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@@ -3,32 +3,41 @@
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struct usData_t usData[2];
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struct usData_t usData[2];
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void us_0_isr() {
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void us_0_isr() {
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- if(digitalRead(US_RX_0_PIN)) {
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- usData[0].pulseStart = micros();
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- } else if(usData[0].rxPending) {
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- usData[0].duration = micros() - usData[0].pulseStart;
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- usData[0].rxPending = 0;
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- usData[0].newData = 1;
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+ if(digitalRead(US_RX_0_PIN) && usData[1].state == rxPending) {
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+ usData[0].pulseStart = TCNT1;
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+ usData[0].state = counting;
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+ } else if(usData[0].state == counting) {
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+ usData[0].duration = TCNT1 - usData[0].pulseStart;
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+ usData[0].state = finished;
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}
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}
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}
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}
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void us_1_isr() {
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void us_1_isr() {
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- if(digitalRead(US_RX_1_PIN)) {
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- usData[1].pulseStart = micros();
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- } else if(usData[1].rxPending) {
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- usData[1].duration = micros() - usData[1].pulseStart;
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- usData[1].rxPending = 0;
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- usData[1].newData = 1;
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+ if(digitalRead(US_RX_1_PIN) && usData[1].state == rxPending) {
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+ usData[1].pulseStart = TCNT1;
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+ usData[1].state = counting;
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+ } else if(usData[1].state == counting) {
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+ usData[1].duration = TCNT1 - usData[1].pulseStart;
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+ usData[1].state = finished;
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}
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}
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}
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}
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void us_init() {
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void us_init() {
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attachInterrupt(digitalPinToInterrupt(US_RX_0_PIN), us_0_isr, CHANGE);
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attachInterrupt(digitalPinToInterrupt(US_RX_0_PIN), us_0_isr, CHANGE);
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attachInterrupt(digitalPinToInterrupt(US_RX_1_PIN), us_1_isr, CHANGE);
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attachInterrupt(digitalPinToInterrupt(US_RX_1_PIN), us_1_isr, CHANGE);
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+
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+ //timer 1 is used as an accurate timer for measuring the TOF pulses
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+
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+ //1:1 prescaler for timer 1
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+ TCCR1A = 0;
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+ TCCR1B = _BV(CS10);
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+ //timer 1 now runs with 16MHz, therefore overflows every (2^16 / 16MHz) = 4096 us
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+
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}
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}
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void us_transmit() {
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void us_transmit() {
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- noInterrupts();
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+ //disable pin interrupts
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+ EIMSK = 0;
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pinMode(US_RX_0_PIN, OUTPUT);
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pinMode(US_RX_0_PIN, OUTPUT);
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pinMode(US_RX_1_PIN, OUTPUT);
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pinMode(US_RX_1_PIN, OUTPUT);
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@@ -48,19 +57,19 @@ void us_transmit() {
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pinMode(US_RX_1_PIN, INPUT);
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pinMode(US_RX_1_PIN, INPUT);
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pinMode(US_TX_0_PIN, INPUT);
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pinMode(US_TX_0_PIN, INPUT);
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- interrupts();
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+ //enable pin interrupts
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+ EIMSK = _BV(INT1) | _BV(INT0);
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- usData[0].rxPending = 1;
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- usData[1].rxPending = 1;
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+ usData[0].state = rxPending;
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+ usData[1].state = rxPending;
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}
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}
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long us_get_duration(byte sensor) {
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long us_get_duration(byte sensor) {
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// check if there is new sensor data
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// check if there is new sensor data
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- if(usData[sensor].newData) {
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- usData[sensor].newData = 0;
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+ if(usData[sensor].state == finished) {
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+ usData[sensor].state = idle;
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return usData[sensor].duration;
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return usData[sensor].duration;
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} else {
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} else {
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- return usData[sensor].duration;
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- //return -1;
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+ return -(F_CPU / 1000000);
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}
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}
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}
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}
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