Abstract
Pulse-echo sensing is the driving principle behind biological echolocation as well as biologically-inspired sonar and radar sensors. In biological echolocation, a single emitter sends a self-generated pulse into the environment which reflects off objects. A fraction of these reflections are captured by two receivers as echoes, from which information about the objects, such as their position in 3D space, can be deduced by means of timing, intensity and spectral analysis. This is opposed to frequency-modulated continuous-wave radar, which analyses the shift in frequency of the returning signal to determine distance, and requires an array of antenna to obtain directional information. In this work, we present a novel simulator which can generate synthetic pulse-echo measurements for a simulated sensor in a virtual environment. The simulation is implemented by replicating the relevant physical processes underlying the pulse-echo sensing modality, while achieving high performance at update rates above 50 . The system is built to perform design space exploration of sensor hardware and software, with the goals of rapid prototyping and preliminary safety testing in mind. We demonstrate the validity of the simulator by replicating real-world experiments from previous work. In the first case, a subsumption architecture vehicle controller is set to navigate an unknown environment using the virtual sensor. We see the same trajectory pattern emerge in the simulated environment rebuilt from the real experiment, as well as similar activation times for the high-priority behaviors (±1.9%), and low-priority behaviors (±0.2%). In a second experiment, the simulated signals are used as input to a biologically-inspired direct simultaneous mapping and localization (SLAM) algorithm. Using only path integration, 83% of the positional errors are larger than 10 , while for the SLAM algorithm 95% of the errors are smaller than . Additionally, we perform design space exploration using the simulator. By creating a synthetic radiation pattern with increased spatiospectral variance, we are able to reduce the average localization error of the system by 11%. From these results, we conclude that the simulation is sufficiently accurate to be of use in developing vehicle controllers and SLAM algorithms for pulse-echo radar sensors.
Highlights
Echolocation is a sensing method used by some species of bats and dolphins to navigate their surroundings, detect obstacles, and classify prey [1]
It shows that the behavioral control algorithm using the simulated radar in a virtual environment produces stables paths, similar to the real-world experiments conducted in previous work
We presented a novel simulator for echolocation using pulse-echo radar
Summary
Echolocation is a sensing method used by some species of bats and dolphins to navigate their surroundings, detect obstacles, and classify prey [1]. They accomplish this through biological sonar; they emit ultrasonic signals from their vocals tract, which reflects off objects in the environment and are received as echoes by their ears. From these echoes, they can determine the location of the reflector, as well as other properties such as size, velocity and even texture [2,3]. As no single sensor is able to provide reliable sensing under all circumstances, systems need to be equipped with multiple sensors that complement each other in various scenarios [6]
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