Most routine motor tasks are complex, involving load transmission through out the body, intricate balance, and eye-head-shoulder-hand-torso-leg coor dination. The quest toward understanding how we perform such tasks with skill and grace, often in the presence of unpredictable perturbations, has a long history. This book arose from the Ninth Engineering Foundation Con ference on Biomechanics and Neural Control of Movement, held in Deer Creek, Ohio, in June 1996. This unique conference, which has met every 2 to 4 years since the late 1960s, is well known for its informal format that promotes…mehr
Most routine motor tasks are complex, involving load transmission through out the body, intricate balance, and eye-head-shoulder-hand-torso-leg coor dination. The quest toward understanding how we perform such tasks with skill and grace, often in the presence of unpredictable perturbations, has a long history. This book arose from the Ninth Engineering Foundation Con ference on Biomechanics and Neural Control of Movement, held in Deer Creek, Ohio, in June 1996. This unique conference, which has met every 2 to 4 years since the late 1960s, is well known for its informal format that promotes high-level, up-to-date discussions on the key issues in the field. The intent is to capture the high quality ofthe knowledge and discourse that is an integral part of this conference series. The book is organized into ten sections. Section I provides a brief intro duction to the terminology and conceptual foundations of the field of move ment science; it is intended primarily for students. All but two of the re maining nine sections share a common format: (l) a designated section editor; (2) an introductory didactic chapter, solicited from recognized lead ers; and (3) three to six state-of-the-art perspective chapters. Some per spective chapters are followed by commentaries by selected experts that provide balance and insight. Section VI is the largest section, and it con sists of nine perspective chapters without commentaries.Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Section I.- 1 Terminology and Foundations of Movement Science.- Section II.- 2 Neural and Muscular Properties: Current Views and Controversies.- 3 Intraoperative Sarcomere Length Measurements Reveal Musculoskeletal Design Principles.- 4 Comparison of Effective Synaptic Currents Generated in Spinal Motoneurons by Activating Different Input Systems.- 5 Length, Shortening Velocity, Activation, and Fatigue Are Not Independent Factors Determining Muscle Force Exerted.- 6 Modeling of Homogeneous Muscle: Is It Realistic to Consider Skeletal Muscle as a Lumped Sarcomere or Fiber?.- 7 Subtle Nonlinear Neuromuscular Properties Are Consistent with Teleological Design Principles.- Section III.- 8 Creating Neuromusculoskeletal Models.- 9 System Identification and Neuromuscular Modeling.- 10 A Reductionist Approach to Creating and Using Neuromusculoskeletal Models.- 11 Musculoskeletal Systems with Intrinsic and Proprioceptive Feedback.- Section IV.- 12 Neuromechanical Interaction in Cyclic Movements.- 13 Musculoskeletal Dynamics in Rhythmic Systems: A Comparative Approach to Legged Locomotion.- 14 Biomechanics of Hydroskeletons: Studies of Crawling in the Medicinal Leech.- 15 Simulation of the Spinal Circuits Controlling Swimming Movements in Fish.- 16 A Simple Neural Network for the Control of a Six-Legged Walking System.- 17 Neuromechanical Function of Reflexes During Locomotion.- 18 Fractal Analysis of Human Walking Rhythm.- Section V.- 19 Postural Adaptation for Altered Environments, Tasks, and Intentions.- 20 Altered Astronaut Performance Following Spaceflight: Control and Modeling Insights.- 21 Adaptive Sensory-Motor Processes Disturb Balance Control After Spaceflight.- 22 Neuromuscular Control Strategies in Postural Coordination.- Section VI.- Introduction: Neural and Mechanical Contributions to Upper Limb Movement.- 23 Maps, Modules, and Internal Models in Human Motor Control.- 24 How Much Coordination Can Be Obtained Without Representing Time?.- 25 Augmenting Postural Primitives in Spinal Cord: Dynamic Force-Field Structures Used in Trajectory Generation.- 26 Learning and Memory Formation of Arm Movements.- 27 What Do We Plan or Control When We Perform a Voluntary Movement?.- 28 Simulation of Multijoint Arm Movements.- 29 Planning of Human Motions: How Simple Must It Be?.- 30 Biomechanics of Manipulation: Grasping the Task at Hand.- 31 A Principle of Control of Rapid Multijoint Movements.- Section VII.- 32 Large-Scale Musculoskeletal Systems: Sensorimotor Integration and Optimization.- 33 Progression of Musculoskeletal Models Toward Large-Scale Cybernetic Myoskeletal Models.- 34 Estimation of Movement from Surface EMG Signals Using a Neural Network Model.- 35 Study Movement Selection and Synergies via a Synthesized Neuro-Optimization Framework.- 36 Clinical Applications of Musculoskeletal Models in Orthopedics and Rehabilitation.- Section VIII.- 37 Human Performance and Rehabilitation Technologies.- 38 Rehabilitators, Robots, and Guides: New Tools for Neurological Rehabilitation.- 39 Nonanalytical Control for Assisting Reaching in Humans with Disabilities.- 40 Soft Computing Techniques for Evaluation and Control of Human Performance.- 41 From Idea to Product.- Section IX.- 42 Movement Synthesis and Regulation in Neuroprostheses.- 43 Properties of Artificially Stimulated Muscles: Simulation and Experiments.- 44 Synthesis of Hand Grasp.- 45 Control with Natural Sensors.- 46 Control of Rhythmic Movements Using FNS.- Section X.- Appendix 1 Morphological Data for the Development of Musculoskeletal Models: An Update Frans C.T. van der Helm and Gary T. Yamaguchi.- Appendix 2 Move3d Software Tom M. Kepple and Steven J. Stanhope.- Appendix 3 Simulation of an Antagonistic Muscle Model in Matlab Bart L. Kaptein, Guido G. Brouwn and Frans C.T. van der Helm.- Appendix 4 SPACAR: A Finite-Element Software Package for Musculoskeletal Modeling Frans C.T van der Helm.- Appendix 5 DataMonster E. Otten.
Section I.- 1 Terminology and Foundations of Movement Science.- Section II.- 2 Neural and Muscular Properties: Current Views and Controversies.- 3 Intraoperative Sarcomere Length Measurements Reveal Musculoskeletal Design Principles.- 4 Comparison of Effective Synaptic Currents Generated in Spinal Motoneurons by Activating Different Input Systems.- 5 Length, Shortening Velocity, Activation, and Fatigue Are Not Independent Factors Determining Muscle Force Exerted.- 6 Modeling of Homogeneous Muscle: Is It Realistic to Consider Skeletal Muscle as a Lumped Sarcomere or Fiber?.- 7 Subtle Nonlinear Neuromuscular Properties Are Consistent with Teleological Design Principles.- Section III.- 8 Creating Neuromusculoskeletal Models.- 9 System Identification and Neuromuscular Modeling.- 10 A Reductionist Approach to Creating and Using Neuromusculoskeletal Models.- 11 Musculoskeletal Systems with Intrinsic and Proprioceptive Feedback.- Section IV.- 12 Neuromechanical Interaction in Cyclic Movements.- 13 Musculoskeletal Dynamics in Rhythmic Systems: A Comparative Approach to Legged Locomotion.- 14 Biomechanics of Hydroskeletons: Studies of Crawling in the Medicinal Leech.- 15 Simulation of the Spinal Circuits Controlling Swimming Movements in Fish.- 16 A Simple Neural Network for the Control of a Six-Legged Walking System.- 17 Neuromechanical Function of Reflexes During Locomotion.- 18 Fractal Analysis of Human Walking Rhythm.- Section V.- 19 Postural Adaptation for Altered Environments, Tasks, and Intentions.- 20 Altered Astronaut Performance Following Spaceflight: Control and Modeling Insights.- 21 Adaptive Sensory-Motor Processes Disturb Balance Control After Spaceflight.- 22 Neuromuscular Control Strategies in Postural Coordination.- Section VI.- Introduction: Neural and Mechanical Contributions to Upper Limb Movement.- 23 Maps, Modules, and Internal Models in Human Motor Control.- 24 How Much Coordination Can Be Obtained Without Representing Time?.- 25 Augmenting Postural Primitives in Spinal Cord: Dynamic Force-Field Structures Used in Trajectory Generation.- 26 Learning and Memory Formation of Arm Movements.- 27 What Do We Plan or Control When We Perform a Voluntary Movement?.- 28 Simulation of Multijoint Arm Movements.- 29 Planning of Human Motions: How Simple Must It Be?.- 30 Biomechanics of Manipulation: Grasping the Task at Hand.- 31 A Principle of Control of Rapid Multijoint Movements.- Section VII.- 32 Large-Scale Musculoskeletal Systems: Sensorimotor Integration and Optimization.- 33 Progression of Musculoskeletal Models Toward Large-Scale Cybernetic Myoskeletal Models.- 34 Estimation of Movement from Surface EMG Signals Using a Neural Network Model.- 35 Study Movement Selection and Synergies via a Synthesized Neuro-Optimization Framework.- 36 Clinical Applications of Musculoskeletal Models in Orthopedics and Rehabilitation.- Section VIII.- 37 Human Performance and Rehabilitation Technologies.- 38 Rehabilitators, Robots, and Guides: New Tools for Neurological Rehabilitation.- 39 Nonanalytical Control for Assisting Reaching in Humans with Disabilities.- 40 Soft Computing Techniques for Evaluation and Control of Human Performance.- 41 From Idea to Product.- Section IX.- 42 Movement Synthesis and Regulation in Neuroprostheses.- 43 Properties of Artificially Stimulated Muscles: Simulation and Experiments.- 44 Synthesis of Hand Grasp.- 45 Control with Natural Sensors.- 46 Control of Rhythmic Movements Using FNS.- Section X.- Appendix 1 Morphological Data for the Development of Musculoskeletal Models: An Update Frans C.T. van der Helm and Gary T. Yamaguchi.- Appendix 2 Move3d Software Tom M. Kepple and Steven J. Stanhope.- Appendix 3 Simulation of an Antagonistic Muscle Model in Matlab Bart L. Kaptein, Guido G. Brouwn and Frans C.T. van der Helm.- Appendix 4 SPACAR: A Finite-Element Software Package for Musculoskeletal Modeling Frans C.T van der Helm.- Appendix 5 DataMonster E. Otten.
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