com.diozero.devices.sandpit.TCS3200 Maven / Gradle / Ivy
package com.diozero.devices.sandpit;
/*
* #%L
* Organisation: mattjlewis
* Project: Device I/O Zero - Core
* Filename: TCS3200.java
*
* This file is part of the diozero project. More information about this project
* can be found at http://www.diozero.com/
* %%
* Copyright (C) 2016 - 2017 mattjlewis
* %%
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
* #L%
*/
import java.io.Closeable;
import java.io.IOException;
import com.diozero.api.*;
import com.diozero.util.RangeUtil;
import com.diozero.util.SleepUtil;
/**
* This class reads RGB values from a TCS3200 colour sensor. Connections:
*
* GND Ground.
* VDD Supply Voltage (2.7-5.5V)
* /OE Output enable, active low. When OE is high OUT is disabled
* allowing multiple sensors to share the same OUT line.
* OUT Output frequency square wave.
* S0/S1 Output frequency scale selection.
* S2/S3 Colour filter selection.
*
*
* - OUT is a square wave whose frequency is proprtional to the
* intensity of the selected filter colour.
* - S2/S3 selects between red, green, blue, and no filter.
* - S0/S1 scales the frequency at 100%, 20%, 2% or off.
*
* To take a reading the colour filters are selected in turn for a
* fraction of a second and the frequency is read and converted to Hz.
*/
public class TCS3200 implements InputEventListener, Runnable, Closeable {
public static final int NOT_SET = -1;
private DigitalInputDevice out;
private DigitalOutputDevice s2;
private DigitalOutputDevice s3;
private DigitalOutputDevice s0;
private DigitalOutputDevice s1;
private DigitalOutputDevice oe;
private int[] rgbBlack;
private int[] rgbWhite = { 10,000, 10,000, 10,000 };
private int[] latestHertz;
private int[] currentHertz;
private int[] latestTally = { 1, 1, 1 };
private int[] currentTally = { 1, 1, 1 };
// Tune delay to get _samples pulses
private double[] delay = { 0.1, 0.1, 0.1 };
private int cycle;
private Frequency frequency;
private double interval;
private int samples;
private long startTick;
private long lastTick;
private boolean read;
public TCS3200(int outGpio, int s2Gpio, int s3Gpio) {
this(outGpio, s2Gpio, s3Gpio, NOT_SET, NOT_SET, NOT_SET);
}
public TCS3200(int outGpio, int s2Gpio, int s3Gpio, int s0Gpio, int s1Gpio, int oeGpio) {
out = new DigitalInputDevice(outGpio);
s2 = new DigitalOutputDevice(s2Gpio);
s3 = new DigitalOutputDevice(s3Gpio);
if (s0Gpio != NOT_SET && s1Gpio != NOT_SET) {
s0 = new DigitalOutputDevice(s0Gpio);
s1 = new DigitalOutputDevice(s1Gpio);
}
if (oeGpio != NOT_SET) {
// Enable device (active low)
oe = new DigitalOutputDevice(oeGpio, false, true);
}
// Disable frequency output
//out.setValue(false);
setSampleSize(20);
// One reading per second
setUpdateInterval(1.0);
// 2%
setFrequency(Frequency.TWO_PERCENT);
// Clear
setFilter(Filter.CLEAR);
out.addListener(this);
Thread t = new Thread(this);
t.start();
}
/**
* Get the latest RGB reading. The raw colour hertz readings are converted
* to RGB values as follows: RGB = 255 * (Fv - Fb) / (Fw - Fb) Where Fv is
* the sampled hertz, Fw is the calibrated white hertz, and Fb is the
* calibrated black hertz.
*
* @return RGB values constrained to be between 0 and 255
*/
public int[] getRgb() {
int top = 255;
int[] rgb = new int[3];
for (int c=0; c<3; c++) {
int v = latestHertz[c] - rgbBlack[c];
int s = rgbWhite[c] - rgbBlack[c];
int p = top * v / s;
if (p < 0) {
p = 0;
} else if (p > top) {
p = top;
}
rgb[c] = p;
}
return rgb;
}
/**
* Get the latest hertz reading
* @return latest hertz reading
*/
public int[] getHertz() {
return latestHertz;
}
/**
* Get the black level calibration
* @return black level calibration
*/
public int[] getBlackLevel() {
return rgbBlack;
}
/**
* Set the black level calibration
* @param rgb new black levels
*/
public void setBlackLevel(int[] rgb) {
for (int c=0; c<3; c++) {
rgbBlack[c] = rgb[c];
}
}
/**
* Get the white level calibration
* @return white level calibration
*/
public int[] getWhiteLevel() {
return rgbWhite;
}
/**
* Set the white level calibration
* @param rgb new white levels
*/
public void setWhiteLevel(int[] rgb) {
for (int c=0; c<3; c++) {
rgbWhite[c] = rgb[c];
}
}
/**
* Get the current frequency scaling
* @return the current frequency scaling
*/
public Frequency getFrequency() {
return frequency;
}
/**
* Set the frequency scaling.
*
* f S0 S1 Frequency scaling
* 0 L L Off
* 1 L H 2%
* 2 H L 20%
* 3 H H 100%
*
* @param f Sampling frequency
*/
public void setFrequency(Frequency f) {
if (s0 == null || s1 == null) {
return;
}
frequency = f;
switch (f) {
case OFF:
s0.off(); s1.off();
break;
case TWO_PERCENT:
s0.off(); s1.on();
break;
case TWENTY_PERCENT:
s0.on(); s1.off();
break;
default:
// 100%
s0.on(); s1.on();
}
}
/**
* Get the interval between RGB updates
* @return the interval between RGB updates
*/
public double getUpdateInterval() {
return interval;
}
/**
* Set the interval between RGB updates
* @param interval the interval between RGB updates ( 0.1 <= interval < 2.0)
*/
public void setUpdateInterval(double interval) {
this.interval = RangeUtil.constrain(interval, 0.1, 2.0);
}
/**
* Get the sample size
* @return the sample size
*/
public int getSampleSize() {
return samples;
}
/**
* Set the sample size (number of frequency cycles to accumulate)
* @param samples the sample size
*/
public void setSampleSize(int samples) {
this.samples = RangeUtil.constrain(samples, 10, 100);
}
/**
* Pause reading (until a call to resume).
*/
public void pause() {
read = false;
}
/**
* Resume reading (after a call to pause)
*/
public void resume() {
read = true;
}
/**
* Set the colour to be sampled.
* f S2 S3 Photodiode
* 0 L L Red
* 1 H H Green
* 2 L H Blue
* 3 H L Clear (no filter)
* @param f Filter
*/
public void setFilter(Filter f) {
switch (f) {
case RED:
s2.off(); s3.off();
break;
case GREEN:
s2.on(); s3.on();
break;
case BLUE:
s2.off(); s3.on();
break;
default:
// Clear
s2.on(); s3.off();
}
}
@Override
public void valueChanged(DigitalInputEvent event) {
int g = event.getGpio();
long t = event.getEpochTime();
if (g == out.getGpio()) {
// Frequency counter
if (cycle == 0) {
startTick = t;
} else {
lastTick = t;
}
cycle += 1;
} else {
// Must be transition between colour samples
int colour;
if (g == s2.getGpio()) {
if (event.getValue()) {
// Blue -> Green
colour = 2;
} else {
// Clear -> Red
cycle = 0;
return;
}
} else {
if (event.getValue()) {
// Red -> Blue
colour = 0;
} else {
// Green -> Clear
colour = 1;
}
}
if (cycle > 1) {
cycle -= 1;
long td = lastTick - startTick;
currentHertz[colour] = (int) ((1_000_000 * cycle) / td);
currentTally[colour] = cycle;
} else {
currentHertz[colour] = 0;
currentTally[colour] = 0;
}
cycle = 0;
// Have we a new set of RGB?
if (colour == 1) {
for (int i=0; i<3; i++) {
latestHertz[i] = currentHertz[i];
latestTally[i] = currentTally[i];
}
}
}
}
@Override
public void run() {
read = true;
while (true) {
if (read) {
long next_time = System.currentTimeMillis() + (int) (interval*1000);
//out.setMode(DeviceMode.DIGITAL_OUTPUT); // Enable output gpio.
// The order Red -> Blue -> Green -> Clear is needed by the
// callback function so that each S2/S3 transition triggers
// a state change. The order was chosen so that a single
// gpio changes state between each colour to be sampled.
setFilter(Filter.RED);
SleepUtil.sleepSeconds(delay[0]);
setFilter(Filter.BLUE);
SleepUtil.sleepSeconds(delay[2]);
setFilter(Filter.GREEN);
SleepUtil.sleepSeconds(delay[1]);
// TODO Disable output gpio
//out.setValue(false);
setFilter(Filter.CLEAR);
long delay_ms = next_time - System.currentTimeMillis();
if (delay_ms > 0) {
SleepUtil.sleepMillis(delay_ms);
}
// Tune the next set of delays to get reasonable results
// as quickly as possible.
for (int c=0; c<3; c++) {
// Calculate dly needed to get _samples pulses
double dly;
if (latestHertz[c] != 0) {
dly = samples / (double) latestHertz[c];
} else {
// Didn't find any edges, increase sample time
dly = this.delay[c] + 0.1;
}
// Constrain dly to reasonable values.
dly = RangeUtil.constrain(dly, 0.001, 0.5);
this.delay[c] = dly;
}
} else {
SleepUtil.sleepSeconds(0.1);
}
}
}
@Override
public void close() throws IOException {
oe.setOn(false);
oe.close();
if (s0 != null) {
s0.close();
}
if (s1 != null) {
s1.close();
}
s2.close();
s3.close();
out.close();
}
public static enum Filter {
RED, GREEN, BLUE, CLEAR;
}
public static enum Frequency {
OFF, TWO_PERCENT, TWENTY_PERCENT, ON;
}
}