New Transmitter To Reduce Power Leakage Of IoT Devices

The need of each thing on the Internet of Things (IoT) might be small, but the number of devices is expected to double between now and 2020.

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Anantha Chandrakasan, professor of electrical engineering at MIT, presented a new transmitter design that reduces power leakage when a radio is in the off state by 100-fold. Even though it has ultra-low power needs, the system can still provide enough power for communication across different standards, including Bluetooth and 802.15.4.   “A key challenge is designing these circuits with extremely low standby power, because most of these devices are just sitting idling, waiting for some event to trigger a communication. When it’s on, you want to be as efficient as possible, and when it’s off, you want to really cut off the off-state power, the leakage power.”  Chandrakasan said the key was to reduce the leakage of power in the transistor. Even when there is no charge applied to the transistor’s gate, it leaks some current. For devices that mostly sit idle waiting for a signal to power up, the slow leak can take a toll on battery life. (Limiting leakage was a main factor in two fundamental redesigns of transistors in computer processors.)

They, applied a negative charge to the gate when the transmitter is idle, making the transistor a better insulator. Just a small negative charge, consuming just 20 picowatts of power, was able to save 10,000 picowatts in leakage.  “Ultralow leakage energy is critical for future sensor nodes that need the transmitter to be on only a very small percentage of time,” Baher Haroun, director of the Embedded Processing Systems Labs at Texas Instruments, said in a statement. Texas Instruments and Shell helped fund the work by Chandrakasan’s team.

See on Scoop.itInternet of Things – Technology focus

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