Iurii Zgoda scite author profile

Iurii Zgoda

5Publications

0Citation Statements Received

26Citation Statements Given

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Saint Petersburg State University of Architecture and Civil Engineering

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High performance modeling of the stress-strain state of thin-walled shell structures with the use of deep learning

Zgoda¹

2023

Naučno-teh. vestn. inf. tehnol. meh. opt.

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Computer modeling is one of the most common approaches to the analysis of thin-walled shell structures stress-strain state analysis. It requires considerable time costs and high-performance hardware, especially when it is necessary to conduct a comparative analysis of various shell configurations. In this paper, we propose the use of deep learning methods to improve performance of this process. The purpose of work is to develop methods for high-performance computer simulation of thin-walled shell structures using deep neural networks, allowing to take into account geometric and physical properties of the structure as well as the load applied to it. A training approach and deep neural network architecture were developed to perform computer modeling of the stress-strain state of the shell. To form a training dataset, a computational experiment was carried out to simulate 3904 different configurations of doubly curved shallow shells that differ in linear dimensions, curvature radii, and materials used. Based on this dataset, 30 deep neural networks with different architectures were trained. To determine the optimal architecture in terms of modeling accuracy, mean absolute percentage error with clipping near-zero samples was calculated for each of the neural networks based on the test dataset. A network has been developed that allows calculating the stress-strain state of different shell configurations under an arbitrary uniformly distributed load. This is the first solution in the field of shell neural network modeling that allows us to vary the applied load, geometric and physical parameters of the shell and obtain calculation results at an arbitrary point of its middle surface. Performance measurements were carried out which show that the developed neural network allows simulating the stress-strain state of a shell structure 2117 times faster compared to the duration of solving the same problem by classical simulation. The modeling error using the network is at an acceptable level. An original architecture of a neural network for modeling the stress-strain state of shells was proposed which, through minor modifications, can be adapted for high-performance modeling of other building structure types. In accordance with the described architecture, a deep neural network was trained which reduces the computation time by several orders of magnitude. The results obtained are of high practical importance for researchers in the field of thin-walled shells modeling since they allow us to significantly reduce the time costs associated with conducting computational experiments. One of the possible applications for developed solution is prototyping of various shell configurations. Once prototyping is complete, the most efficient shell configurations can be explored in detail using classical computer simulation techniques. Keywords thin-walled shell structures, stress-strain state, deep learning, neural networks, computer modeling, Julia programming language For citation: Zgoda Iu.N. High performance modeling of the stress-stra...

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Virtual and Augmented Reality Technologies in Training Architecture and Civil Engineering Specialists

Zgoda

Semenov

2020

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This paper discusses the aspects of training architecture and civil engineering specialists using virtual and augmented reality technologies. It also addresses the issues of training specialists in software development for visualization of buildings and structures information models. The paper deals with the selection of optimal hardware and software for the most effective learning process and provides an overview of the most relevant areas of scientific research in this field.

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Stress-strain state interactive visualization of the parametrically-defined thin-shell structures with the use of AR and VR technologies

Semenov¹,

Zgoda²

2020

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The paper describes a mathematical model of changes in the geometry of thin-shell structures for visualization of the analysis data on their stress-strain state (SSS). Based on this mathematical model, a module for shell SSS visualization using VR and AR technologies was developed. The interactive visualization environment Unity 2019.3 and C# programming language were used. The interactive visualization module makes a 3D image of a shell structure and visualizes the SSS either through heat maps over the shell or through the changes in the shell geometry via the shell type, its geometric characteristics, and SSS analysis data (transferred to the visualization module by means of a JSON file). While working on the visualization module, the authors developed a software system that makes it possible to visualize any 3D surface with coordinate axes (including numbers with a pitch determined automatically), visualize heat maps with a graduated scale, visualize a mesh over the graph to improve the perception of the surface deformations. The middle surface deformation can also performed via SSS analysis data. This solution increases the efficiency of the work of specialists in civil engineering and architecture and can be used when training specialists in courses on thin-shell structures and procedural geometry.

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Visualization of the Stress-Strain State of Shell Structures Using Virtual and Augmented Reality Technologies

Semenov

Zgoda

2020

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The paper describes a mathematical model of changes in the geometry of thin-shell structures for visualization of the analysis data on their stress-strain state (SSS). Based on this mathematical model, a visualization module for shell SSS visualization using VR and AR technologies was developed. The interactive visualization environment Unity 2019.3 and C# programming language were used. The interactive visualization module makes a 3D image of a shell structure and visualizes the SSS either through heat maps over the shell or through the changes in the shell geometry on the basis of the shell type, its geometric characteristics, and SSS analysis data (transferred to the visualization module by means of a JSON file). While working on the visualization module, the authors developed a system of components that makes it possible to visualize any 3D surface with coordinate axes (including numbers with a pitch determined automatically), visualize heat maps with a graduated scale, visualize a mesh over the graph to improve the perception of the surface deformations. The middle surface can also be deformed on the basis of SSS analysis data. This solution increases the efficiency of the work of specialists in civil engineering and architecture and can be used when training specialists in courses on thin-shell structures and procedural geometry.

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The sunflower equation: novel stability criteria

2021

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Iurii Zgoda

High performance modeling of the stress-strain state of thin-walled shell structures with the use of deep learning

Virtual and Augmented Reality Technologies in Training Architecture and Civil Engineering Specialists

Stress-strain state interactive visualization of the parametrically-defined thin-shell structures with the use of AR and VR technologies

Visualization of the Stress-Strain State of Shell Structures Using Virtual and Augmented Reality Technologies

The sunflower equation: novel stability criteria

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