpr[chan/10] |= ADC_SMPR_SMP_384P5 << (3*(chan%10));
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if (i < 4) {
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adcgrpcfg.sqr[0] |= chan << (6*(i+1));
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} else if (i < 9) {
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adcgrpcfg.sqr[1] |= chan << (6*(i-4));
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} else {
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adcgrpcfg.sqr[2] |= chan << (6*(i-9));
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}
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#elif defined(STM32F3) || defined(STM32G4) || defined(STM32L4)
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#if defined(STM32G4) || defined(STM32L4)
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adcgrpcfg.smpr[chan/10] |= ADC_SMPR_SMP_640P5 << (3*(chan%10));
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#else
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adcgrpcfg.smpr[chan/10] |= ADC_SMPR_SMP_601P5 << (3*(chan%10));
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#endif
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// setup channel sequence
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if (i < 4) {
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adcgrpcfg.sqr[0] |= chan << (6*(i+1));
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} else if (i < 9) {
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adcgrpcfg.sqr[1] |= chan << (6*(i-4));
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} else {
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adcgrpcfg.sqr[2] |= chan << (6*(i-9));
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}
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#else
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if (chan < 10) {
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adcgrpcfg.smpr2 |= ADC_SAMPLE_480 << (3*chan);
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} else {
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adcgrpcfg.smpr1 |= ADC_SAMPLE_480 << (3*(chan-10));
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}
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// setup channel sequence
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if (i < 6) {
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adcgrpcfg.sqr3 |= chan << (5*i);
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} else if (i < 12) {
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adcgrpcfg.sqr2 |= chan << (5*(i-6));
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} else {
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adcgrpcfg.sqr1 |= chan << (5*(i-12));
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}
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#endif
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}
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adcStartConversion(&ADCD1, &adcgrpcfg, samples, ADC_DMA_BUF_DEPTH);
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#if HAL_WITH_MCU_MONITORING
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setup_adc3();
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#endif
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}
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/*
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calculate average sample since last read for all channels
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*/
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void AnalogIn::read_adc(uint32_t *val)
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{
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chSysLock();
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for (uint8_t i = 0; i < ADC_GRP1_NUM_CHANNELS; i++) {
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val[i] = sample_sum[i] / sample_count;
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}
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memset(sample_sum, 0, sizeof(sample_sum));
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sample_count = 0;
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chSysUnlock();
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}
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#if HAL_WITH_MCU_MONITORING
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/*
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on H7 we can support monitoring MCU temperature and voltage using ADC3
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*/
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#define ADC3_GRP1_NUM_CHANNELS 3
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// internal ADC channels (from H7 reference manual)
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#define ADC3_VSENSE_CHAN 18
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#define ADC3_VREFINT_CHAN 19
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#define ADC3_VBAT4_CHAN 17
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// samples filled in by ADC DMA engine
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adcsample_t *AnalogIn::samples_adc3;
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uint32_t AnalogIn::sample_adc3_sum[ADC3_GRP1_NUM_CHANNELS];
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// we also keep min and max so we can report the range of voltages
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// seen, to give an idea of supply stability
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uint16_t AnalogIn::sample_adc3_max[ADC3_GRP1_NUM_CHANNELS];
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uint16_t AnalogIn::sample_adc3_min[ADC3_GRP1_NUM_CHANNELS];
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uint32_t AnalogIn::sample_adc3_count;
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/*
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callback from ADC3 driver when sample buffer is filled
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*/
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void AnalogIn::adc3callback(ADCDriver *adcp)
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{
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const adcsample_t *buffer = samples_adc3;
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stm32_cacheBufferInvalidate(buffer, sizeof(adcsample_t)*ADC_DMA_BUF_DEPTH*ADC3_GRP1_NUM_CHANNELS);
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for (uint8_t i = 0; i < ADC_DMA_BUF_DEPTH; i++) {
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for (uint8_t j = 0; j < ADC3_GRP1_NUM_CHANNELS; j++) {
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const uint16_t v = *buffer++;
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sample_adc3_sum[j] += v;
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if (sample_adc3_min[j] == 0 ||
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sample_adc3_min[j] > v) {
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sample_adc3_min[j] = v;
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}
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if (sample_adc3_max[j] == 0 ||
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sample_adc3_max[j] < v) {
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sample_adc3_max[j] = v;
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}
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}
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}
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sample_adc3_count += ADC_DMA_BUF_DEPTH;
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}
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/*
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setup ADC3 for internal temperature and voltage monitoring
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*/
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void AnalogIn::setup_adc3(void)
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{
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samples_adc3 = (adcsample_t *)hal.util->malloc_type(sizeof(adcsample_t)*ADC_DMA_BUF_DEPTH*ADC3_GRP1_NUM_CHANNELS, AP_HAL::Util::MEM_DMA_SAFE);
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if (samples_adc3 == nullptr) {
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// not likely, but can't setup ADC3
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return;
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}
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adcStart(&ADCD3, NULL);
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adcSTM32EnableVREF(&ADCD3);
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adcSTM32EnableTS(&ADCD3);
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adcSTM32EnableVBAT(&ADCD3);
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memset(&adc3grpcfg, 0, sizeof(adc3grpcfg));
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adc3grpcfg.circular = true;
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adc3grpcfg.num_channels = ADC3_GRP1_NUM_CHANNELS;
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adc3grpcfg.end_cb = adc3callback;
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#if defined(ADC_CFGR_RES_16BITS)
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// use 16 bit resolution
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adc3grpcfg.cfgr = ADC_CFGR_CONT | ADC_CFGR_RES_16BITS;
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#elif defined(ADC_CFGR_RES_12BITS)
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// use 12 bit resolution
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adc3grpcfg.cfgr = ADC_CFGR_CONT | ADC_CFGR_RES_12BITS;
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#else
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// use 12 bit resolution with ADCv1 or ADCv2
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adc3grpcfg.sqr1 = ADC_SQR1_NUM_CH(ADC3_GRP1_NUM_CHANNELS);
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adc3grpcfg.cr2 = ADC_CR2_SWSTART;
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#endif
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const uint8_t channels[ADC3_GRP1_NUM_CHANNELS] = { ADC3_VBAT4_CHAN, ADC3_VSENSE_CHAN, ADC3_VREFINT_CHAN };
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for (uint8_t i=0; i<ADC3_GRP1_NUM_CHANNELS; i++) {
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uint8_t chan = channels[i];
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// setup cycles per sample for the channel
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adc3grpcfg.pcsel |= (1<<chan);
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adc3grpcfg.smpr[chan/10] |= ADC_SMPR_SMP_384P5 << (3*(chan%10));
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if (i < 4) {
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adc3grpcfg.sqr[0] |= chan << (6*(i+1));
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} else if (i < 9) {
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adc3grpcfg.sqr[1] |= chan << (6*(i-4));
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} else {
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adc3grpcfg.sqr[2] |= chan << (6*(i-9));
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}
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}
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adcStartConversion(&ADCD3, &adc3grpcfg, samples_adc3, ADC_DMA_BUF_DEPTH);
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}
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/*
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calculate average sample since last read for all channels
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*/
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void AnalogIn::read_adc3(uint32_t *val, uint16_t *min, uint16_t *max)
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{
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chSysLock();
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for (uint8_t i = 0; i < ADC3_GRP1_NUM_CHANNELS; i++) {
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val[i] = sample_adc3_sum[i] / sample_adc3_count;
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min[i] = sample_adc3_min[i];
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max[i] = sample_adc3_max[i];
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}
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memset(sample_adc3_sum, 0, sizeof(sample_adc3_sum));
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memset(sample_adc3_min, 0, sizeof(sample_adc3_min));
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memset(sample_adc3_max, 0, sizeof(sample_adc3_max));
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sample_adc3_count = 0;
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chSysUnlock();
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}
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#endif // HAL_WITH_MCU_MONITORING
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/*
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called at 1kHz
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*/
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void AnalogIn::_timer_tick(void)
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{
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// read adc at 100Hz
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uint32_t now = AP_HAL::micros();
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uint32_t delta_t = now - _last_run;
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if (delta_t < 10000) {
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return;
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}
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_last_run = now;
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uint32_t buf_adc[ADC_GRP1_NUM_CHANNELS];
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/* read all channels available */
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read_adc(buf_adc);
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// update power status flags
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update_power_flags();
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// match the incoming channels to the currently active pins
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for (uint8_t i=0; i < ADC_GRP1_NUM_CHANNELS; i++) {
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#ifdef ANALOG_VCC_5V_PIN
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if (pin_config[i].channel == ANALOG_VCC_5V_PIN) {
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// record the Vcc value for later use in
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// voltage_average_ratiometric()
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_board_voltage = buf_adc[i] * pin_config[i].scaling * ADC_BOARD_SCALING;
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}
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#endif
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#ifdef FMU_SERVORAIL_ADC_CHAN
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if (pin_config[i].channel == FMU_SERVORAIL_ADC_CHAN) {
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_servorail_voltage = buf_adc[i] * pin_config[i].scaling * ADC_BOARD_SCALING;
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}
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#endif
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}
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#if HAL_WITH_IO_MCU
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// now handle special inputs from IOMCU
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_servorail_voltage = iomcu.get_vservo_adc_count() * (VOLTAGE_SCALING * HAL_IOMCU_VSERVO_SCALAR);
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_rssi_voltage = iomcu.get_vrssi_adc_count() * (VOLTAGE_SCALING * HAL_IOMCU_VRSSI_SCALAR);
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#endif
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for (uint8_t i=0; i<ADC_GRP1_NUM_CHANNELS; i++) {
|
|
Debug("chan %u value=%u\n",
|
|
(unsigned)pin_config[i].channel,
|
|
(unsigned)buf_adc[i]);
|
|
for (uint8_t j=0; j < ANALOG_MAX_CHANNELS; j++) {
|
|
ChibiOS::AnalogSource *c = _channels[j];
|
|
if (c != nullptr) {
|
|
if (pin_config[i].channel == c->_pin) {
|
|
// add a value
|
|
c->_add_value(buf_adc[i] * ADC_BOARD_SCALING, _board_voltage);
|
|
} else if (c->_pin == ANALOG_SERVO_VRSSI_PIN) {
|
|
c->_add_value(_rssi_voltage / VOLTAGE_SCALING, 0);
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
#if HAL_WITH_MCU_MONITORING
|
|
// 20Hz temperature and ref voltage
|
|
static uint32_t last_mcu_temp_us;
|
|
if (now - last_mcu_temp_us > 50000 &&
|
|
hal.scheduler->is_system_initialized()) {
|
|
last_mcu_temp_us = now;
|
|
|
|
uint32_t buf_adc3[ADC3_GRP1_NUM_CHANNELS];
|
|
uint16_t min_adc3[ADC3_GRP1_NUM_CHANNELS];
|
|
uint16_t max_adc3[ADC3_GRP1_NUM_CHANNELS];
|
|
|
|
read_adc3(buf_adc3, min_adc3, max_adc3);
|
|
|
|
// factory calibration values
|
|
const float TS_CAL1 = *(const volatile uint16_t *)0x1FF1E820;
|
|
const float TS_CAL2 = *(const volatile uint16_t *)0x1FF1E840;
|
|
const float VREFINT_CAL = *(const volatile uint16_t *)0x1FF1E860;
|
|
|
|
_mcu_temperature = ((110 - 30) / (TS_CAL2 - TS_CAL1)) * (float(buf_adc3[1]) - TS_CAL1) + 30;
|
|
_mcu_voltage = 3.3 * VREFINT_CAL / float(buf_adc3[2]+0.001);
|
|
// note min/max swap due to inversion
|
|
_mcu_voltage_min = 3.3 * VREFINT_CAL / float(max_adc3[2]+0.001);
|
|
_mcu_voltage_max = 3.3 * VREFINT_CAL / float(min_adc3[2]+0.001);
|
|
}
|
|
#endif
|
|
}
|
|
|
|
AP_HAL::AnalogSource* AnalogIn::channel(int16_t pin)
|
|
{
|
|
WITH_SEMAPHORE(_semaphore);
|
|
for (uint8_t j=0; j<ANALOG_MAX_CHANNELS; j++) {
|
|
if (_channels[j] == nullptr) {
|
|
_channels[j] = new AnalogSource(pin);
|
|
return _channels[j];
|
|
}
|
|
}
|
|
DEV_PRINTF("Out of analog channels\n");
|
|
return nullptr;
|
|
}
|
|
|
|
/*
|
|
update power status flags
|
|
*/
|
|
void AnalogIn::update_power_flags(void)
|
|
{
|
|
uint16_t flags = 0;
|
|
|
|
/*
|
|
primary "brick" power supply valid pin. Some boards have this
|
|
active high, some active low. Use nVALID for active low, VALID
|
|
for active high
|
|
*/
|
|
#if defined(HAL_GPIO_PIN_VDD_BRICK_VALID)
|
|
if (palReadLine(HAL_GPIO_PIN_VDD_BRICK_VALID) == 1) {
|
|
flags |= MAV_POWER_STATUS_BRICK_VALID;
|
|
}
|
|
#elif defined(HAL_GPIO_PIN_VDD_BRICK_nVALID)
|
|
if (palReadLine(HAL_GPIO_PIN_VDD_BRICK_nVALID) == 0) {
|
|
flags |= MAV_POWER_STATUS_BRICK_VALID;
|
|
}
|
|
#endif
|
|
|
|
/*
|
|
secondary "brick" power supply valid pin. This is servo rail
|
|
power valid on some boards. Some boards have this active high,
|
|
some active low. Use nVALID for active low, VALID for active
|
|
high. This maps to the MAV_POWER_STATUS_SERVO_VALID in mavlink
|
|
(as this was first added for older boards that used servo rail
|
|
for backup power)
|
|
*/
|
|
#if defined(HAL_GPIO_PIN_VDD_BRICK2_VALID)
|
|
if (palReadLine(HAL_GPIO_PIN_VDD_BRICK_VALID) == 1) {
|
|
flags |= MAV_POWER_STATUS_SERVO_VALID;
|
|
}
|
|
#elif defined(HAL_GPIO_PIN_VDD_BRICK2_nVALID)
|
|
if (palReadLine(HAL_GPIO_PIN_VDD_BRICK2_nVALID) == 0) {
|
|
flags |= MAV_POWER_STATUS_SERVO_VALID;
|
|
}
|
|
#endif
|
|
|
|
/*
|
|
USB power. This can be VBUS_VALID, VBUS_nVALID or just
|
|
VBUS. Some boards have both a valid pin and VBUS. The VBUS pin
|
|
is an analog pin that could be used to read USB voltage.
|
|
*/
|
|
#if defined(HAL_GPIO_PIN_VBUS_VALID)
|
|
if (palReadLine(HAL_GPIO_PIN_VBUS_VALID) == 1) {
|
|
flags |= MAV_POWER_STATUS_USB_CONNECTED;
|
|
}
|
|
#elif defined(HAL_GPIO_PIN_VBUS_nVALID)
|
|
if (palReadLine(HAL_GPIO_PIN_VBUS_nVALID) == 0) {
|
|
flags |= MAV_POWER_STATUS_USB_CONNECTED;
|
|
}
|
|
#elif defined(HAL_GPIO_PIN_VBUS)
|
|
if (palReadLine(HAL_GPIO_PIN_VBUS) == 1) {
|
|
flags |= MAV_POWER_STATUS_USB_CONNECTED;
|
|
}
|
|
#endif
|
|
|
|
/*
|
|
overcurrent on "high power" peripheral rail.
|
|
*/
|
|
#if defined(HAL_GPIO_PIN_VDD_5V_HIPOWER_OC)
|
|
if (palReadLine(HAL_GPIO_PIN_VDD_5V_HIPOWER_OC) == 1) {
|
|
flags |= MAV_POWER_STATUS_PERIPH_HIPOWER_OVERCURRENT;
|
|
}
|
|
#elif defined(HAL_GPIO_PIN_VDD_5V_HIPOWER_nOC)
|
|
if (palReadLine(HAL_GPIO_PIN_VDD_5V_HIPOWER_nOC) == 0) {
|
|
flags |= MAV_POWER_STATUS_PERIPH_HIPOWER_OVERCURRENT;
|
|
}
|
|
#endif
|
|
|
|
/*
|
|
overcurrent on main peripheral rail.
|
|
*/
|
|
#if defined(HAL_GPIO_PIN_VDD_5V_PERIPH_OC)
|
|
if (palReadLine(HAL_GPIO_PIN_VDD_5V_PERIPH_OC) == 1) {
|
|
flags |= MAV_POWER_STATUS_PERIPH_OVERCURRENT;
|
|
}
|
|
#elif defined(HAL_GPIO_PIN_VDD_5V_PERIPH_nOC)
|
|
if (palReadLine(HAL_GPIO_PIN_VDD_5V_PERIPH_nOC) == 0) {
|
|
flags |= MAV_POWER_STATUS_PERIPH_OVERCURRENT;
|
|
}
|
|
#endif
|
|
|
|
#if defined(HAL_GPIO_PIN_VDD_SERVO_VALID)
|
|
#error "building with old hwdef.dat"
|
|
#endif
|
|
|
|
#if 0
|
|
/*
|
|
this bit of debug code is useful when testing the polarity of
|
|
VALID pins for power sources. It allows you to see the change on
|
|
USB with a 3s delay, so you can see USB changes by unplugging
|
|
and re-inserting USB power
|
|
*/
|
|
static uint32_t last_change_ms;
|
|
uint32_t now = AP_HAL::millis();
|
|
if (_power_flags != flags) {
|
|
if (last_change_ms == 0) {
|
|
last_change_ms = now;
|
|
} else if (now - last_change_ms > 3000) {
|
|
last_change_ms = 0;
|
|
hal.console->printf("POWR: 0x%02x -> 0x%02x\n", _power_flags, flags);
|
|
_power_flags = flags;
|
|
}
|
|
if (hal.util->get_soft_armed()) {
|
|
// the power status has changed while armed
|
|
flags |= MAV_POWER_STATUS_CHANGED;
|
|
}
|
|
return;
|
|
}
|
|
#endif
|
|
|
|
if (_power_flags != 0 &&
|
|
_power_flags != flags &&
|
|
hal.util->get_soft_armed()) {
|
|
// the power status has changed while armed
|
|
flags |= MAV_POWER_STATUS_CHANGED;
|
|
}
|
|
_accumulated_power_flags |= flags;
|
|
_power_flags = flags;
|
|
}
|
|
#endif // HAL_USE_ADC
|