AI-Based Vehicle State Estimation Using Multi-Sensor Perception and Real-World Data

AI-Based Vehicle State Estimation Using Multi-Sensor Perception and Real-World Data

With the rise of vehicle automation, accurate estimation of driving dynamics has become crucial for ensuring safe and efficient operation. Vehicle dynamics control systems rely on these estimates to provide necessary control variables for stabilizing vehicles in various scenarios. Traditional model-...

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Bibliographic Details
Main Authors: Julian Ruggaber, Daniel Pölzleitner, Jonathan Brembeck
Format: Article
Language:English
Published: MDPI AG 2025-07-01
Series:Sensors
Subjects:
vehicle dynamics state estimation
AI-based vehicle state estimation
perception data for state estimation
camera
lidar
recurrent neural network
Online Access:https://www.mdpi.com/1424-8220/25/14/4253
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Summary:With the rise of vehicle automation, accurate estimation of driving dynamics has become crucial for ensuring safe and efficient operation. Vehicle dynamics control systems rely on these estimates to provide necessary control variables for stabilizing vehicles in various scenarios. Traditional model-based methods use wheel-related measurements, such as steering angle or wheel speed, as inputs. However, under low-traction conditions, e.g., on icy surfaces, these measurements often fail to deliver trustworthy information about the vehicle states. In such critical situations, precise estimation is essential for effective system intervention. This work introduces an AI-based approach that leverages perception sensor data, specifically camera images and lidar point clouds. By using relative kinematic relationships, it bypasses the complexities of vehicle and tire dynamics and enables robust estimation across all scenarios. Optical and scene flow are extracted from the sensor data and processed by a recurrent neural network to infer vehicle states. The proposed method is vehicle-agnostic, allowing trained models to be deployed across different platforms without additional calibration. Experimental results based on real-world data demonstrate that the AI-based estimator presented in this work achieves accurate and robust results under various conditions. Particularly in low-friction scenarios, it significantly outperforms conventional model-based approaches.
ISSN:1424-8220

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