Events in early 2010 at Newark Liberty International Airport demonstrate the vulnerability of civil GPS infrastructure to interference. Over a period of several weeks, sporadic outages of the GPS Ground Based Augmentation System (GBAS) located at the airport to provide precision approach services occurred, due to radio-frequency (RF) interference from unknown sources. Analysis showed that certain vehicles on a nearby freeway were the likely culprit(s), and an interdiction effort was launched to catch an offender. Using advanced interference detection equipment and multiple surveillance cameras, an offender — a truck driver — was caught and arrested. In his possession: a widely available $33 GPS jammer.

For sale over the Internet, the jammer emits 200 mW and plugs directly into a vehicle’s cigarette lighter (see photo). To prevent future incidents, the FAA is relocating the airport’s GBAS system to a more protected location away from the freeway.

Such an approach to jammer detection, localization, and enforcement, while successful in this instance, ultimately serves only as a stopgap. It took tremendous resources and several weeks to find one offender.

Increasing use of GPS jamming and spoofing to cover both licit and illicit activities is likely, given the general public’s desire for privacy and the general lack of awareness of how devastating GPS jamming can be. The $33 jammer in this instance could have affected critical flight operations 10 miles away. Currently, most jammers are not even detected; we simply have an unidentified GPS outage. It was only because of the technical sophistication of the FAA’s GBAS that the outage’s underlying cause was identified as jamming.

GPS Jammer. A $33, 200mW jammer for sale over the Internet.

At the ION-GNSS 2010 plenary session, Phil Ward advanced the notion that cell phones could incorporate GPS jam-to-noise (J/N) ratio detectors to provide timely interference detection. Having an extensive background in cellular communications as well as GPS, I found the idea intriguing. In this article, I explore the viability of this concept, whether jammer location can be determined, and what it would take to implement such a system.

In urban and suburban areas, it appears feasible to provide warning of jamming in less than 10 seconds while providing real-time jammer location to better than 40 meters. Such a capability would aid immensely in mitigating jamming events by enabling effective law-enforcement action. Potential jammers will know they are likely to be caught and that the penalties are severe. They won’t do it after a few well publicized interdictions. The cost for this nationwide system can be relatively modest. It won’t take billions of dollars and decades to implement; it will take an act of national will similar to the phase II wireless E911 effort. IOC could happen as early as 2015, with full national coverage by 2017.