2020
DOI: 10.1609/icaps.v30i1.6741
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Real Time Crowd Navigation from First Principles of Probability Theory

Abstract: Constructing realistic and real time human-robot interaction models is a core challenge in crowd navigation. In this paper we derive a robot-agent interaction density from first principles of probability theory; we call our approach “first order interacting Gaussian processes” (foIGP). Furthermore, we compute locally optimal solutions—with respect to multi-faceted agent “intent” and “flexibility”—in near real time on a laptop CPU. We test on challenging scenarios from the ETH crowd dataset and show that the sa… Show more

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Cited by 9 publications
(3 citation statements)
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“…In [6], an individual's intent is modeled as a Gaussian process and CCA is modeled as a joint decision-making process by coupling Gaussian processes through a collision avoidance-based likelihood function. The statistical optimality of coupled Gaussian processes is further investigated in [38], [39]. In [40], a distribution space crowd navigation model is proposed, with agent intent modeled as a distribution of trajectories.…”
Section: Coupled Prediction and Planningmentioning
confidence: 99%
“…In [6], an individual's intent is modeled as a Gaussian process and CCA is modeled as a joint decision-making process by coupling Gaussian processes through a collision avoidance-based likelihood function. The statistical optimality of coupled Gaussian processes is further investigated in [38], [39]. In [40], a distribution space crowd navigation model is proposed, with agent intent modeled as a distribution of trajectories.…”
Section: Coupled Prediction and Planningmentioning
confidence: 99%
“…Mobile service robots offer great societal value, such as transporting personal mobility devices (Segway, USA, Rokuro, Japan), last-mile delivery services (Starship Inc. USA), autonomous cleaning robots (Bluebotics, Switzerland), autonomous wheelchairs (Whill Inc. Japan), telepresence robots and tour-guide robots. Nonetheless, most robots are still limited to navigation in low-density areas, such as pathways or large open areas with the basic safety control system setting the robot to freeze as soon as it perceives a likely contact with pedestrians [1], [2]. Such a reaction would most likely be unexpected by pedestrians and lead to more dangerous collisions with pedestrians stumbling on the robot, a "frozen" robot would become a danger to itself Fig.…”
Section: Introductionmentioning
confidence: 99%
“…As well as, all source code for processing and analyzing interactions II. PROBLEM STATEMENT Obstacle avoidance methods usually consider a bi-state problem with collisions as an absolute negative state which in turn leads to the "freezing robot" problem [1], [2]. Nonetheless, contact might be inescapable when the robot's kinematic and dynamic constraints are below the pedestrians.…”
Section: Introductionmentioning
confidence: 99%