Djordje Slijepcevic1, Matthias Zeppelzauer2, Caterine Schwab3, Anna-Maria Raberger3, Christian Breiteneder4, Brian Horsak3. 1. St. Pölten University of Applied Sciences, Institute for Creative Media Technologies, St. Pölten, Austria. Electronic address: djordje.slijepcevic@fhstp.ac.at. 2. St. Pölten University of Applied Sciences, Institute for Creative Media Technologies, St. Pölten, Austria. 3. St. Pölten University of Applied Sciences, Institute of Health Sciences, St. Pölten, Austria. 4. TU Wien, Institute of Visual Computing and Human-Centered Technology, Vienna, Austria.
Abstract
BACKGROUND: Quantitative gait analysis produces a vast amount of data, which can be difficult to analyze. Automated gait classification based on machine learning techniques bear the potential to support clinicians in comprehending these complex data. Even though these techniques are already frequently used in the scientific community, there is no clear consensus on how the data need to be preprocessed and arranged to assure optimal classification accuracy outcomes. RESEARCH QUESTION: Is there an optimal data aggregation and preprocessing workflow to optimize classification accuracy outcomes? METHODS: Based on our previous work on automated classification of ground reaction force (GRF) data, a sequential setup was followed: firstly, several aggregation methods - early fusion and late fusion - were compared, and secondly, based on the best aggregation method identified, the expressiveness of different combinations of signal representations was investigated. The employed dataset included data from 910 subjects, with four gait disorder classes and one healthy control group. The machine learning pipeline comprised principle component analysis (PCA), z-standardization and a support vector machine (SVM). RESULTS: The late fusion aggregation, i.e., utilizing majority voting on the classifier's predictions, performed best. In addition, the use of derived signal representations (relative changes and signal differences) seems to be advantageous as well. SIGNIFICANCE: Our results indicate that great caution is needed when data preprocessing and aggregation methods are selected, as these can have an impact on classification accuracies. These results shall serve future studies as a guideline for the choice of data aggregation and preprocessing techniques to be employed.
BACKGROUND: Quantitative gait analysis produces a vast amount of data, which can be difficult to analyze. Automated gait classification based on machine learning techniques bear the potential to support clinicians in comprehending these complex data. Even though these techniques are already frequently used in the scientific community, there is no clear consensus on how the data need to be preprocessed and arranged to assure optimal classification accuracy outcomes. RESEARCH QUESTION: Is there an optimal data aggregation and preprocessing workflow to optimize classification accuracy outcomes? METHODS: Based on our previous work on automated classification of ground reaction force (GRF) data, a sequential setup was followed: firstly, several aggregation methods - early fusion and late fusion - were compared, and secondly, based on the best aggregation method identified, the expressiveness of different combinations of signal representations was investigated. The employed dataset included data from 910 subjects, with four gait disorder classes and one healthy control group. The machine learning pipeline comprised principle component analysis (PCA), z-standardization and a support vector machine (SVM). RESULTS: The late fusion aggregation, i.e., utilizing majority voting on the classifier's predictions, performed best. In addition, the use of derived signal representations (relative changes and signal differences) seems to be advantageous as well. SIGNIFICANCE: Our results indicate that great caution is needed when data preprocessing and aggregation methods are selected, as these can have an impact on classification accuracies. These results shall serve future studies as a guideline for the choice of data aggregation and preprocessing techniques to be employed.
Authors: Johannes Burdack; Fabian Horst; Sven Giesselbach; Ibrahim Hassan; Sabrina Daffner; Wolfgang I Schöllhorn Journal: Front Bioeng Biotechnol Date: 2020-04-15