Your smartphone is a seriously high-tech bit of kit.
From face unlock and fingerprint reader to GPS and auto-brightness, your smartphone relies on numerous specialized sensors to allow you to use the apps, features, and services that make your life easier. Let's see how many sensors your smartphone has and how they work.
A sensor is a tiny device or module that analyzes its surroundings and reports the quantitative measure to the processor. Smartphone sensors measure various aspects of their surroundings, including ambient light, device orientation, movement, etc.
Every smartphone has a 3-dimensional coordinate system. Based on this system, sensors in your smartphone detect and record changes in real-time.
All the different sensors of your smartphone operate based on these axes. However, do note that the coordinate system remains stable as per the phone's default orientation. It doesn't shift when you hold your phone in landscape mode or tilt it in any direction.
Based on the parameters they measure, smartphone sensors are broadly classified into three types.
Motion sensors detect the movement, acceleration, and rotation along the three axes of the device's coordinate system. These are the sensors that help your smartphone measure the number of steps you take, the direction of your path, and detect tilts when you are playing a game.
Some examples of motion sensors are accelerometers, gravity sensors, gyroscopes, and so on.
Related: Android Motion Sensor Security Risks and How to Stay Safe
Position sensors record the physical location of the device. They do this by identifying your phone's coordinates—taking the world around them as a frame of reference and its orientation in 3-dimensional space. Phones use them for navigation, detecting screen orientation, and much more.
Examples of position sensors are proximity sensors, GPS, and magnetometers.
Environmental sensors detect any significant changes in the surroundings of your smartphone. For example, these include changes in the lighting, pressure, temperature, adjusting the brightness when the auto-brightness is enabled, display temperature, measuring air pressure, and more.
Examples of environmental sensors are ambient light sensors, thermometers, barometers, air-humidity sensors, etc.
Smartphones are packed with various sensors, each playing a vital role in enabling different functions. Let's check out the most common smartphone sensors and understand how they work.
An accelerometer records the movement of your device along the three axes of the coordinate system. The X-axis measures the movement of your device from side to side, the Y-axis measures the movement along top and bottom (including gravity), and the Z-axis measures the movement forward and backward.
Using the data obtained by measuring the motion of your device, it calculates your acceleration. This info is then used by apps to detect direction, orientation, and speed. For instance, a fitness app measures the direction and pace of your morning jog.
A gyroscope measures the rotation along the three axes of the device's coordinate system. It detects the exact measure of your phone's rotation in radians per second.
Simply put, an accelerometer measures linear movement, and a gyroscope measures angular movement. Both combined enable functions like auto-rotation, and they are used for motion-sensitive games like Temple Run or Asphalt 9.
A magnetometer senses your phone's orientation according to the earth's magnetic field. This sensor is essential to navigation and compass apps as it helps your phone identify directions and adjust the map accordingly.
Like a magnetometer, a Global Positioning System (GPS) is a sensor with antennas to help navigation. It receives continuous signals from satellites that help calculate the distance traveled and the location of your phone.
When a signal is received, the GPS sensor records a location. Depending on the time difference between any two signals, the distance is calculated. Navigation apps use both GPS and magnetometer to identify location and direction.
Ambient light sensors measure the intensity of light around the device. These sensors detect the changes in brightness of the surroundings and record its intensity.
If the auto-brightness feature is enabled, the data from the ambient light sensor helps adjust the screen brightness as per the light in the room. Auto-brightness is a handy feature, but if you want to change the brightness manually, you can disable it.
Proximity sensors detect how close a certain object is to your phone. A quick example of this is your phone's display turning off when you pick up and answer a call. This helps save battery and avoid accidental taps during phone calls.
In this example, proximity sensors work by measuring the distance between the screen and your ear, and when the distance equals a set value, it turns off the display before your ear touches the screen.
Related: What to Do if Your Android Phone's Proximity Sensor Stops Working
A Hall sensor is quite similar to a proximity sensor, except it detects changes in the magnetic fields around the device. When it senses a change in the magnetic field, it sends this data to the processor, turning off the phone's display. This sensor is specifically used to detect the magnets in flip covers.
When you close the flip cover, the magnet is close to the device and disrupts the magnetic field around the device. This cues the processor to turns off the display. When the cover is open, the magnetic field goes back to normal, and the screen wakes up.
Related: Why Are Smartphone Brands Are Designing Their Own Processors?
Biometric sensors use physical attributes for identification and are typically used for security purposes. As physical features like fingerprints, irises, and faces are unique to a person, using them for identity authentication provides enhanced protection.
Some of the biometric sensors found in your mobile are:
Atmospheric sensors detect several aspects of your device's surrounding like atmospheric pressure, ambient temperature, air humidity, etc. Atmospheric sensors include:
Sensors are the devices that make your smartphone smarter. These are the offstage stars that help processors enable various features. While some sensors like accelerometers and gyroscopes have multiple applications, others like ambient-light and hall sensors have specific functions.
Regardless, most of the ones we discussed are found in every smartphone. And with time, just like any other tech, sensors are also becoming more compact, energy-efficient, and reliable. This allows manufacturers to load more features in smartphones with fewer trade-offs.
Ayush is a freelance writer and holds a BBA degree in marketing. He has written on a variety of niches including tech, lifestyle, business, and entertainment. At MUO, he spends most of his time hunting for the latest stories on mobile gadgets.
Join our newsletter for tech tips, reviews, free ebooks, and exclusive deals!