You can use Arduino to send (sensor) data to TouchDesigner and vice versa.

For example, you might want to measure the light condition of a room and use this data to trigger something in TouchDesigner. Or you might want to be able to have a light bulb react to a sound file, or a motor spin in sync with a projection.
To do so there are typically to methods that can be used:

• Firmata

• Serial Communication

With this method you are making Arduino & TD talk to each other by using Serial, a communication protocol that is able to send info essentially through a wire (the usb wire that connect the board to the computer running TD). TD has a Serial DAT operator that is able to receive this data.
This method is preferred when your Arduino needs to use library or specific code to gather data from the sensors you are using.

Using Serial Communication

Arduino and the computer saying Hi to each other

Serial communication is a method for transferring data between devices. It is able to send data sequentially over a wire. In this case the USB cable that connects your Arduino with the computer running TD.
For this example we are getting sensor data from a LDR and a Ultrasonic sensor, sensing light values and distance.

Arduino to TouchDesigner

Arduino wiring and code

Pic 1. Arduino Micro and sensors on breadboard

Pic 2. Wiring on Arduino Uno

First we wire the sensors to Arduino and upload the code to the board. The following example uses a LDR (light sensor) and an Ultrasonic sensor (distance sensor).
Follow the wiring diagram as in Pic 2:

Here is the code:

 
//LDR PIN and VARIABLE
int sensorPin = A0; // select the input pin for LDR
int sensorValue = 0; // variable to store the value coming from the sensor
//ULTRASONIC SENSOR PIN and VARIABLEs
const int WINDOW_SIZE = 10; // Adjust the window size as needed
const int sensorTriggerPin = 2; // Connect to the trigger pin of HC-SR04
const int sensorEchoPin = 3; // Connect to the echo pin of HC-SR04
const int glitchThreshold = 2000; // Threshold for excluding glitchy readings

// Variables
int readings[WINDOW_SIZE]; // Array to store recent sensor readings
int index = 0; // Index for circular buffer
long sum = 0; // Sum of recent readings

void setup() {
  //start serial communication
  Serial.begin(9600); //sets serial port for communication
 
 //define ultrasonic sensor pin as in or out 
    pinMode(sensorTriggerPin, OUTPUT);
    pinMode(sensorEchoPin, INPUT);
}

void loop() {
  //getting and printing sensor data from LDR 
    sensorValue = analogRead(sensorPin); // read the value from the sensor
    Serial.print(sensorValue); 
    Serial.print(" ");

  //getting sensor data from ultrasonic sensor 
    // Trigger the sensor
    digitalWrite(sensorTriggerPin, LOW);
    delayMicroseconds(2);
    digitalWrite(sensorTriggerPin, HIGH);
    delayMicroseconds(10);
    digitalWrite(sensorTriggerPin, LOW);

    // Read the echo pulse duration
    long duration = pulseIn(sensorEchoPin, HIGH);

    // Calculate distance in centimeters
    float distance_cm = duration * 0.034 / 2;

    // Exclude glitchy readings
    if (distance_cm < glitchThreshold) {
        // Add the new reading to the window
        sum -= readings[index]; // Subtract the oldest reading
        readings[index] = distance_cm; // Store the new reading
        sum += distance_cm; // Add the new reading

        // Increment the index (circular buffer)
        index = (index + 1) % WINDOW_SIZE;

        // Calculate the moving average
        float movingAverage = static_cast<float>(sum) / WINDOW_SIZE;

        // Convert movingAverage to an integer
        int filteredDistance = static_cast<int>(movingAverage);

        // Print the filtered distance (as an integer)
        Serial.println(filteredDistance);

    }
      
   // add a delay - slow down data flow
        delay(10);
}

By opening the serial monitor you can check the data coming from the sensors. The LDR one is going to appear as a number going from 0 to 1023 while the ultrasonic sensor value is expressed in cm.
Once we checked that everything works smooth we are going to close the serial monitor window.

Getting the data in TouchDesigner

1. Open the Serial DAT

In the panel you should set it on Active and select the callback format. Select the port where you have your Arduino connected. You should now see the numbers that you were previously seeing on the Arduino serial monitor appearing in the Serial DAT.

2. Select DAT

When getting the data in we are seeing that the Serial DAT is printing a line saying "message". We are going to get rid of it with the Select DAT.

3. Convert DAT

We are now using a Convert DAT to be able to split our row into two columns so that we can eventually target each value separately. To do so we using the Split Cells option: instead of using the default \t we are going to do it at each space.

4. DAT to CHOP

We need now to convert our DAT into a CHOP. We can use the DAT to operator in the CHOPs menu. Inside the panel we have to set:

Output: Channel per column

Fist Row: Values

First Column:Values

5. Select CHOP

Once you assigned each value to a channel to can use a Select CHOP to split them into two different operators. You can also rename the channel.

6.Math CHOP

Because we are receiving the sensor data in ranges that might not be suitable with what we want to trigger in TD we can use a Math CHOP to adjust the values to the desired range. In this case I want to remap the values coming from the sensor from 0-1023 to 0-1.

7.Use LDR data to trigger the alpha

You can now use the remapped value to trigger the op value that you want. In this case I am using the light sensor data to affect the alpha level of a Circle TOP.

8.Trigger the circle size with distance sensor data

We can do something similar with the distance data. You can once again use the Math CHOP to remap the distance values to trigger the dimensions of the circle.

TouchDesigner to Arduino

We manage to send data from Arduino to TouchDesigner. We can now do it the other way around. In the same TD project we are going to add another functionality, where this time the data will flow from TD to Arduino. To do so we are going to make TD analyse a sound file and its parameters to have real time audio reactive LEDs in Arduino.

Connecting the LEDs

Audio analysis from TD to Arduino

1. Add an audio file

In the CHOP list select the Audio File In. you can replace the file from the op menu. You can also use a Audio Device In alternatively. To be able to hear it you can connect it to the Audio Device Out CHOP.

2. Analyse the audio

We are now adding the Audio Analysis component. You can find this in the Palette menu (usually on the left side). Drag it into the pane and connect it to the audio file. In the menu you can see all the different controls. We are going to set the Kick, Snare and Rhythm to Active and define the threshold. When the correspondent value crosses the threshold it will pulse. We will use these pulses to trigger the LEDs.

3. Select the values

Connect a Select CHOP and pick the kick, snare and rhythm channels.

4. Add a Fan CHOP

We now have three different channels: we are using a Fan CHOP to bring it to one. Add a Fan CHOP and set the Operation to Fan In: this option is used to make into one channel a series of binary input like the ones we have. The result is a number that moves from 0 to 2 accordingly to the channel that is pulsing in that moment: 0 is the kick, 1 is the snare and 2 is the rhythm.

5. Add a Math CHOP

We use a Math CHOP to add 1 to our number

6. Send the value to Arduino

We add a CHOP Execute DAT. In the menu we make sure we connect it to the corresponding CHOP.

We then press Edit. At this point a window with some Python code will appear. We make sure we change it to:

 
# me - this DAT
# 
# channel - the Channel object which has changed
# sampleIndex - the index of the changed sample
# val - the numeric value of the changed sample
# prev - the previous sample value
# 
# Make sure the corresponding toggle is enabled in the CHOP Execute DAT.

def onOffToOn(channel, sampleIndex, val, prev):
	return

def whileOn(channel, sampleIndex, val, prev):
	return

def onOnToOff(channel, sampleIndex, val, prev):
	return

def whileOff(channel, sampleIndex, val, prev):
	return

def onValueChange(channel, sampleIndex, val, prev):
	op('serial1').sendBytes(val)
	return

We use this code to send our CHOP value to the Serial operator (in this case serial1) so that it can go to Arduino.

Here is a overview of the network we have been building:

Receiving the data in Arduino

1. Update the Arduino code

We are going to add to our Arduino sketch some code to be able to receive the serial messages and trigger the LEDs.

Here is the full code:

 
 
//LDR PIN and VARIABLE
int sensorPin = A0; // select the input pin for LDR
int sensorValue = 0; // variable to store the value coming from the sensor
//ULTRASONIC SENSOR PIN and VARIABLEs
const int WINDOW_SIZE = 10; // Adjust the window size as needed
const int sensorTriggerPin = 2; // Connect to the trigger pin of HC-SR04
const int sensorEchoPin = 3; // Connect to the echo pin of HC-SR04
const int glitchThreshold = 2000; // Threshold for excluding glitchy readings
int readings[WINDOW_SIZE]; // Array to store recent sensor readings
int index = 0; // Index for circular buffer
long sum = 0; // Sum of recent readings

//LED

#define led_kick 6
#define led_snare 7
#define led_rythm 8

void setup() {
  //start serial communication
  Serial.begin(9600); //sets serial port for communication
 
 //define ultrasonic sensor pin as in or out 
    pinMode(sensorTriggerPin, OUTPUT);
    pinMode(sensorEchoPin, INPUT);

 //leds
    pinMode(led_kick, OUTPUT);
    pinMode(led_snare, OUTPUT);
    pinMode(led_rythm, OUTPUT);
}

void loop() {
  //getting and printing sensor data from LDR 
    sensorValue = analogRead(sensorPin); // read the value from the sensor
    Serial.print(sensorValue); 
    Serial.print(" ");

  //getting sensor data from ultrasonic sensor 
    // Trigger the sensor
    digitalWrite(sensorTriggerPin, LOW);
    delayMicroseconds(2);
    digitalWrite(sensorTriggerPin, HIGH);
    delayMicroseconds(10);
    digitalWrite(sensorTriggerPin, LOW);

    // Read the echo pulse duration
    long duration = pulseIn(sensorEchoPin, HIGH);

    // Calculate distance in centimeters
    float distance_cm = duration * 0.034 / 2;

    // Exclude glitchy readings
    if (distance_cm < glitchThreshold) {
        // Add the new reading to the window
        sum -= readings[index]; // Subtract the oldest reading
        readings[index] = distance_cm; // Store the new reading
        sum += distance_cm; // Add the new reading

        // Increment the index (circular buffer)
        index = (index + 1) % WINDOW_SIZE;

        // Calculate the moving average
        float movingAverage = static_cast<float>(sum) / WINDOW_SIZE;

        // Convert movingAverage to an integer
        int filteredDistance = static_cast<int>(movingAverage);

        // Print the filtered distance (as an integer)
        Serial.println(filteredDistance);

    }
      
   // add a delay - slow down data flow
   //delay(10);
   
  if (Serial.available()>0){
   int incomingByte = Serial.read();

   if (incomingByte == 1){
    digitalWrite(led_kick, HIGH);  
    digitalWrite(led_snare, LOW);  
    digitalWrite(led_rythm, LOW);               
   }
   else if (incomingByte == 2){
    digitalWrite(led_kick, LOW);  
    digitalWrite(led_snare, HIGH);  
    digitalWrite(led_rythm, LOW);               
   }
   else if (incomingByte == 3){
    digitalWrite(led_kick, LOW);  
    digitalWrite(led_snare, LOW);  
    digitalWrite(led_rythm, HIGH);               
   }
   } else {
    digitalWrite(led_kick, LOW);  
    digitalWrite(led_snare, LOW);  
    digitalWrite(led_rythm, LOW);               
   }
}

Before uploading the code on the board set the Serial DAT on TD to Active: off. Activate it back when the code is uploaded.

You should know see the three different light blinking accordingly to the audio analysis values.

Using Firmata