On Infusing Reachability-Based Safety Assurance Within Probabilistic Planning Frameworks for Human-Robot Vehicle Interactions

Leung, Karen; Szczerbicki, Edward; Chen, Mo; Gerdes, J. Christian; Pavone, Marco

doi:10.1007/978-3-030-33950-0_48

Cited by 18 publications

(18 citation statements)

References 17 publications

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“…One of the most difficult issues in this scenario is handling vehicles that maneuver from the inner ring of the roundabout to the outer ring, which is the ring used by the AD vehicle in our method. In practice, it is very challenging to predict a lane change maneuver, especially when vehicles attempt to make a lane change with nudging [21]. In [25] we proposed three different strategies for handling the navigation of multiple vehicles inside a two-lane roundabout.…”

Section: B Lane Change and Nudging Behaviorsmentioning

confidence: 99%

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Roundabout Crossing With Interval Occupancy and Virtual Instances of Road Users

Masi

2022

IEEE Trans. Intell. Transport. Syst.

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Although autonomous vehicle technology has evolved significantly in recent years, the navigation of self-driving vehicles in complex scenarios is still an open issue. One of the major challenges in these conditions is safe navigation on roads open to public traffic. The main issue is the interaction of the autonomous vehicle with regular traffic, as the behaviors and intentions of human-driven vehicles are hard to predict and understand. In this paper we propose a strategy to allow an autonomous vehicle to safely cross a multi-lane roundabout. Our approach uses a High-Definition (HD) map to predict at lane level the future situation, harnessing the concept of virtual instances of road users, which is a key concept in anticipating the situation in a roundabout that can be represented by a navigation graph with loops. This paper presents a methodology that uses intervals representing road occupancy by vehicles, with the road being widened to reflect uncertainties in localization. Our method safely avoids collisions and guarantees that no priority constraints are violated during the insertion maneuver. Moreover, the method does not provide an overly cautious insertion policy, i.e., an autonomous vehicle does not wait for a long time before the insertion. The performance of our strategy was evaluated using the SUMO simulation framework. To better evaluate the complexity of the simulation scenario, a highly interactive vehicle flow was generated using real dynamic traffic data from the INTERACTION dataset. We report real tests carried out with an experimental self-driving vehicle on a test circuit. Our results show that this approach is easy to integrate into an embedded system and that it allows roundabouts to be crossed with a high level of safety.

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Section: B Lane Change and Nudging Behaviorsmentioning

confidence: 99%

“…In a mixed traffic environment with AD and MD vehicles (in this paper an MD vehicle can be a car or any road user in the drivable space), avoidance sets can be computed with reachability theory [11], [21], [39]. The authors in [28], [29] implemented a collaborative motion planning algorithm that cooperates with MD vehicles.…”

Section: Introductionmentioning

confidence: 99%

Roundabout Crossing With Interval Occupancy and Virtual Instances of Road Users

Masi

2022

IEEE Trans. Intell. Transport. Syst.

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“…The semi-autonomous vehicle paradigm is distinct from the concept of a fully autonomous self-driving cars as the autonomy's goal is not to take full control of the vehicle, but instead to act as a guardian or intelligent co-pilot [4], intervening on the person's control when deemed necessary to ensure safety. For this reason, there is a growing line of work that follows the minimum intervention principle in the semi-autonomous vehicle domain [25]. For example, Schwarting et al [28,29] describe a parallel autonomy framework that develops control trajectories for semi-autonomous vehicles that minimize deviation from userinput and achieve task-specific metrics like road following and contour tracking.…”

Section: A Shared Controlmentioning

confidence: 99%

“…return u r 6: end procedure result" [3,25,28]. By developing a shared control algorithm that adheres to the MIP we maximize the influence of the human partner's control at each given moment.…”

Section: B Minimum Intervention Principlementioning

confidence: 99%

“…The majority of related work requires hand-written (and potentially complex) models of the system and control dynamics [3,25,28]. In this work, we instead use a representation that is simple (i.e., linear) regardless of the underlying dynamics and can be learned from data when the model is not known a priori.…”

Section: A Model Representation and Data-driven Approximationsmentioning

confidence: 99%

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Highly Parallelized Data-Driven MPC for Minimal Intervention Shared Control

Broad¹,

Murphey²,

Argall³

2019

Robotics: Science and Systems XV

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We present a shared control paradigm that improves a user's ability to operate complex, dynamic systems in potentially dangerous environments without a priori knowledge of the user's objective. In this paradigm, the role of the autonomous partner is to improve the general safety of the system without constraining the user's ability to achieve unspecified behaviors. Our approach relies on a data-driven, model-based representation of the joint human-machine system to evaluate, in parallel, a significant number of potential inputs that the user may wish to provide. These samples are used to (1) predict the safety of the system over a receding horizon, and (2) minimize the influence of the autonomous partner. The resulting shared control algorithm maximizes the authority allocated to the human partner to improve their sense of agency, while improving safety. We evaluate the efficacy of our shared control algorithm with a human subjects study (n=20) conducted in two simulated environments: a balance bot and a race car. During the experiment, users are free to operate each system however they would like (i.e., there is no specified task) and are only asked to try to avoid unsafe regions of the state space. Using modern computational resources (i.e., GPUs) our approach is able to consider more than 10,000 potential trajectories at each time step in a control loop running at 100Hz for the balance bot and 60Hz for the race car. The results of the study show that our shared control paradigm improves system safety without knowledge of the user's goal, while maintaining high-levels of user satisfaction and low-levels of frustration. Our code is available online at https://github.com/asbroad/mpmi shared control.

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Game-theoretic multi-agent motion planning in a mixed environment

Zhang,

Xie

2024

Control Theory Technol.

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On Infusing Reachability-Based Safety Assurance Within Probabilistic Planning Frameworks for Human-Robot Vehicle Interactions

Cited by 18 publications

References 17 publications

Roundabout Crossing With Interval Occupancy and Virtual Instances of Road Users

Roundabout Crossing With Interval Occupancy and Virtual Instances of Road Users

Highly Parallelized Data-Driven MPC for Minimal Intervention Shared Control

Game-theoretic multi-agent motion planning in a mixed environment

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