• DocumentCode
    1654600
  • Title

    Fourier domain beamforming for medical ultrasound

  • Author

    Chernyakova, Tanya ; Eldar, Yonina C. ; Amit, Ron

  • Author_Institution
    Dept. of Electr. Eng., Technion - Israel Inst. of Technol., Haifa, Israel
  • fYear
    2013
  • Firstpage
    924
  • Lastpage
    928
  • Abstract
    Sonography techniques use multiple transducer elements for tissue visualization. Signals detected at each element are sampled prior to digital beamforming. The required sampling rates are up to 4 times the Nyquist rate of the signal and result in considerable amount of data, that needs to be stored and processed. A developed technique, based on the finite rate of innovation model, compressed sensing (CS) and Xampling ideas, allows to reduce the number of samples needed to reconstruct an image comprised of strong reflectors. A significant drawback of this method is its inability to treat speckle, which is of significant importance in medical imaging. Here we build on previous work and show explicitly how to perform beamforming in the Fourier domain. Beamforming in frequency exploits the low bandwidth of the beamformed signal and allows to bypass the oversampling dictated by digital implementation of beamforming in time. We show that this allows to obtain the same beamformed image as in standard beamforming but from far fewer samples. Finally, we present an analysis based CS-technique that allows for further reduction in sampling rate, using only a portion of the beamformed signal´s bandwidth, namely, sampling the signal at sub-Nyquist rates. We demonstrate our methods on in vivo cardiac ultrasound data and show that reductions up to 1/25 over standard beamforming rates are possible.
  • Keywords
    Fourier analysis; biomedical ultrasonics; cardiology; compressed sensing; image coding; medical image processing; Fourier domain beamforming; Xampling ideas; beamformed image reconstruction; beamformed signal bandwidth; compressed sensing technique; in vivo cardiac ultrasound data; medical imaging; medical ultrasound; signal detection; sonography technique; subNyquist rate; tissue visualization; transducer element; Array signal processing; Bandwidth; Discrete Fourier transforms; Fourier series; Image reconstruction; Imaging; Ultrasonic imaging; Array Processing; Beamforming; Compressed Sensing; Speckle; Ultrasound;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Acoustics, Speech and Signal Processing (ICASSP), 2013 IEEE International Conference on
  • Conference_Location
    Vancouver, BC
  • ISSN
    1520-6149
  • Type

    conf

  • DOI
    10.1109/ICASSP.2013.6637784
  • Filename
    6637784