Grating lobe reduction in plane wave imaging with angular compounding using subtraction of coherent signals

TL;DR

This paper introduces a nonlinear beamforming technique called Null Subtraction Imaging (NSI) that effectively reduces grating lobes in plane wave ultrasound imaging with angular compounding, improving image quality without sacrificing resolution.

Contribution

The study demonstrates that NSI significantly diminishes grating lobes in PWI, outperforming traditional methods like DAS with Hann and GCF, with validation in simulations and in vivo experiments.

Findings

NSI reduces grating lobes compared to DAS and GCF.

NSI maintains spatial resolution and contrast.

Validated with tissue-mimicking phantoms and rat tumors.

Abstract

Plane wave imaging (PWI) with angular compounding has gained in popularity over recent years because it provides high frame rates and good image properties. However, most linear arrays used in clinical practice have a pitch that is equal to than the wavelength of ultrasound. Hence, the presence of grating lobes is a concern for PWI using multiple transmit angles. The presence of grating lobes produces clutter in images and reduces the ability to observe tissue contrast. Techniques to reduce or eliminate the presence of grating lobes for PWI using multiple angles will result in improved image quality. Null subtraction imaging (NSI) is a nonlinear beamforming technique that has been explored for improving the lateral resolution of ultrasonic imaging. However, the apodization scheme used in NSI also eliminates or greatly reduces the presence of grating lobes. Imaging tasks using NSI were evaluated in simulations and physical experiments involving tissue-mimicking phantoms and rat tumors in vivo. Images created with NSI were compared with images created using traditional delay and sum (DAS) with Hann apodization and images created using a generalized coherence factor (GCF). NSI was observed to greatly reduce the presence of grating lobes in ultrasonic images, compared to DAS with Hann and GCF, while maintaining spatial resolution and contrast in the images. Therefore, NSI can provide a novel means of creating images using PWI with multiple steering angles on clinically available linear arrays while reducing the adverse effects associated with grating lobes.