For Second Year in a Row, Velodyne 3D LiDAR Sensor Enables Embry-Riddle Entry to Take First Place in RoboBoat Competition
Popular VLP-16 LiDAR Puck Guides the Way Toward Second Win in Maritime Event
MORGAN HILL, Calif. November 04, 2015 -- Just ask the RoboBoat team from Embry-Riddle Aeronautical University (http://roboticsassociation.org/), which successfully defended its title as champions in the eighth annual RoboBoat Competition, held this summer in Virginia Beach, Virginia.
Outfitted with Velodynes compact 16-channel 3D VLP-16 LiDAR Puck, the pilot-less Embry-Riddle vessel crossed the finish line ahead of the 15 other teams participating in the event, which was sponsored by the Office of Naval Research (ONR), the Association for Unmanned Vehicle Systems International Foundation (AUVSI) and several industry partners. The VLP-16 from Velodynes LiDAR Division (http://www.velodynelidar.com) is part of a growing family of solutions built around the companys Light Detection and Ranging technology.
A year ago, Embry-Riddle finished first with a boat that incorporated Velodynes 32-channel HDL-32E LiDAR sensor. "Our performance in the RoboBoat competition was made possible for the second year in a row by the amazing Velodyne sensor," said first-year student and team lead Kelsey Klein. "The Velodyne VLP-16 puck is an integral part of our autonomous vessel, and pairing it with our robust identification and classification algorithms gave us the edge to successfully complete the aquatic obstacle course."
Hailing from places as far-flung as Indonesia, Taiwan, and South Korea, teams were evaluated based on the performance and designs of their student-built vessels. The mandatory tasks measured vessel speed, navigation and propulsion. Among the other challenges: automated docking, obstacle avoidance, launch and recovery from a moving boat, return to dock, and acoustic beacon positioning.
"The Embry-Riddle teams success was largely due to Velodynes continued support, this time with the quick turnaround of a VLP-16 unit," said Hitesh Patel, former team member and now a consultant. "Last year, we were the first team to debut the HDL-32E and this year, with Velodynes state-of-the-art sensors, we continue to prove the benefits of Velodyne LIDAR products in today's autonomous technology applications. The team loved the VLP-16 sensors just as much as they did the HDL-32E. Having used the HDL-32E made it easier for the team to integrate the VLP-16 onto the RoboBoat platform."
"Our 3D LiDAR sensors guide autonomous vehicles on land, on the seas and in air, and our hats are off to Embry-Riddle University for retaining its crown," said Wolfgang Juchmann, Director of North America Sales and Product Management, Velodyne LiDAR division. "Were recognized worldwide for developing real-time LiDAR sensors for all kinds of autonomous applications, including 3D mapping and surveillance. With a continuous 360-degree sweep of its environment, the lightweight, extremely affordable VLP-16 is scanning power in a pint-size package - and is ideal for taking on obstacle courses, wherever they may be."
Added Kelly Cooper, program officer, sea warfare and weapons, ship systems and engineering research division, Office of Naval Research, "the [RoboBoat] course provides students with realistic maritime environment missions. The successes and challenges students experience via the competition are good preparation for a future in engineering. From completing a run to making onsite adjustments, RoboBoat offers students a first-hand look at what real-life engineers go through when developing and testing navy technologies for our sailors and Marines."
About Embry-Riddle Aeronautical University
Embry-Riddle Aeronautical University, the worlds largest, fully accredited university specializing in aviation and aerospace, is a nonprofit, independent institution offering more than 70 baccalaureate, masters and Ph.D. degree programs in its colleges of Arts & Sciences, Aviation, Business, Engineering and Security & Intelligence. Embry-Riddle educates students at residential campuses in Daytona Beach, Fla., and Prescott, Ariz., through the Worldwide Campus with more than 150 locations in the United States, Europe, Asia and the Middle East, and through online programs. The university is a major research center, seeking solutions to real-world problems in partnership with the aerospace industry, other universities and government agencies. For more information, visit http://www.embryriddle.edu.
About Velodyne LiDAR
Founded in 1983 and based in Californias Silicon Valley, Velodyne Acoustics, Inc. is a diversified technology company known worldwide for its high-performance audio equipment and real-time LiDAR sensors. The companys LiDAR division evolved after founder/inventor David Hall competed in the 2004-05 DARPA Grand Challenge using stereovision technology. Based on his experience during this challenge, Hall recognized the limitations of stereovision and developed the HDL-64 high-resolution LiDAR sensor. Velodyne subsequently released its compact, lightweight HDL 32E sensor, available for many applications including UAVs, and the new VLP-16 LiDAR Puck, a 16-channel real-time LiDAR sensor that is both substantially smaller and dramatically less expensive than previous generation sensors. Market research firm Frost & Sullivan has honored the company and the VLP-16 with its 2015 North American Automotive ADAS (Advanced Driver Assistance System) Sensors Product Leadership Award. Since 2007, Velodynes LiDAR division has emerged as the leading developer, manufacturer and supplier of real-time LiDAR sensor technology used in a variety of commercial applications including autonomous vehicles, vehicle safety systems, 3D mobile mapping, 3D aerial mapping and security. For more information, visit http://www.velodynelidar.com.
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