Extension of the distributed point source method for ultrasonic field modeling

Cheng, Jiqi; Lin, Wei; Qin, Yi‐Xian

doi:10.1016/j.ultras.2010.12.011

Cited by 14 publications

(5 citation statements)

References 53 publications

(34 reference statements)

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“…More complex analyses, also taking into account nonlinear effects, can be addressed only by numerical methods. 128 The k-wave Matlab toolbox 129 is probably the most widely used US simulation software nowadays. It is based on a numerical model that solves the main partial differential acoustic equations in the k-space frequency domain.…”

Section: Discussionmentioning

confidence: 99%

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Piezoelectric Nanomaterials Activated by Ultrasound: The Pathway from Discovery to Future Clinical Adoption

et al. 2021

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Electrical stimulation has shown great promise in biomedical applications, such as regenerative medicine, neuromodulation, and cancer treatment. Yet, the use of electrical end effectors such as electrodes requires connectors and batteries, which dramatically hamper the translation of electrical stimulation technologies in several scenarios. Piezoelectric nanomaterials can overcome the limitations of current electrical stimulation procedures as they can be wirelessly activated by external energy sources such as ultrasound. Wireless electrical stimulation mediated by piezoelectric nanoarchitectures constitutes an innovative paradigm enabling the induction of electrical cues within the body in a localized, wireless, and minimally invasive fashion. In this review, we highlight the fundamental mechanisms of acoustically mediated piezoelectric stimulation and its applications in the biomedical area. Yet, the adoption of this technology in a clinical practice is in its infancy, as several open issues, such as piezoelectric properties measurement, control of the ultrasound dose in vitro , modeling and measurement of the piezo effects, knowledge on the triggered bioeffects, therapy targeting, biocompatibility studies, and control of the ultrasound dose delivered in vivo , must be addressed. This article explores the current open challenges in piezoelectric stimulation and proposes strategies that may guide future research efforts in this field toward the translation of this technology to the clinical scene.

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Section: Discussionmentioning

confidence: 99%

“…However, they are limited by simplifications such as low intensities, simple geometries, and linear approximation. More complex analyses, also taking into account nonlinear effects, can be addressed only by numerical methods . The k-wave Matlab toolbox is probably the most widely used US simulation software nowadays.…”

Section: Discussionmentioning

confidence: 99%

Piezoelectric Nanomaterials Activated by Ultrasound: The Pathway from Discovery to Future Clinical Adoption

et al. 2021

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“…Focusing on acoustic and elastodynamic ultrasonic waves, it has been applied to problems including beam profile modeling in homogeneous and layered structures [22], [23], as well as scattering caused by singular and multiple elliptical cavities within semi-infinite and plate-like structures [24], [25]. It operates by placing point sources within close proximity to boundaries; by using the known boundary conditions, the complex amplitudes of these point sources can be calculated and are subsequently used to propagate the wavefield to any set of target points within the problem domain.…”

Section: The Distributed Point Source Methodsmentioning

confidence: 99%

Scattering of near normal incidence SH waves by sinusoidal and rough surfaces in 3-D: Comparison to the scalar wave approximation

Jarvis

Cegla

2014

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

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The challenge of accurately simulating how incident scalar waves interact with rough boundaries has made it an important area of research within many scientific disciplines. Conventional methods, which in the majority of cases focus only on scattering in two dimensions, often suffer from long simulation times or reduced accuracy, neglecting phenomena such as multiple scattering and surface self-shadowing. A simulation based on the scalar wave distributed point source method (DPSM) is presented as an alternative which is computationally more efficient than fully meshed numerical methods while obtaining greater accuracy than approximate analytical techniques. Comparison is made to simulated results obtained using the finite element method for a sinusoidally periodic surface where scattering only occurs in two dimensions, showing very good agreement (<0.2 dB). In addition to two-dimensional scattering, comparison to experimental results is also carried out for scattering in three dimensions when the surface has a Gaussian roughness distribution. Results indicate that for two-dimensional scattering and for rough surfaces with a correlation length equal to the incident wavelength (λ) and a root mean square height less than 0.2λ, the scalar wave approximation predicts reflected pulse shape change and envelope amplitudes generally to within 1 dB. Comparison between transducers within a three-element array also illustrate the sensitivity pulse amplitude can have to sensor position above a rough surface, differing by as much as 17 dB with a positional change of just 1.25λ.

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“…In 2005, Ahmad et al [43] of the University of Arizona used the DPSM to model the ultrasonic field generated by ultrasonic array transducers and studied the interaction of two-phased array transducers placed in a homogeneous fluid. In 2011, Cheng et al [44] further extended the DPSM and proposed to solve the least-squares minimization problem by calculating the sound intensity of point sources without using the traditional matrix iterative method. In the same year, Rahani et al [45] proposed the Gaussian distributed point source method (G-DPSM) and the elemental source method (ESM), which further optimized the DPSM.…”

Section: The Distributed Point Source Methodsmentioning

confidence: 99%

Sound Field Modeling Method and Key Imaging Technology of an Ultrasonic Phased Array: A Review

Wang

2022

Applied Sciences

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An ultrasonic phased array consists of multiple ultrasonic probes arranged in a certain regular order, and the delay time of the excitation signal sent to each array element is controlled electronically. The testing system model based on ultrasonic propagation theory is established to obtain a controllable and focused sound field, which has theoretical and engineering guiding significance for the calculation and analysis of ultrasonic array sound fields. Perfecting array theory and exploring array imaging methods can obtain rich acoustic information, provide more intuitive and reliable research results, and further the development of ultrasonic phased-array systems. This paper reviews the progress of research on the application of ultrasound arrays for non-destructive testing (NDT) and brings together the most relevant published work on the application of simulation methods and popular imaging techniques for ultrasonic arrays. It mainly reviews the modeling approaches, including the angular spectrum method (ASM), multi-Gaussian beam method (MGB), ray tracing method, finite element method (FEM), finite difference method (FDM), and distributed point source method (DPSM), which have been used to assess the performance and inspection modality of a given array. In addition, the array of imaging approaches, including the total focusing method (TFM), compression sensing imaging (CSI), and acoustic nonlinearity imaging (ANI), are discussed. This paper is expected to provide strong technical support in related areas such as ultrasonic array testing theory and imaging methods.

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Extension of the distributed point source method for ultrasonic field modeling

Cited by 14 publications

References 53 publications

Piezoelectric Nanomaterials Activated by Ultrasound: The Pathway from Discovery to Future Clinical Adoption

Piezoelectric Nanomaterials Activated by Ultrasound: The Pathway from Discovery to Future Clinical Adoption

Scattering of near normal incidence SH waves by sinusoidal and rough surfaces in 3-D: Comparison to the scalar wave approximation

Sound Field Modeling Method and Key Imaging Technology of an Ultrasonic Phased Array: A Review

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