Path Planning for Autonomous Vehicle Control in Analogy to Supersonic Compressible Fluid Flow—An Obstacle Avoidance Scenario in Vehicular Traffic Flow

There have been many attempts to model the flow of vehicular traffic in analogy to the flow of fluids. Given the evident change in distance between vehicles driving in platoons, the compressibility of traffic flow is inferred and, considering the reaction time-scales of the driver (human or autonomous), it is argued that this compressibility is increased as relative velocities increase—giving the lag in imposed redirection by the driver and the controller units a higher relative importance. Therefore, a supersonic compressible flow field has been opted for as the most analogous base flow. On this point, added to by the overall extreme similarities of the two above-mentioned flows, the non-dimensional group of the traffic Mach number MT has been defined in the present research, providing the possibility of calculating a suggested flow field and its corresponding shockwave systems, for any given obstacle ahead of the traffic flow. This suggested flow field is then taken as the basis to obtain trajectories designed for avoiding collision with the obstacle, and in compliance with the physics of the underlying analogous fluid flow phenomena, namely the internal supersonic compressible flow around a double wedge. It should be noted that herein we do not model the traffic flow but propose these trajectories for more optimal collision avoidance, and therefore the above-mentioned similarities (explained in detail in the manuscript) suffice, without the need to rely on full analogies between the two flows. The manuscript further analyzes the applicability of the proposed analogy in the path-planning process for an autonomous passenger vehicle, through dynamics and control of a full-planar vehicle model with an autonomous path-tracking controller. Simulations are performed using realistic vehicle parameters and the results show that the fluid flow analogy is compatible with the vehicle dynamics, as it is able to follow the target path generated by fluid flow calculations with minor deviations. Simulation results demonstrate that the proposed method produces smooth and dynamically consistent trajectories that remain stable under varying traffic scenarios. The controller achieves accurate path tracking and rapid convergence, confirming the feasibility of the fluid-flow analogy for real-time vehicle control.

• Publication year

  2025

• Venue

  Future Transportation

• Publication date

  2025-11-10

• Fields of study

  Not labeled

• Identifiers
  DOI 10.3390/futuretransp5040173
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar

• No claims are published for this paper.

• No concepts are published for this paper.

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  2009cited by this paper
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  2008cited by this paper
• On the mathematical theory of vehicular traffic flow II: Discrete velocity kinetic models

  2007cited by this paper
• A comprehensive vehicle braking model for predictions of stopping distances

  2004influential reference
• Driver memory, traffic viscosity and a viscous vehicular traffic flow model

  2003cited by this paper
• Stochastic modelling of traffic flow

  2002cited by this paper
• Modeling self-consistent multi-class dynamic traffic flow

  2002cited by this paper
• From the modelling of driver's behavior to hydrodynamic models and problems of traffic flow

  2002cited by this paper
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  2001cited by this paper
• Robust Scalable Vehicle Control via Non-Dimensional Vehicle Dynamics

  2001influential reference
• Brake reaction times and driver behavior analysis

  2000cited by this paper
• Self-Organization in Four-Direction Traffic-Flow Model

  2000cited by this paper
• Nonlinear hydrodynamic models of traffic flow modelling and mathematical problems

  1999cited by this paper
• Numerical simulations for traffic-flow models on a decorated square lattice

  1998cited by this paper
• One-Dimensional Fukui-Ishibashi Traffic Flow Model

  1997cited by this paper
• Self-organized criticality in 1D traffic flow model with inflow or outflow

  1995cited by this paper
• Dynamical model of traffic congestion and numerical simulation.

  1995cited by this paper
• Modelling of Driver/Vehicle Directional Control System

  1993cited by this paper
• Applied Nonlinear Control

  1991cited by this paper
• Introduction to the Theory of Traffic Flow

  1987cited by this paper
• Theory and Applications of Cellular Automata

  1986cited by this paper
• Tire and Vehicle Dynamics

  1982cited by this paper
• MODELS OF FREEWAY TRAFFIC AND CONTROL.

  1971cited by this paper
• Shock Waves on the Highway

  1956cited by this paper
• On kinematic waves II. A theory of traffic flow on long crowded roads

  1955influential reference

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