/// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*- #include #include "AP_AnalogSource_Arduino.h" // increase this if we need more than 5 analog sources #define MAX_PIN_SOURCES 5 // number of times to read a pin // before considering the value valid. // This ensures the value has settled on // the new source #define PIN_READ_REPEAT 2 static uint8_t num_pins_watched; static uint8_t next_pin_index; static uint8_t next_pin_count; static volatile struct { uint8_t pin; uint8_t sum_count; uint16_t output; uint16_t sum; } pins[MAX_PIN_SOURCES]; // ADC conversion timer. This is called at 1kHz by the timer // interrupt // each conversion takes about 125 microseconds static void adc_timer(uint32_t t) { if (bit_is_set(ADCSRA, ADSC) || num_pins_watched == 0) { // conversion is still running. This should be // very rare, as we are called at 1kHz return; } next_pin_count++; if (next_pin_count != PIN_READ_REPEAT) { // we don't want this value, so start the next conversion // immediately, discarding this value ADCSRA |= _BV(ADSC); return; } // remember the value we got uint8_t low = ADCL; uint8_t high = ADCH; pins[next_pin_index].output = low | (high<<8); pins[next_pin_index].sum += pins[next_pin_index].output; if (pins[next_pin_index].sum_count >= 63) { // we risk overflowing the 16 bit sum pins[next_pin_index].sum >>= 1; pins[next_pin_index].sum_count = 32; } else { pins[next_pin_index].sum_count++; } next_pin_count = 0; if (num_pins_watched != 0) { next_pin_index = (next_pin_index+1) % num_pins_watched; } uint8_t pin = pins[next_pin_index].pin; if (pin == ANALOG_PIN_VCC) { // we're reading the board voltage ADMUX = _BV(REFS0)|_BV(MUX4)|_BV(MUX3)|_BV(MUX2)|_BV(MUX1); } else { // we're reading an external pin ADCSRB = (ADCSRB & ~(1 << MUX5)) | (((pin >> 3) & 0x01) << MUX5); ADMUX = _BV(REFS0) | (pin & 0x07); } // start the next conversion ADCSRA |= _BV(ADSC); } // setup the timer process. This must be called before any analog // values are available void AP_AnalogSource_Arduino::init_timer(AP_PeriodicProcess * scheduler) { scheduler->register_process(adc_timer); } // read raw 16 bit value uint16_t AP_AnalogSource_Arduino::read_raw(void) { uint16_t ret; cli(); ret = pins[_pin_index].output; sei(); return ret; } // scaled read for board Vcc uint16_t AP_AnalogSource_Arduino::read_vcc(void) { uint16_t v = read_raw(); if (v == 0) { return 0; } return 1126400UL / v; } // read the average 16 bit value since the last // time read_average() was called. This gives a very cheap // filtered value, as new values are produced at 500/N Hz // where N is the total number of analog sources float AP_AnalogSource_Arduino::read_average(void) { uint16_t sum; uint8_t sum_count; // we don't expect this loop to trigger, unless // you call read_average() very frequently while (pins[_pin_index].sum_count == 0) ; cli(); sum = pins[_pin_index].sum; sum_count = pins[_pin_index].sum_count; pins[_pin_index].sum = 0; pins[_pin_index].sum_count = 0; sei(); return sum / (float)sum_count; } // read with the prescaler. This uses the averaged value since // the last read, which matches that the AP_ADC APM1 library does // for ADC sources float AP_AnalogSource_Arduino::read(void) { return read_average() * _prescale; } // assign a slot in the pins_watched void AP_AnalogSource_Arduino::assign_pin_index(uint8_t pin) { // ensure we don't try to read from too many analog pins if (num_pins_watched == MAX_PIN_SOURCES) { while (true) { Serial.printf_P(PSTR("MAX_PIN_SOURCES REACHED\n")); delay(1000); } } if (pin != ANALOG_PIN_VCC) { // allow pin to be a channel (i.e. "A0") or an actual pin #if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__) if (pin >= 54) pin -= 54; #elif defined(__AVR_ATmega32U4__) if (pin >= 18) pin -= 18; #elif defined(__AVR_ATmega1284__) if (pin >= 24) pin -= 24; #else if (pin >= 14) pin -= 14; #endif } _pin_index = num_pins_watched; pins[_pin_index].pin = pin; num_pins_watched++; if (num_pins_watched == 1) { // enable the ADC PRR0 &= ~_BV(PRADC); ADCSRA |= _BV(ADEN); } }