Brain electrical impedance tomography method based on GAN

A technology of electrical impedance tomography and imaging method, applied in the field of biomedical imaging, can solve the problem of low precision of reconstructed images, achieve fast imaging speed, reduce requirements, improve solution accuracy and image reconstruction quality

Inactive Publication Date: 2020-01-24
ZHEJIANG UNIV OF TECH
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Problems solved by technology

[0004] In order to overcome the lack of high accuracy of existing reconstructed images, the present invention provides a high-precision GAN-based brain electrical impedance tomography method. Compared with shallow artificial neural networks, deep learning has more hidden Layer, with excellent feature learning ability, can realize complex function approximation by learning a deep nonlinear network structure, and express complex functions with fewer parameters

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  • Brain electrical impedance tomography method based on GAN
  • Brain electrical impedance tomography method based on GAN
  • Brain electrical impedance tomography method based on GAN

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Embodiment Construction

[0030] The present invention will be further described below in conjunction with accompanying drawing.

[0031] refer to figure 1 with figure 2 , a GAN-based brain electrical impedance tomography method, the present invention uses data collected by laboratory EIT hardware equipment as a data set. The method includes data collection, data preprocessing, generative confrontation network model training and test set generation.

[0032] The present invention comprises the following steps:

[0033] S1: Obtain the original data, collect the boundary voltage sequence through the experimental device, grid the object field area, and obtain the corresponding real conductivity distribution map as the sample data;

[0034] S2: Data preprocessing, normalize the collected boundary voltage sequence and convert the sequence into a two-dimensional graph;

[0035] S3: Build a generative confrontational network, use the sample data set to train the network, and obtain the nonlinear mapping ...

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Abstract

The invention relates to a brain electrical impedance tomography method based on GAN, which comprises the following steps: 1) acquiring original data, acquiring a boundary voltage sequence through anexperimental device, and performing grid subdivision on an object field area to obtain a corresponding real conductivity distribution diagram as sample data; 2) preprocessing data, performing normalization processing on the acquired boundary voltage sequence and converting the sequence into a two-dimensional graph; 3) constructing a generative adversarial network, and training the network by usinga sample data set to obtain a nonlinear mapping relationship between the boundary measurement voltage sequence and the conductivity distribution sequence; and 4) generating a corresponding conductivity distribution diagram from the untrained voltage sequence through the trained network. According to the method, the nonlinear problem during electrical impedance tomography inverse problem solving is solved, the precision of reconstructed images is improved, the noise immunity is high, the requirement for the noise immunity of an imaging system is lowered, and the imaging speed is high.

Description

technical field [0001] The invention belongs to the technical field of biomedical imaging, and relates to deep learning and image reconstruction, in particular to a GAN-based brain electrical impedance tomography method. Background technique [0002] Bioelectrical impedance tomography (Electrical Impedance Tomography, EIT) technology is a non-invasive detection imaging technology. Its principle is to apply a weak current to the surface electrode of the human body and measure the voltage value on other electrodes. According to the voltage The relationship between the electrical conductivity and the current reconstructs the image of the conductivity distribution or its change inside the object field. Due to the characteristics of non-radiation, non-invasive, fast imaging speed and low cost, EIT has broad application prospects in the field of medical imaging. [0003] The EIT image reconstruction process has nonlinear, ill-posed and ill-posed problems, which makes image recons...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): A61B5/053
CPCA61B5/0536A61B5/7267
Inventor 宣琦袁琴孙翊杰翔云
Owner ZHEJIANG UNIV OF TECH
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