Mohamed Elbanhawi scite author profile

Mohamed Elbanhawi

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5Publications

644Citation Statements Received

367Citation Statements Given

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Affiliations

RMIT University, MIT University

Publications

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Sampling-Based Robot Motion Planning: A Review

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2014

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Motion planning is a fundamental research area in robotics. Sampling-based methods offer an efficient solution for what is otherwise a rather challenging dilemma of path planning. Consequently, these methods have been extended further away from basic robot planning into further difficult scenarios and diverse applications. A comprehensive survey of the growing body of work in sampling-based planning is given here. Simulations are executed to evaluate some of the proposed planners and highlight some of the implementation details that are often left unspecified. An emphasis is placed on contemporary research directions in this field. We address planners that tackle current issues in robotics. For instance, real-life kinodynamic planning, optimal planning, replanning in dynamic environments, and planning under uncertainty are discussed. The aim of this paper is to survey the state of the art in motion planning and to assess selected planners, examine implementation details and above all shed a light on the current challenges in motion planning and the promising approaches that will potentially overcome those problems.

In the Passenger Seat: Investigating Ride Comfort Measures in Autonomous Cars

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2015

IEEE Intell. Transport. Syst. Mag.

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Continuous Path Smoothing for Car-Like Robots Using B-Spline Curves

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2015

J Intell Robot Syst

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Receding horizon lateral vehicle control for pure pursuit path tracking

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2016

Journal of Vibration and Control

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The assimilation of path planning and motion control is a crucial capability for autonomous vehicles. Pure pursuit controllers are a prevalent class of path tracking algorithms for front wheel steering cars. Nonetheless, their performance is rather limited to relatively low speeds. In this paper, we propose a model predictive active yaw control implementation of pure pursuit path tracking that accommodates the vehicle’s steady state lateral dynamics to improve tracking performance at high speeds. A comparative numerical analysis was under taken between the proposed strategy and the traditional pure pursuit controller scheme. Tests were conducted for three different paths at iteratively increasing speeds from 1 m/s up to 20 m/s. The traditional pure pursuit controller was incapable of maintaining the vehicle stable at speeds upwards of 5m/s. The results show that implementing receding horizon strategy for pure pursuit tracking improves their performance. The contribution is apparent by preserving a relatively constant controller effort and consequently maintaining vehicle stability for speeds up to 100Km/h in different scenarios. A Matlab implementation of the proposed controller and datasets of the experimental paths are provided to supplement this work.

Randomized Bidirectional B-Spline Parameterization Motion Planning

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2016

IEEE Trans. Intell. Transport. Syst.

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