Guided by the conceptualization of content knowledge, this book covers sports analysis (identification of techniques and tactics), skill analysis (identification of critical elements, observation, evaluation of students’ performance through error detection, and interventions), and biomechanical principles and their applications to skill performance and analysis, which teachers or coaches need to possess for effective teaching and coaching. The importance for preservice and in-service physical education teachers or coaches to acquire in-depth content knowledge is supported by national standards and research. Studies have shown that an improvement in preservice and in-service physical education teachers’ specialized content knowledge leads to an increase in their pedagogical content knowledge, which results in better learning and performance among students. Practical examples for conducting sports and skill analysis, designing teaching progressions for interventions, and applying biomechanical principles are provided. This book equips teachers or coaches with knowledge and skills to conduct sports and skill analysis, which are essential for effective teaching and coaching, and will be key reading for undergraduate and graduate students majoring in physical education teacher education and sports coaching and in-service physical education teachers and current coaches.
Wearable Systems Based Gait Monitoring and Analysis provides a thorough overview of wearable gait monitoring techniques and their use in health analysis. The text starts with an examination of the relationship between the human body’s physical condition and gait, and then introduces and explains nine mainstream sensing mechanisms, including piezoresistive, resistive, capacitive, piezoelectric, inductive, optical, air pressure, EMG and IMU-based architectures. Gait sensor design considerations in terms of geometry and deployment are also introduced. Diverse processing algorithms for manipulating sensors outputs to transform raw data to understandable gait features are discussed. Furthermore, gait analysis-based health monitoring demonstrations are given at the end of this book, including both medical and occupational applications. The book will enable students of biomedical engineering, electrical engineering, signal processing, and ergonomics and practitioners to understand the medical and occupational applications of engineering-based gait analysis and falling injury prevention methods.
Guided by the conceptualization of content knowledge, this book covers sports analysis (identification of techniques and tactics), skill analysis (identification of critical elements, observation, evaluation of students’ performance through error detection, and interventions), and biomechanical principles and their applications to skill performance and analysis, which teachers or coaches need to possess for effective teaching and coaching. The importance for preservice and in-service physical education teachers or coaches to acquire in-depth content knowledge is supported by national standards and research. Studies have shown that an improvement in preservice and in-service physical education teachers’ specialized content knowledge leads to an increase in their pedagogical content knowledge, which results in better learning and performance among students. Practical examples for conducting sports and skill analysis, designing teaching progressions for interventions, and applying biomechanical principles are provided. This book equips teachers or coaches with knowledge and skills to conduct sports and skill analysis, which are essential for effective teaching and coaching, and will be key reading for undergraduate and graduate students majoring in physical education teacher education and sports coaching and in-service physical education teachers and current coaches.
Wearable Systems Based Gait Monitoring and Analysis provides a thorough overview of wearable gait monitoring techniques and their use in health analysis. The text starts with an examination of the relationship between the human body’s physical condition and gait, and then introduces and explains nine mainstream sensing mechanisms, including piezoresistive, resistive, capacitive, piezoelectric, inductive, optical, air pressure, EMG and IMU-based architectures. Gait sensor design considerations in terms of geometry and deployment are also introduced. Diverse processing algorithms for manipulating sensors outputs to transform raw data to understandable gait features are discussed. Furthermore, gait analysis-based health monitoring demonstrations are given at the end of this book, including both medical and occupational applications. The book will enable students of biomedical engineering, electrical engineering, signal processing, and ergonomics and practitioners to understand the medical and occupational applications of engineering-based gait analysis and falling injury prevention methods.
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