New system uses low-power Wi-Fi signal to track moving humans — even behind walls

‘Wi-Vi’ is based on a concept similar to radar and sonar imaging.

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The comic-book hero Superman uses his X-ray vision to spot bad guys lurking behind walls and other objects. Now we could all have X-ray vision, thanks to researchers at MIT’s Computer Science and Artificial Intelligence Laboratory.

Researchers have long attempted to build a device capable of seeing people through walls. However, previous efforts to develop such a system have involved the use of expensive and bulky radar technology that uses a part of the electromagnetic spectrum only available to the military.

Now a system being developed by Dina Katabi, a professor in MIT’s Department of Electrical Engineering and Computer Science, and her graduate student Fadel Adib, could give all of us the ability to spot people in different rooms using low-cost Wi-Fi technology. “We wanted to create a device that is low-power, portable and simple enough for anyone to use, to give people the ability to see through walls and closed doors,” Katabi says.

The system, called “Wi-Vi,” is based on a concept similar to radar and sonar imaging.  But in contrast to radar and sonar, it transmits a low-power Wi-Fi signal and uses its reflections to track moving humans. It can do so even if the humans are in closed rooms or hiding behind a wall. 

As a Wi-Fi signal is transmitted at a wall, a portion of the signal penetrates through it, reflecting off any humans on the other side. However, only a tiny fraction of the signal makes it through to the other room, with the rest being reflected by the wall, or by other objects. “So we had to come up with a technology that could cancel out all these other reflections, and keep only those from the moving human body,” Katabi says.

Motion detector

To do this, the system uses two transmit antennas and a single receiver. The two antennas transmit almost identical signals, except that the signal from the second antenna is the inverse of the first. As a result, the two signals interfere with each other in such a way as to cancel each other out. Since any static objects that the signals hit — including the wall — create identical reflections, they too are cancelled out by this nulling effect.

In this way, only those reflections that change between the two signals, such as those from a moving object, arrive back at the receiver, Adib says. “So, if the person moves behind the wall, all reflections from static objects are cancelled out, and the only thing registered by the device is the moving human.”

Once the system has cancelled out all of the reflections from static objects, it can then concentrate on tracking the person as he or she moves around the room. Most previous attempts to track moving targets through walls have done so using an array of spaced antennas, which each capture the signal reflected off a person moving through the environment. But this would be too expensive and bulky for use in a handheld device.

So instead Wi-Vi uses just one receiver. As the person moves through the room, his or her distance from the receiver changes, meaning the time it takes for the reflected signal to make its way back to the receiver changes too. The system then uses this information to calculate where the person is at any one time.

Possible uses in disaster recovery, personal safety, gaming

Wi-Vi, being presented at the Sigcomm conference in Hong Kong in August, could be used to help search-and-rescue teams to find survivors trapped in rubble after an earthquake, say, or to allow police officers to identify the number and movement of criminals within a building to avoid walking into an ambush.

It could also be used as a personal safety device, Katabi says: “If you are walking at night and you have the feeling that someone is following you, then you could use it to check if there is someone behind the fence or behind a corner.”

The device can also detect gestures or movements by a person standing behind a wall, such as a wave of the arm, Katabi says. This would allow it to be used as a gesture-based interface for controlling lighting or appliances within the home, such as turning off the lights in another room with a wave of the arm.

Venkat Padmanabhan, a principal researcher at Microsoft Research, says the possibility of using Wi-Vi as a gesture-based interface that does not require a line of sight between the user and the device itself is perhaps its most interesting application of all. “Such an interface could alter the face of gaming,” he says.

Unlike today’s interactive gaming devices, where users must stay in front of the console and its camera at all times, users could still interact with the system while in another room, for example. This could open up the possibility of more complex and interesting games, Katabi says.

Topics: Computer Science and Artificial Intelligence Laboratory (CSAIL), Electrical Engineering & Computer Science (eecs), Radar, Wireless, X-ray, Motion sensing, Research


"Wi-Vi uses just one receiver....The system then uses this information to calculate where the person is at any one time."

Gee, that is interesting, but at 5 gigahertz wi-fi, the wavelength is a bit over 2 inches. with only 2 transmitters and one receiver, it seems to me you aren't going to get hardly any directional information with an i-phone sized device.

Maybe there is the possibility of calculating some distance information with a time manipulated signal, but what kind of black magic will allow you to calculate position if you don't have direction information?

Would this device "see" through an exterior wall made of brick or stone 12 inches thick?

All I would need is motion detection.

Please say no. My novel would be happier for it.

It`s a useful technology, but would it be popular or for everyone ?

Could we find it in upcoming smart phones systems as an app ?

This article fails to address the potentially negative impacts of "a device that is low-power, portable and simple enough for anyone to use, to give people the ability to see through walls and closed doors". Though boasting many positive impacts such as improving disaster recovery, this technology would wreak havoc on our everyday lives if it became available to the public.

Thievery and criminality may be advanced by this technology. Would be thieves will be able to better identify vacant homes and businesses susceptible to burglary. Criminals will be able to identify approaching police officers, just as police officers will identify them. If you are being pursued, yes, you can identify your pursuer, but so too can your pursuer identify you - even if you succeed in hiding. Finally, personal privacy will become a thing of the past. Never more will you be able to escape that nosy neighbor watching your every move through closed curtains, doors and behind walls.

And wheres (real) difference from existing MW technology for intruder alarm MW detectors? (some are also working on 2,4GHz)

Its VERY interesting idea of use its side effect, of course, but its "just" enhancing something many years known, nothing new. And of course Wifi has about 10-100x stronger power output than intruder alarm MW detector.

With this ability, maybe this could be the personal (tricorder) scanner!

What if there is no movement?Would the device still detect people who are still?In such a case, there would be no change in the nature of the signal.

if there is two moving object consider , 1 moving object is man and othr one let it be a fan how we come to know the diff between them in wavefoarm u showed in the screen

Can u pliz send me pdf full report on wi vi technology for seminar. Its urgent email id:

Wow, I can use it as my final year project.. THANKS !!!!

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