Java Code Examples for android.hardware.Sensor#TYPE_TEMPERATURE

@Nullable
public static String getHumanStringType(Sensor sensor) {
    switch (sensor.getType()) {
        case Sensor.TYPE_ACCELEROMETER:
            return "Accelerometer";

        case Sensor.TYPE_AMBIENT_TEMPERATURE:
            return "Ambient Temperature";

        case Sensor.TYPE_GAME_ROTATION_VECTOR:
            return "Game Rotation Vector";

        case Sensor.TYPE_GEOMAGNETIC_ROTATION_VECTOR:
            return "Geomagnetic Rotation Vector";

        case Sensor.TYPE_GRAVITY:
            return "Gravity";

        case Sensor.TYPE_GYROSCOPE:
            return "Gyroscope";

        case Sensor.TYPE_GYROSCOPE_UNCALIBRATED:
            return "Gyroscope (Uncalibrated)";

        case Sensor.TYPE_HEART_RATE:
            return "Heart Rate";

        case Sensor.TYPE_LIGHT:
            return "Light";

        case Sensor.TYPE_LINEAR_ACCELERATION:
            return "Linear Acceleration";

        case Sensor.TYPE_MAGNETIC_FIELD:
            return "Magnetic Field";

        case Sensor.TYPE_MAGNETIC_FIELD_UNCALIBRATED:
            return "Magnetic Field (Uncalibrated)";

        case Sensor.TYPE_PRESSURE:
            return "Pressure";

        case Sensor.TYPE_PROXIMITY:
            return "Proximity";

        case Sensor.TYPE_RELATIVE_HUMIDITY:
            return "Relative Humidity";

        case Sensor.TYPE_ROTATION_VECTOR:
            return "Rotation Vector";

        case Sensor.TYPE_SIGNIFICANT_MOTION:
            return "Significant Motion";

        case Sensor.TYPE_STEP_COUNTER:
            return "Step Counter";

        case Sensor.TYPE_STEP_DETECTOR:
            return "Step Detector";

        case Sensor.TYPE_ORIENTATION:
            return "Orientation";

        case Sensor.TYPE_TEMPERATURE:
            return "Temperature";
    }
    return null;
}
 

public static String getDescription(Sensor sensor) {
    switch (sensor.getType()) {
        case Sensor.TYPE_ACCELEROMETER:
            return "Measures the acceleration force in m/s² that is applied to a device on all three physical axes (x, y, and z), including the force of gravity.";

        case Sensor.TYPE_AMBIENT_TEMPERATURE:
            return "Measures the ambient room temperature in degrees Celsius (°C).";

        case Sensor.TYPE_GRAVITY:
            return "Measures the force of gravity in m/s² that is applied to a device on all three physical axes (x, y, z).";

        case Sensor.TYPE_GYROSCOPE:
            return "Measures a device's rate of rotation in rad/s around each of the three physical axes (x, y, and z).";

        case Sensor.TYPE_HEART_RATE:
            return "Measures heart rate.";

        case Sensor.TYPE_LIGHT:
            return "Measures the ambient light level (illumination) in lx.";

        case Sensor.TYPE_LINEAR_ACCELERATION:
            return "Measures the acceleration force in m/s² that is applied to a device on all three physical axes (x, y, and z), excluding the force of gravity.";

        case Sensor.TYPE_MAGNETIC_FIELD:
            return "Measures the ambient geomagnetic field for all three physical axes (x, y, z) in μT.";

        case Sensor.TYPE_PRESSURE:
            return "Measures the ambient air pressure in hPa or mbar.";

        case Sensor.TYPE_PROXIMITY:
            return "Measures the proximity of an object in cm relative to the view screen of a device. This sensor is typically used to determine whether a handset is being held up to a person's ear.";

        case Sensor.TYPE_RELATIVE_HUMIDITY:
            return "Measures the relative ambient humidity in percent (%).";

        case Sensor.TYPE_ROTATION_VECTOR:
            return "Measures the orientation of a device by providing the three elements of the device's rotation vector.";

        case Sensor.TYPE_ORIENTATION:
            return "Measures degrees of rotation that a device makes around all three physical axes (x, y, z). ";

        case Sensor.TYPE_TEMPERATURE:
            return "Measures the temperature of the device in degrees Celsius (°C). ";

        default:
            return "Information about this sensor is unavailable.";
    }
}
 

@SuppressWarnings({ "unchecked", "deprecation" })
public EnvironmentalSucker(Context context) {
	super(context);
	setSucker(this);
	
	sm = (SensorManager)context.getApplicationContext().getSystemService(Context.SENSOR_SERVICE);
	availableSensors = sm.getSensorList(Sensor.TYPE_ALL);
	
	for(Sensor s : availableSensors) {
		switch(s.getType()) {
		case Sensor.TYPE_AMBIENT_TEMPERATURE:
			sm.registerListener(this, s, SensorManager.SENSOR_DELAY_NORMAL);
			break;
		case Sensor.TYPE_RELATIVE_HUMIDITY:
			sm.registerListener(this, s, SensorManager.SENSOR_DELAY_NORMAL);
			break;
		case Sensor.TYPE_PRESSURE:
			sm.registerListener(this, s, SensorManager.SENSOR_DELAY_NORMAL);
			break;
		case Sensor.TYPE_LIGHT:
			sm.registerListener(this, s, SensorManager.SENSOR_DELAY_NORMAL);
			break;				
		case Sensor.TYPE_TEMPERATURE:
			sm.registerListener(this, s, SensorManager.SENSOR_DELAY_NORMAL);
			break;
		}
			
	}
	
	setTask(new TimerTask() {
		
		@Override
		public void run() {
				if(currentAmbientTemp != null)
					sendToBuffer(currentAmbientTemp);
				if(currentDeviceTemp != null)
					sendToBuffer(currentDeviceTemp);
				if(currentHumidity != null)
					sendToBuffer(currentHumidity);
				if(currentPressure != null)
					sendToBuffer(currentPressure);
				if(currentLight != null)
					sendToBuffer(currentLight);
		}
	});
	
	getTimer().schedule(getTask(), 0, Environment.LOG_RATE);
}
 

/**
	 * 
Sensor	Sensor event data	Units of measure	Data description
TYPE_AMBIENT_TEMPERATURE	event.values[0]	°C	Ambient air temperature.
TYPE_LIGHT	event.values[0]	lx	Illuminance.
TYPE_PRESSURE	event.values[0]	hPa or mbar	Ambient air pressure.
TYPE_RELATIVE_HUMIDITY	event.values[0]	%	Ambient relative humidity.
TYPE_TEMPERATURE	event.values[0]	°C	Device temperature.1

	 */
	@SuppressWarnings("deprecation")
	@Override
	public void onSensorChanged(SensorEvent event) {
		synchronized(this) {
			if(getIsRunning()) {
				ILogPack sVals = new ILogPack();
				
				try {				
					switch(event.sensor.getType()) {
					case Sensor.TYPE_AMBIENT_TEMPERATURE:
						sVals.put(Environment.Keys.AMBIENT_TEMP_CELSIUS, event.values[0]);
						currentAmbientTemp = sVals;
						break;
					case Sensor.TYPE_TEMPERATURE:
						sVals.put(Environment.Keys.DEVICE_TEMP_CELSIUS, event.values[0]);
						currentDeviceTemp = sVals;
						break;
					case Sensor.TYPE_RELATIVE_HUMIDITY:
						sVals.put(Environment.Keys.HUMIDITY_PERC,event.values[0]);
						currentHumidity = sVals;
						break;
					case Sensor.TYPE_PRESSURE:
						sVals.put(Environment.Keys.PRESSURE_MBAR, event.values[0]);
						
						//TODO we need to get real local sea level pressure here from a dynamic source
						//as the default value doesn't cut it
						float altitudeFromPressure = SensorManager.getAltitude(mPressureSeaLevel, event.values[0]);						
						sVals.put(Environment.Keys.PRESSURE_ALTITUDE, altitudeFromPressure);
						
						currentPressure = sVals;
						break;
					case Sensor.TYPE_LIGHT:
						sVals.put(Environment.Keys.LIGHT_METER_VALUE, event.values[0]);
						currentLight = sVals;
						break;
						
					}
					
				} catch(JSONException e) {}
			}
		}
	}
 

@SuppressWarnings("deprecation")
private boolean isRestricted(XParam param, int type) throws Throwable {
	if (type == Sensor.TYPE_ALL)
		return false;
	else if (type == Sensor.TYPE_ACCELEROMETER || type == Sensor.TYPE_LINEAR_ACCELERATION) {
		if (isRestricted(param, "acceleration"))
			return true;
	} else if (type == Sensor.TYPE_GRAVITY) {
		if (isRestricted(param, "gravity"))
			return true;
	} else if (type == Sensor.TYPE_RELATIVE_HUMIDITY) {
		if (isRestricted(param, "humidity"))
			return true;
	} else if (type == Sensor.TYPE_LIGHT) {
		if (isRestricted(param, "light"))
			return true;
	} else if (type == Sensor.TYPE_MAGNETIC_FIELD || type == Sensor.TYPE_MAGNETIC_FIELD_UNCALIBRATED) {
		if (isRestricted(param, "magnetic"))
			return true;
	} else if (type == Sensor.TYPE_SIGNIFICANT_MOTION) {
		if (isRestricted(param, "motion"))
			return true;
	} else if (type == Sensor.TYPE_ORIENTATION || type == Sensor.TYPE_GYROSCOPE
			|| type == Sensor.TYPE_GYROSCOPE_UNCALIBRATED) {
		if (isRestricted(param, "orientation"))
			return true;
	} else if (type == Sensor.TYPE_PRESSURE) {
		if (isRestricted(param, "pressure"))
			return true;
	} else if (type == Sensor.TYPE_PROXIMITY) {
		if (isRestricted(param, "proximity"))
			return true;
	} else if (type == Sensor.TYPE_GAME_ROTATION_VECTOR || type == Sensor.TYPE_GEOMAGNETIC_ROTATION_VECTOR
			|| type == Sensor.TYPE_ROTATION_VECTOR) {
		if (isRestricted(param, "rotation"))
			return true;
	} else if (type == Sensor.TYPE_TEMPERATURE || type == Sensor.TYPE_AMBIENT_TEMPERATURE) {
		if (isRestricted(param, "temperature"))
			return true;
	} else if (type == Sensor.TYPE_STEP_COUNTER || type == Sensor.TYPE_STEP_DETECTOR) {
		if (isRestricted(param, "step"))
			return true;
	} else if (type == Sensor.TYPE_HEART_RATE) {
		if (isRestricted(param, "heartrate"))
			return true;
	} else if (type == 22) {
		// 22 = TYPE_TILT_DETECTOR
		// Do nothing
	} else if (type == 23 || type == 24 || type == 25) {
		// 23 = TYPE_WAKE_GESTURE
		// 24 = TYPE_GLANCE_GESTURE
		// 25 = TYPE_PICK_UP_GESTURE
		// 23/24 This sensor is expected to only be used by the system ui
		// 25 Expected to be used internally for always on display
	} else
		Util.log(this, Log.WARN, "Unknown sensor type=" + type);
	return false;
}