High-speed Switching of Droplet by Electric Meniscus Actuation

Tech ID: 20259 / UC Case 2007-386-0

Summary

UCLA researchers in the department of Mechanical and Aerospace Engineering have developed and reduced to practice a method for actuating droplets for devices requiring high speed, low latency operation (e.g. switching, display etc.)

Background

Liquid-solid contacts have many benefits, such as no wear, no surface degradation, and low contact resistance that have made them desirable for several applications including electrical and optical switches. However, attempts to design droplet-based switches have been limited due to their slower speeds (larger latency), with the best latencies being on the order of 1 millisecond. In order to achieve high speed (low latency) operation of droplet switching, using a large actuation force alone is most often insufficient.

Innovation

This invention reports a high speed droplet actuation technique. This invention includes provisions to accurately position the droplet, restrict its unwanted free motion and buffer against droplet volume variations, thus allowing a microactuation mechanism suitable for high speed (low latency) droplet switching.

Applications

High speed droplet-based switching opens up possibilities for a whole new range of devices such as radio-frequency (RF) switches, dynamic displays, and low-loss, high-performance electrical and optical micro switches.

Advantages

  • Significantly improved switching speeds over existing droplet (e.g., liquid-metal) switching technology. Switch-on latency times of ~50 s has been demonstrated, a 20 times improvement over existing technologies of 1 ms.
  • No signal bounce, low contact resistance and high power
  • No contact degradation leads to improved reliability and longer life
  • Low loss: 0.2dB simulated insertion loss for an RF switch as compared to 1dB for existing technology
  • Very high droplet stability against shock and vibration to a kG range.

State of Development

The low latency design concept has been experimentally verified (~50 s). A DC switch has been built, tested, and characterized. An RF switch has been designed and simulated.

Patent Status

Country Type Number Dated Case
United States Of America Issued Patent 8,362,376 01/29/2013 2007-386
 

Contact

Learn About UC TechAlerts - Save Searches and receive new technology matches

Inventors

  • Kim, Chang-Jin

Other Information

Keywords

mems electronics switches

Categorized As