Large elements and advanced beamformers for increased field of view in 2-D ultrasound matrix arrays

TL;DR

This study demonstrates that increasing element size and employing advanced beamformers can expand the field of view in 2-D ultrasound matrix arrays without sacrificing resolution, validated through simulations and in vivo experiments.

Contribution

The paper introduces a method to increase ultrasound array FOV by enlarging elements and using advanced beamformers, overcoming limitations of reduced element count architectures.

Findings

Larger elements with advanced beamformers maintain resolution and double FOV.

NSI and DCF beamformers outperform DAS in resolution and sidelobe reduction.

In vivo rabbit liver imaging confirms practical effectiveness.

Abstract

Three-dimensional (3D) ultrasound promises various medical applications for abdominal, obstetrics, and breast imaging. However, ultrasound matrix arrays have extremely high element counts limiting their field of view (FOV). Current reduced element count architectures, such as row-column arrays, diverging lenses, or sparse arrays, suffer from limited resolution and high side- and grating-lobe levels. This work seeks to demonstrate an increased field-of-view using a reduced element count array design. The approach is to increase the element size and use advanced beamformers to maintain image quality. The delay and sum (DAS), Null Subtraction Imaging (NSI), directional coherence factor (DCF), and Minimum Variance (MV) beamformers were compared. K-wave simulations of the 3D point-spread functions (PSF) of NSI, DCF, and MV display reduced side lobes and narrowed main lobes compared to DAS. Experiments were conducted using a multiplexed 1024-element matrix array on a Verasonics 256 system. Elements were electronically coupled to imitate a larger pitch and element size. Then, a virtual large aperture was created by using a positioning system to collect data in sections with the matrix array. Resolution and contrast was also assessed on a rabbit liver in vivo. Resolution was maintained using coupling numbers up to four, doubling the FOV while reducing the element count. The NSI and DCF beamformers demonstrated the best resolution performance in simulations, in a phantom with the virtual aperture, and in vivo on a rabbit liver. Our results demonstrate how larger matrix arrays could be constructed with larger elements, with resolution maintained by advanced beamformers.