Particle filter‐based aerial tracking for moving targets

Yılmaz, M. Koray; Bayram, Haluk

doi:10.1002/rob.22134

Cited by 5 publications

(1 citation statement)

References 32 publications

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“…Because of the advantages offered by the ease of deployment and high mobility , UAVs have the potential to automate and scale up manual tasks to significantly reduce the time, labor, and cost of employing traditional tracking approaches. Early achievements in autonomous systems for wildlife tracking have demonstrated robotic platforms for the task (Cliff et al, 2018; Nguyen, Chesser, et al, 2019; Tokekar et al, 2010; Vander Hook et al, 2014; Yılmaz & Bayram, 2023). The approaches localize VHF radio‐tagged animals using either the Receiver Signal Strength Indicator (RSSI) or Angle of Arrival (AoA) of radio signals emitted from radio tags where the robot's trajectory‐planning algorithm endows autonomy to improve the localization accuracy—(Cliff et al, 2015, 2018) or reduce the tracking error— (Nguyen, Chesser, et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

ConservationBots: Autonomous aerial robot for fast robust wildlife tracking in complex terrains

Chen,

Nguyen,

Taggart

et al. 2023

Journal of Field Robotics

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Radio tagging and tracking are fundamental to understanding the movements and habitats of wildlife in their natural environments. Today, the most widespread, widely applicable technology for gathering data relies on experienced scientists armed with handheld radio‐telemetry equipment to locate low‐power radio transmitters attached to wildlife from the ground. Although aerial robots can transform labor‐intensive conservation tasks, the realization of autonomous systems for tackling task complexities under real‐world conditions remains a challenge. We developed ConservationBots—small aerial robots for tracking multiple, dynamic, radio‐tagged wildlife. The aerial robot achieves robust localization performance and fast task completion times—significant for energy‐limited aerial systems while avoiding close encounters with potential, counterproductive disturbances to wildlife. Our approach overcomes the technical and practical problems posed by combining a lightweight sensor with new concepts: (i) planning to determine both trajectory and measurement actions guided by an information‐theoretic objective, which allows the robot to strategically select near‐instantaneous range‐only measurements to achieve faster localization, and time‐consuming sensor rotation actions to acquire bearing measurements and achieve robust tracking performance; (ii) a bearing detector more robust to noise; and (iii) a tracking algorithm formulation robust to missed and false detections experienced in real‐world conditions. We conducted extensive studies: simulations built upon complex signal propagation over high‐resolution elevation data on diverse geographical terrains; field testing; studies with wombats (Lasiorhinus latifrons; nocturnal, vulnerable species dwelling in underground warrens) and tracking comparisons with a highly experienced biologist to validate the effectiveness of our aerial robot and demonstrate the significant advantages over the manual method.

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