Archive/AI-Based Two-Stage Estimation of Ankle Dorsiflexion from a Single IMU: A Gazebo-Based Transtibial Prosthesis Simulation Study
AI-Based Two-Stage Estimation of Ankle Dorsiflexion from a Single IMU: A Gazebo-Based Transtibial Prosthesis Simulation Study
Diana C. Martínez, Oscar M. Navas, Juan S. Rada et al.
July 3, 2026
en

Abstract

Background/Objectives: Ankle dorsiflexion plays a fundamental role in gait stability, impact absorption, and the stance-to-swing transition, and its impairment is a major limitation in transtibial prostheses. This study proposes and evaluates a lightweight two-stage pipeline for generating ankle-dorsiflexion references using a single shank-mounted inertial measurement unit (IMU). Methods: In the first stage, a deep neural network (DNN) estimates the shank pitch waveform from raw three-axis accelerations and angular velocities. In the second stage, the estimated shank pitch is transformed into an ankle-dorsiflexion waveform using a temporal mapping model. The approach was evaluated on a multisubject subset of the NONAN GaitPrint database comprising 35 healthy young adults, 598 walking trials, and approximately 122,468 gait cycles, using a strict subject-held-out protocol. Results: A feature-based Random Forest baseline showed limited performance, whereas the waveform-based DNN achieved high accuracy for shank pitch estimation, with test R2 values up to 0.97. A conventional polynomial mapping between shank pitch and dorsiflexion yielded weak performance, whereas a temporal mapping model substantially improved the estimation of ankle dorsiflexion, with test R2 values up to 0.85. The resulting ankle reference was integrated into a Gazebo/Robot Operating System 2 (ROS 2) simulation of a transtibial prosthesis, where the generated trajectories were executed in a software integration test under open-loop position control, confirming stable and consistent trajectory execution. Conclusions: These results indicate that combining accurate shank pitch estimation with temporal mapping enables feasible ankle-dorsiflexion reference generation from a single sensor in able-bodied gait, offering a preliminary, simulation-based pathway for single-sensor artificial intelligence (AI) pipelines in prosthetic development. The framework supports waveform-level feasibility, not clinical readiness or functional prosthetic control.

IPC Classification

G06H04A61

Keywords

ai-basedtwo-stageestimationankledorsiflexionsinglegazebo-basedtranstibialprosthesissimulationbiomechanicsbackgroundobjectivesplaysfundamentalrolegaitstabilityimpactabsorptionstance-to-swingtransitionimpairmentmajor
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