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Virtual Wall That Can Improve Security and Performance Developed

08 November 2017

A team of researchers led by Dartmouth College may have finally solved the problem of how to inexpensively improve wireless signal strength for indoor spaces with multiple rooms. The same technology for enhancing office and home Wi-Fi signals can be used to strengthen wireless security.

The research relies on 3D printing to produce a cheap, customized reflector that directs wireless signals to where users need them the most.

"Through this single solution, we address a number of challenges that plague wireless users," said Xia Zhou, an assistant professor of computer science at Dartmouth. "Not only do we strengthen wireless signals, we make those same signals more secure."

For only $35 and 23 minutes, Wi-Fi users can increase signal strength and boost security in offices and homes. (Xia Zhou)For only $35 and 23 minutes, Wi-Fi users can increase signal strength and boost security in offices and homes. (Xia Zhou)

Customizing the coverage of wireless networks inside buildings is critical for users to improve signal reception in desired areas while weakening signals in others. By shaping signals, users can increase wireless efficiency through lessening the signal-deadening impact of building materials and interior layouts.

This system can make it more difficult for attackers by adding to existing security measures like encryption through physically confining wireless signals to limited spaces. This also leads to reduced interference.

Achieving the goal of improved wireless performance is particularly challenging indoors because of the complex interactions of radio signals with the environment. Existing approaches to optimizing wireless signals rely on directional antennae to concentrate signals. But the equipment is either difficult to configure or affected by high cost.

Through experiments presented in the research paper, the team improves on previous studies that placed an aluminum soft-drink can behind a Wi-Fi access point to strengthen the signal in one direction. The current research generalizes this idea by presenting a systematic approach to optimizing reflector shapes for enabling a more developed set of signal distributors.

After assessing the interior layouts and the target areas to strengthen or weaken signal strength, the Dartmouth research team placed a “computationally optimized” signal reflector around a wireless router. The reflector is composed of just plastic and a thin layer of metal redirects wireless signals to the desired coverage areas.

After testing this approach in two different interiors for signal strength and speed, the researchers reported that optimized 3D reflectors provide many benefits including strong physical security, low cost, and ease of use for non-expert users.

The research tested the reflector with a variety of off-the-shelf Wi-Fi access points, including those that use the latest Wi-Fi protocol 802.11ac.

"With a simple investment of about $35 and specifying coverage requirements, a wireless reflector can be custom-built to outperform antennae that cost thousands of dollars," said Zhou.

In order to create the technology, the researchers designed an algorithm that optimized a reflector’s 3D shape to target wireless coverage. The team developed an approach to simulating how radio signals spread and interact with objects in their environment.

With information on a specific interior space, locations of wireless access points and desired target area, the system computes an optimized reflector shape in just 23 minutes. Researchers found that the reflectors can decrease strength by up to 10 dB where the signal is not wanted and increase strength by 6 dB where it is desired. The reflector is also fairly easy to place.

The current design is limited by its static shape, so the research team will now study reflectors made of different materials so that the device can automatically adapt its shape when the interior layout changes. The team will also examine higher frequency bands, like millimeter waves and visible light.

This research will be presented at ACM’s BuildSys 2017 in Delft, Netherlands.

To contact the author of this article, email Siobhan.Treacy@ieeeglobalspec.com


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