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Compressive Sensing Strategy on Sparse Array to Accelerate Ultrasonic TFM Imaging.

Lucas Pereira Piedade, Guillaume Painchaud-April, Alain Le Duff

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    Summary
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    Compressive sensing (CS) significantly reduces data in full matrix capture (FMC) phased array ultrasonic testing (PAUT). This method accelerates total focusing method (TFM) imaging while maintaining image quality for defect characterization.

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    Area of Science:

    • Materials Science and Engineering
    • Nondestructive Testing
    • Signal Processing

    Background:

    • Phased array ultrasonic testing (PAUT) using full matrix capture (FMC) is increasingly vital for defect characterization.
    • The combination of FMC and total focusing method (TFM) yields high-resolution images but is data-intensive.
    • Data volume in FMC-TFM is proportional to the square of the probe's elements, posing hardware and processing challenges.

    Purpose of the Study:

    • To investigate the application of compressive sensing (CS) for reducing data requirements in FMC-TFM.
    • To evaluate the effectiveness of CS in accelerating TFM imaging and assess its impact on image quality.
    • To explore the use of sparse arrays in conjunction with CS for further optimization.

    Main Methods:

    • Experimental data acquisition using FMC with phased array ultrasonic transducers.
    • Application of compressive sensing (CS) algorithms for data compression and signal recovery.
    • Comparison of TFM images generated from FMC, CS-compressed FMC (CS-FMC), and sparse CS data using contrast-to-noise ratio (CNR).

    Main Results:

    • CS methodology reduced data volume by up to 80% while achieving adequate FMC data recovery.
    • CS-FMC produced TFM images comparable in quality to those obtained from full FMC data.
    • Sparse arrays combined with CS improved reconstruction times by up to 11-fold and accelerated image formation by 6.6 times, with minimal image quality degradation.

    Conclusions:

    • Compressive sensing is a viable technique for overcoming the data-intensive nature of FMC-TFM.
    • CS enables significant data reduction and accelerated imaging without substantial loss of defect characterization capability.
    • The integration of sparse arrays with CS offers a promising pathway for more efficient and faster ultrasonic imaging.