Testing Solution Simulates Actual Road Conditions in a Lab for Vehicle Radar Tests

Sensors in autonomous vehicles have to be extremely reliable and are thus subjected to arduous road tests, making the whole process cumbersome. The Fraunhofer Institute for High Frequency Physics and Radar Techniques FHR has thus developed a new testing device which will help move a large portion of these road tests to the laboratory. The new device, called ATRIUM, puts on a show for the vehicle’s radar sensor, generating artificial scenery that comes very close to the actual conditions encountered while drivin down a street.

Cars of the future will be driverless. Passengers will sit in the back seat of the car as if they are being driven by a private chauffeur while enjoying a conversation, reading the newspaper or perhaps watching a video. Although driver assistance systems such as automatic distance control are no longer new to the market, we are still a few years away from cars being completely autonomous.

When it comes to autonomous vehicles, one thing we can not compromise on is the safety and accuracy of the sensors. The sensors are the deciding factor here: for example, today’s radar sensors are already capable of independently detecting obstacles and applying the brakes in case of danger. These and other sensors are rigorously tested before being installed in the car. And autonomous vehicles require an even higher level of reliability, since if the driver is no longer at the wheel, the vehicle manufacturer may well be ultimately responsible for avoiding an accident.

That is why automobile manufacturers have relatively high demands when it comes to sensor reliability. They demand sensors that cause no more than a single error over driving distances of several million kilometers, which means that today’s cars often have to complete very long tests. This, according to Dr. Ing Thomas Dallmann, the Leader of Research Group Aachen at the Fraunhofer Institute for High Frequency Physics and Radar Techniques FHR, is a lot of kilometers on the road. On top of that, multiple sensors have to be tested in order to statistically prove their reliability. This means several test vehicles with sensors have to spend quite a long time on the road. Another difficulty is if an error occurs after several thousand kilometers, the sensor has to be optimized and the road tests have to begin all over again, an extremely time-consuming process.

To simplify the situation, attempts are being made to simulate reality and bring the road tests into the laboratory. This type of laboratory test already exists for radar sensors. Radar sensors emit a radio signal that is reflected by various objects. Based on the echo, electronic sensor systems can then analyze the surroundings, measuring the distance to detected objects and the speed at which they are moving.

This principle has already been simulated in the laboratory using what is referred to as radar target simulators. These simulators collect the radar waves emitted by the vehicle radar and modify the radar signal to behave as if it had encountered objects. The simulator then returns the information to the car in the form of an artificial echo image. Thus the radar target simulator generates a simulated landscape for the vehicle’s radar. The advantage is obvious: The test rig with a car radar and radar target simulator can run in the laboratory day and night, without having to put a car onto the street.

Unfortunately, the few radar target simulators available on the market today are nowhere close to being able to generate a complete echo landscape. Most of the models can only generate a highly restricted image with a single-digit number of reflections returned to the car’s radar, says Dallmann. That’s an extremely small number compared to the situation in a natural environment. After all, real scenery contains hundreds of reflecting objects: people, cars, trees, traffic signals. Even a single vehicle in traffic can generate various reflections from different angles, for example a passenger car whose bumpers, wheels and side-view mirrors reflect differently. Dallmann’s team is still very far removed from a realistic setting when it comes to testing sensors for autonomous driving.

That is why he and his team are developing the new, higher-performance radar target simulator, ATRIUM (the German acronym for “Automotive test environment for radar in-the-loop testing and measurements”), capable of generating significantly more reflecting objects. The current goal of the Fraunhofer FHR is to be able to generate 300 reflections by the time the project ends, a tremendous objective. This will mean that ATRIUM can present the car’s radar sensor with a relatively true-to-life scene, something like a drive-in movie for the radar sensor.

Since a patent application has been filed for the ATRIUM technology, Thomas Dallmann cannot yet reveal any details. But he says that they have optimized the structure of the transmission channels, making them much more cost-effective. As a result, the reflections can be represented in such a way that they reach the radar from a number of different directions. This could make it possible to test new sensors for autonomous vehicles in full scope and under highly realistic conditions in the lab. In the future, they’ll be able to run highly complex tests, which will make it possible to greatly reduce the time involved in road tests. Dallmann and his colleagues will present the laboratory test facility with vehicle radar and the ATRIUM radar target simulator at the Automotive Testing Expo in Stuttgart from May 21 to 23.