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https://github.com/DCC-EX/CommandStation-EX.git
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f3658aaee7
Change transmitPin to trigPin and receivePin to echoPin to match the markings on the device module.
195 lines
7.3 KiB
C++
195 lines
7.3 KiB
C++
/*
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* © 2021, Neil McKechnie. All rights reserved.
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*
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* This file is part of DCC++EX API
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*
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* This is free software: you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the 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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* It is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* 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
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* along with CommandStation. If not, see <https://www.gnu.org/licenses/>.
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*/
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/*
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* The HC-SR04 module has an ultrasonic transmitter (40kHz) and a receiver.
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* It is operated through two signal pins. When the transmit pin is set to 1
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* for 10us, on the falling edge the transmitter sends a short transmission of
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* 8 pulses (like a sonar 'ping'). This is reflected off objects and received
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* by the receiver. A pulse is sent on the receive pin whose length is equal
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* to the delay between the transmission of the pulse and the detection of
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* its echo. The distance of the reflecting object is calculated by halving
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* the time (to allow for the out and back distance), then multiplying by the
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* speed of sound (assumed to be constant).
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*
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* This driver polls the HC-SR04 by sending the trigger pulse and then measuring
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* the length of the received pulse. If the calculated distance is less than
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* the threshold, the output state returned by a read() call changes to 1. If
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* the distance is greater than the threshold plus a hysteresis margin, the
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* output changes to 0. The device also supports readAnalogue(), which returns
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* the measured distance in cm, or 32767 if the distance exceeds the
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* offThreshold.
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*
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* It might be thought that the measurement would be more reliable if interrupts
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* were disabled while the pulse is being timed. However, this would affect
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* other functions in the CS so the measurement is being performed with
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* interrupts enabled. Also, we could use an interrupt pin in the Arduino for
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* the timing, but the same consideration applies. In any case, the DCC
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* interrupt occurs once every 58us, so any IRC code is much faster than that.
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* And 58us corresponds to 1cm in the calculation, so the effect of
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* interrupts is negligible.
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*
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* Note: The timing accuracy required for measuring the pulse length means that
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* the pins have to be direct Arduino pins; GPIO pins on an IO Extender cannot
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* provide the required accuracy.
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*/
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#ifndef IO_HCSR04_H
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#define IO_HCSR04_H
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#include "IODevice.h"
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class HCSR04 : public IODevice {
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private:
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// pins must be arduino GPIO pins, not extender pins or HAL pins.
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int _trigPin = -1;
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int _echoPin = -1;
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// Thresholds for setting active state in cm.
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uint8_t _onThreshold; // cm
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uint8_t _offThreshold; // cm
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// Last measured distance in cm.
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uint16_t _distance;
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// Active=1/inactive=0 state
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uint8_t _value = 0;
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// Time of last loop execution
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unsigned long _lastExecutionTime;
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// Factor for calculating the distance (cm) from echo time (ms).
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// Based on a speed of sound of 345 metres/second.
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const uint16_t factor = 58; // ms/cm
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public:
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// Constructor perfroms static initialisation of the device object
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HCSR04 (VPIN vpin, int trigPin, int echoPin, uint16_t onThreshold, uint16_t offThreshold) {
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_firstVpin = vpin;
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_nPins = 1;
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_trigPin = trigPin;
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_echoPin = echoPin;
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_onThreshold = onThreshold;
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_offThreshold = offThreshold;
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addDevice(this);
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}
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// Static create function provides alternative way to create object
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static void create(VPIN vpin, int trigPin, int echoPin, uint16_t onThreshold, uint16_t offThreshold) {
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new HCSR04(vpin, trigPin, echoPin, onThreshold, offThreshold);
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}
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protected:
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// _begin function called to perform dynamic initialisation of the device
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void _begin() override {
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pinMode(_trigPin, OUTPUT);
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pinMode(_echoPin, INPUT);
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ArduinoPins::fastWriteDigital(_trigPin, 0);
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_lastExecutionTime = micros();
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#if defined(DIAG_IO)
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_display();
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#endif
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}
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// _read function - just return _value (calculated in _loop).
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int _read(VPIN vpin) override {
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(void)vpin; // avoid compiler warning
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return _value;
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}
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int _readAnalogue(VPIN vpin) override {
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(void)vpin; // avoid compiler warning
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return _distance;
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}
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// _loop function - read HC-SR04 once every 50 milliseconds.
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void _loop(unsigned long currentMicros) override {
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if (currentMicros - _lastExecutionTime > 50000UL) {
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_lastExecutionTime = currentMicros;
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read_HCSR04device();
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// Delay next loop entry until 50ms have elapsed.
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//delayUntil(currentMicros + 50000UL);
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}
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}
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void _display() override {
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DIAG(F("HCSR04 Configured on Vpin:%d TrigPin:%d EchoPin:%d On:%dcm Off:%dcm"),
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_firstVpin, _trigPin, _echoPin, _onThreshold, _offThreshold);
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}
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private:
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// This polls the HC-SR04 device by sending a pulse and measuring the duration of
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// the pulse observed on the receive pin. In order to be kind to the rest of the CS
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// software, no interrupts are used and interrupts are not disabled. The pulse duration
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// is measured in a loop, using the micros() function. Therefore, interrupts from other
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// sources may affect the result. However, interrupts response code in CS typically takes
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// much less than the 58us frequency for the DCC interrupt, and 58us corresponds to only 1cm
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// in the HC-SR04.
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// To reduce chatter on the output, hysteresis is applied on reset: the output is set to 1 when the
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// measured distance is less than the onThreshold, and is set to 0 if the measured distance is
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// greater than the offThreshold.
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//
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void read_HCSR04device() {
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// uint16 enough to time up to 65ms
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uint16_t startTime, waitTime, currentTime, maxTime;
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// If receive pin is still set on from previous call, abort the read.
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if (ArduinoPins::fastReadDigital(_echoPin))
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return;
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// Send 10us pulse to trigger transmitter
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ArduinoPins::fastWriteDigital(_trigPin, 1);
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delayMicroseconds(10);
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ArduinoPins::fastWriteDigital(_trigPin, 0);
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// Wait for receive pin to be set
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startTime = currentTime = micros();
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maxTime = factor * _offThreshold * 2;
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while (!ArduinoPins::fastReadDigital(_echoPin)) {
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// lastTime = currentTime;
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currentTime = micros();
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waitTime = currentTime - startTime;
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if (waitTime > maxTime) {
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// Timeout waiting for pulse start, abort the read
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return;
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}
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}
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// Wait for receive pin to reset, and measure length of pulse
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startTime = currentTime = micros();
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maxTime = factor * _offThreshold;
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while (ArduinoPins::fastReadDigital(_echoPin)) {
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currentTime = micros();
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waitTime = currentTime - startTime;
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// If pulse is too long then set return value to zero,
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// and finish without waiting for end of pulse.
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if (waitTime > maxTime) {
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// Pulse length longer than maxTime, reset value.
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_value = 0;
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_distance = 32767;
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return;
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}
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}
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// Check if pulse length is below threshold, if so set value.
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//DIAG(F("HCSR04: Pulse Len=%l Distance=%d"), waitTime, distance);
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_distance = waitTime / factor; // in centimetres
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if (_distance < _onThreshold)
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_value = 1;
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}
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};
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#endif //IO_HCSR04_H
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