In the last three or four decades, studies of biomechanics have expanded from simple topical applications of elementary mechanics to entire areas of study. Studies and research in biomechanics now exceed those in basic mechanics itself, underlining the continuing and increasing importance of this area of study. With an emphasis on biodynamic modeling, Fundamentals of Biomechanics provides an accessible, basic understanding of the principles of biomechanics analyses.
Following a brief introductory chapter, the book reviews gross human anatomy and basic terminology currently in use. It describes methods of analysis from elementary mathematics to elementary mechanics and goes on to fundamental concepts of the mechanics of materials. It then covers the modeling of biosystems and provides a brief overview of tissue biomechanics. The author then introduces the concepts of biodynamics and human body modeling, looking at the fundamentals of the kinematics, the kinetics, and the inertial properties of human body models. He supplies a more detailed analysis of kinematics, kinetics, and dynamics of these models and discusses the numerical procedures for solving the governing dynamical equations. The book concludes with a review of a few example applications of biodynamic models such as simple lifting, maneuvering in space, walking, swimming, and crash victim simulation.
The inclusion of extensive lists of problems of varying difficulty, references, and an extensive bibliography add breadth and depth to the coverage. Focusing on biodynamic modeling to a degree not found in other texts, this book equips readers with the expertise in biomechanics they need for advanced studies, research, and employment in biomedical engineering. -- Provided by publisher
CONTENT
Review of human anatomy and some basic terminology -- Methods of analysis I: review of vectors, dyadics, matrices, and determinants -- Methods of analysis II: forces and force systems -- Methods of analysis III: mechanics of materials -- Methods of analysis IV: modeling of biosystems -- Tissue biomechanics -- Kinematical preliminaries: fundamental equations -- Kinematic preliminaries: inertia force considerations -- Human body inertia properties -- Kinematics of human body models -- Kinetics of human body models -- Dynamics of human body models -- Numerical methods -- Simulations and applications
