MODULE HIGH-EFFICIENCY MULTIPROCESSOR SYSTEM WITH MULTIDIMENSIONAL AGGREGATING OF CHANNELS OF NETWORK INTERFACE

Authors

  • D. M. Moroz Dnipro University of Technology, Dnipro, Ukraine , Ukraine

DOI:

https://doi.org/10.15588/1607-3274-2022-3-13

Keywords:

multiprocessor systems, network interface, aggregating, fast-acting, memory, knots, latentness.

Abstract

Context. In modern terms problem of constructing of the multiprocessor systems the special value acquires the base of standard popular technologies and components. It is caused by that such systems became popular and cheap vehicle platforms for highperformance calculations. In addition, practice pulls out problems complete decision of which in most cases possibly only due to application of high-performance calculations. Consequently, a theme of constructing of the cluster multiprocessor systems for today is actual, interesting and is on the stage of the active development. At the same time, the new high-quality stage of development of the multiprocessor cluster systems lies in area of the use of new modern network technologies. Presently the problem of choice and analysis of network technologies for the module multiprocessor cluster systems did not get due development, as well as problem of reorganization of structure ofnetwork interfaceby aggregating of channels of network interface.

Objective. An aim is in-process put improvement of structure and increase of the productivity of the multiprocessor computer system by the multidimensional aggregating of channels of network interface, adapted to the decision of tasks of the investigated class.

Method. The task of increase of efficiency of the module multiprocessor computer system is decided due to multidimensional aggregating of channels of network interface. Offered approach allowed not only to promote efficiency of parallelization but also substantially to decrease time of calculations. Such results succeeded to be attained due to diminishing to time of border exchange of data between the calculable knots of the cluster system.

Results. A feature offered approach is that he allowed to realize a direct exchange data between main memory of knots of the multiprocessor system, that promotes the fast-acting of calculations and provides high-speed access to memory of her slave -nodes. Thus during an exchange by data between the knots of the system the system CPU gets unloaded and loading of channel which passes between the knots of the computer system goes down, that assists diminishing of time of border exchange of data between the calculable knots of the system.

Conclusions. The results of the conducted experiments showed that the worked out multiprocessor system was used for creation of new technological processes. So, she is used in a fluidizer intensification of the сфероидизируещего annealing of long-length steelwork. Directly the technological process of heat treatment of metal acquires such advantages, as a high yield, substantial mionectic energy consumption and allows to carry out control of technological parameters in the modes of unisothermal treatment of metal.

Author Biography

D. M. Moroz, Dnipro University of Technology, Dnipro, Ukraine

Assistant of the Department of Computer Systems Software

References

Robey R., Zamora Y. Parallel and High Performance Computing. 2021. 704 p.

Voevodin Vl. V., Zhumatiy S. A. Computing and cluster systems. Moscow, 2007, 150 p.

Bashkov E. O., Ivashchenko V. P., Shvachich G. G. A highly productive rich processor system based on a personal enumeration cluster, Problems of modeling and automation of design, 2011, No. 9(179). pp. 312–324. DOI 10.31474/2074-7888.

Shvachych G., Pobochii I., Ivaschenko О., Busygin V. Research of compatibility in the multi-processing compound systems, Science Review. Poland, 2018, No. 2(9), Vol. 1. pp. 15–19. Access mode: https://ws-conference.com/.

Zhou D., Lo V. Cluster Computing on the Fly: resource discovery in a cycle sharing peer-to-peer system, IEEE International Symposium on Cluster Computing and the Grid, 2004, pp. 66–73. DOI: 10.1109/CCGrid.2004.1336550.

Ivashchenko V. P., Bashkov E. O., Shvachych G. G., Tkach M. O., Shcherbyna P. O., Volnyanskyi V. V. Patent 105438, Ukraine, IPC G06F 15/16 (2006.01) Module of a highly efficient multiprocessor system with an extended computing area /; patent owners: National Metallurgical Academy of Ukraine, Donetsk National Technical University. No. u 201507019; statement 14.07.2015; published 25.03.2016. Bul. No. 6.

Shvachych G., Pobochii I., Khokhlova T., Kholod O., Busygin V., Moroz D. Multiprocessor Computing based Parallel Structures of Mathematical Models of Tridiagonal Systems, 2020 International Conference on Inventive Computation Technologies (ICICT), 2020, pp. 1031–1035. DOI: 10.1109/ICICT48043.2020.9112512.

Latsis A. O. How to build and use a supercomputer. Moscow, 2003, 240 p.

Glushan V. M., Lavrik P. V. Network technologies as a tool for distributed electronic design, Software Journal: Theory and Applications, 2013, No. 1, pp. 1–12. DOI: 10.15827/2311-6749.7.119.

Ivashchenko V. P., Bashkov E. A., Shvachich G. G., Tkach M. A. Modern communication technologies in modular multiprocessor systems: experience of use, study of efficiency estimates, prospects for application. Dnepropetrovsk, 2012, 140 p.

Besta M., Hoefler T. Slim fly: A cost effective low-diameter network topology, Proceedings of the International Conference for High Performance Computing, Networking, Storage and Analysis, IEEE Press, 2014, pp. 348–359. DOI: 10.1109/SC.2014.34.

Shvachich G. G., Kholod E. G., Tkach M. A. Peculiarities of the use of the INFINIBAND seismic interface in multiprocessor systems with a distributed computing area, Information processing systems, 2016, No. 3(140), pp. 175–181.

Gergel V. P., Strongin R. G. Fundamentals of parallel computing for multiprocessor computing systems, 2003, 184 p.

Maksimov N. V., Popov I. I. Computer networks. Moscow, 2011, 464 p.

Moroz D. M. Aggregation arrangement features of network interface channels in multiprocessor computing systems, System technologies, 2022, No. 2(139), pp. 111–121. DOI 10.34185/1562-9945-2-139-2022-11.

Shlomchak G., Shvachych G., Moroz B., Fedorov E., Kozenkov D. Automated control of temperature regimes of alloyed steel products based on multiprocessors computing systems, Metalurgija, 2019, No. 58 (3–4), pp. 299–302. Access mode: https://pubweb.carnet.hr/metalurg/arhiva/1983.

Shvachych G., Moroz B., Khylko M., Perepolkina O., Busygin V. Distributed Data Register Technology as the Main Component of Economic Decentralization, Applied Computational Technologies. Springer, 2022, pp. 533–542. Access mode: https://doi.org/10.1007/978-981-19-2719-5.

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Published

2022-10-17

How to Cite

Moroz, D. M. (2022). MODULE HIGH-EFFICIENCY MULTIPROCESSOR SYSTEM WITH MULTIDIMENSIONAL AGGREGATING OF CHANNELS OF NETWORK INTERFACE . Radio Electronics, Computer Science, Control, (3), 133. https://doi.org/10.15588/1607-3274-2022-3-13

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Section

Progressive information technologies