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RFID License Plates: A Successful In-Metal RFID Application
University of Bremen researchers explain how a vehicle's license plate can function as an antenna for a passive UHF tag, outperforming smart labels on windshields, as well as on-metal tags.
The first tests were performed in an anechoic chamber and static outdoor environments. Different license plates and RFID inlays were tested and optimized. Using the anechoic chamber, we measured the minimal activation power of each RFID license plate type for various read angles and frequencies. By measuring activation power, we were able to draw conclusions regarding the maximal reading range, and succeeded in improving license plate activation levels by as much as 6 dB.
But there was soon a demand to verify the improvements in realistic scenarios. Various test facilities, such as automotive proving grounds and an airport, have been used to test the solution at multiple driving speeds, antenna heights and traffic scenarios. Up to three vehicles were driven on two lanes in the same direction, only a short distance from each other. Driving speed varied from 10 kilometers per hour (6.2 miles per hour), in order to simulate access control simulations, to a maximum of 250 kilometers per hour (155 miles per hour) and beyond, to prove feasibility—for example, for use on German high-speed highways.
The results with the final, optimized RFID license plate designs were amazing. The reading antennas were mounted at a height of 5 meters. The positioning of the RFID antennas at the bridge spanning across the high-speed test ground required special attention, as the surface of the high-speed circular road-testing track is tilted at an angle of 35 degrees. The RFID license plates achieved 100 percent reading rates at all speeds up to 250 kilometers per hour, through the final test phase in October 2011. Even at the maximum speed of about 260 kilometers per hour (162 miles per hour), the RFID license plate remained readable. Overall, the tests encompassed more than 1,500 kilometers (932 miles) of driving distance.
The test showed quite clearly that read-range improvements in passive UHF RFID applications may still be achieved. Chip, inlay and antenna improvements allow the technology to move beyond prior limitations. Additionally, a metal environment is not necessarily a burden—it may be an opportunity that can be exploited through innovative in-metal designs—as provided, for example, via the innovative license plates created by J.H. Tönnjes E.A.S.T.
Dieter Uckelmann is a manager at the University of Bremen's LogDynamics Lab, which serves as a research center for the use of RFID, sensors and other mobile technologies within logistics. Dennis Brandwein works as a research scientist at the BIBA Institute.
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