Mandelbrot, B. B. 1982. Fractal geometry of nature. San Francisco, CA: W. H. Freeman and Co. 460 p.
Rudakova, О.А. 2012. Fraktal'nyy podkhod k analizu osobennostey ustalostnogo razrusheniya svarnykh shvov [Fractal approach to the analysis of fatigue failure char-acteristics welds]. Vestnik Permskogo natsional'nogo issledovatel'skogo politekhniche- skogo universiteta. Mashinostroenie, materialovedenie [Bulletin of the Perm National Research Polytechnic University. Mechanical Engineering, Materials Science] 14:102107.
Abdel-Qader, I., O. Abudayyeh, and M.E. Kelly. 2003. Analysis of edge-detection techniques for crack identification in bridges. J. Comput. Civil Eng. 17(4):255-263.
Yamaguchi, T., S. Nakamura, R. Saegusa, and S. Hashimoto. 2008. Image-based crack detection for real concrete surfaces. IEEJ T. Electr. Electr. 3:128-135.
Abdel-Qader, I., S. Pashaie-Rad, O. Abudayyeh, and S. Yehia. 2006. PCA-based algorithm for unsupervised bridge crack detection. Adv. Eng. Softw. 37(12):771-778.
Prasanna, P., K. Dana, N. Gucunski, and B. Basily. 2012. Computer-vision based crack detection and analysis. Proc. SPIE 8345:115.
Lattanzi, D., and G. R. Miller. 2014. Robust automated concrete damage detection algorithms for field applications. J. Comput. Civil Eng. 28(2):253-262.
Itzhar, D., I. Dinstein, and T. Zilberberg. 1981. Pitting corrosion evaluation by computer image processing. Corros. Sci. 21(1):17-22.
Quinn, M. J., M. G. Bailey, B. M. Ikeda, andD. W. Shoesmith. 1993. Image-analysis techniques for investigating localized corrosion processes. Atomic Energy of Canada Ltd. 52 p.
Yan, Y. H., J.H. Gao, Y. Liu, and S. C. Lei. 2002. Recognition and classification of metal fracture surface models based on wavelet transform. Acta Metall. Sin. 38(3):309-314.
Enikeev, M. R., M. A. Maleeva, and I. M. Gubaydullin. 2015. Komp'yuternoe zrenie v zadache issledovaniya mekhanizma razvitiya korrozionnykh porazheniy [Computer vision in identification of corrosion processes]. Sistemy upravleniya i informatsionnye tekhnologii [Automat. Rem. Contr.] 59(1. 1): 198-204.
Dalal, N., and B. Triggs. 2005. Histograms of oriented gradients for human detection. IEEE Computer Society Conference on Computer Vision and Pattern Recognition Proceedings. IEEE. 1:886-893.
Vapnik, V.N. 1999. An overview of statistical learning theory. IEEE T. Neural Networ. 10(5):988-999.
Gubaydullin, I. M., and Yu.B. Lind. 2010. Informatsionno-analiticheskaya sistema resheniya zadach khimicheskoy kinetiki na osnove sovremennykh vysokoproizvodi- tel'nykh vychisleniya [Information-analytical system for solving problems of chemical kinetics based on modern high-performance computing]. Vestnik Omskogo Universiteta [Bulletin of Omsk University] 4:137-146.
Bogdanov, R.I. 2012. Zakonomernosti korrozionnogo rastreskivaniya pod napryazhe- niem trubnoy stali X70 v gruntovykh elektrolitakh s pH, blizkim k neytral'nomu [The patterns of stress-corrosion cracking of X70 tube steel in ground electrolytes with a pH close to neutral]. PhD Diss. Moscow: IPCE RAS. 196 p.

Title

INFORMATION COMPUTATION AND ANALYTICAL SYSTEM OF ESTIMATION AND FORECASTING OF CORROSION PROCESSES ON THE SURFACE OF STEEL AND ALUMINUM

Journal

Systems and Means of Informatics
Volume 27, Issue 3, pp 155-170

Cover Date

2017-09-30

DOI

10.14357/08696527170313

Print ISSN

0869-6527

Publisher

Institute of Informatics Problems, Russian Academy of Sciences

Additional Links

Key words

information and analytical system; metal corrosion; computer vision

Authors

M. R. Enikeev

, I. M. Gubaydullin

, and M. A. Maleeva

Author Affiliations

Institute of Petrochemistry and Catalysis, Russian Academy of Sciences, 141 Pr. Oktyabria, Ufa 450075, Republic of Bashkortostan, Russian Federation

Ufa State Petroleum Technological University, 1 Kosmonavtov Str., Ufa 450062, Republic of Bashkortostan, Russian Federation

Frumkin Institute of Physical Chemistry and Electrochemistry, Russian Academy of Sciences, 31 Leninsky Prosp., Moscow 199071, Russian Federation

Systems and Means of Informatics