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Version: 12 Dec 2024

Sensors Input

Sensors are devices that measure environmental characteristics of the device that the content is running on, such as light, pressure, temperature, orientation, and motion. Unity’s Input System allows you to access sensors on Android devices using the standard Android Sensor API. In this guide, we will show you how to enable, disable, and read data from sensors on Android using the Input System.

Android Sensor API

Developers will need to use the standard Android Sensor API by creating a custom plugin to access additional sensors. Using the Android Sensor API directly allows for greater flexibility and lets developers choose specific sensors. For example, they can use the Gyro sensor on the compute pack instead of the one on the headset.

Additional Sensors

While generic sensors, such as the Light Sensor, can be accessed using the Android Sensor API and Unity Input System, platform-specific sensors, like World Cameras, can only be obtained through APIs provided in the Magic Leap SDK.

Prerequisites

Available sensors

The following table lists the sensors that are available on Android devices and their corresponding sensor types and controls in the Input System.

Sensor NameSensor TypeControl TypeDescription
AccelerometerAccelerometerVector3ControlMeasures the acceleration of the device in meters per second squared
GyroscopeGyroscopeVector3ControlMeasures the angular velocity of the device in radians per second
Light SensorLightSensorAxisControlMeasures the ambient light level of the device in lux
Pressure SensorPressureSensorAxisControlMeasures the atmospheric pressure of the device in hectopascals

Enabling and disabling sensors

Unlike other input devices, sensors are disabled by default in the Input System. To enable a sensor, you need to call InputSystem.EnableDevice() with the sensor device as an argument. For example, to enable the gyroscope sensor, you can write:

using UnityEngine.InputSystem;
...
InputSystem.EnableDevice(UnityEngine.InputSystem.Gyroscope.current);

To disable a sensor, you need to call InputSystem.DisableDevice() with the sensor device as an argument. For example, to disable the gyroscope sensor, you can write:

InputSystem.DisableDevice(UnityEngine.InputSystem.Gyroscope.current);

To check whether a sensor is currently enabled, you can use the InputDevice.enabled property. For example, to check if the gyroscope sensor is enabled, you can write:

if  (UnityEngine.InputSystem.Gyroscope.current.enabled)
{
Debug.Log("Gyroscope is enabled");
}

Reading sensor data

The simplest way to read the sensor data, like the Gyroscope, is to read the value directly. In the following example we will access the angularVelocity control from the Gyroscope device and print the value to the console. The angularVelocity returns a Vector3 value that represents the angular velocity of the device in radians per second.

using UnityEngine;
using UnityEngine.InputSystem;

public class GyroTest : MonoBehaviour
{
void Update()
{
// Get the gyroscope device
Gyroscope gyro = UnityEngine.InputSystem.Gyroscope.current;
// Check if the device is available and enabled
if (gyro != null && gyro.enabled)
{
// Read the angular velocity
Vector3 angularVelocity = gyro.angularVelocity.ReadValue();
// Print the value to the console
Debug.Log("Gyroscope angular velocity: " + angularVelocity);
}
}
}

Make sure to enable the gyroscope device before you can read its data, as sensors are disabled by default. You can do this by calling InputSystem.EnableDevice(UnityEngine.InputSystem.Gyroscope.current). You can also disable the device by calling InputSystem.DisableDevice(UnityEngine.InputSystem.Gyroscope.current).

Reading the data using Input Actions

Another way to read the gyroscope data is to use Input Actions. Input Actions are a way to abstract input devices and controls, and map them to logical actions in your game. For example, you can create an Input Action called “Rotate” and map it to the gyroscope’s angularVelocity control. Then, you can subscribe to the action’s events and perform some logic based on the input value. For example, you can rotate an object in your scene according to the gyroscope input.

Input Action Asset

To create an Input Action, you need to use the Input Action Asset Editor, which is a graphical tool that lets you create and edit Input Action Assets. An Input Action Asset is a ScriptableObject that contains a set of Input Actions and Input Action Maps. An Input Action Map is a collection of Input Actions that belong to a specific context or mode in your game, such as “Menu” or “Gameplay”.

To create an Input Action that references the gyroscope do the following:

  1. Create an Input Action Asset, go to Assets > Create > Input Actions. This will create a new asset in your project and open the editor window.
  2. Create an Input Action Map, click on the + button next to Action Maps and give it a name, such as "Gameplay".
  3. Create an Input Action, click on the + button next to Actions and give it a name, such as “Rotate”
  4. Set its Action Type to Value and Control Type to Vector3.
  5. Map the action to the gyroscope’s angularVelocity control, click on the + button next to Bindings and select Gyroscope > angularVelocity from the dropdown menu.

To use the Input Action in your script, you need to reference the Input Action Asset and enable it. You also need to register a callback function for the action’s events, such as started, performed, and canceled. For example, you can do something like this:

using UnityEngine;
using UnityEngine.InputSystem;

public class GyroActionTest : MonoBehaviour
{
// Reference to the Input Action Asset
public InputActionAsset inputActions;
// Reference to the Rotate action
private InputAction rotateAction;
// Reference to an object in the scene
public Transform target;

void Awake()
{
// Get the Rotate action from the Gameplay action map
rotateAction = inputActions.FindActionMap("Gameplay").FindAction("Rotate");
// Register a callback for the performed event
rotateAction.performed += OnRotatePerformed;
}

void OnEnable()
{
// Enable the action
rotateAction.Enable();
}

void OnDisable()
{
// Disable the action
rotateAction.Disable();
}

void OnRotatePerformed(InputAction.CallbackContext context)
{
// Read the angular velocity value from the context
Vector3 angularVelocity = context.ReadValue<Vector3>();
// Rotate the target object according to the input value
target.Rotate(angularVelocity * Time.deltaTime);
}
}

Create Input Actions at runtime

You can also create input actions at runtime using code, without using the editor tool or an asset. This gives you more flexibility and control over how you define and use input actions. For example, you can create an input action for reading gyroscope data like this:

using UnityEngine;
using UnityEngine.InputSystem;

public class GyroRuntimeTest : MonoBehaviour
{
// Reference to the Rotate action
private InputAction rotateAction;
// Reference to an object in the scene
public Transform target;

void Start()
{
// Create a new input action with the gyroscope's angularVelocity control
rotateAction = new InputAction("GyroRuntime", InputActionType.Value, "<Gyroscope>/angularVelocity");

rotateAction.Enable();
// Register a callback for the performed event
rotateAction.performed += OnRotatePerformed;
}

void OnEnable()
{
// Enable the action
rotateAction.Enable();
}

void OnDisable()
{
// Disable the action
rotateAction.Disable();
}

void OnRotatePerformed(InputAction.CallbackContext context)
{
// Read the angular velocity value from the context
Vector3 angularVelocity = context.ReadValue<Vector3>();
// Rotate the target object according to the input value
target.Rotate(angularVelocity * Time.deltaTime);
}
}

Note that you can also use InputActionMap, which is a class that represents a collection of input actions. You can create and add input actions to an input action map at runtime, and enable and disable the whole map or individual actions.

Simple Example

Below is a very simple example of how to log sensor data to the unity console at runtime:

using UnityEngine;
using UnityEngine.InputSystem;
public class SensorLogger : MonoBehaviour
{
// Declare the sensors you want to enable and log
private Gyroscope gyroscope;
private Accelerometer accelerometer;
private LightSensor lightSensor;
// Use this for initialization
void Start()
{
// Enable the sensors using InputSystem.EnableDevice()
gyroscope = Gyroscope.current;
accelerometer = Accelerometer.current;
lightSensor = LightSensor.current;
InputSystem.EnableDevice(gyroscope);
InputSystem.EnableDevice(accelerometer);
InputSystem.EnableDevice(lightSensor);
}
// Update is called once per frame
void Update()
{
// Read the sensor values using ReadValue()
Vector3 angularVelocity = gyroscope.angularVelocity.ReadValue();
Vector3 acceleration = accelerometer.acceleration.ReadValue();
float lightLevel = lightSensor.lightLevel.ReadValue();
// Log the sensor values using Debug.Log()
Debug.Log("Gyroscope: " + angularVelocity);
Debug.Log("Accelerometer: " + acceleration);
Debug.Log("Light Sensor: " + lightLevel);
}
}

References

For more information and examples on how to use Android’s Sensor API or how to obtain sensor data in Unity’s Input System, please refer to the following resources: