You may have to Search all our reviewed books and magazines, click the sign up button below to create a free account.
The biophysics of diving and decompression in the human body are complex. The average individual experiences atmospheric pressure swings of 3% at sea level and over 20% at altitudes greater than a mile. Divers and their equipment can experience compressions and decompressions in orders of greater magnitude than pressures outside water, all within considerably shorter time spans. The understanding of the mechanics behind diving is based on absolute pressure and pressure changes. While these mechanics are readily quantified in physics, chemistry, and engineering applications, the physiological and medical aspects of pressure changes in living systems need to be understood clearly to assess the...
This book focuses on physics and associated mathematical relationships. Basic principles are first presented, and then practical applications and results are detailed. The intent here is to present a working view of physical phase mechanics, then followed by application to decompression theory in diving. It is directed toward the diver and reader with a basic understanding of decompression. Basically the mechanics of tissue gas exchange, bubbles and nucleation, supersaturation, perfusion and diffusion, and related mechanisms are discussed. The targeted audience is especially the doctor or physiologist, physicist, chemist, mathematician, engineer or biologist by training and also the commercial diver, technical diver, instructor, hyperbaric technician, underwater researcher, looking for greater detail.
This book is the very first to cover the decompression theory in detail. It gives many information on all topics of the diving medicine, and is richly and uniquely illustrated. It offers a good guideline of high quality practice in diving medicine. The author provides a very structured and easy to understand book, by covering all aspects of the diving medicine, such as equipment, physiology, and related issues as gas intoxications, venomous animals or damages that can occur in the diving practice. Relevant physiological and anatomical illustrations enlight even complex topics. The Diving medicine book will appeal to health experts like doctors and nurses, but also to diving schools and teachers
This brief provides a complete yet concise description of modern dive computers and their operations to date in one source with coupled applications for added understanding. Basic diving principles are detailed with practical computer implementations. Interrelated topics to diving protocols and operational procedures are included. Tests, statistics and correlations of computer models with data are underscored. The exposition also links phase mechanics to dissolved gases in modern decompression theory with mathematical relationships and equations used in dive computer synthesis. Applications focus upon and mimic dive computer operations within model implementations for added understanding. Th...
"3rd Edition of BASIC DECOMPRESSION THEORY AND APPLICATION takes all rudiments of decompression theory and phase mechanics to considerable depth, while focusing on diving applications in a historical perspective. Topics span many disciplines, and the targeted audience is the commercial diver, hyperbaric scientist, doctor, physical scientist, technical diver, and dive instructor. The intent of the 3rd Edition is to present a working view of decompression in diving, mostly focusing on theory with application, including equations. The discussion is neither a medical nor physiological synthesis. Such aspects are simplified, and for some certainly oversimplified. Nonetheless, it is directed towar...
This book includes seminal papers on technical subjects - transport theory, invariant imbedding, and integral equations - presented as contributions to honour George Milt Wing in celebration of his 65th birth anniversary in 1988.
This twenty-fifth volume in a distinguished series addresses a range of topics including: the difficult matter of questioning scientific hypotheses in court the use of Monte Carlo simulation to evaluate time-dependent development and to study system reliability in nuclear reactors of considerable complexity the genetic optimization algorith wavelet analysis ergonomic design of safer and more efficient plant control rooms.