Sleiman Safaoui scite author profile

Sleiman Safaoui

5Publications

47Citation Statements Received

38Citation Statements Given

How they've been cited

How they cite others

132

Affiliations

The University of Texas at Dallas, Mitsubishi Electric (United States)

Publications

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Robust 3D Distributed Formation Control With Collision Avoidance And Application To Multirotor Aerial Vehicles

Fathian

Safaoui

Summers

et al. 2019

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We present a distributed control strategy for a team of quadrotors to autonomously achieve a desired 3D formation. Our approach is based on local relative position measurements and does not require global position information or inter-vehicle communication. We assume that quadrotors have a common sense of direction, which is chosen as the direction of gravitational force measured by their onboard IMU sensors. However, this assumption is not crucial, and our approach is robust to inaccuracies and effects of acceleration on gravitational measurements. In particular, converge to the desired formation is unaffected if each quadrotor has a velocity vector that projects positively onto the desired velocity vector provided by the formation control strategy. We demonstrate the validity of proposed approach in an experimental setup and show that a team of quadrotors achieve a desired 3D formation.

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Control Design for Risk-Based Signal Temporal Logic Specifications

Safaoui¹,

Lindemann²,

Dimarogonas³

et al. 2020

IEEE Control Syst. Lett.

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Robust Distributed Planar Formation Control for Higher Order Holonomic and Nonholonomic Agents

et al. 2021

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Risk-Averse RRT* Planning with Nonlinear Steering and Tracking Controllers for Nonlinear Robotic Systems Under Uncertainty

Safaoui¹,

Gravell²,

Renganathan³

et al. 2021

Preprint

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We propose a two-phase risk-averse architecture for controlling stochastic nonlinear robotic systems. We present Risk-Averse Nonlinear Steering RRT* (RANS-RRT*) as an RRT* variant that incorporates nonlinear dynamics by solving a nonlinear program (NLP) and accounts for risk by approximating the state distribution and performing a distributionally robust (DR) collision check to promote safe planning. The generated plan is used as a reference for a low-level tracking controller. We demonstrate three controllers: finite horizon linear quadratic regulator (LQR) with linearized dynamics around the reference trajectory, LQR with robustness-promoting multiplicative noise terms, and a nonlinear model predictive control law (NMPC). We demonstrate the effectiveness of our algorithm using unicycle dynamics under heavy-tailed Laplace process noise in a cluttered environment.

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Risk-Averse RRT* Planning with Nonlinear Steering and Tracking Controllers for Nonlinear Robotic Systems Under Uncertainty

Safaoui¹,

Gravell

Renganathan

et al. 2021

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Sleiman Safaoui

Robust 3D Distributed Formation Control With Collision Avoidance And Application To Multirotor Aerial Vehicles

Control Design for Risk-Based Signal Temporal Logic Specifications

Robust Distributed Planar Formation Control for Higher Order Holonomic and Nonholonomic Agents

Risk-Averse RRT* Planning with Nonlinear Steering and Tracking Controllers for Nonlinear Robotic Systems Under Uncertainty

Risk-Averse RRT* Planning with Nonlinear Steering and Tracking Controllers for Nonlinear Robotic Systems Under Uncertainty

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