Dynamic Modeling of Musculoskeletal Motion introduces biomechanists to modern methods of modeling and analyzing dynamic biomechanical systems in three dimensions. Using vector kinematics, the reader is taught a systematic method which significantly reduces the complexity of working with multiple, moving limb segments in three dimensions. Operations which usually require the application of differential calculus are replaced by simple algebraic formulae. To derive dynamical equations of motion, a practical introduction to Kane's Method is given.

Kane's Method builds upon the foundation of vector kinematics and represents one of the most exciting theoretical developments of the modern era. Together, these techniques enable biomechanists to decipher and model living systems with great realism, efficiency and accuracy. Interwoven with the theoretical presentation are chapters and examples which highlight the subtle differences between inanimate linkages and the biomechanical systems we seek to understand.

Acknowledgments. Foreword. Part I: An Introduction to Musculotendon Modeling and Analysis. 1. Overview of Dynamic Musculoskeletal Modeling. 2. An Introduction to Modeling Muscle and Tendon. Part II: Defining Skeletal Kinematics. 3. Rigid Bodies and Reference Frames. 4. Vector Based Kinematics. 5. Models of the Skeletal System. Part III: Dynamic Equations of Motion. 6. Dynamic Equations of Motion. 7. Control. Appendices. About the Author. Index.