COMPUTER SIMULATION OF THE OPERABILITY OF FINISHING PROCEDURES AND PARASITIC ELEMENTS IN THE HARDWARE AND SOFTWARE COMPLEX OF CHIP DESIGN
Abstract and keywords
Abstract (English):
The constant intensive development of productive forces and industrial relations is closely related to the needs of the na-tional economy in the creation of new increasingly complex machines, mechanisms and integrated circuits. Ensuring the solution of the development issue is conditioned by contra-dictory requirements: reducing the set deadlines for project development and improving its quality indicators. By in-creasing the number of designers, it is not possible to meet these requirements. The solution of the tasks set is possible through comprehensive automation of design work, the creation of a new design methodology, the widespread use of mathematical modeling methods, robotization of the manu-facturing process and the manufacture of finished products. This article is devoted to the issue of the automatic design system. The article shows that the set of programs used in the prototype of the CAD package allows you to perform work on creating an electronic component database. The testing of the compiled set of computer-aided design tools took place as part of the implementation of work on the design of digital and analog circuits along the full route of the Cadence computer-aided design system. The article at-tempts to demonstrate the problem of big data processing based on the methods of performing design procedures for building design routes for modern element databases

Keywords:
L-shaped structures, F-shaped structures, sizing, nosizing, dummy area, CAD, GDSII, CAD PACK
References

1. Mathematical models of MOS transistors with induced and ion-doped conditions in energy engineering / T. Skvortsova, A. Achkasov, O. Minakova, I. Kochetkov // E3S Web of Conferences, St. Petersburg, 19–21 sentyabrya 2023 goda. Vol. 460. – St. Petersburg: EDP Sciences , 2023. – P. 07023. – DOIhttps://doi.org/10.1051/e3sconf/202346007023. – EDN KTPCOE.

2. Analiz problem modelirovaniya elementov KMOP BIS / V.K. Zol'nikov, S.A. Evdokimova, A.V. Fomichev [i dr.] // Modelirovanie sistem i processov. – 2018. – T. 11, № 4. – S. 20-25.

3. Proektirovanie interfeysov sboeustoychivyh mikroshem / V.K. Zol'nikov, N.V. Mozgovoy, S.V. Grechanyy [i dr.] // Modelirovanie sistem i processov. – 2020. – T. 13, № 1. – S. 17-24.

4. Methodology for designing microcircuits of various levels of CAD description taking into account quality indicators and energy efficient production / K. V. Zolnikov, T. V. Skvortsova, K. Zatorkina, A. Matusevich // E3S Web of Conferences, St. Petersburg, 19–21 sentyabrya 2023 goda. Vol. 460. – St. Petersburg: EDP Sciences , 2023. – P. 04021. – DOIhttps://doi.org/10.1051/e3sconf/202346004021. – EDN KWGJFN.

5. Razrabotka testovogo kristalla pri proektirovanii mikroshem tehnologii KMOP / V.K. Zol'nikov, O.V. Oksyuta, K.A. Chubur, O.N. Kvasov // Modelirovanie sistem i processov. – 2020. – T. 13, № 3. – S. 58-65.

6. Razrabotka proektnoy sredy i ocenka tehnologichnosti proizvodstva mikroshemy s uchetom stoykosti k special'nym faktoram na primere SBIS 1867C6F / V.A. Sklyar, V.A. Smerek, K.V. Zol'nikov [i dr.] // Modelirovanie sistem i processov. – 2020. – T. 13, № 1. – S. 77-82.

7. Zol'nikov, V.K. Verifikaciya proektov i sozdanie testovyh posledovatel'nostey dlya proektirovaniya mikroshem / V.K. Zol'nikov, S.A. Evdokimova, T.V. Skvorcova // Modelirovanie sistem i processov. – 2019. – T. 12, № 1. – S. 10-16.

8. Metody kontrolya nadezhnosti pri razrabotke mikroshem / K.V. Zol'nikov, S.A. Evdokimova, T.V. Skvorcova, A.E. Gridnev // Modelirovanie sistem i processov. – 2020. – T. 13, № 1. – S. 39-45.

9. Utkin, D.M. Ocenka nadezhnosti programmno-tehnicheskih kompleksov special'nogo naznacheniya / D.M. Utkin, V.K. Zol'nikov // Modelirovanie sistem i processov. – 2018. – T. 11, № 2. – S.78-84.

10. Zol'nikov, V.K. Metody verifikacii slozhno funkcional'nyh blokov v SAPR dlya mikroshem gluboko submikronnyh proektnyh norm / V.K. Zol'nikov, S.A. Evdokimova, T.V. Skvorcova // Modelirovanie sistem i processov. – 2019. – T. 12, № 1. – S. 16-24.

11. Zol'nikov, V.K. Obzor programm dlya SAPR submikronnyh SBIS i uchet elektrofizicheskih effektov gluboko submikronnogo urovnya / V.K. Zol'nikov, A.L. Savchenko, A.Yu. Kulay // Modelirovanie sistem i processov. – 2019. – T. 12, № 1. – S. 40-47.

12. Chubur K.A., Strukov I.I., Evdokimova S.A., Belokurov V.P., Platonov A.D., Cherkasov O.N., Zol'nikov K.V. Razrabotka matematicheskih modeley fizicheskih processov v raznorodnoy mnogosloynoy strukture pri radiacionnom vozdeystvii// Modelirovanie sistem i processov. – 2022. – T. 15, № 1. – S. 125-133.

13. Achkasov A.V., Solodilov M.V., Litvinov N.N., Chubunov P.A., Zol'nikov V.K., Shehovcov D.V., Bordyuzha O.L. Osobennosti proektirovaniya mikroshem, vypolnennyh po gluboko-submikronnym tehnologiyam // Modelirovanie sistem i processov. – 2022. – T. 15, № 4. – S. 7-17.

14. Makarenko F.V., Yagodkin A.S., Zol'nikov K.V., Denisova O.A., Poluektov A.V. Obzor logicheskih bazisov i mikroshem pri postroenii kombinacionnogo ustroystva s uchetom nadezhnosti// Modelirovanie sistem i processov. – 2022. – T. 15, № 1. – S. 115-124.

15. Yagodkin A.S., Zol'nikov V.K., Skvorcova T.V., Achkasov A.V., Kuznecov S.A., Makarenko F.V. Razrabotka algoritmov i programm analiza elektricheskih harakteristik BIS // Modelirovanie sistem i processov. – 2022. – T. 15, № 3. – S. 136-148.

16. Suhanov, V.V. Logicheskoe proektirovanie informacionnogo obespecheniya raspredelennyh informacionnyh sistem kriticheskogo primeneniya / V.V. Suhanov, O.V. Lankin // Modelirovanie sistem i processov. – 2021. – T. 14, № 2. – S. 67-73. – DOI:https://doi.org/10.12737/2219-0767-2021-14-2-67-73.

17. Nguyen T. et al. The performance and energy efficiency potential of FPGAs in scientific computing //2020 IEEE/ACM Performance Modeling, Benchmarking and Simulation of High Performance Computer Systems (PMBS). – IEEE, 2020. – S. 8-19.

18. Corperation A. Cyclone IV FPGA Device Family Overview //Cyclone IV Device Handbook. – 2013. – T. 1.

19. Murray K. E. et al. Vtr 8: High-performance cad and customizable FPGA architecture modelling //ACM Transactions on Reconfigurable Technology and Systems (TRETS). – 2020. – T. 13. – №. 2. – S. 1-55.

20. Verification methods for complex-functional blocks in CAD for chips deep submicron design standards / V. K. Zolnikov, K. V. Zolnikov, N. V. Iljina, K. P. Grabovyi // E3S Web of Conferences : International Scientific and Practical Conference “Environmental Risks and Safety in Mechanical Engineering” (ERSME-2023), Rostov-on-Don, Russia, 01–03 marta 2023 goda. Vol. 376. – Rostov-on-Don: EDP Sciences, 2023. – P. 01090. – DOIhttps://doi.org/10.1051/e3sconf/202337601090. – EDN XNXOCF.

21. Vivado Design Suite User Guide: Model-Based DSP. Design Using System Generator. UG897 (v2020.2), November 18, 2020. Available at: https://www.xilinx.com/content/dam/xilinx/support/documents/sw_manuals/xilinx2020_2/ug897-vivado-sysgen-user.pdf, accessed 02.11.2022.

22. FIRRTL. Available at: https://github.com/chipsalliance/firrtl, accessed 02.11.2022.

23. DSLX Reference. Available at: https://google.github.io/xls/dslx_reference, accessed 02.11.2022.

24. Kalms L., Podlubne A., Göhringer D. HiFlipVX: an Open Source High-Level Synthesis FPGA Library for Image Processing. Lecture Notes in Computer Science, vol. 11444, 2019, pp. 149-164.

25. Meeus W., Van Beeck K. et al. An overview of today’s high-level synthesis tools. Design Automation for Embedded Systems, vol. 16, 2012, pp. 31-51.

26. Daoud L., Zydek D., Selvaraj H. A survey of high level synthesis languages, tools, and compilers for reconfigurable high performance computing. Advances in Intelligent Systems and Computing, vol. 240, 2014, pp. 483-492.

27. Nane R., Sima V.-M. et al. A survey and evaluation of FPGA high-level synthesis tools. IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems, vol. 35, issue 10, 2016, pp. 1591-1604.

28. Design and research of the behavioral model for the modular reduction device // Eurasian Physical Technical Journal. 2020; 17: 151-156. https://doi.org/10.31489/2020No1/151-156

Login or Create
* Forgot password?