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Machine learning model outperforms physics-based simulation for hydraulic clutch control

This paper introduces a data-driven method for modeling hydraulic clutch control pressure, addressing nonlinear behaviors like hysteresis and latch transitions. By incorporating current derivative information and using a nonlinear Support Vector Classifier (SVC) to separate operating regimes, the researchers developed a Gaussian Process regression model. This machine-learning approach demonstrated superior accuracy in reproducing measured pressure responses and hysteresis compared to a physics-based Amesim model, suggesting its utility in hardware development and controller calibration. AI

IMPACT This research demonstrates the potential of machine learning models to complement traditional physics-based simulations in complex engineering systems, potentially speeding up development and calibration processes.

RANK_REASON Academic paper detailing a new modeling approach. [lever_c_demoted from research: ic=1 ai=0.7]

Read on arXiv cs.LG →

AI-generated summary · Google Gemini · from 1 sources. How we write summaries →

Machine learning model outperforms physics-based simulation for hydraulic clutch control

COVERAGE [1]

  1. arXiv cs.LG TIER_1 English(EN) · Yash Bagla, Jason Schneider ·

    Fast Data-Driven Modeling of Hydraulic Clutch Control Pressure with Latch-State Classification and Gaussian Process Regression

    arXiv:2607.10477v1 Announce Type: cross Abstract: This paper presents a data-driven method for modeling the pressure response of a hydraulic clutch control circuit. The system consists of a variable-force solenoid, accumulator, pressure regulator valve, and latch valve, and exhib…