Echodyne Radars Anchor DARPA’s Urban Drone Testing

Active radars on aerostats and at multiple fixed sites provide real-time airspace situational awareness

Echodyne, the manufacturer of innovative, high-performance radars for government and commercial markets, announced today that its radars were key active sensors deployed by the Defense Advanced Research Projects Agency (DARPA) for its Aerial Dragnet program in San Diego during the week of October 21, 2019. In conjunction with the Applied Physics Laboratory at the University of Washington (APL-UW), Echodyne's EchoGuard and EchoFlight radars provided comprehensive surveillance of drone activity in San Diego's urban airspace.


The DARPA testing involved radar sensors on two large tethered aerostat balloons flying at up to 400 feet above ground level (AGL) over San Diego and National City, as well as fixed building-top and tower mounted locations providing large-area coverage. The sensors were tuned to detect and track small drones and distinguish them from background objects such as buildings, vehicles, and birds. The testing assessed how well the system could detect, track and identify over 150 sorties of drones including various commercial off-the-shelf models, similar to those available at electronics stores or online retailers, which simulated unauthorized / unidentified drones flying in the city.

Drone sales into the consumer and commercial segments will result in nearly 2 million unmanned aerial vehicles (UAVs) in the US in 2020, and the global market is expected to grow at a compound annual growth rate of 20.5% to reach nearly $43 billion in 2024, per the FAA Aerospace Forecast and a separate industry report, Drone Analytics - Market Analysis, Trends, and Forecasts. With this volume of drones in the airspace, dense urban areas will need to evolve from point security deployments to full urban airspace situational awareness.

San Diego was a natural choice to test this system given the city's participation in the FAA's Unmanned Aircraft System Integration Pilot Program (IPP). While DARPA's focus is on protecting U.S. troops from drone attacks in urban settings overseas, the system under development could ultimately help protect U.S. metropolitan areas from potential drone-enabled terrorist threats.

"The DARPA requirement to create full urban airspace situational awareness has been challenging yet rewarding," said Tom Driscoll, CTO of Echodyne. "In conjunction with APL-UW, we operated more than a dozen radars on aerostats and rooftops to detect and track urban drone flights. Our performance demonstrated that Echodyne's innovative, beam-steering, electronically scanning radars have unique operational, sensitivity, and intelligence characteristics necessary to conduct networked airspace surveillance over a major US city like San Diego."

To learn more about how Echodyne is reinventing radars, contact info@echodyne.com or visit www.echodyne.com.

About Echodyne

Echodyne introduces the world's first compact, software-defined, solid-state, true electronically scanned array (ESA) radar sensor. Ideally suited for machine perception in an autonomous age, Echodyne offers high-performance commercially priced radars to governments, industries, and integrators engineering solutions for border security, critical infrastructure protection, first responders, unmanned aircraft systems, and autonomous vehicles. Privately held, the company is based in Kirkland, Washington, and is backed by Bill Gates, NEA, Madrona Venture Group, Vulcan Capital, and Lux Capital among others. For more information, please visit: Echodyne.com

Featured Product

FAULHABER MICROMO - Game changer in logistics

FAULHABER MICROMO - Game changer in logistics

Faster, more efficient, more sustainable - due to global competition in industry combined with booming online trade, transport structures in intralogistics are facing new challenges. The industries' answer: Automation. From storage to shipping, key work steps are being taken over by intelligent logistics robots, such as automatic storage and retrieval machines and driverless transport systems. To work efficiently and reliably around the clock, these robots need flexible and particularly compact drive solutions.