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Neural Networks Versus Conventional Filters for Inertial-Sensor-based Attitude Estimation

Daniel Weber, Clemens Gühmann, Thomas Seel

202039 citationsDOIOpen Access PDF

Abstract

Inertial measurement units are commonly used to estimate the attitude of moving objects. Numerous nonlinear filter approaches have been proposed for solving the inherent sensor fusion problem. However, when a large range of different dynamic and static rotational and translational motions is considered, the attainable accuracy is limited by the need for situation-dependent adjustment of accelerometer and gyroscope fusion weights. We investigate to what extent these limitations can be overcome by means of artificial neural networks and how much domain-specific optimization of the neural network model is required to outperform the conventional filter solution. A diverse set of motion recordings with a marker-based optical ground truth is used for performance evaluation and comparison. The proposed neural networks are found to outperform the conventional filter across all motions only if domain-specific optimizations are introduced. We conclude that they are a promising tool for inertial-sensor-based real-time attitude estimation, but both expert knowledge and rich datasets are required to achieve top performance.

Topics & Concepts

Inertial frame of referenceArtificial neural networkComputer scienceInertial measurement unitEstimationInertial navigation systemArtificial intelligenceControl theory (sociology)EngineeringPhysicsControl (management)Quantum mechanicsSystems engineeringInertial Sensor and NavigationTarget Tracking and Data Fusion in Sensor NetworksRobotics and Sensor-Based Localization
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