everhack Stuff I've been messing with, or just thinking about.

3May/130

LED as a light sensor

This is nothing new, but it's still pretty neat. Using a LED as a light sensor.

I modded this demo code from the Blinkenlight blog to read just one LED as input and turn a second LED on and off based on a simple threshold.

led_sensor_circuit

led_light_sensor

//
// www.blinkenlight.net
//
// Copyright 2011 Udo Klein
// modded 2013 by david mitchell - turn an LED on and off based on the light sensor value
//
// This program 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.
//
// This program 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 this program. If not, see http://www.gnu.org/licenses/

// Usage
//
// This sketch uses the Blinkenlight Shield as a light
// sensor. In order to make this work jumper the shield
// such the common cathode of the LEDs it connected
// to +5V.
//
// It will output hexadecimal digits that correspond
// to the amount of light captured by the LEDs.
// 0 = very bright light
// higher numbers = less light
//
//
// Theory of operation
//
// For each LED the following happens:

// 1) The PIN is pulled low thus reversing the LED.
// Thus the LED will act like a capacitor and gets
// charged.
// 2) We store the current milli second count in
// start_millis for later use.
// 3) The PIN is put to high Z input and starts to
// "float" with the voltage of the "LED cap".
// 4) If the LED captures light the "LED cap" will
// discharge fast, otherwise it discharges slow.
// 5) As the cap discharges the input PIN will
// float high.
// 6) Once the pin is detected to be high we will
// compute elapsed_millis by subtracting
// start_millis from the current milli second
// count

// The loops are coded in such a way that this
// happens "in parallel". They are also coded
// in such a way that each pin gets some time
// to settle.

// used to store the start milli second count per pin
uint16_t start_millis[1];
// used to store the last computed milli second count when pin floated to high
uint16_t elapsed_millis[1];

uint8_t transform(uint16_t data) {
// output transformation, used to map uint16_t to 1 hex digit
// basically a logarithm to the base of 2
uint8_t i=0;
while (data) {
data >>= 1;
++i;
}
return i;
}

boolean pin_is_ok(uint8_t pin) {
// used to determine which pins are good for light detection
// pins 0,1 are spoiled by the serial port
// pin 13 is spoiled by the Arduino's LED
return (pin == 5);
}
#define MINPIN 5
#define MAXPIN 5
#define ANODE_POWER 6

#define LED_OUT 7

void setup() {
Serial.begin(115200);
Serial.println("go");

pinMode(LED_OUT, OUTPUT);
digitalWrite(LED_OUT, HIGH);

pinMode(ANODE_POWER, OUTPUT);
// turn on the LED charge power
digitalWrite(ANODE_POWER, HIGH);

for (uint8_t pin = MINPIN; pin <= MAXPIN; ++pin) if (pin_is_ok(pin)) { pinMode(pin, OUTPUT); digitalWrite(pin, LOW); start_millis[pin] = millis(); elapsed_millis[pin] = 0; } for (uint8_t pin = MINPIN; pin <= MAXPIN; ++pin) if (pin_is_ok(pin)) { pinMode(pin, INPUT); } } void loop() { for (uint8_t pin = MINPIN; pin <= MAXPIN; ++pin) if (pin_is_ok(pin)) { if (digitalRead(pin)) { pinMode(pin, OUTPUT); elapsed_millis[pin] = millis()-start_millis[pin]; start_millis[pin] = millis(); pinMode(pin, INPUT); } } for (uint8_t pin = MINPIN; pin <= MAXPIN; ++pin) if (pin_is_ok(pin)) { int diff = transform(elapsed_millis[pin]); if (diff > 6) {
digitalWrite(LED_OUT, HIGH);
}
else {
digitalWrite(LED_OUT, LOW);
}
Serial.print(diff, HEX);
}
Serial.println();
}

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