Load-Aware Calibration of EMG-Driven Musculoskeletal Models for Accurate and Generalizable Joint Torque Estimation

TL;DR

This study presents a load-aware calibration framework for EMG-driven musculoskeletal models, enhancing joint torque prediction accuracy and generalizability across different mechanical loads and tasks.

Contribution

It introduces a load-specific calibration approach combined with advanced optimization methods, improving model robustness and physiological plausibility across varying loads.

Findings

Load-specific calibration reduces RMSE and increases correlation ($r > 0.75$).

PSO-based optimization yields more consistent estimates than simulated annealing.

Parameters related to muscle force and activation are highly load-sensitive.

Abstract

Accurate EMG-driven musculoskeletal (MSK) modeling is critical for biomechanics, rehabilitation, and assistive technology. However, most models calibrate parameters under a single load, ignoring the fact that tasks with similar kinematics may differ in mechanical demand. This study introduces a load-aware calibration framework to improve joint torque prediction accuracy and generalizability. Surface EMG and joint kinematics were recorded from eleven participants during elbow flexion-extension under 0, 2, and 4\,kg loads. We evaluated three calibration strategies (load-specific, global, cross-load) and three optimization frameworks (simulated annealing (SA), particle swarm optimization (PSO), and hybrid PSO-pattern search (PSO-PS)). Results indicate that load-specific calibration significantly improves performance, with lower RMSE and higher correlation ($r > 0.75$). Parameters related to muscle force, fiber length, and activation dynamics showed high load sensitivity. PSO-based methods yielded more consistent and physiologically plausible estimates than simulated annealing. The proposed framework enables MSK models to distinguish between visually similar but mechanically distinct tasks, supporting robust subject-specific modeling for clinical and real-world applications.