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05-07-2024 | Original Paper

A novel dual-layer cascaded torque control mechanism for the improved drivetrain performance for electric vehicles

Authors: Pritam Bhowmik, Sandip Saha, Soubhik Bagchi, Krishna Sarker, Pravat Kumar Rout, Josep M. Guerrero

Published in: Electrical Engineering | Issue 1/2025

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Abstract

The article introduces a novel dual-layer cascaded torque control mechanism designed to improve the drivetrain performance of electric vehicles (EVs). The mechanism addresses the nonlinearity in the drivetrain, which is often caused by ambiguous mechanical stray losses. By incorporating an auxiliary control layer that dynamically tunes the gain function according to measured nonlinear and uncertain mechanical stray losses, the proposed mechanism ensures a significant improvement in acceleration performance and cruising ability. The performance of the proposed control mechanism is evaluated through simulations and hardware-in-the-loop (HIL) testing, demonstrating its effectiveness in handling uncertain road loads and maintaining stable vehicle dynamics. The article highlights the practicality and potential on-board application of the proposed mechanism in the EV manufacturing industry, offering a promising solution for enhancing EV performance.

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Title: A novel dual-layer cascaded torque control mechanism for the improved drivetrain performance for electric vehicles
Authors: Pritam Bhowmik
Sandip Saha
Soubhik Bagchi
Krishna Sarker
Pravat Kumar Rout
Josep M. Guerrero
Publication date: 05-07-2024
Publisher: Springer Berlin Heidelberg
Published in: Electrical Engineering / Issue 1/2025
Print ISSN: 0948-7921
Electronic ISSN: 1432-0487
DOI: https://doi.org/10.1007/s00202-024-02570-x

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Springer Professional "Business + Economics & Engineering + Technology"

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