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References

1 
Cheney, M., Isaacson, D., and Newell, J. C. (1999) Electrical Impedance Tomography. SIAM Review 41(1), 85-101.DOI
2 
Fung, S., Adler, A., and Chan, A. D (2010) Using Distmesh as a Mesh Generating Tool for EIT. Journal of Physics: Conference Series 224(1), 012149.DOI
3 
Harikumar, R., Prabu, R., and Raghavan, S. (2013) Electrical Impedance Tomography (EIT) and Its Medical Applications: A Review. International Journal of Soft Computing and Engineering 3(4), 193-198.URL
4 
Jeon, D., Kim, M. K., Jeong, Y., Oh, J. E., Moon, J., Kim, D. J., and Yoon, S. (2022) High-accuracy Rebar Position Detection Using Deep Learning–based frequency-difference Electrical Resistance Tomography. Automation in Construction 135, 104116.DOI
5 
Jeon, D., Kim, M. K., Woo, H., Jeong, Y., Oh, J. E., Kim, D. J., and Yoon, S. (2021) Detecting Embedded Rebar in Cement Mortar by Frequency-difference Electrical Resistance Tomography. Automation in Construction 132, 103974.DOI
6 
Jeon, D., Kim, M., Kim, D., and Yoon, S. (2021) Detecting Rebar Inside Concrete using Frequency-difference Electric Resistance Tomography (ERT). KCI 2021 Fall Conference. 3-5 November 1999. Kyeongju, Korea; Korea Concrete Institute (KCI). 33(2), 525-526. (In Korean)URL
7 
Karhunen, K., Seppänen, A., Lehikoinen, A., Monteiro, P. J. M., and Kaipio, J. P. (2010) Electrical Resistance Tomography Imaging of Concrete. Cement and Concrete Research 40, 137-145.DOI
8 
Kim, M. K., Le, H. V., and Kim, D. J. (2021) Electromechanical Response of Smart Ultra-high Performance Concrete under External Loads Corresponding to Different Electrical Measurements. Sensors 21(4), 1281.DOI
9 
Kim, M. K., Yoon, S., and Kim, D. J. (2022) Different Electrical Voltage Responses of Cement Composites under Forward and Backward Current Directions. Case Studies in Construction Materials 16, e01118.DOI
10 
Lee, H. J., and Yim, H. J. (2017) Setting Time Evaluation of Concrete Using Electrical Resistivity Measurement. Journal of the Korea Concrete Institute 29(4), 361-369. (In Korean)DOI
11 
Sarode, V., Patkar, S., and Cheeran, A. N. (2013) Comparison of 2-D algorithms in ElT based Image Reconstruction. International Journal of Computer Applications 69(8).URL
12 
Smyl, D. (2020) Electrical Tomography for Characterizing Transport Properties in Cement-based Materials: A Review. Construction and Building Materials 244, 118299.DOI
13 
Smyl, D., Rashetnia, R., Seppänen, A., and Pour-Ghaz, M. (2017) Can Electrical Resistance Tomography be used for Imaging Unsaturated Moisture Flow in Cement-based Materials with Discrete Cracks?. Cement and Concrete Research 91, 61-72.DOI
14 
Vauhkonen, M., Lionheart, W. R., Heikkinen, L. M., Vauhkonen, P. J., and Kaipio, J. P. (2001) A MATLAB Package for the EIDORS Project to Reconstruct Two-dimensional EIT Images. Physiological Measurement 22(1), 107.DOI
15 
Yoon, S., Jeon, D., Oh, J. E., Kim, M. K., and Kim, D. J. (2022) Experimentally Validated Analytical Solutions to Homogeneous Problems of Electrical Impedance Tomography (EIT) on Rectangular Cement-based Materials. Applied Sciences 13(1), 335.DOI
16 
Yoon, S., Kim, M. K., Kim, T. U., Jeon, D., Song, H., Suh, J. I., Oh, J. E., and Kim, D. J. (2024) Enhancing Image Resolution in Single-side Electrical Resistance Tomography (ERT) by Utilizing Theoretical Sensitivity Analysis: Experimental Validation and Application to Cement Mortar. Journal of Building Engineering 84, 108480.DOI
17 
Zhdanov, M. S., and Keller, G. V. (1994) The Geoelectrical Methods in Geophysical Exploration. Methods in Geochemistry and Geophysics 31, I-IX.URL