Dinesh Bharadia, an alum of IIT Kanpur and Stanford University, now works at the Massachusetts Institute of Technology. (Adam DeTou/MIT Technology Review)


A 28-year-old Indian-origin MIT scientist has won a prestigious award for his research on radio waves, solving a problem that had stumped scientists for almost 150 years and enabling a host of new applications from Internet of Things connectivity to motion tracking. – @siliconeer #siliconeer #DineshBharadia #MIT #StanfordUniversity #IITKanpur #IoT #Research #Radiowaves #MarconiSociety #PaulBaranYoungScholarAward


Dinesh Bharadia, a graduate of Indian Institute of Technology (IIT) Kanpur, was honored with the 2016 Marconi Society Paul Baran Young Scholar Award that carries a cash prize of $4,000.

Bharadia’s research disproved a long-held assumption that it is “generally not possible for a radio to receive and transmit on the same frequency band because of the interference that results.”

His work culminated in making full-duplex radios a reality through the development of effective self-interference cancellation technology.

Bharadia, who pursued his PhD from Stanford University, will receive the award in November in California.

“Let’s say you are shouting at someone and they are shouting at you. Neither of you can hear the other, because you are both shouting in the same frequency,” said Bharadia, currently a researcher at Massachusetts Institute of Technology.

“The noise in your ears (interference) from your own shout prevents you from hearing the other person. That’s a good analogy for why radios have needed to use two different frequencies to transmit and receive simultaneously,” he said.

“It’s also why solving the challenge of developing ‘full duplex radios’ effectively doubles the amount of available spectrum,” Bharadia said.

The problem is more difficult than it sounds, said Bharadia. First, the interference is extremely strong – nearly a hundred billion times stronger than the signal that the radio might be trying to receive.

The resulting interference depends on the environment and its reflectors, changing in real time as people move around.

Typical radios (e.g. Wi-Fi) span many frequencies and use multi-antenna systems. Bharadia was able to demonstrate systems that overcame all these obstacles.

He turned full-duplex radios into a commercial reality by inventing new formulas that could in real time, model the non-linear, time-varying self-interference as well as analog and digital self-interference cancellation circuits to apply the model to the known transmitted signal and cancel the self-interference.

The analog cancellation filter Bharadia developed, also unleashed the potential for many more applications. The unique architecture had to allow cancellation in all environments.

“Dinesh’s work enables a whole host of new applications, from extremely low-power Internet of Things connectivity to motion tracking,” said Sachin Katti, Bharadia’s PhD advisor at Stanford.

“It has the potential to be used for important future applications such as building novel wireless imaging that can enable driverless cars in severe weather scenarios, help blind people to navigate indoors, and much more,” Katti said.