Lumped-Parameter Equivalent Circuit Modeling of CMUT Array Elements

Merrien, Tony; Boulme, Audren; Certon, Dominique

doi:10.1109/ojuffc.2021.3134938

Cited by 9 publications

(11 citation statements)

References 65 publications

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“…This difference decreases with increased cell spacing. Similar effects were reported in literature, where a shift in center frequency and a reduction in bandwidth was predicted when increasing the cell-to-cell distance in an element (see [40], [16] and [20]).…”

Section: Discussionsupporting

confidence: 88%

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Studying the Effects of Mutual Acoustic Impedance on the Performance of Polymer-Based CMUTs

Angerer,

Welsch,

Gerardo

et al. 2024

IEEE Open J. Ultrason., Ferroelect., Freq. Contr.

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The objective of this work was to investigate changes in the acoustic characteristics of micromachined transducers caused by acoustic cross-coupling between cells. We used hexagonal, polymer-based capacitive micromachined ultrasonic transducers (polyCMUTs) consisting of 127 cells connected in parallel. The distances between the cells were varied, while the cell dimensions and number of cells remained constant. The resulting changes in characteristics were evaluated in terms of peak frequency f pk , fractional bandwidth F BW , peak transmit sensitivity S pk and opening angle Φ t . The study relies on results from an analytic multicell model (MCM) which considers cross-coupling effects between cells through a mutual acoustic impedance matrix. The results are compared with finite element (FE) analyses and measurements on fabricated prototypes. The manufacturing processes used to produce the polyCMUT prototypes are explained in detail. We found significant changes in all acoustic characteristics: as cell spacing increases, f pk and Φ t decrease, while S pk gradually rises to about twice the initial value. The F BW varies due to the change in f pk , peaking at small to intermediate cell-to-cell distances. While both modeling approaches cover the general effects, discrepancies in comparison to the measurements were identified. The FE model provided better fits than the analytic MCM, albeit at significantly higher computational costs. The effects on the acoustic characteristics were found strongest at lower frequencies and if many cells are in close proximity to each other. Hence, rotational symmetric or square transducers operating at lower frequencies are affected most. The results demonstrate that design approaches based on modeling single cells may lead to significant deviations from design goals. Both, analytic and FE models are suitable tools to estimate the effects of acoustic interactions and to predict the performance. This aids in meeting design requirements of micromachined ultrasound transducers consisting of multiple radiators.

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Section: Discussionsupporting

confidence: 88%

“…More recently, Merrien et. al [20] presented a method to model elements of linear arrays with a single twoport network model. Their approach is based on reducing the degree of freedom of a CMUT element, consisting of multiple cell-columns, to a single piston transducer.…”

Section: Introductionmentioning

confidence: 99%

Studying the Effects of Mutual Acoustic Impedance on the Performance of Polymer-Based CMUTs

Angerer,

Welsch,

Gerardo

et al. 2024

IEEE Open J. Ultrason., Ferroelect., Freq. Contr.

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“…However, noise modeling of an array comprised of hundreds of cells can be tedious [25]. We will show that the two-port network model of a CMUT array element recently published by our group simplifies the noise modeling [26].…”

Section: Introductionmentioning

confidence: 91%

“…The modeling approach is based on the finite-difference, multiscale method developed by Meynier et al [27] and recently extended to an equivalent two-port network representation of the array element by Merrien et al [26]. The lumped-parameter approach of the array element enables the combination of hundreds of cells into single equivalent impedance terms, hence easier implementation of parasitic components and integration of cascaded two-port networks.…”

Section: A Cmut Noise With Parasitic Componentsmentioning

confidence: 99%

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Thermal-Mechanical Noise Modeling and Measurements of a Row-Column Addressed CMUT Probe

Merrien

Boulme²,

Certon

2022

IEEE Open J. Ultrason., Ferroelect., Freq. Contr.

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Thermal-Mechanical (T-M) noise is a natural phenomenon occurring in Capacitive Micromachined Ultrasonic Transducers (CMUT). T-M noise is a value of great interest because it is linked to the minimal detectable pressure of a transducer and can also serve as a convenient characterization tool. Indeed, the general behavior of a CMUT array is translated through its T-M noise which does not require any external applied source to be assessed. However, T-M noise is difficult to measure, often time requires a dedicated measurement chain and is mostly based on spectrum analyzers in a carefully controlled environment. In this paper, we present a temporal technique to characterize the T-M noise of CMUT-based arrays with a commercially available amplifier and a digital oscilloscope. The approach is applied to an air coupled Row-Column Addressed (RCA) matrix array, for which the elements cannot be measured with traditional microprobes systems. This task is performed using a Printed Circuit Board (PCB) dedicated to the characterization of RCA arrays and designed to drive rows and columns individually. Noise Power Spectral Density (PSD) modeling of the complete measurement chain is achieved using a lumped-parameter model of the RCA array element and using the amplifier gain, electrical impedance, and noise characteristics. Measurements obtained with the signal analyzer and the temporal method are in good agreement with the model. The presented characterization technique can be extended to other micromachined ultrasonic transducer probe architectures, technologies, and amplification systems.

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Equivalent electrical circuits for electroacoustic MEMS design: a review

Liechti

2024

J. Micromech. Microeng.

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At the era of powerful computers, it’s tempting to employ finite element models early in the design phase of a device. However, especially for MEMS devices, the dimensional ratios and short wavelengths compared to the device’s dimensions, along with the involvement of multiple physics, can necessitate complex and computationally intensive models, making them impractical for optimization processes. Hence, reduced order models, like the lumped element model, are often preferred as they accurately represent complex system behavior within a defined frequency range. This review explores the use of lumped element models and their corresponding electrical equivalent circuits for simulating MEMS electro-acoustic devices, offering insights into their diverse applications within this specific domain.

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Lumped-Parameter Equivalent Circuit Modeling of CMUT Array Elements

Cited by 9 publications

References 65 publications

Studying the Effects of Mutual Acoustic Impedance on the Performance of Polymer-Based CMUTs

Studying the Effects of Mutual Acoustic Impedance on the Performance of Polymer-Based CMUTs

Thermal-Mechanical Noise Modeling and Measurements of a Row-Column Addressed CMUT Probe

Equivalent electrical circuits for electroacoustic MEMS design: a review

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