This book demonstrates the application of mathematics to modeling accident reconstructions involving a range of moving vehicles, including automobiles, small and large trucks, bicycles, motorcycles, all-terrain vehicles, and construction equipment such as hoists and cranes.
Mathematical Methods for Accident Reconstruction: A Forensic Engineering Perspective, Second Edition demonstrates the application of mathematics to modeling accident reconstructions involving a range of moving vehicles, including automobiles, small and large trucks, bicycles, motorcycles, all-terrain vehicles, and construction equipment such as hoists and cranes.
The book is anchored on basic principles of physics that may be applied to any of the above-named vehicles or equipment. Topics covered include the foundations of measurement, the various energy methods used in reconstruction, momentum methods, vehicle specifications, failure analysis, geometrical characteristics of highways, and softer scientific issues such as visibility, perception, and reaction. The authors examine the fundamental characteristics of different vehicles, discuss the retrieval of data from crash data recorders, and review low speed impacts with an analysis of staged collisions. Finally, the book details established standards and protocols for accident reconstruction—for use in both investigations and in the courtroom. In addition, this new edition covers non-vehicle related topics like slips and falls analysis, fall protection, as well as engine and mechanical failure as well as federal rules and laws that have been established for the work environment. Many reconstructions of incidents require extensive analysis that may require a variety of methods in order to properly model the incident.
Exploring a broad range of accident scenarios, the breadth and depth of the book’s coverage makes Mathematical Methods for Accident Reconstruction, Second Edition a critical reference for engineers and scientists who perform vehicular accident reconstructions.
