Fundamentals of Neuromechanics

1. Front Matter

   Pages i-xxiv

   PDF

2. Introduction

   • Francisco J. Valero-Cuevas

   Pages 1-5

3. Fundamentals

   1. Front Matter

      Pages 7-7

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   2. Limb Kinematics

      • Francisco J. Valero-Cuevas

      Pages 9-24

   3. Limb Mechanics

      • Francisco J. Valero-Cuevas

      Pages 25-36

   4. Tendon-Driven Limbs

      • Francisco J. Valero-Cuevas

      Pages 37-51

4. Introduction to the Neural Control of Tendon-Driven Limbs

   1. Front Matter

      Pages 53-53

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   2. The Neural Control of Joint Torques in Tendon-Driven Limbs Is Underdetermined

      • Francisco J. Valero-Cuevas

      Pages 55-69

   3. The Neural Control of Musculotendon Lengths and Excursions Is Overdetermined

      • Francisco J. Valero-Cuevas

      Pages 71-87

5. Feasible Actions of Tendon-Driven Limbs

   1. Front Matter

      Pages 89-89

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   2. Feasible Neural Commands and Feasible Mechanical Outputs

      • Francisco J. Valero-Cuevas

      Pages 91-111

   3. Feasible Neural Commands with Mechanical Constraints

      • Francisco J. Valero-Cuevas

      Pages 113-131

6. Neuromechanics as a Scientific Tool

   1. Front Matter

      Pages 133-134

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   2. The Nature and Structure of Feasible Sets

      • Francisco J. Valero-Cuevas

      Pages 135-157

   3. Implications

      • Francisco J. Valero-Cuevas

      Pages 159-174

7. Back Matter

   Pages 175-194

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This book provides a conceptual and computational framework to study how the nervous system exploits the anatomical properties of limbs to produce mechanical function. The study of the neural control of limbs has historically emphasized the use of optimization to find solutions to the muscle redundancy problem. That is, how does the nervous system select a specific muscle coordination pattern when the many muscles of a limb allow for multiple solutions?
I revisit this problem from the emerging perspective of neuromechanics that emphasizes finding and implementing families of feasible solutions, instead of a single and unique optimal solution. Those families of feasible solutions emerge naturally from the interactions among the feasible neural commands, anatomy of the limb, and constraints of the task. Such alternative perspective to the neural control of limb function is not only biologically plausible, but sheds light on the most central tenets and debates in the fields of neural control, robotics, rehabilitation, and brain-body co-evolutionary adaptations. This perspective developed from courses I taught to engineers and life scientists at Cornell University and the University of Southern California, and is made possible by combining fundamental concepts from mechanics, anatomy, mathematics, robotics and neuroscience with advances in the field of computational geometry.
Fundamentals of Neuromechanics is intended for neuroscientists, roboticists, engineers, physicians, evolutionary biologists, athletes, and physical and occupational therapists seeking to advance their understanding of neuromechanics. Therefore, the tone is decidedly pedagogical, engaging, integrative, and practical to make it accessible to people coming from a broad spectrum of disciplines. I attempt to tread the line between making the mathematical exposition accessible to life scientists, and convey the wonder and complexity of neuroscience to engineers and computational scientists. While no one approach can hope to definitively resolve the important questions in these related fields, I hope to provide you with the fundamental background and tools to allow you to contribute to the emerging field of neuromechanics.

• Computational Geometry
• Musculoskeletal structure
• Neural Control
• Neuroscience
• Robotics

• Department of Biomedical Engineering, The University of Southern California, Los Angeles, USA

  Francisco J. Valero-Cuevas

Francisco Valero-Cuevas is a Full Professor in the Department of Biomedical Engineering, and the Division of Biokinesiology & Physical Therapy at the University of Southern California. He also holds appointments in the departments of Aerospace & Mechanical Engineering and Computer Science. Prior to this he was Assistant and Associate Professor at Cornell University.

He holds a Bachelor’s degree in Engineering Science from Swarthmore College, a Masters degree from Queen’s University, and a Doctoral degree in Mechanical Engineering focused on neuroscience from Stanford University.

He has been visiting professor at the Max Planck Institute in Munich, Germany, ETH-Zurich, Switzerland, and the Institute of Sports Sciences in Innsbruck, Austria. He has served as Associate Editor of the IEEE Transactions on Biomedical Engineering and Guest Editor of PLoS Computational Biology. In 2013 he was elected Senior Member of the IEEE, and in 2014 to the College of Fellows of the American Institute for Medical and Biological Engineers.

His research focuses on an integrative approach to brain-body interactions for versatile function in machines and organisms.

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