An Acceleration Based Fusion of Multiple Spatiotemporal Networks for Gait Phase Detection

Human-gait-phase-recognition is an important technology in the field of exoskeleton robot control and medical rehabilitation. Inertial sensors with accelerometers and gyroscopes are easy to wear, inexpensive and have great potential for analyzing gait dynamics. However, current deep-learning methods extract spatial and temporal features in isolation—while ignoring the inherent correlation in high-dimensional spaces—which limits the accuracy of a single model. This paper proposes an effective hybrid deep-learning framework based on the fusion of multiple spatiotemporal networks (FMS-Net), which is used to detect asynchronous phases from IMU signals. More specifically, it first uses a gait-information acquisition system to collect IMU sensor data fixed on the lower leg. Through data preprocessing, the framework constructs a spatial feature extractor with CNN module and a temporal feature extractor, combined with LSTM module. Finally, a skip-connection structure and the two-layer fully connected layer fusion module are used to achieve the final gait recognition. Experimental results show that this method has better identification accuracy than other comparative methods with the macro-F1 reaching 96.7%.

[1]  Huayong Yang,et al.  Proportion-based fuzzy gait phase detection using the smart insole , 2018 .

[2]  Lei Yan,et al.  Walking Gait Phase Detection Based on Acceleration Signals Using Voting-Weighted Integrated Neural Network , 2020, Complex..

[3]  Qaiser Riaz,et al.  Person Re-Identification Using Deep Modeling of Temporally Correlated Inertial Motion Patterns , 2020, Sensors.

[4]  Bernd Markert,et al.  A systematic review of gait analysis methods based on inertial sensors and adaptive algorithms. , 2017, Gait & posture.

[5]  Shouqian Sun,et al.  A Low-Cost End-to-End sEMG-Based Gait Sub-Phase Recognition System , 2020, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[6]  Deok-Hwan Kim,et al.  Multiple gait phase recognition using boosted classifiers based on sEMG signal and classification matrix , 2014, ICUIMC.

[7]  Mario Lamontagne,et al.  Side does not matter in healthy young and older individuals - Examining the importance of how we match limbs during gait studies. , 2019, Gait & posture.

[8]  Yu Zhong,et al.  Sensor orientation invariant mobile gait biometrics , 2014, IEEE International Joint Conference on Biometrics.

[9]  Bram Vanderborght,et al.  ED-FNN: A New Deep Learning Algorithm to Detect Percentage of the Gait Cycle for Powered Prostheses , 2018, Sensors.

[10]  Omid Dehzangi,et al.  IMU-Based Gait Recognition Using Convolutional Neural Networks and Multi-Sensor Fusion , 2017, Sensors.

[11]  Tingli Su,et al.  Probability Fusion Decision Framework of Multiple Deep Neural Networks for Fine-Grained Visual Classification , 2019, IEEE Access.

[12]  T. Karthikeyan,et al.  A novel hidden Markov model-based adaptive dynamic time warping (HMDTW) gait analysis for identifying physically challenged persons , 2019, Soft Comput..

[13]  Eduardo Palermo,et al.  Gait Partitioning Methods: A Systematic Review , 2016, Sensors.

[14]  Xiao-yi Wang,et al.  Dynamic Correlation Analysis Method of Air Pollutants in Spatio-Temporal Analysis , 2020, International journal of environmental research and public health.

[15]  Tingli Su,et al.  Deep Learning Predictor for Sustainable Precision Agriculture Based on Internet of Things System , 2020, Sustainability.

[16]  Hanghang Tong,et al.  Activity recognition with smartphone sensors , 2014 .

[17]  Giancarlo Ferrigno,et al.  A Novel Adaptive, Real-Time Algorithm to Detect Gait Events From Wearable Sensors , 2015, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[18]  Alan Godfrey,et al.  Gait Asymmetry Post-Stroke: Determining Valid and Reliable Methods Using a Single Accelerometer Located on the Trunk , 2019, Sensors.

[19]  Hailong Zhu,et al.  Support vector machine for classification of walking conditions of persons after stroke with dropped foot. , 2009, Human movement science.

[20]  Shamik Sural,et al.  Information fusion from multiple cameras for gait-based re-identification and recognition , 2015, IET Image Process..

[21]  Marimuthu Palaniswami,et al.  A hybrid Support Vector Machine and autoregressive model for detecting gait disorders in the elderly , 2007, 2007 International Joint Conference on Neural Networks.

[22]  Carlotta Mummolo,et al.  Quantifying dynamic characteristics of human walking for comprehensive gait cycle. , 2013, Journal of biomechanical engineering.

[23]  Yuan Peng,et al.  Walking Gait Phase Detection Based on Acceleration Signals Using LSTM-DNN Algorithm , 2019 .

[24]  Haiping Lu,et al.  Boosting Discriminant Learners for Gait Recognition Using MPCA Features , 2009, EURASIP J. Image Video Process..

[25]  Liu Ming,et al.  Identification of Individual Walking Patterns Using Gait Acceleration , 2007, 2007 1st International Conference on Bioinformatics and Biomedical Engineering.

[26]  Tobi Delbrück,et al.  Recurrent Neural Network Control of a Hybrid Dynamical Transfemoral Prosthesis with EdgeDRNN Accelerator , 2020, 2020 IEEE International Conference on Robotics and Automation (ICRA).

[27]  Alberto Esquenazi,et al.  A Randomized Comparative Study of Manually Assisted Versus Robotic‐Assisted Body Weight Supported Treadmill Training in Persons With a Traumatic Brain Injury , 2013, PM & R : the journal of injury, function, and rehabilitation.

[28]  Min Zuo,et al.  CropDeep: The Crop Vision Dataset for Deep-Learning-Based Classification and Detection in Precision Agriculture , 2019, Sensors.

[29]  Gabriella Balestra,et al.  Muscle activation patterns during gait: A hierarchical clustering analysis , 2017, Biomed. Signal Process. Control..

[30]  Alexei A. Morozov,et al.  Normal and pathological gait classification LSTM model , 2019, Artif. Intell. Medicine.

[31]  Marcela Munera,et al.  Gait Phase Detection for Lower-Limb Exoskeletons using Foot Motion Data from a Single Inertial Measurement Unit in Hemiparetic Individuals , 2019, Sensors.

[32]  R. Kram,et al.  Changing the demand on specific muscle groups affects the walk–run transition speed , 2008, Journal of Experimental Biology.

[33]  Manuel J. Marín-Jiménez,et al.  Automatic Learning of Gait Signatures for People Identification , 2016, IWANN.

[34]  Tingli Su,et al.  Deep Hybrid Model Based on EMD with Classification by Frequency Characteristics for Long-Term Air Quality Prediction , 2020, Mathematics.

[35]  Sergey Ioffe,et al.  Batch Normalization: Accelerating Deep Network Training by Reducing Internal Covariate Shift , 2015, ICML.

[36]  Gracián Triviño,et al.  Walking pattern classification using a granular linguistic analysis , 2015, Appl. Soft Comput..

[37]  Yu Zhong,et al.  Pace independent mobile gait biometrics , 2015, 2015 IEEE 7th International Conference on Biometrics Theory, Applications and Systems (BTAS).

[38]  Lucy Parrington,et al.  Detecting gait abnormalities after concussion or mild traumatic brain injury: A systematic review of single-task, dual-task, and complex gait. , 2018, Gait & posture.

[39]  Baihai Zhang,et al.  A Neuron-Based Kalman Filter with Nonlinear Autoregressive Model , 2020, Sensors.