Wearable Sensors for Activity Recognition in Ultimate Frisbee Using Convolutional Neural Networks and Transfer Learning

Link, Johannes; Perst, Timur; Stoeve, Maike; Eskofier, Bjoern M.

doi:10.3390/s22072560

Cited by 9 publications

(7 citation statements)

References 31 publications

(46 reference statements)

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“…The dataset comprises three-dimensional acceleration data from joint actions of beach volleyball athletes, each of whom was fitted with an accelerometer worn on the wrist and sampled at 39 Hz. The signal was recorded at 14 bits per axis and then compressed to 16 g. The x , y , and z axes relate to the athletes' spatial arrangement, which is recorded in an independent coordinate system based on the sensor configuration, as there was no transfer to real-world coordinates [ 45 , 46 ]. The 30 athletes recorded ranged in expertise from novice to professional volleyball players.…”

Section: Experiments and Resultsmentioning

confidence: 99%

Leakage Prediction in Machine Learning Models When Using Data from Sports Wearable Sensors

Qi-zheng

2022

Computational Intelligence and Neuroscience

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One of the major problems in machine learning is data leakage, which can be directly related to adversarial type attacks, raising serious concerns about the validity and reliability of artificial intelligence. Data leakage occurs when the independent variables used to teach the machine learning algorithm include either the dependent variable itself or a variable that contains clear information that the model is trying to predict. This data leakage results in unreliable and poor predictive results after the development and use of the model. It prevents the model from generalizing, which is required in a machine learning problem and thus causes false assumptions about its performance. To have a solid and generalized forecasting model, which will be able to produce remarkable forecasting results, we must pay great attention to detecting and preventing data leakage. This study presents an innovative system of leakage prediction in machine learning models, which is based on Bayesian inference to produce a thorough approach to calculating the reverse probability of unseen variables in order to make statistical conclusions about the relevant correlated variables and to calculate accordingly a lower limit on the marginal likelihood of the observed variables being derived from some coupling method. The main notion is that a higher marginal probability for a set of variables suggests a better fit of the data and thus a greater likelihood of a data leak in the model. The methodology is evaluated in a specialized dataset derived from sports wearable sensors.

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Section: Experiments and Resultsmentioning

confidence: 99%

Leakage Prediction in Machine Learning Models When Using Data from Sports Wearable Sensors

Qi-zheng

2022

Computational Intelligence and Neuroscience

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“…[22][23][24]. However, CNN-based transfer learning sometimes does not perform as expected, giving unexpectedly lower prediction accuracy in the testing stage despite a high accuracy rate in the training and validation stages [25]. For a given medical image dataset, which usually has a limited number of images and small image differences, overfitting is a common problem using the popular CNN models, which often have over 10 layers with 60+ million trained parameters and have been trained on a large dataset (imageJ) containing 1000 categories.…”

Section: Introductionmentioning

confidence: 81%

Convolutional Neural Network Classification of Exhaled Aerosol Images for Diagnosis of Obstructive Respiratory Diseases

Talaat

Tan

et al. 2023

JNT

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Aerosols exhaled from the lungs have distinctive patterns that can be linked to the abnormalities of the lungs. Yet, due to their intricate nature, it is highly challenging to analyze and distinguish these aerosol patterns. Small airway diseases pose an even greater challenge, as the disturbance signals tend to be weak. The objective of this study was to evaluate the performance of four convolutional neural network (CNN) models (AlexNet, ResNet-50, MobileNet, and EfficientNet) in detecting and staging airway abnormalities in small airways using exhaled aerosol images. Specifically, the model’s capacity to classify images inside and outside the original design space was assessed. In doing so, multi-level testing on images with decreasing similarities was conducted for each model. A total of 2745 images were generated using physiology-based simulations from normal and obstructed lungs of varying stages. Multiple-round training on datasets with increasing images (and new features) was also conducted to evaluate the benefits of continuous learning. Results show reasonably high classification accuracy on inbox images for models but significantly lower accuracy on outbox images (i.e., outside design space). ResNet-50 was the most robust among the four models for both diagnostic (2-class: normal vs. disease) and staging (3-class) purposes, as well as on both inbox and outbox test datasets. Variation in flow rate was observed to play a more important role in classification decisions than particle size and throat variation. Continuous learning/training with appropriate images could substantially enhance classification accuracy, even with a small number (~100) of new images. This study shows that CNN transfer-learning models could detect small airway remodeling (<1 mm) amidst a variety of variants and that ResNet-50 can be a promising model for the future development of obstructive lung diagnostic systems.

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“…In future work, we will investigate if methods from the area of out-of-distribution generalization can further improve the algorithm’s precision to unseen venues and athletes [ 45 ]. Other possibilities include using transfer learning to utilize IMU data from other application areas, where data are more readily available, as completed in earlier work [ 46 ].…”

Section: Discussionmentioning

confidence: 99%

xLength: Predicting Expected Ski Jump Length Shortly after Take-Off Using Deep Learning

Link

Schwinn²,

Pulsmeyer³

et al. 2022

Sensors

Self Cite

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With tracking systems becoming more widespread in sports research and regular training and competitions, more data are available for sports analytics and performance prediction. We analyzed 2523 ski jumps from 205 athletes on five venues. For every jump, the dataset includes the 3D trajectory, 3D velocity, skis’ orientation, and metadata such as wind, starting gate, and ski jumping hill data. Using this dataset, we aimed to predict the expected jump length (xLength) inspired by the expected goals metric in soccer (xG). We evaluate the performance of a fully connected neural network, a convolutional neural network (CNN), a long short-term memory (LSTM), and a ResNet architecture to estimate the xLength. For the prediction of the jump length one second after take-off, we achieve a mean absolute error (MAE) of 5.3 m for the generalization to new athletes and an MAE of 5.9 m for the generalization to new ski jumping hills using ResNet architectures. Additionally, we investigated the influence of the input time after the take-off on the predictions’ accuracy. As expected, the MAE becomes smaller with longer inputs. Due to the real-time transmission of the sensor’s data, xLength can be updated during the flight phase and used in live TV broadcasting. xLength could also be used as an analysis tool for experts to quantify the quality of the take-off and flight phases.

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Wearable Sensors for Activity Recognition in Ultimate Frisbee Using Convolutional Neural Networks and Transfer Learning

Cited by 9 publications

References 31 publications

Leakage Prediction in Machine Learning Models When Using Data from Sports Wearable Sensors

Leakage Prediction in Machine Learning Models When Using Data from Sports Wearable Sensors

Convolutional Neural Network Classification of Exhaled Aerosol Images for Diagnosis of Obstructive Respiratory Diseases

xLength: Predicting Expected Ski Jump Length Shortly after Take-Off Using Deep Learning

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