Towards Mechatronics Approach of System Design, Verification and Validation for Autonomous Vehicles (2301.13425v2)

Abstract: Modern-day autonomous vehicles are increasingly becoming complex multidisciplinary systems composed of mechanical, electrical, electronic, computing and information sub-systems. Furthermore, the individual constituent technologies employed for developing autonomous vehicles have started maturing up to a point, where it seems beneficial to start looking at the synergistic integration of these components into sub-systems, systems, and potentially, system-of-systems. Hence, this work applies the principles of mechatronics approach of system design, verification and validation for the development of autonomous vehicles. Particularly, we discuss leveraging multidisciplinary co-design practices along with virtual, hybrid and physical prototyping and testing within a concurrent engineering framework to develop and validate a scaled autonomous vehicle using the AutoDRIVE ecosystem. We also describe a case-study of autonomous parking application using a modular probabilistic framework to illustrate the benefits of the proposed approach.

• The paper introduces a concurrent engineering framework that unifies mechanical, electrical, and software subsystems for autonomous vehicle design.
• The study emphasizes a multiphase testing strategy with virtual, hybrid, and physical prototypes to detect design issues early and validate performance.
• The paper leverages the AutoDRIVE Ecosystem for modular and flexible reconfigurability, enabling tailored integration of sensors, actuators, and computing systems.

The Mechatronics Approach to Autonomous Vehicle System Development

The paper entitled "Towards Mechatronics Approach of System Design, Verification and Validation for Autonomous Vehicles" presents a cohesive framework for the development, verification, and validation of autonomous vehicles through a mechatronics lens. The authors highlight the intricacies involved in the convergence of multidisciplinary systems—comprising mechanical, electrical, electronic, and software components—in modern autonomous vehicle design. The mechatronics approach posits a synergistic integration of these diverse subsystems, advocating for a concurrent engineering framework that bridges the gap between academia and industry practices.

System Design and Integration

The work outlines the use of a modified V-model to guide the system design, verification, and validation processes. This model embraces mechatronics principles by promoting a concurrent and interdisciplinary methodology that efficiently incorporates mechanical, electronic, and computational elements. The concurrent engineering thinking not only marries hardware and software co-design but also leverages virtual, hybrid, and physical prototyping techniques to foster efficient system testing and integration.

The vehicle design is facilitated through the AutoDRIVE Ecosystem, an open-source and reconfigurable platform that supports modular design and experimentation. This ecosystem provides two levels of design reconfigurability: primitive and advanced. Primitive reconfigurability includes the modular arrangement of sensors, actuators, communication, and computation systems, allowing for flexibility in component selection to suit application needs. Advanced reconfigurability, on the other hand, offers comprehensive architectural adjustments, enabling modifications of physical and software configurations.

Verification and Validation Paradigms

Verification and validation are achieved through a multiphase testing approach, encompassing virtual, hybrid, and physical environments. Initial phases involve virtual prototypes that are created and validated against the defined system specifications using AutoDRIVE Simulator. This step ensures early detection of design issues before costly physical prototyping. Hybrid testing bridges virtual and real-world gaps by employing processor-in-the-loop (PIL), hardware-in-the-loop (HIL), and vehicle-in-the-loop (VIL) testing methodologies, validating embedded system performances within a controlled simulation environment that incorporates real-world feedback.

In the concluding stage, physical prototypes are rigorously tested in realistic settings within the AutoDRIVE Testbed. These comprehensive tests validate individual system components and the integrated system, emphasizing the robustness and reliability of the vehicle's autonomy stack, particularly in scenarios like autonomous parking, under varied environmental conditions.

Practical and Theoretical Implications

The mechatronics-based approach outlined in this paper significantly impacts both academic and industrial spheres by promoting a structured framework that enhances the development process's efficiency and the final product's reliability. Practical implications include reduced development cycles, minimized resource wastage through early-stage error detection, and improved adaptability of the system design.

Theoretically, this work provides a scaffold for future research into co-design and concurrent engineering processes, suggesting a path towards standardizing verification and validation methods across the multidisciplinary spectrum of autonomous vehicle systems. Moreover, the proposition of qualitative and quantitative metrics facilitates more rigorous comparisons between mechatronic approaches and other methodologies, presenting opportunities for future studies to explore these propositions in depth.

Overall, the integration of mechatronics principles into the autonomous vehicle development cycle enhances systematic design coherence and optimizes integration processes, laying the groundwork for future evolutions in this dynamic field.