A proficient recommendation system for athletes utilizing an adaptive learning model integrated with wearable IoT devices
DOI:
https://doi.org/10.56294/dm2025851Keywords:
recommendation system, learning model, prediction accuracy, uncertainty model, attention modelAbstract
In the current digital context, recommendation algorithms must be used. It has found use in various contexts, including music streaming services and athletics. Athletic recommendation systems have received little study attention. Sedentary lifestyles are now the primary cause of many flaws and a significant portion of expenses. Based on user profiles, connections to other users, and histories in the current study, we create a system to suggest daily workout plans to athletes. The created recommendation system uses profiles of users and temporal processes in Adaptive Support Vector Machine (). Additionally, compared to streaming recommendation algorithms, we cannot gather input from athletes using the wearable IoT Devices and sensors for collecting the data of exercise and workout the system is proposed, which sets them apart significantly. As a result, we suggest an active learning process that involves an expert in real. The active learner estimates the recommendation system's level of uncertainty for every user at each successive step and, finally, when it is high, gets assistance from a professional. We construct and use the marginal distance distribution of its probability function in the present research to determine whether to consult subject-matter experts. Our test findings on a real-time dataset demonstrate increased accuracy after incorporating a live and engaged learner into the search engine.
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Copyright (c) 2025 DEEPAK V., X.S. ASHA SHINY, VIDYABHARATHI DAKSHINAMURTHI, S. JOHN JUSTIN THANGARAJ, DINESH KUMAR ANGURAJ (Author)
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The article is distributed under the Creative Commons Attribution 4.0 License. Unless otherwise stated, associated published material is distributed under the same licence.
