Get our free email newsletter

“Near-Zero-Power” Temperature Sensor Could Extend Battery Life in Wearables

Photo Credit: University of California - San Diego
Photo Credit: University of California – San Diego

Researchers at the University of California, San Diego have created a “near-zero-power” temperature sensor. This remarkable new sensor has the potential to extend the battery life of wearable devices, smart home monitoring systems, and a variety of devices from the Internet of Things.

The near-zero-temperature sensor runs on a mere 113 picowatts of power. To put that into perspective, it’s 10 billion times smaller than a watt. The technology used in this design opens up the possibility for more devices powered by low-energy sources, such as the human body itself.

“Our vision is to make wearable devices that are so unobtrusive, so invisible that users are virtually unaware that they’re wearing their wearables, making them ‘unawearables.’ Our new near-zero-power technology could one day eliminate the need to ever change or recharge a battery.”

- Partner Content -

A Dash of Maxwell’s: A Maxwell’s Equations Primer – Part Two

Maxwell’s Equations are eloquently simple yet excruciatingly complex. Their first statement by James Clerk Maxwell in 1864 heralded the beginning of the age of radio and, one could argue, the age of modern electronics.
Patrick Mercier, electrical engineering professor at UC San Diego Jacobs School of Engineering and senior author on the study

The system relies on two power sources. One power source charges a capacitor based on a fixed amount of time; the other charges depending on the temperature (slower at low temperatures, faster at high ones). When the temperature changes, the system adjusts accordingly. This allows the temperature-dependent source to charge at the same rate as the fixed current source. The charging times are equalized by a built-in digital feedback loop, which reconnects the temperature-based current source to a differently-size capacitor.

“We’re building systems that have such low power requirements that they could potentially run for years on just a tiny battery.”

Hui Wang, electrical engineering Ph.D. student and the first author of the study

All this technology is integrated into an amazingly small chip. The chip measures about 0.15 X 0.15 square millimeters, and can operate at temperatures anywhere from negative 20 C up to 40 C. Although the device can keep up with state-of-the-art technology in most aspects, it is slightly slower than other temperature sensors. It averages about one temperature update per second.

The scientists hope to improve upon the speed of their device, as well as its accuracy. Once those issues are taken care of, the next step will be integrating the design into commercial devices. All of this adds up to smaller, faster, more effective wearables as well as other similar devices.

 

Related Articles

Digital Sponsors

Become a Sponsor

Discover new products, review technical whitepapers, read the latest compliance news, and check out trending engineering news.

Get our email updates

What's New

- From Our Sponsors -

Sign up for the In Compliance Email Newsletter

Discover new products, review technical whitepapers, read the latest compliance news, and trending engineering news.