University deploys high-density antennas to deliver Wi-Fi for 40,000-plus devices
- By Toni Fuhrman
- Jan 07, 2014
The increasing number of mobile devices on university and agency campuses is creating a dramatic acceleration in data traffic and pushing networks to their limits — especially where there are large concentrations of simultaneous users. One way to ensure connectivity is to use high-density, narrow-beamwidth antennas that reduce channel-to-channel interference, increase capacity and enable stronger and more reliable Wi-Fi signals, according to a report in Campus Technology.
Students at Georgia Institute of Technology were experiencing poor mobile performance, especially in several large auditoriums across campus, where there were too many client devices on too few wireless access points. There were complaints that performance was very degraded, almost to the point of being unusable said Bill Lawrence, IT project manager principal at the university.
"On a typical day, we have more than 40,000 unique client devices using our wireless network on campus," Lawrence said. "We were also seeing uneven client distribution across the access points that were in the rooms."
Lawrence and his team had started out with internal omni-directional antennas. "An omni-directional antenna is like an incandescent light bulb," said Lawrence. "The light goes everywhere." Needing to focus the radio signal into a certain space, the IT team researched wireless vendors and decided to go with directional antennas from TerraWave Solutions, a division of Tessco Technologies. "The TerraWave antenna is like a flashlight or a spotlight," Lawrence said. "It focuses energy where you want it to go."
TerraWave high-density antennas are external antennas that connect to all of the industry's leading access points. For WiFi users in indoor and outdoor large public venues, the antennas increase capacity and coverage by providing a narrower, focused beam enabling stronger, more reliable WiFi signals. The antennas also cut channel-to-channel interference.
To address interference and connectivity, high-density networks are designed to provide small RF (radio frequency) cells of operation, said TerraWave product manager Dennis Burrell. "These small RF cells are achieved by using narrow-beamwidth antennas [35 degrees vs. the traditional 50-80 degrees] on the access point. This limits the users per access point, which in turn increases the bandwidth available to each user."
The TerraWave High-Density 2.4/5 GHz Patch Antenna — about the size of a small pizza box — is installed on the ceiling or the wall, depending on where the access points are located. In order to determine how many antennas are needed, a school considers the number of devices they want the network to support; the applications the network supports (Internet research, e-mail access, shared online classroom resources, etc.); and the throughput needed for each of those applications.
Georgia Tech did a pilot project involving two 300-seat auditoriums during this year's spring break. Based on promising results, the school used the same solution in several large auditoriums across campus last summer.
Since then, Lawrence and his team have installed 279 high-density antennas. The installations took place in 48 rooms, within 21 campus buildings. The upgraded rooms seat anywhere from 83 to 348 students.
"This will be the model we use going forward, for large classrooms and auditoriums," said Lawrence. "I used this antenna/access point combination for an outdoor courtyard this semester, and have plans to use it in other outdoor locations, provided funding becomes available."
Since the installation, the team has seen a significant reduction in the number of complaints regarding a slow wireless network. "We're shooting for about 25 people per wireless access point/antenna. It's not as nice and clean as that, but that's the metric. The actual number may be more or less," said Lawrence.
The issue they've run into is that the spotlight analogy is not quite that "clean" when it comes to radio signals, which tend to "bleed out," he explained. "We can't get them too close together or they will interfere with each other. The more you focus the beam, the more problems associated with it."
Still, after doing a survey of two of its large auditoriums, and some empirical testing, the school has found that it now has better performance on its wireless networks. Rather than hearing complaints that the "network is junk," a typical problem these days is authentication — a much easier problem to resolve.
Going forward, Lawrence has recommendations for other schools considering narrow-beamwidth antennas. "I would say get with your wireless equipment vendor and utilize some of their expertise," he advised.
"That's one of the things we did, because it's not just a matter of installing the antennas. The antennas are only part of the equation. The access point and controller settings are just as important. I would say, do a pilot project like we did, and then monitor the network to see if things improve. You also have to deal with channel management because there are a finite number of channels available, and co-channel interference can severely degrade the network performance."
"As far as budgeting is concerned," he said," you need to be creative and look for funding sources. We've worked with our facilities and campus planning departments to incorporate wireless funding into the construction and renovation budgets. We also partner with the different colleges and schools on campus for funding. In addition, we have a student technology fee." The money from this fee is used for instructional technology.
"We've been installing wireless networking on campus since the late 1990s and this is the first year we've actually had a dedicated wireless budget," said Lawrence. "We don't always get funding, and sometimes, when we do, it's not all we ask for. But we keep at it."
This article originally appeared on GCN’s sister site, Campus Technology.