A reconfigurable arbitrary waveform generator using PWM modulation for ultrasound research

Assef, Amauri Amorin; Maia, Joaquim Miguel; Schneider, Fábio Kurt; Button, Vera L. S. N.; Costa, Eduardo Tavares

doi:10.1186/1475-925x-12-24

Cited by 16 publications

(5 citation statements)

References 22 publications

(51 reference statements)

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“…The function generator utilized a CMOS synthesizer (AD9851, Analog Device, Norwood, MA) to produce pulse-width modulated (PWM) signals with duty cycles ranging from 20 to 80% at 2 MHz frequency. The high-voltage ultrasonic signal transmission, with a PWM voltage amplitude up to 50 V, was achieved using four high-speed dual MOSFET drivers (MD1213, Microchip Technology, Chandler, AZ) and N- and P-channel MOSFETs (TC6320, Microchip Technology, Chandler, AZ) [23–25]. A maximum amplitude of 50 V was selected in the present study to achieve the target temperature (around 60 °C) with minimum driver size.…”

Section: Methodsmentioning

confidence: 99%

Development of temperature controller-integrated portable HIFU driver for thermal coagulation

et al. 2019

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Background Temperature monitoring during high-intensity focused ultrasound (HIFU) therapy on tissue is essential to regulate the degree of thermal coagulation and to achieve the desired treatment outcomes eventually. The aim of the current study was to design and investigate the feasibility of a proportional–integral–derivative (PID) temperature controller-integrated portable HIFU driver for thermal coagulation. Methods A portable HIFU driver was designed and operated at a maximum output voltage of 50 V with pulse-width modulation signals at 2 MHz. The temperature of ex vivo bovine liver tissue was monitored using a K-type thermocouple during the 2-MHz HIFU exposure. Results The tissue temperature was maintained at 60 °C using a PID controller-integrated HIFU driver that modulated the output voltage during the 300-s HIFU exposure. The ex vivo testing demonstrated that the tissue temperature at the focal point approached the chosen temperature, i.e., 60 °C, within 70 s. The temperature was maintained with a deviation of less than 4 °C until the HIFU driver voltage was turned off at 300 s. Conclusions The designed PID controller-integrated HIFU driver can be used as a small portable tool to regulate the tissue temperature in real time and achieve thermal coagulation via HIFU sonication.

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Section: Methodsmentioning

confidence: 99%

Development of temperature controller-integrated portable HIFU driver for thermal coagulation

et al. 2019

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“…Initially, the functionality of the MD2131 transmitter was tested by generating an arbitrary pulse with the Gaussian profile and 35% relative bandwidth, using the method presented by Assef et al (2013). In order to demonstrate the feasibility of the US research system, two applications are illustrated below.…”

Section: Methodsmentioning

confidence: 99%

A flexible multichannel FPGA and PC-Based ultrasound system for medical imaging research: initial phantom experiments

2015

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Introduction: In this paper, we present the initial results of a fully programmable 128-channel FPGA and PC-based system that has been developed for medical ultrasound (US) imaging research in our University laboratory (Federal University of Technology -Paraná, Brazil). Methods: In order to demonstrate the feasibility of the US research system, two applications involving unfocused plane wave transmission and conventional B-mode beamforming were evaluated using a commercial tissue-mimicking phantom and a 3.2 MHz 128-element convex array transducer. Results: Testing results show that the hardware platform is able to synthesize arbitrary pulses up to 100 Vpp with second order harmonic distortion below 80 dB. For the first application, a 41-tap digital FIR bandpass filter was applied to the acquired RF echoes, sampled at 40 MHz with 12-bit resolution, to improve the noise suppression. In the second application, after offline apodization weighting, filtering, delay-and-sum processing, envelope detection, log compression and scan conversion, the reconstructed B-mode image is displayed over a 50 dB range. Conclusion: The presented results indicate that the open US imaging system can be used to support different ultrasonic transmission and reception strategies, which typically cannot be implemented in conventional data flow architectures that are mainly based on hardware.

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“…Yet, their power efficiency is higher than that for linear power amplifiers. As well, space integration is a plus, since the market offers ICs that integrate 16 channels, five-level pulsers in 1 cm 2 to support arbitrary waveform generation [65] .…”

Section: Architecture Of Open Platforms: Software-based Platformsmentioning

confidence: 99%

Ultrasound Open Platforms for Next-Generation Imaging Technique Development

Boni

Freear

et al. 2018

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

113

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Open platform (OP) ultrasound systems are aimed primarily at the research community. They have been at the forefront of the development of synthetic aperture, plane wave, shear wave elastography, and vector flow imaging. Such platforms are driven by a need for broad flexibility of parameters that are normally preset or fixed within clinical scanners. OP ultrasound scanners are defined to have three key features including customization of the transmit waveform, access to the prebeamformed receive data, and the ability to implement real-time imaging. In this paper, a formative discussion is given on the development of OPs from both the research community and the commercial sector. Both software- and hardware-based architectures are considered, and their specifications are compared in terms of resources and programmability. Software-based platforms capable of real-time beamforming generally make use of scalable graphics processing unit architectures, whereas a common feature of hardware-based platforms is the use of field-programmable gate array and digital signal processor devices to provide additional on-board processing capacity. OPs with extended number of channels (>256) are also discussed in relation to their role in supporting 3-D imaging technique development. With the increasing maturity of OP ultrasound scanners, the pace of advancement in ultrasound imaging algorithms is poised to be accelerated.

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A reconfigurable arbitrary waveform generator using PWM modulation for ultrasound research

Cited by 16 publications

References 22 publications

Development of temperature controller-integrated portable HIFU driver for thermal coagulation

Development of temperature controller-integrated portable HIFU driver for thermal coagulation

A flexible multichannel FPGA and PC-Based ultrasound system for medical imaging research: initial phantom experiments

Ultrasound Open Platforms for Next-Generation Imaging Technique Development

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