Experimental Evaluation of a Pseudo-Doppler Direction-Finding System for Localizing Radio Tags
This work addresses the challenge of efficient and rapid radio-tagged wildlife localization for robotics and UAS applications, though it is incremental as it builds on existing pseudo-Doppler principles and open-source components.
The paper tackles the problem of slow and energy-consuming wildlife tracking with directional antennas by designing a low-cost pseudo-Doppler antenna array system for instantaneous bearing measurements, achieving localization of radio tags within 5 meter accuracy from an initial 200m x 200m estimate in outdoor tests.
We present the design of a radio antenna system for obtaining instantaneous bearing measurements towards a radio emitter. Our work is motivated by applications where robots are used for localizing and tracking radio-tagged wildlife. The traditional method is to use directional antennas that need to be rotated in order find the bearing which is time consuming. Instead, we present a low-cost system capable of finding bearing measurements almost instantaneously using an antenna array. This is particularly appealing for wildlife tracking with Unmanned Aerial Systems (UASs) where remaining stationary can be challenging and energy consuming, in addition to being slow. The proposed system uses existing open source hardware and software systems and leverages principles of pseudo Doppler direction-finding. The resulting system was tested in an anechoic chamber and in outdoor settings. The outdoor tests with particle filtering show that the resulting system is capable of localizing radio tags within 5 meter accuracy starting with an initial estimate of 200m x 200m.