Details

#1 Introduction <br> R.G. Maev<br> <br> #2 Fundamentals <br> Multiwave Imaging (M. Fink and M. Tanter, France)<br> Imaging via Speckle Interferometry and Non-linear Methods (J. Sadler, R.G. Maev;<br> Canada) <br> Making Waves in Biomedical Research with Micro-ultrasound (F.S. Foster, Canada)<br> <br> #3 Novel Development in Advanced Imaging Technical and Methods<br> Fundamentals and Applications of Quantitative Ultrasonic Microscope for Soft Biological Tissues (K. Kobayashi, N. Hozumi;<br> Japan)<br> Portable Ultrasonic Imaging Systems Approach (R.G. Maev, J.J. Hwang, F. Seviaryn, A. Denissov, S. Titov;<br> USA, Canada) <br> High Frequency Ultrasonic Systems for High Resolution Ranging and Imaging (M. Vogt and H. Ermert;<br> Germany)<br> <br> #4 Advanced Biomedical Applications<br> Thickly Sectioned Melanoma Skin Tissues Examined by Mechanical Scanning Acoustic Reflection Microscopy (B. R. Tittmann, C. Miyasaka, E. Maeva, D. Shum;<br> USA, Canada) <br> New concept of pathology - mechanical properties provided by acoustic microscopy (Y. Saijo;<br> Japan)<br> Quantitative acoustic scanning microscopy of bone (P. Laugier, A. Saied, M. Mouchet, K. Raum;<br> France, Germany)<br> <br> #5 Advanced Materials Applications<br> Array imaging and defect characterization using post-processing approaches (B.W. Drinkwater, P.D. Wilcox, A. Velichko, UK)<br> Quantitative Acoustic Microscopy based on array approach (S. Titov, R.G. Maev;<br> Canada, Russia) <br> <br> #6 Atomic Force Acoustic Microscopy<br> Acoustically excited probe microscopy (G.A.D. Briggs, O.V. Kolosov, UK)<br> Ultrasonic atomic force microscopy (K. Yamanaka and T. Tsuji;<br> Japan)<br> High-Resolution Acoustical Imaging Using Atomic Force Acoustic Microscopes (W. Arnold;<br> Germany)<br> <br>

<b>Roman Maev</b> is a celebrated academic scientist, scholar and administrator. He is founding General Director of The Institute for Diagnostic Imaging Research in Ontario, a multi-disciplinary, collaborative research and innovation consortium. His research interests include theoretical fundamentals of physical acoustics, experimental research in ultrasonic and nonlinear acoustical imaging, and the theory of propagation of waves through layered structures. Professor Maev has published 13 books, over 320 articles, holds twenty-three patents, and received numerous awards.

<p><b>N</b>ovel physical solutions, including new results in the field of adaptive methods and inventive approaches to inverse problems, original concepts based on high harmonic imaging algorithms, intriguing vibro-acoustic imaging and vibro-modulation technique, etc. were successfully introduced and verified in numerous studies of industrial materials and biomaterials in the last few years. Together with the above mentioned traditional academic and practical avenues in ultrasonic imaging research, intriguing scientific discussions have recently surfaced and will hopefully continue to bear fruits in the future. The goal of this book is to provide an overview of the recent advances in high-resolution ultrasonic imaging techniques and their applications to biomaterials evaluation and industrial materials. The result is a unique collection of papers presenting novel results and techniques that were developed by leading research groups worldwide.</p> <p>This book offers a number of topical results from well-known authors who are engaged in the development of novel physical principles, methods, and the implementation of modern technological solutions into current imaging devices as well as finding new applications of high-resolution imaging systems. The ultimate purpose of this book is to highlight the great potential of high resolution acoustic imaging and its various industrial and biomedical applications, and to encourage more researchers to enter this exciting field of study.</p>

SG