How Many Sensors are in a Drone, And What do they Do? Position/Presence/Proximity

In today's fast growing drone market, sensor technologies are often the unheralded secret sauce inside. In this article, we discuss some of the types of sensor technologies that power today's drones.


The Technology That Makes Drones Work
Fig. 1: Various sensor technologies are used in a variety of ways in modern drones.
Fig. 1: Various sensor technologies are used in a variety of ways in modern drones.

Accelerometers
Accelerometers are used to determine position and orientation of the drone in flight. Like your Nintendo Wii controller or your iPhone screen position, these small silicon-based sensors play a key role in maintaining flight control. MEMS accelerometers sense movement in several ways. One type of technology senses the micro movement of very small structures embedded in a small integrated circuit. The movement of these small 'diving boards' changes the amount of electrical current moving through the structure, indicating a change of position relative to gravity.
Another technology used in accelerometers is thermal sensing, which offers several distinct advantages. It does not have moving parts, but instead senses changes in the movement of gas molecules passing over a small integrated circuit. Because of the sensitivity of these sensors, they play a role in stabilizing on-board cameras that are vital for applications like filmmaking.
By controlling up and down movement, as well as removing jitter and vibration, filmmakers are able to capture extremely smooth looking video. Additionally, because these sensors are more immune to vibrations than other technologies, thermal MEMS sensors are perfect in drone applications to minimize problems from the increased vibration generated by the movement of rotating propulsion fans and propellers.


Fig. 2:  Because they have no moving parts, accelerometers based on thermal sensing technology offer much better stability and accuracy than mechanical based sensors.
Fig. 2: Because they have no moving parts, accelerometers based on thermal sensing technology offer much better stability and accuracy than mechanical based sensors.


Inertial Measurement Units
Inertial measurement units combined with GPS are critical for maintaining direction and flight paths. As drones become more autonomous, these are essential to maintain adherence to flight rules and air traffic control.
Inertial measurement units utilize multi-axis magnetometers that are in essence small, accurate compasses. These sense changes in direction and feed data into a central processor, which ultimately indicates direction, orientation, and speed.

Fig.3:  The INS380SA module pictured here is a complete inertial navigation system with a built-in 48-channel GPS receiver.
Fig.3: The INS380SA module pictured here is a complete inertial navigation system with a built-in 48-channel GPS receiver.

Tilt Sensors
Tilt sensors, combined with gyros and accelerometers, provide input to the flight-control system in order to maintain level flight. This is extremely important for applications where stability is paramount, from surveillance to delivery of fragile goods.
These types of sensors combine accelerometers with gyroscopes, allowing the detection of small variations of movement. It is the gyroscope compensation that allows these tilt sensors to be used in moving applications like motor vehicles or drones.
Fig.4:  Incorporating both an accelerometer and a gyroscope, Tilt sensors help drones maintain level flight.
Fig.4: Incorporating both an accelerometer and a gyroscope, Tilt sensors help drones maintain level flight.


Current Sensors
In drones, power consumption and use are important. Current sensors can be used to monitor and optimize power drain, safe charging of internal batteries, and detect fault conditions with motors or other areas of the system.
Current sensors work by measuring electrical current (bi-directional) and ideally provide electrical isolation to reduce power loss and eliminate the opportunity for electrical shock or damage to the user or systems. Sensors with fast response time and high accuracy optimize battery life and performance of drones.

Magnetic Sensors
In drones, electronic compasses provide critical directional information to inertial navigation and guidance systems. Anisotropic magnetoresistive (AMR) permalloy technology sensors, which have superior accuracy and response time characteristics while consuming significantly less power than alternative technologies, are well-suited to drone applications. Turnkey solutions provide drone manufacturers with quality data sensing in a very rugged and compact package.

Engine Intake Flow Sensors
Flow sensors can be used to effectively monitor air flow into small gas engines used to power some drone varieties. These help the engine CPU determine the proper fuel-to-air ratio at a specified engine speed, which results in improved power and efficiency, and reduced emissions.
Many gas engine mass-flow sensors employ a calorimetric principal utilizing a heated element and at least one temperature sensor to quantify mass flow. MEMS thermal mass air flow sensors also utilize the calorimetric principal, but in a micro scale, making it highly suitable for applications where reduced weight is critical.

About the Author
Chris Winkler is a Senior Product Manager for Emerging Markets at MEMSIC, an Andover, MA based MEMS company. He is a member of IEEE and IEEE Power Electronics Society (PELS) and the author of over 12 technical articles and whitepapers focusing on mobile devices, power and analog semiconductors, and remote sensing. Prior to MEMSIC, Chris held senior level roles in Product Line Management at Fairchild Semiconductor, Senior Engineering roles at Motorola and Home Wireless Networks. He holds a BSEE from Iowa State University and an MSEE from National Technical University with a focus on RF Circuits, Electro-Magnetics and Analog Design.

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