Abstract.

The method of computed tomography (CT) is a hardware-software nondestructive diagnostic method. The area of its application is quite extensive. It spreads from medicine for preclinical visualization of problem areas, monitoring of surgical intervention, or monitoring the dynamics of results of such intervention to usage in industrial tomographic imaging for the control of finished products, in flaw detection for monitoring the quality of permanent joints or for testing products at different technological stages during creation of new technological processes. CT is also an important tool for conducting the latest scientific research. The hardware part of the method is a measuring system, which includes a line of nodes. The program part of the CT method is independent, full and necessary. The modular principle used in software development allows for the development of versions for various computing platforms. And the final phase is the stage of recognizing the reconstructed images, because, as it often happens with rapidly developing methods, the final users of the method would like to use it also as a measurement tool. So, we have to solve the problem of searching in the probed volume of interesting objects, determine their position, dimensions and describe the form. Information taken directly from tomographic projections, could help in this. The article formulates the problem of tomography, provides an overview of Russian manufacturers of nodes that form the basis of the hardware-software tomographic system, including potential computing platforms.

Keywords:

computed tomography, tomography system, Elbrus, Baikal, KOMDIV.

PP. 90-99.

DOI: 10.14357/20790279180510

References

1. Natterer, F., The Mathematics of Computerized Tomography, Springer Vieweg, 1986
2. Voprosy kibernetiki. Matematicheskiye problemy tomografii [Questions of cybernetics. Mathematical problems of tomography.]. Sb. statey pod. red. I.M. Gel’fanda i S.G. Gindikina. Moskva, Nauchnyy sovet po kompleksnoy probleme “Kibernetika” [Sat. articles under. Ed. I.M. Gelfand and S.G. Gindikin. Moscow, Scientific Council on the Complex Problem “Cybernetics”], 1990.
3. Chukalina M.V., Buzmakov A.V., Nikolayev D.P., Chulichkov A.I., Karimov M.G., Rasulov G.A., Senin R.A., Asadchikov V.Ye. Rentgenovskaya mikrotomografiya na laboratornom istochnike: tekhnika izmereniy i sravneniye algoritmov rekonstruktsii [X-ray microtomography on a laboratory source: measurement technique and comparison of reconstruction algorithms] // Izmeritel’naya tekhnika [Measuring techniques], N. 2, 2008, p. 19-24.
4. M. Chukalina, S. Zaitsev, A. Simionovici, C.J. Vanegas. Two X-ray fluorescence microtomography experimental set ups: standard and confocal collimator apparatus. Spectrochimica Acta. Part B.6-7, 62, 2007, 544-548.
5. M. Goswami, S. Shakya, A. Saxena, P Munshi. Optimal Spatial Filtering Schemes and Compact Tomography Setups. Journal Research in Nondestructive Evaluation, 27(2), 2016, 69-85.
6. M.L. Taubin, D.A. Chesnokov, and A.A. Pavlov. Cathodes for medical purpose X-ray tubes. 3rd International Conference on X-ray Technique IOP Publishing IOP Conf. Series: Journal of Physics: Conf Series 808(2017) 012004.
7. V.E. Asadchikov, A.V. Buzmakov, S.V. Savel’yev. Rentgenovskaya mikrotomografiya [X-ray microtomography] // Fundamental’nyye nauki – meditsine: Biofizicheskiye meditsinskiye tekhnologii: Monografiya: V 2-kh t.: T. 1 c 390-445/ Pod red. A.I. Grigor’yeva i YU.A. Vladimirova. [Fundamental sciences for medicine: Biophysical medical technologies: Monography: In 2 volumes: V. 1 p. 390-445 / Ed. A.I. Grigorieva and Yu.A. Vladimirova] – Moscow: MAX Press, 2015. p. 392.
8. M.L. Taubin, A.A. Yaskolko, D.A. Chesnokov. Otsenka temperatury fokusnogo pyatna anodov moshchnykh rentgenovskikh trubok [Estimation of the temperature of the focal spot of the anodes of powerful X-ray tubes]. Meditsinskaya tekhnika [Medical technology], N. 5, 2017 / p. 18-20
9. Nano news net, http://www.nanonewsnet.ru/news/2014/v-zelenograde-planiruyut-proizvoditrentgenovskie
10. Tehindustriya, aspect-bez.ru
11. Parsek, spectrometric ADCs, http://www.parsek.ru/ru/index.html
12. Closed Joint-Stock Company Research and Production Center “ASPECT”, http://aspect.dubna.ru/new/page.php?page=430
13. I.A. Ivanov, D.N. Karimov, I.L. Snetkov, O.V. Palashov, V.V. Kochurikhin, A.V. Masalov, V.A. Fedorov, D.A. Ksenofontov, Y.K. Kabalov. Study of the influence of Tb-Sc-Al garnet crystal composition on Verdet constant // Optical Materials. 2017. V. 66. P.106-109.
14. Antonov E.V., Bagdasarov KH.S., Butashin A.V., Kanevskiy V.M., Nabatov B.V., Fedorov V.A. Kristally YAG: Yb dlya shirokoaperturnykh lazerov i usiliteley [YAG: Yb crystals for wide-aperture lasers and amplifiers] // Perspektivnyye materialy [Perspective materials], 2012. N. 6. p. 23-26.
15. Bogolubov, E., Bugaenko, O., Kuzin, S., Mikerov, V., Monitch, E., Monitch, A., Pertsov, A. (2005). CCD detectors for fast neutron radiography and tomography with a cone beam. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 542(1-3), 187-191.
16. Nersesyan N.S., Shevelev A.E, Chugunov I.N., Khil’kevich E.M., Gin D.B., Polunovskiy I.A., Doynikov D.N., Naydenov V.O., Gorodkov I.V. NEYTRONNYY LIH-ATTENYUATOR DLYA GAMMA-SPEKTROMETRA ITER [NEUTRON LIH-ATTENUATOR FOR THE ITER GAMMASPECTROMETER]. Uspekhi prikladnoy fiziki [Advances in applied physics]. 2016. V. 4. N. 3. p. 294-300.
17. Kulikov N.A., Bazhenova O.B., Serbin V.A. ZAVOD RENTGENOVSKIKH PRIBOROV – ZAO «SVETLANA-RENTGEN» [FACTORY OF X-RAY INSTRUMENTS – CJSC “SVETLANAX-RAY”]. Peterburgskiy zhurnal elektroniki [Petersburg Journal of Electronics]. 2008. N. 2-3. P. 167-176.
18. Savitskiy YA.V. Sovremennyye vozmozhnosti metoda rentgenovskoy tomografii pri issledovanii kerna neftyanykh i gazovykh mestorozhdeniy [Modern possibilities of the X-ray tomography method in the study of cores of oil and gas fields]. Vestnik Permskogo natsional’nogo issledovatel’skogo politekhnicheskogo Universiteta. Geologiya. Neftegazovoye i gornoye delo [Bulletin of the Perm National Research Polytechnic University. Geology. Oil and gas and mining]. 14(15), 2015, 28-37.
19. NTTS “Amplituda”, http://amplituda.ru/catalog/petrofizika/oborudovanie/laboratornye-issledovaniya-kerna/rkt-160-rentgenovskiytomograf
20. Geology, X-ray computed tomography core in the formation conditions “RKT-225-PL”, http:// http://www.geologika.ru/13-produkty/rentgenovskijanaliz/
21. V.E. Asadchikov, V.G. Babak, A.V. Buzmakov, YU.P. Dorokhin, I.P. Glagolev, YU.V. Zanevskiy, N.V. Zryuyev, YU.S. Krivonosov, V.F. Mamich, L.A. Moseyko, N.I. Moseyko, B.V. Mchedlishvili, S.V. Savel’yev, R.A. Senin, L.P. Smykov, G.A. Tudosi, V.D. Fateyev, S.P. Chernenko, G.A. Cheremukhina, Ye.A. Cheremukhin, A.I. Chulichkov, YU.N. Shilin, V.A. Shishkov. “Rentgenovskiy difraktometr s podvizhnoy sistemoy izluchatel’-detektor” [X-ray diffractometer with a mobile radiator-detector system] // Pribory i tekhnika eksperimenta [Devices and experimental technique], 3, c. 99-107 (2005)
22. V.E. Asadchikov, A.V. Buzmakov, D.A. Zolotov, R.A. Senin, A.S. Geranin. Laboratornyye rentgenovskiye mikrotomografy na monokhromaticheskom izluchenii [Laboratory X-ray microtomographs on monochromatic radiation]. Kristallografiya [Crystallography], 2010. v. 55. n. 1. p. 167–176.
23. A.V. Buzmakov, A.S. Ingacheva, M.V. Chukalina, D.A. Zolotov, A.V. Vatsyuk, K.O. Dorina, D.E. Ichalova, P.V. Matavina, R.R. Mardanov, A.N. Oparin, V.A. Sobolev, M. Caselle, S. Chilingaryan, M. Balzer, T. Baumbach, V.E. Asadchikov. Novyy apparatno-programmnyy kompleks s mnogopol’zovatel’skim dostupom dlya provedeniya tomograficheskikh izmereniy [New hardware-software complex with multi-user access for tomographic measurements] // Sbornik materialov Vos’mogo mezhdunarodnogo nauchnogo seminara i Shestoy mezhdunarodnoy molodezhnoy nauchnoy shkoly-seminara “Sovremennyye metody analiza difraktsionnykh dannykh i aktual’nyye problemy rentgenovskoy optiki” [Collected materials of the Eighth International Scientific Seminar and the Sixth International Youth Scientific School-Seminar “Modern Methods for Analysis of Diffraction Data and Actual Problems of X-ray Optics”], 22 June – 02 July 2016., Velikiy Novgorod, pp. 30-31.
24. Matthew Chalmers. ESRF news, March (2013) http://www.esrf.eu/Instrumentation/news/Tangocontrolsystem
25. V.E. Prun, A.V. Buzmakov, D.P. Nikolayev, M.V. Chukalina, V.E. Asadchikov. Vychislitel’no effektivnyy variant algebraicheskogo metoda komp’yuternoy tomografii [Computationally effective variant of the algebraic method of computed tomography] // Avtomat. i telemekh. [Automation and Remote Control], 2013, N. 10, 86–97
26. Fokin E.A., Savel’yev S.V., Gulimova V.I., Asadchikov V.E., Senin R.A., Buzmakov A.V. Morfogenez i prostranstvennaya organizatsiya konkrementov epifiza cheloveka pri bolezni Al’tsgeymera, shizofrenii i alkogolizme [Morphogenesis and spatial organization of concrements of the human epiphysis in Alzheimer’s disease, schizophrenia and alcoholism]. Arkhiv patologii [Archive of pathology], 2006, v.68, N. 5, p. 20-22.
27. D.A. Zolotov, A.V. Buzmakov, A.A. Shiryayev, V.E. Asadchikov. Rentgenovskaya komp’yuternaya tomografiya yestestvennykh almazov i soderzhashchikhsya v nikh mikrovklyucheniy [X-ray computed tomography of natural diamonds and microinclusions contained in them] // Poverkhnost’. Rentgenovskiye, sinkhrotronnyye i neytronnyye issledovaniya [Surface. X-ray, synchrotron and neutron studies]. 2009. N. 9, p. 3-8.
28. Senin R.A., Khlebnikov A.S., Vyazovetskova A.E., Blinov I.A., Golubitskiy A.O., Kazakov I.V., Vorob’yev A.A., Buzmakov A.V., Asadchikov V.E., Shishkov V.A., Mukhamedzhanov E.KH., Koval’chuk M.V. MODERNIZIROVANNAYA STANTSIYA “RENTGENOVSKAYA TOPOGRAFIYA I MIKROTOMOGRAFIYA” NA KURCHATOVSKOM ISTOCHNIKE SINKHROTRONNOGO IZLUCHENIYA [MODERNIZED STATION “X-RAY TOPOGRAPHY AND MICROTOMOGRAPHY” ON THE KURCHATOV SOURCE OF SYNCHROTRON RADIATION] // Kristallografiya [Crystallography]. 2013. V. 58. N. 3. p. 510.
29. Gan’zha, D. 2016. IBS rasshiryayet svoy portfel’ giperkonvergentnykh resheniy [IBS is expanding its portfolio of hyper-convergent solutions] // Zhurnal setevykh resheniy LAN [LAN Networking Log], (6), pp.2-6a.
30. Kim A.K., Perekatov V.I., Ermakov S.G. Mikroprotsessory i vychislitel’nye kompleksy semeystva «El’brus» [Microprocessors and computing systems of the Elbrus family]. — SPb.: Piter, 2013. — 272 С.
31. Kim A.K., Bychkov I.N. et al. Rossiyskie tekhnologii “El’brus” dlya personal’nykh komp’yuterov, serverov i superkomp’yuterov [Russian Technologies “Elbrus” for personal computers, servers and supercomputers] // Sovremennye informatsionnye tekhnologii i IT-obrazovanie, M.: Fond sodeystviya razvitiyu internet-media, IT-obrazovaniya, chelovecheskogo potentsiala “Liga internet-media” [Modern Information Technologies and IT Education, Moscow: Foundation for the Promotion of Internet Media,
IT Education, Human Capacity “League of Internet Media”], 2014, No. 10. 39-50.
32. Bailkal electronics, https://www.baikalelectronics.ru/products/T1/
33. P.B. Bogdanov, O.J. Sudareva. The KOMDIV microprocessors performance on a number of typical computational problems // Journal of Information Technologies and Computing Systems – 2017 – V. 4 – p. 104-111.