Modeling and FPGA-based implementation of an efficient and simple envelope detector using a Hilbert Transform FIR filter for ultrasound imaging applications

Assef, Amauri Amorin; Ferreira, Breno Mendes; Maia, Joaquim Miguel; Costa, Eduardo Tavares

doi:10.1590/2446-4740.02417

Cited by 8 publications

(3 citation statements)

References 11 publications

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“…Given the clear and smooth envelope achieved through the Hilbert demodulation method, effectively emphasizing the regularity, periodicity, and frequency traits of the original signal, additional optimization steps are deemed unnecessary. Therefore, in this study, we employ a Hilbert Transform-based demodulation algorithm to extract the signal envelope of ultrasound signals [ 42 ].…”

Section: Methodsmentioning

confidence: 99%

A Novel Three-Point Localization Method for Bladder Volume Estimation

Yuan,

Shen,

Zhang

et al. 2024

Sensors

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The measurement of bladder volume is crucial for the diagnosis and treatment of urinary system diseases. Ultrasound imaging, with its non-invasive, radiation-free, and repeatable scanning capabilities, has become the preferred method for measuring residual urine volume. Nevertheless, it still faces some challenges, including complex imaging methods leading to longer measurement times and lower spatial resolution. Here, we propose a novel three-point localization method that does not require ultrasound imaging to calculate bladder volume. A corresponding triple-element ultrasound probe has been designed based on this method, enabling the ultrasound probe to transmit and receive ultrasound waves in three directions. Furthermore, we utilize the Hilbert Transform algorithm to extract the envelope of the ultrasound signal to enhance the efficiency of bladder volume measurements. The experiment indicates that bladder volume estimation can be completed within 5 s, with a relative error rate of less than 15%. These results demonstrate that this novel three-point localization method offers an effective approach for bladder volume measurement in patients with urological conditions.

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Section: Methodsmentioning

confidence: 99%

A Novel Three-Point Localization Method for Bladder Volume Estimation

Yuan,

Shen,

Zhang

et al. 2024

Sensors

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“…FPGAs are also introduced to speed up the acquisition of US imaging as well as to reduce the computational cost. Thus, Assef et al designed an envelope detector for US imaging using a Hilbert Transform finite impulse response filter on an FPGA [143]. The results showed high efficiency for real-time envelope detection with a cost minimization of up to 75%.…”

Section: Fpga In Medical Imagingmentioning

confidence: 99%

Hardware Architectures for Real-Time Medical Imaging

et al. 2021

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Medical imaging is considered one of the most important advances in the history of medicine and has become an essential part of the diagnosis and treatment of patients. Earlier prediction and treatment have been driving the acquisition of higher image resolutions as well as the fusion of different modalities, raising the need for sophisticated hardware and software systems for medical image registration, storage, analysis, and processing. In this scenario and given the new clinical pipelines and the huge clinical burden of hospitals, these systems are often required to provide both highly accurate and real-time processing of large amounts of imaging data. Additionally, lowering the prices of each part of imaging equipment, as well as its development and implementation, and increasing their lifespan is crucial to minimize the cost and lead to more accessible healthcare. This paper focuses on the evolution and the application of different hardware architectures (namely, CPU, GPU, DSP, FPGA, and ASIC) in medical imaging through various specific examples and discussing different options depending on the specific application. The main purpose is to provide a general introduction to hardware acceleration techniques for medical imaging researchers and developers who need to accelerate their implementations.

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“…For envelope detection, Liu et al performed inverse modulation and re-modulation processing to assimilate the Doppler distortion pattern of the acoustic signal [18]. Assef A A et al proposed the modeling and FPGA implementation of an efficient envelope detector based on the Hilbert transform approximation for medical ultrasound imaging applications [19]. In [20], Zhang et al implemented data compression of image pixels based on FPGA lookup tables.…”

Section: Introductionmentioning

confidence: 99%

The Ultrasound Signal Processing Based on High-Performance CORDIC Algorithm and Radial Artery Imaging Implementation

et al. 2023

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The radial artery reflects the largest amount of physiological and pathological information about the human body. However, ultrasound signal processing involves a large number of complex functions, and traditional digital signal processing can hardly meet the requirements of real-time processing of ultrasound data. The research aims to improve computational accuracy and reduce the hardware complexity of ultrasound signal processing systems. Firstly, this paper proposes to apply the coordinate rotation digital computer (CORDIC) algorithm to the whole radial artery ultrasound signal processing, combines the signal processing characteristics of each sub-module, and designs the dynamic filtering module based on the radix-4 CORDIC algorithm, the quadrature demodulation module based on the partitioned-hybrid CORDIC algorithm, and the dynamic range transformation module based on the improved scale-free CORDIC algorithm. A digital radial artery ultrasound imaging system was then built to verify the accuracy of the three sub-modules. The simulation results show that the use of the high-performance CORDIC algorithm can improve the accuracy of data processing. This provides a new idea for the real-time processing of ultrasound signals. Finally, radial artery ultrasound data were collected from 20 volunteers using different probe scanning modes at three reference positions. The vessel diameter measurements were averaged to verify the reliability of the CORDIC algorithm for radial artery ultrasound imaging, which has practical application value for computer-aided clinical diagnosis.

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Modeling and FPGA-based implementation of an efficient and simple envelope detector using a Hilbert Transform FIR filter for ultrasound imaging applications

Cited by 8 publications

References 11 publications

A Novel Three-Point Localization Method for Bladder Volume Estimation

A Novel Three-Point Localization Method for Bladder Volume Estimation

Hardware Architectures for Real-Time Medical Imaging

The Ultrasound Signal Processing Based on High-Performance CORDIC Algorithm and Radial Artery Imaging Implementation

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