Manynationshavebecomevictimsofterrorism. Bombshaveexplodedinand around buildings and other structures. Such events have generated cons- erable concern over the ability of countries and governments to protect - stallations and their occupants against a potential threat of terrorism. Many countries have established defence agencies and research councils who are currently examining the structural integrity of existing buildings and other vital installations. In some countries codi?ed methods have been developed together with the design methodologies and construction techniques to try to protect old installations against vehicle bomb e?ects in particular. The purpose of this book is to give an exhaustive study of buildings structures resistingexplosion with and withoutexternal/internalimpactand ?recaused by such e?ects. A number of case studies with damage scenarios are included. The book is divided into various chapters. Chapter 1 gives a review of bomb-a?ected buildings. Case studies incl- ingAlfred P. Murrah Federal Building in Oklahoma and World Trade Center (WTC) Twin Towers in New York have been given a wide coverage. Notable explosionsintheworldwithrelevantdataaretabulated. Afterthesethed- age scenario of the Pentagon building is fully described. This chapter now resorts to the availability of data on major explosive elements, their ingre- ents and material properties.

A number of books and research papers have been published on trauma and biomechanics.Theyhavesofarnotbeenrealisticallyintegrated.Thebasicaim ofthisbookistopresentauni?edapproachbetweentheengineeringandm- ical professions. The available engineering analyses and mathematical models can be interlinked and glued together with the medical ?ndings by means of surgeries and X-rays/scans. They can be translated into vastly developed computer programs predicting e?ects of plasticity, temperature, cracking, and crushing with and without muscles and other interlocking phenomenon. The available mathematical-cum-engineering model on trauma and bone mechanics are then linked to the ?nite element analysis and to a computer programinwhichprovisionsaremadetocaterforallpossibleeventualitiesand medicalparameters.Theproblemencounteredbysurgeriescanbeeasilybe- corporated into hybrid ?nite element computer programs such as PROGRAM ISOPARusedinthisbook.Inallcasestudiesthesurgicalin?uenceshavebeen considered together with the bone material data for both the operational, nonoperational and overloading behaviour of the human body structure. In all circumstances the human body structure and its important elements were treated as composite. The bone-blood interaction has been incorporated in ordertoobtainrealisticsolutions.Materialpropertiesinthree-dimensionhave always been considered in throughout in various investigations. Engineering analysis of trauma is being continuously developed taking into consideration the ever increasing changes in analytical, design, safety, and manufacturing techniques. The engineering advances in that direction are steadily gaining international acceptance in the wide sense of the medical profession.

A number of books and research papers have been published on trauma and biomechanics.Theyhavesofarnotbeenrealisticallyintegrated.Thebasicaim ofthisbookistopresentauni?edapproachbetweentheengineeringandm- ical professions. The available engineering analyses and mathematical models can be interlinked and glued together with the medical ?ndings by means of surgeries and X-rays/scans. They can be translated into vastly developed computer programs predicting e?ects of plasticity, temperature, cracking, and crushing with and without muscles and other interlocking phenomenon. The available mathematical-cum-engineering model on trauma and bone mechanics are then linked to the ?nite element analysis and to a computer programinwhichprovisionsaremadetocaterforallpossibleeventualitiesand medicalparameters.Theproblemencounteredbysurgeriescanbeeasilybe- corporated into hybrid ?nite element computer programs such as PROGRAM ISOPARusedinthisbook.Inallcasestudiesthesurgicalin?uenceshavebeen considered together with the bone material data for both the operational, nonoperational and overloading behaviour of the human body structure. In all circumstances the human body structure and its important elements were treated as composite. The bone-blood interaction has been incorporated in ordertoobtainrealisticsolutions.Materialpropertiesinthree-dimensionhave always been considered in throughout in various investigations. Engineering analysis of trauma is being continuously developed taking into consideration the ever increasing changes in analytical, design, safety, and manufacturing techniques. The engineering advances in that direction are steadily gaining international acceptance in the wide sense of the medical profession.