Published August 31, 2020 | Version v1
Journal article Open

DEVELOPMENT AND RESEARCH OF A VIRTUAL TEST BENCH FOR ELECTRIC IMPEDANCE TOMOGRAPHY CHANNEL MAIN COMPONENTS SIMULATION

Authors/Creators

  • 1. Federal State Budget Educational Institution of Higher Education "Platov South-Russian State Polytechnic University (NPI)"

Description

When developing and determining the principles of construction and algorithms for the operation of electrical impedance tomography devices, it is necessary to verify the adequacy of the adopted circuitry solutions, their technical level and the possibility of practical implementation. To assess the technical capabilities and operating parameters of the device and its components, it is advisable to develop specialized tools for research and adjustment. Considering that the devices for electrical impedance tomography being developed are hardware and software solutions, and their components are complete electronic units that interact with each other, it seems possible to develop an experimental bench.

The development of a virtual automated experimental bench for preliminary tests of the main components of the electrical impedance tomography channel is proposed. On the basis of the operating principles of the hardware bench, the principles of building a virtual bench are formulated. The correspondence of the main elements of hardware and virtual benches in terms of their functional purpose is shown.

For each of the software components of the virtual bench, input actions and output parameters are determined.

A schematic diagram of the analog part of the electrical impedance tomography channel has been developed to test the performance of the virtual bench. Studies have shown that the developed virtual bench is suitable for preliminary testing of all analog components of the channel.

The use of the developed virtual bench will allow optimizing the time and material costs for conducting experimental research in the process of developing hardware for technical means of electrical impedance tomography

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References

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