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I am delighted to have been invited to Bath for the opening of this Third International Congress of Thermology. The connection between the Congress and the City of Bath is significant. The properties of sunlight have been recognized throughout the centuries. Indeed, many ancient religions were based on the worship of the sun gods. The study of radiant heat was pioneered by Sir William Herschel, whose experiments led him to the study of heat and ultimately of infrared radiation. His son, John, furthered these experiments and formed an image by evaporating alcohol with carbon. In modern technology, infrared radiation plays a vital role in a wide range of applications. Thermal imaging is widely used in the manufacturing industries, especially plastics, glass and paper. The motor industry, for example, employs thermography in the design of windscreens and tire development. Chemical plants and refineries also use it in the important control of expensive energy losses. The communications industry makes extensive use of thermal imaging since overheating and cracks in insulation may cause the unscheduled shut-down of expensive equipment. There is now a special thermal imaging system for the examination of very large scale integrated circuits to help in the development of diagnostic tools for examining circuits which now have features of 1 micron in size, making the conventional method of mechanical probing impossible. This revolution in probing will enable us to maintain the high levels of quality control which are essential in the communications industry.
As the third volume of The Biomedical Engineering Handbook, Fourth Edition, this book covers broad areas such as biosignal processing, medical imaging, infrared imaging, and medical informatics. More than three dozen specific topics are examined including biomedical signal acquisition, thermographs, infrared cameras, mammography, computed tomography, positron-emission tomography, magnetic resonance imaging, hospital information systems, and computer-based patient records. The material is presented in a systematic manner and has been updated to reflect the latest applications and research findings.
The definitive bible for the field of biomedical engineering, this collection of volumes is a major reference for all practicing biomedical engineers and students. Now in its fourth edition, this work presents a substantial revision, with all sections updated to offer the latest research findings. New sections address drugs and devices, personalized medicine, and stem cell engineering. Also included is a historical overview as well as a special section on medical ethics. This set provides complete coverage of biomedical engineering fundamentals, medical devices and systems, computer applications in medicine, and molecular engineering.
Want to incorporate medical infrared imaging into your practice but can’t find a book that explains how to do it? Well, this book is for you! Complete, practical instructions are provided on imager choice and care as well as the physical needs of a thermography service from the imaging room layout to the computer requirements. How to acquire, interpret, and report a thermal examination is covered in detail. Fully illustrated with both normal and abnormal images, Human Medical Thermography provides practitioners of all types with the knowledge to design and operate a scientifically based thermography practice. Key Features • Shows how to select the best thermal imager for your clinical practice, care for it, and use it correctly. • Explains how to take medical quality thermal images and scale them for maximum visual effect using the guidelines detailed in this book. • Details myriad ways that thermography can aid in medical diagnosis and improve surgical outcomes.
The book covers the latest updates in the application of infrared to biomedical sciences, a non-invasive, contactless, safe and easy approach imaging of skin and tissue temperatures. Its diagnostic procedure allows practitioners to identify the locations of abnormal chemical and blood vessel activity such as angiogenesis in body tissue. Its non-invasive approach works by applying the technology of the infrared camera and state-of-the-art software, where high-resolution digital infrared imaging technology benefits highly from enhanced image production, standardized image interpretation protocols, computerized comparison and storage, and sophisticated image enhancement and analysis. The book contains contributions from global prominent scientists in the area of infrared applications in biomedical studies. The target audience includes academics, practitioners, clinicians and students working in the area of infrared imaging in biomedicine.
The evolution of technological advances in infrared sensor technology, image processing, "smart" algorithms, knowledge-based databases, and their overall system integration has resulted in new methods of research and use in medical infrared imaging. The development of infrared cameras with focal plane arrays no longer requiring cooling, added a new dimension to this modality. Medical Infrared Imaging: Principles and Practices covers new ideas, concepts, and technologies along with historical background and clinical applications. The book begins by exploring worldwide advances in the medical applications of thermal imaging systems. It covers technology and hardware including detectors, detector materials, un-cooled focal plane arrays, high performance systems, camera characterization, electronics for on-chip image processing, optics, and cost-reduction designs. It then discusses the physiological basis of the thermal signature and its interpretation in a medical setting. The book also covers novel and emerging techniques, the complexities and importance of protocols for effective and reproducible results, storage and retrieval of thermal images, and ethical obligations. Of interest to both the medical and biomedical engineering communities, the book explores many opportunities for developing and conducting multidisciplinary research in many areas of medical infrared imaging. These range from clinical quantification to intelligent image processing for enhancement of the interpretation of images, and for further development of user-friendly high-resolution thermal cameras. These would enable the wide use of infrared imaging as a viable, noninvasive, low-cost, first-line detection modality.
Over the last century, medicine has come out of the "black bag" and emerged as one of the most dynamic and advanced fields of development in science and technology. Today, biomedical engineering plays a critical role in patient diagnosis, care, and rehabilitation. More than ever, biomedical engineers face the challenge of making sure that medical d