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CommandStation-EX/IO_HCSR04.h
Neil McKechnie 9dacd24d27
Various HAL enhancements. (#182) 
* Add <D SERVO vpin position> command

Allow a PWM servo to be driven to any arbitrary position.

* Enhancements for HAL drivers

Add state change notification for external GPIO module drivers;
Allow drivers to be installed statically by declaration (as an alternative to the 'create' call).

* Create IO_HCSR04.h

HAL driver for HC-SR04 ultrasonic distance sensor (sonar).

* Enable servo commands in NO-HAL mode, but return error.

Avoid compile errors in RMFT.cpp when compiled with basic HAL by including the Turnout::createServo function as a stub that returns NULL.

* Update IO_HCSR04.h

Minor changes

* Change <D SERVO>

Give the <D SERVO> command an optional parameter of the profile.  For example, <D SERVO 100 200 3> will slowly move the servo on pin 100 to PWM position corresponding to 200.  If omitted, the servo will move immediately (no animation).

* IODevice (HAL) changes

1) Put new devices on the end of the chain instead of the beginning.  This will give better performance for devices created first (ArduinoPins and extender GPIO devices, typically).
2) Remove unused functions.

* Update IO_HCSR04.h

Allow thresholds for ON and OFF to be separately configured at creation.

* Update IODevice.cpp

Fix compile error on IO_NO_HAL minimal HAL version.

* Update IO_PCA9685.cpp

Remove unnecessary duplicated call to min() function.
2021-08-17 23:41:34 +01:00

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/*
* © 2021, Neil McKechnie. All rights reserved.
*
* This file is part of DCC++EX API
*
* This is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* It is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with CommandStation. If not, see <https://www.gnu.org/licenses/>.
*/
/*
* The HC-SR04 module has an ultrasonic transmitter (40kHz) and a receiver.
* It is operated through two signal pins. When the transmit pin is set to 1 for
* 10us, on the falling edge the transmitter sends a short transmission of
* 8 pulses (like a sonar 'ping'). This is reflected off objects and received
* by the receiver. A pulse is sent on the receive pin whose length is equal
* to the delay between the transmission of the pulse and the detection of
* its echo. The distance of the reflecting object is calculated by halving
* the time (to allow for the out and back distance), then multiplying by the
* speed of sound (assumed to be constant).
*
* This driver polls the HC-SR04 by sending the trigger pulse and then measuring
* the length of the received pulse. If the calculated distance is less than the
* threshold, the output changes to 1. If it is greater than the threshold plus
* a hysteresis margin, the output changes to 0.
*
* The measurement would be more reliable if interrupts were disabled while the
* pulse is being timed. However, this would affect other functions in the CS
* so the measurement is being performed with interrupts enabled. Also, we could
* use an interrupt pin in the Arduino for the timing, but the same consideration
* applies.
*
* Note: The timing accuracy required by this means that the pins have to be
* direct Arduino pins; GPIO pins on an IO Extender cannot provide the required
* accuracy.
*/
#ifndef IO_HCSR04_H
#define IO_HCSR04_H
#include "IODevice.h"
class HCSR04 : public IODevice {
private:
// pins must be arduino GPIO pins, not extender pins or HAL pins.
int _transmitPin = -1;
int _receivePin = -1;
// Thresholds for setting active state in cm.
uint8_t _onThreshold; // cm
uint8_t _offThreshold; // cm
// Active=1/inactive=0 state
uint8_t _value = 0;
// Time of last loop execution
unsigned long _lastExecutionTime;
// Factor for calculating the distance (cm) from echo time (ms).
// Based on a speed of sound of 345 metres/second.
const uint16_t factor = 58; // ms/cm
public:
// Constructor perfroms static initialisation of the device object
HCSR04 (VPIN vpin, int transmitPin, int receivePin, uint16_t onThreshold, uint16_t offThreshold) {
_firstVpin = vpin;
_nPins = 1;
_transmitPin = transmitPin;
_receivePin = receivePin;
_onThreshold = onThreshold;
_offThreshold = offThreshold;
addDevice(this);
}
// Static create function provides alternative way to create object
static void create(VPIN vpin, int transmitPin, int receivePin, uint16_t onThreshold, uint16_t offThreshold) {
new HCSR04(vpin, transmitPin, receivePin, onThreshold, offThreshold);
}
protected:
// _begin function called to perform dynamic initialisation of the device
void _begin() override {
pinMode(_transmitPin, OUTPUT);
pinMode(_receivePin, INPUT);
ArduinoPins::fastWriteDigital(_transmitPin, 0);
_lastExecutionTime = micros();
DIAG(F("HCSR04 configured on VPIN:%d TXpin:%d RXpin:%d On:%dcm Off:%dcm"),
_firstVpin, _transmitPin, _receivePin, _onThreshold, _offThreshold);
}
// _read function - just return _value (calculated in _loop).
int _read(VPIN vpin) override {
(void)vpin; // avoid compiler warning
return _value;
}
// _loop function - read HC-SR04 once every 50 milliseconds.
void _loop(unsigned long currentMicros) override {
if (currentMicros - _lastExecutionTime > 50000) {
_lastExecutionTime = currentMicros;
_value = read_HCSR04device();
}
}
private:
// This polls the HC-SR04 device by sending a pulse and measuring the duration of
// the pulse observed on the receive pin. In order to be kind to the rest of the CS
// software, no interrupts are used and interrupts are not disabled. The pulse duration
// is measured in a loop, using the micros() function. Therefore, interrupts from other
// sources may affect the result. However, interrupts response code in CS typically takes
// much less than the 58us frequency for the DCC interrupt, and 58us corresponds to only 1cm
// in the HC-SR04.
// To reduce chatter on the output, hysteresis is applied on reset: the output is set to 1 when the
// measured distance is less than the onThreshold, and is set to 0 if the measured distance is
// greater than the offThreshold.
//
uint8_t read_HCSR04device() {
// uint16 enough to time up to 65ms
uint16_t startTime, waitTime, currentTime, maxTime;
// If receive pin is still set on from previous call, abort the read.
if (ArduinoPins::fastReadDigital(_receivePin)) return _value;
// Send 10us pulse to trigger transmitter
ArduinoPins::fastWriteDigital(_transmitPin, 1);
delayMicroseconds(10);
ArduinoPins::fastWriteDigital(_transmitPin, 0);
// Wait for receive pin to be set
startTime = currentTime = micros();
maxTime = factor * _offThreshold * 2;
while (!ArduinoPins::fastReadDigital(_receivePin)) {
// lastTime = currentTime;
currentTime = micros();
waitTime = currentTime - startTime;
if (waitTime > maxTime) {
// Timeout waiting for pulse start, abort the read
return _value;
}
}
// Wait for receive pin to reset, and measure length of pulse
startTime = currentTime = micros();
maxTime = factor * _offThreshold;
while (ArduinoPins::fastReadDigital(_receivePin)) {
currentTime = micros();
waitTime = currentTime - startTime;
// If pulse is too long then set return value to zero,
// and finish without waiting for end of pulse.
if (waitTime > maxTime) {
// Pulse length longer than maxTime, reset value.
return 0;
}
}
// Check if pulse length is below threshold, if so set value.
//DIAG(F("HCSR04: Pulse Len=%l Distance=%d"), waitTime, distance);
uint16_t distance = waitTime / factor; // in centimetres
if (distance < _onThreshold)
return 1;
return _value;
}
};
#endif //IO_HCSR04_H
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