GaN技术杂谈

随着电机技术的进步，功率密度增加；电机设计成更小的外形尺寸和更高的速度、更高的精度，这需要更高的电频率。

Gallium nitride (GaN) is a better semiconductor than silicon. There are many crystals that are better than silicon, but the problem has always been that they are far too expensive to be used in every application where silicon is used. But, GaN can be grown as an inexpensive thin layer on top of a standard silicon wafer enabling devices that are faster, smaller, more efficient, and less costly than their aging silicon counterparts.

Drones are on the rise. In fact, use of drones is only limited by our imagination – from merely recreational (think “drone races”) to delivering packages (as promised by Amazon) to a range of life-saving military uses (such as real-time battlefield imaging). Emerging high speed, small size, and highly efficient gallium nitride power semiconductors are key contributors to the expansion of drone applications, including onboard equipment such as LiDAR imaging and navigation systems and 4G/5G communication transmitters. Let’s take a look at how GaN technology and the expansion of drone applications intersect.

A drone, or more technically, an unmanned aerial vehicle (UAV) is an aircraft without a pilot on board. Control of the drone is accomplished either under remote control from the ground or under control of an onboard computer.

Although drones originated mostly in military applications, civilian drones now vastly outnumber military drones, with estimates of over 9 million consumer drones to be sold in 2016 world wide for a total market value of near $3 billion.