Aim of the project is to build lightweight laser/light sensor that can be mounted on quadcopter and used for gaming purposes. Sensor reads environmental light level via LDR, and sets the threshold below it. Any significant change in the light level will trigger the LED-s. Sensor will be used for the Dronosphere workshop and performance.

• 1 Arduino Uno (or Duemilanove with an ATmega328)
• 1 ATtiny45 or ATtiny85
• 3 LDRs
• 1 1KΩ resistor
• 1 ultra bright LED
• 220 to 330 ohm resistor for LED
• 1 CR20 battery holder
• 1 3V CR2032 battery
• protoboard
• jumper wires
• stripboard

It's recommended to test the circuit on Arduino first. You will have serial monitor available and you will be able to read LDR readings and further fine-tune the code or components.

laser_light_sensor_Arduino.ino

const int LDR = A0;         // analog pin to which LDR is connected
const int LED = 13;         // pin to which LED is connected
const int sensitivity = 50; // setting the light sensitivity
 
int LDRValue = 0;           // variable to store LDR values
int threshold;              // light sensitivity threshold
float voltage;              // variable to store voltage
 
void setup()
{
  Serial.begin(9600);                         // start the serial monitor with 9600 baud
  pinMode(LED, OUTPUT);                       // configure LED pin to behave as output
  threshold = analogRead(LDR) - sensitivity;  // set light sensitivity threshold
}
 
void loop()
{
  LDRValue = analogRead(LDR);                 // read LDR value
  Serial.print("Raw Rate: ");                 // print text
  Serial.println(LDRValue);                   // print value to serial monitor
  float voltage = LDRValue * (5.0 / 1023.0);  // convert analog reading (which goes from 0-1023) to a voltage (0-5V)
  Serial.print("Voltage: ");
  Serial.println(voltage);
  Serial.println();
 
  if (LDRValue <= threshold)                  // if the LDR reading is lower than the threshold
  {
    for (int i = 0; i <= 50; i++) {           // blink LEDs
      digitalWrite(LED, HIGH);
      delay(50);
      digitalWrite(LED, LOW);
      delay(50);
    }
    delay(3000);
    threshold = analogRead(LDR) - sensitivity; // set light sensitivity threshold
  }
  else
  {
    digitalWrite(LED, LOW);
  }
}

Now that we have tested everything, we can go on and move it to ATtiny microcontroller (tested on ATtiny45, ATtiny85), which has significantly smaller profile its cheaper and works on 3V.

• http://highlowtech.org/?p=1695
• http://highlowtech.org/?p=1706

laser_light_sensor_ATtiny.ino

#define LDR A1          // analog pin to which LDR is connected
int LDRValue = 0;       // that’s a variable to store LDR values
#define LED 1           // LED pin
int light_sensitivity;  // sensitivity treshold
float voltage;
 
void setup()
{
  pinMode(LED, OUTPUT);
  light_sensitivity = analogRead(LDR)-40;   // setting sensitivity treshold level
}
 
void loop()
{
  LDRValue = analogRead(LDR);       // read LDR value
  if (LDRValue < light_sensitivity)
  { 
    digitalWrite(LED, HIGH); 
    delay(3000); 
    digitalWrite(LED, LOW);
    delay(1000); 
  }
  else
  {
    digitalWrite(LED, LOW);
  }
}

• Sensor works best in low-light conditions
• Recalibrate the sensor on every ambient light change
• Recalibrate by triggering it or by removing battery

• http://hobbybotics.com/tutorials/tutorial-use-a-light-dependent-resistor-ldr-to-measure-light-levels/
• http://arduinobasics.blogspot.com/2011/06/arduino-uno-photocell-sensing-light.html
• https://learn.sparkfun.com/tutorials/sik-experiment-guide-for-arduino---v32/experiment-6-reading-a-photoresistor
• https://blog.udemy.com/arduino-ldr/
• http://www.instructables.com/id/Photocell-tutorial/?ALLSTEPS