PRACA POGLĄDOWA
Image reconstruction and bladder stimulation using electrical impedance tomography
 
Więcej
Ukryj
1
Lubelska Akademia WSEI
 
2
Institute of Philosophy and Sociology of the Polish Academy of Sciences
 
 
Data nadesłania: 28-06-2024
 
 
Data akceptacji: 18-07-2024
 
 
Data publikacji: 20-08-2024
 
 
Autor do korespondencji
Robert Pietrzyk   

Lubelska Akademia WSEI
 
 
JoMS 2024;57(Numer specjalny 3):668-683
 
SŁOWA KLUCZOWE
DZIEDZINY
_Inne
 
STRESZCZENIE
Impedance tomography (EIT) is an imaging technique that harnesses differences in electrical conductivity to visualize the interior of objects. Despite limitations such as low resolution and nonlinearity of current distribution, its potential in medicine and industry is a source of fascination. The research in this work is a step towards unlocking this potential, focusing on improving the quality of EIT image reconstruction, particularly in bladder modeling. A key element is regularization techniques, including Laplace matrices and the iterative Gauss-Newton algorithm, which balance matching accuracy and image smoothness. In the practical part, simulations were conducted on dense and sparse meshes. Modeling the urinary bladder as a rotational ellipse significantly influences the interpretation of data by algorithms, a crucial factor for the accuracy of reconstruction. Various electrode configurations were also analyzed, revealing the impact of their arrangement on electrical properties and imaging quality. Iterative testing led to identifying optimal electrode placement and grid configuration, underscoring the importance of precise modeling for obtaining high-quality images. The results underscore the critical role of appropriately selecting the regularization parameter in minimizing reconstruction errors.
Licencja
REFERENCJE (7)
1.
Dunne, E., Santorelli, A., McGinley, B., Leader, G., O’Halloran, M., Porter, E. (2018). Super-vised Learning Classifiers for Electrical Impedance-based Bladder State Detection. Scien-tific Reports 8, 1, 5363.
 
2.
Kłosowski, G., Rymarczyk, T. (2017). Using Neural Networks and Deep Learning Algorithms in Electrical Impedance Tomography. Informatyka, Automatyka, Pomiary w Gospodarce i Ochronie Środowiska 7, 3, 99-102.
 
3.
Leron, E., Weintraub, A. Y., Mastrolia, S. A., Schwarzman ,P. (2018). Overactive Bladder Syn-drome: Evaluation and Management. Curr. Urol. 11, 3, 117—125.
 
4.
Rodríguez, P. (2013). Total Variation Regularization Algorithms for Images Corrupted with Different Noise Models: A Review. Journal of Electrical and Computer Engineering, 217021.
 
5.
Rymarczyk, T., Kłosowski. G., Guzik. M., Niderla. K., Lipski. J. (2021). Hybrid Machine Learning in Electrical Impedance Tomography. Prz. Elektrotech. 1, 12, 171—174.
 
6.
Rymarczyk, T., Nita, P., Vejar, A., Stefaniak, B., Sikora, J. (2019). Electrical tomography sys-tem for Innovative Imaging and Signal Analysis. Przegląd Elektrotechniczny 95(6), 133–136.
 
7.
Rymarczyk, T., Szulc, K. (2019). Minimization of Objective Function in Electrical Impedance Tomography by Topological Derivative. Prz. Elektrotech. 1, 6 (June 2019), 139-142.
 
eISSN:2391-789X
ISSN:1734-2031
Journals System - logo
Scroll to top