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International Journal of Next-Generation Engineering and Technology

Open Access Peer Review International
Open Access

Advanced Paradigms In 10G Automotive Ethernet: Integrating Hyperlynx-Validated Electromagnetic Shielding, Sustainable Printed Electronics, And Adaptive Control for Next-Generation ADAS Architectures

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Dr. Theresa Vance 1 ,
4 Department of Electrical Engineering and Information Technology, Munich University of Applied Sciences, Germany

Abstract

The rapid evolution of Advanced Driver Assistance Systems (ADAS) has necessitated a transition from traditional Controller Area Network (CAN) protocols to high-bandwidth 10G Automotive Ethernet. This architectural shift introduces profound challenges regarding electromagnetic interference (EMI), signal integrity, and the physical sustainability of electronic components. This comprehensive research article investigates the integration of high-speed networking with emerging materials science and adaptive control systems. We explore the application of HyperLynx-validated shielding techniques specifically designed for camera Printed Circuit Board (PCB) modules within automotive lighting control systems to mitigate broadband noise. Furthermore, the study evaluates the transition toward sustainable printed electronics, utilizing silver nanowire inks and single-crystal copper conductors to enhance electrical performance while reducing environmental impact. A significant portion of the analysis is dedicated to adaptive extremum-seeking receding horizon control to manage the nonlinear dynamics of automotive sub-systems. By synthesizing wide modulated bandwidth MIMO receivers with interference cancellation techniques, this paper provides a holistic framework for the resilient vehicular networks of the future. The results indicate that the strategic implementation of additive manufacturing for mm-wave antennas and active EMI filtering significantly enhances the reliability of 10 Gbps data links under harsh automotive conditions.

Keywords

Automotive Ethernet, ADAS, Electromagnetic Interference, Printed Electronics

References

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