/
pP_function.h
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/
pP_function.h
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/*
pyr0-piezo functions library
Created by Alan "pyr0ball" Weinstock 6/26/2019
*/
void digitalWriteFast(uint8_t pin, uint8_t x) {
if (pin / 8) { // pin >= 8
PORTB ^= (-x ^ PORTB) & (1 << (pin % 8));
}
else {
PORTD ^= (-x ^ PORTD) & (1 << (pin % 8));
}
}
/*------------------------------------------------*/
void pulse() {
digitalWriteFast(TRG_OUT, LOW);
sensorHReading = 1;
delay(TRG_DUR);
digitalWriteFast(TRG_OUT, HIGH);
}
/*------------------------------------------------*/
long readVcc() {
// Read 1.1V reference against AVcc
// Atmega's Secret Voltmeter setup:
// set the reference to Vcc and the measurement to the internal 1.1V reference
#if defined(__AVR_ATmega32U4__) || defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__)
ADMUX = _BV(REFS0) | _BV(MUX4) | _BV(MUX3) | _BV(MUX2) | _BV(MUX1);
#elif defined(__AVR_ATtiny24__) || defined(__AVR_ATtiny44__) || defined(__AVR_ATtiny84__)
ADMUX = _BV(MUX5) | _BV(MUX0);
#elif defined(__AVR_ATtiny25__) || defined(__AVR_ATtiny45__) || defined(__AVR_ATtiny85__)
ADMUX = _BV(MUX3) | _BV(MUX2);
#else
ADMUX = _BV(REFS0) | _BV(MUX3) | _BV(MUX2) | _BV(MUX1);
#endif
delay(2); // Wait for vref to settle
ADCSRA |= _BV(ADSC); // Start conversion
while (bit_is_set(ADCSRA,ADSC)); // measuring
uint8_t low = ADCL; // must read ADCL first - it then locks ADCH
uint8_t high = ADCH; // unlocks both
long result = (high<<8) | low;
result = voltMeterConstant / result; // Calculate Vcc (in mV); 1125300 = 1.1*1023*1000
return result; // Vcc in millivolts
}
/*-------------------------------------------------
The above function assumes an "ideal" multiplier constant.
Each Atmega chip is slightly different, so it won't be completely accurate
without tuning. Most of the time this won't be necessary, so don't mess
with this if you don't know what you're doing!
The reading can be fine-tuned by using a multimeter, and this equation:
scale_constant = internal1.1Ref * 1023 * 1000
where
internal1.1Ref = 1.1 * Vcc1 (per voltmeter) / Vcc2 (per readVcc() function)
If the scale_constant calculated is different from the default 1125300,
update the voltMeterConstant variable in pP_config.h with the correct value
--------------------------------------------------*/
void readVin() {
VOld = Vin;
Vin = readVcc(), DEC;
followerLong = followerThrs * 1023L;
compLong = compThrs * 1023L;
followerInt = (long long) followerLong / Vin;
compInt = (long long) compLong / Vin;
followerInt = (int) followerInt;
compInt = (int) compInt;
}
/*------------------------------------------------*/
void adjustFollow() {
/* Compares diffs of threshold vs read value
if positive, adjusts the follower to within
the range set above*/
ADJ_FOLLOW = (followerInt / 4);
// Analog output (PWM) of duty cycle
OCR2B = ADJ_FOLLOW;
}
/*------------------------------------------------*/
void adjustComp() {
OCR1A = compInt;
}
/*------------------------------------------------*/
void calibrateAlert() {
VLast = VOld - Vin;
if (VLast > Hyst || VLast < -Hyst ) {
ERR_STATE = 1;
}
}
/*------------------------------------------------*/
void adjustGain() {
if (GAIN_FACTOR == 0) {
pinMode(GADJ_R3, INPUT);
pinMode(GADJ_R2, INPUT);
pinMode(GADJ_R1, INPUT);
pinMode(GADJ_R0, INPUT);
}
else if (GAIN_FACTOR > 0) {
pinMode(GADJ_R3, OUTPUT);
digitalWrite(GADJ_R3, LOW);
pinMode(GADJ_R2, INPUT);
pinMode(GADJ_R1, INPUT);
pinMode(GADJ_R0, INPUT);
}
else if (GAIN_FACTOR > 1) {
pinMode(GADJ_R2, OUTPUT);
digitalWrite(GADJ_R2, LOW);
pinMode(GADJ_R1, INPUT);
pinMode(GADJ_R0, INPUT);
}
else if (GAIN_FACTOR > 2) {
pinMode(GADJ_R1, OUTPUT);
digitalWrite(GADJ_R1, LOW);
pinMode(GADJ_R0, INPUT);
}
else if (GAIN_FACTOR > 3) {
pinMode(GADJ_R0, OUTPUT);
digitalWrite(GADJ_R0, LOW);
}
}
/*------------------------------------------------*/
void checkError () {
if (ERR_STATE == 1) {
digitalWrite(ERR_LED, BlinkState);
BlinkState = !BlinkState;
}
else if (ERR_STATE == 0) {
BlinkState = LOW;
digitalWrite(ERR_LED, BlinkState);
}
}