acm-header
Sign In

Communications of the ACM

ACM Careers

Two Radio Signals, One Chip, Open a New World For Wireless Communication


View as: Print Mobile App Share:
Cornell's Alyosha Molnar and Hazal Yuksel

Cornell professor Alyosha Molnar (left), holding a test board with the two-way transceiver chip, with graduate student Hazal Yksel.

Credit: Cornell University

Cornell University engineers have devised a method for transmitting and receiving radio signals on a single chip, which could ultimately help change the way wireless communication is done.

Separating the send and receive bands is difficult enough, but the problem is compounded by the ever-increasing number of bands in the latest devices, which handle everything wireless technology has to offer. From GPS to Bluetooth to Wi-Fi, each band requires a filter to stop the strong transmit signals from drowning out reception.

Alyosha Molnar, associate professor of electrical and computer engineering (ECE), and Alyssa Apsel, professor of ECE, have come up with an ingenious way to separate the signals. Their work is described in "A Wideband Fully Integrated Software-Defined Transceiver for FDD and TDD Operation," published online in the IEEE Journal of Solid-State Circuits.

Their idea lies in the transmitter — actually a series of six subtransmitters — all hooked into an artificial transmission line. Each of the subtransmitters send signals at regular intervals, and their individually weighted outputs are programmed so that they combine to produce a radio frequency signal in the forward direction, at the antenna port, while canceling out at the receive port.

The programmability of the individual outputs allows this simultaneous summation and cancellation to be tuned across a wide range of frequencies, and to adjust to signal strength at the antenna.

"In one direction, it's a filter and you basically get this cancellation," Apsel says. "And in the other direction, it's an amplifier."

"You put the antenna at one end and the amplified signal goes out the antenna, and you put the receiver at the other end and that's where the nulling happens," Molnar says. "Your receiver sees the antenna through this wire, the transmission line, but it doesn't see the transmit signal because it's canceling itself out at that end."

This work builds on research reported six years ago by a group from Stanford University, which devised a way for the transmitter to filter its own transmission, allowing the weaker incoming signal to be heard. It's the theory behind noise-canceling headphones.

Unlike the Stanford work, the Cornell group's subtransmitter concept will work over a range of frequencies — a positive in this age of scrambling for available frequencies that used to be the realm of over-the-air television.

"This wire is a fairly broadband structure," Molnar says. "And the thing you do to make it work over a wide range of frequencies is just control those different subgains of the transmitters to make this cancellation always happen."

Instead of needing a filter for every band, signal separation can be controlled digitally. Upgrading to the latest version would be like updating an app — as simple as downloading the latest software.

The IEEE Journal of Solid-State Circuits article is authored by Hazal Yüksel, Zachariah Boynton, Changhyuk Lee, Thomas Tapen, Alyosha Molnar, and Alyssa Apsel of Cornell, and Dong Yang of Cypress Semiconductor Corp.

Financial support for this work came from the Defense Advanced Research Projects Agency.


 

No entries found

Sign In for Full Access
» Forgot Password? » Create an ACM Web Account