%0 Journal Article
%T Consideration of generated beam angles increases the accuracy of ultrasonic displacement measurements
%A Sumi C
%A Takanashi Y
%A Ichimaru K
%J Reports in Medical Imaging
%D 2012
%I Dove Medical Press
%R http://dx.doi.org/10.2147/RMI.S27307
%X nsideration of generated beam angles increases the accuracy of ultrasonic displacement measurements Original Research (2469) Total Article Views Authors: Sumi C, Takanashi Y, Ichimaru K Published Date March 2012 Volume 2012:5 Pages 23 - 50 DOI: http://dx.doi.org/10.2147/RMI.S27307 Received: 13 October 2011 Accepted: 11 November 2011 Published: 09 March 2012 Chikayoshi Sumi, Yuuki Takanashi, Kento Ichimaru Department of Information and Communication Sciences, Faculty of Science and Technology, Sophia University, Tokyo, Japan Abstract: The development of practical ultrasonic (US) tissue displacement measurement methods increases the number of available and useful applications of displacement/strain measurements that can be made (eg, various blood flow measurements and measurements of tissue motion in organs such as the heart, liver, and so forth). Previously developed lateral modulation (LM) methods with a multidimensional autocorrelation method (MAM) or multidimensional Doppler method (MDM) and a steering angle method (ASTA) with lateral Doppler method produced accurate displacement vector and lateral displacement measurements, respectively. Such measurements cannot be obtained using only a conventional Doppler technique. Another new method has also been reported, using multiple crossed beams (MCBs) to obtain high-accuracy displacement vector measurements; that is, a displacement vector is synthesized using accurately measured axial displacements with previously developed multidimensional displacement measurement methods, including the one-dimensional autocorrelation method (1D AM) with a multidimensional moving average (MA), together with conventional rotation processing of global echo data or a coordinate system (ie, a global echo rotation referred to as r method) by the negative value of the steering angles used in beamforming. However, in real-world applications, directivities of transmission and reception apertures, scattering, reflection, and attenuation affect the direction and properties of US beams used for conventional axial displacement measurements employing beamforming methods such as a conventional nonsteered, steered, or secta beam, and they also affect ASTA and MCB methods. In this report, to improve accuracy in the measurements of an arbitrary directional displacement and a displacement vector using any beamforming methods, a spatial resolution in a beam angle (BA) is generated. For instance, for a two-dimensional (2D) Cartesian coordinate system, this is obtained by calculating the arctangent of the ratio of the axial and lateral instantaneous frequencies or the first moments of local spectra. On the basis of the 1D AM with a multidimensional MA, the local displacement in the beam direction is accurately measured by dividing the local instantaneous phase change by the instantaneous frequency calculated in the beam direction, and an arbitrary directional displacement can be measured (axial, lateral, radial, and so forth), which is
%K beam direction
%K beam angle (BA)
%K axial displacement
%K lateral displacement
%K displacement vector
%K lateral modulation (LM)
%K a steering angle (ASTA)
%K multiple crossed beams (MCBs)
%K multidimensional or one-dimensional autocorrelation method (MAM or 1DAM)
%K multidirectional moving-average (MA)
%K spectra frequency division method (SFDM)
%U https://www.dovepress.com/consideration-of-generated-beam-angles-increases-the-accuracy-of-ultra-peer-reviewed-article-RMI