Your search keyword '"Chang, Jin Ho"' showing total 2 results

1. Coded tissue harmonic imaging with nonlinear chirp signals

Author

Song, Jaehee, Chang, Jin Ho, Song, Tai-kyong, and Yoo, Yangmo

Subjects

*MEDICAL imaging systems, *SIGNAL-to-noise ratio, *NONLINEAR optics, *EXPERIMENTS, *PULSE compression radar, *TISSUES, *BANDPASS filters, *BANDWIDTHS, *IMAGE quality analysis

Abstract

Abstract: Coded tissue harmonic imaging with pulse inversion (CTHI-PI) based on a linear chirp signal can improve the signal-to-noise ratio with minimizing the peak range sidelobe level (PRSL), which is the main advantage over CTHI with bandpass filtering (CTHI-BF). However, the CTHI-PI technique could suffer from motion artifacts due to decreasing frame rate caused by two firings of opposite phase signals for each scanline. In this paper, a new CTHI method based on a nonlinear chirp signal (CTHI-NC) is presented, which can improve the separation of fundamental and harmonic components without sacrificing frame rate. The nonlinear chirp signal is designed to minimize the PRSL value by optimizing its frequency sweep rate and time duration. The performance of the CTHI-NC method was evaluated by measuring the PRSL and mainlobe width after compression. From the in vitro experiments, the CTHI-NC provided the PRSL of −40.6dB and the mainlobe width of 2.1μs for the transmit quadratic nonlinear chirp signal with the center frequency of 2.1MHz, the fractional bandwidth at −6dB of 0.6 and the time duration of 15μs. These results indicate that the proposed method could be used for improving frame rates in CTHI while providing comparable image quality to CTHI-PI. [ABSTRACT FROM AUTHOR]

Published

2011

2. Frequency compounded imaging with a high-frequency dual element transducer

Author

Chang, Jin Ho, Kim, Hyung Ham, Lee, Jungwoo, and Shung, K. Kirk

Subjects

*TRANSDUCERS, *IMAGING systems, *SIGNAL-to-noise ratio, *INFORMATION measurement, *SIGNAL processing, *BANDWIDTHS, *FREQUENCIES of oscillating systems, *ELECTRIC equipment, *ELECTROMECHANICAL devices

Abstract

Abstract: This paper proposes a frequency compounding method to reduce speckle interferences, where a concentric annular type high-frequency dual element transducer is used to broaden the bandwidth of an imaging system. In frequency compounding methods, frequency division is carried out to obtain sub-band images containing uncorrelated speckles, which sacrifices axial resolution. Therefore, frequency compounding often deteriorates the target-detecting capability, quantified by the total signal-to-noise ratio (SNR), when the speckle’s SNR (SSNR) is not improved as much as the degraded axial resolution. However, this could be avoided if the effective bandwidth required for frequency compounding is increased. The primary goal of the proposed approach, hence, is to improve SSNR by a factor of two under the condition where axial resolution is degraded by a factor of less than two, which indicates the total SNR improvement to higher than 40% compared to that of an original image. Since the method here employs a dual element transducer operating at 20 and 40MHz, the effective bandwidth necessary for frequency compounding becomes broadened. By dividing each spectrum of RF samples from both elements into two sub-bands, this method eventually enables four sets of the sub-band samples to contain uncorrelated speckles. This causes the axial resolution to be reduced by a factor of as low as 1.85, which means that this method would improve total SNR by at least 47%. An in vitro experiment on an excised pig eye was performed to validate the proposed approach, and the results showed that the SSNR was improved from 2.081±0.365 in the original image to 4.206±0.635 in the final compounding image. [Copyright &y& Elsevier]

Published

2010