* Dept. of Laser and Microwave Information Systems, Moscow State Institute of Electronics and Mathematics (Technical University), 3/12 B. Tryokhsvyatitelsky per., 109028 Moscow, Russia

Laboratory for Super High-Speed Signal Processing

[email protected]
[email protected]
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Staff of Laboratory:

F.Al-Shedifat ����Eng
G.Domashenko Eng
A.Kalita ������������Eng
D.Krivolapov ����Eng
I.Nazarov ���������PhD
P.Smirnov ��������Eng

ôîòî Ãåííàäèÿ À. Êóçàåâà Professor Guennadi A. Kouzaev was born in 1958 in Samara, Russia. In 1980 he received his MaSc in Electrocommunications from Kuibyshev Electrotechnical Institut for Communications, followed in 1986 by a PhD in Physics and Mathematics from the Institute of Radio Engineering and Electronics (USSR Acad. Sci.). In 1998 he gained a DrSc in Engineering at the Moscow State Institute of Electronics and Mathematics (Technical University). From 1984 to 1988 he was a Researcher at the Research Institute for Space Instrument Design of Russia, followed by three years as a Senior Researcher at the Moscow State Institute of Electronics and Mathematics. In January 1993 he was appointed Principal Lecturer on Eiectromagnetism and Microwave Electronics at the Institute and from August 1994 until November 1997 he also worked at the Russian Academy of Natural Sciences and the Research Institute of Promising Technologies, Moscow, as Head of the Department for Millimeter Wave Radio Vision Systems. He is currently Head of the Research Laboratory for Super High-Speed Signal Processing and Professor on Electromagnetism and Microwave Electronics at the Moscow State Institute of Electronics and Mathematics. Professor Kouzaev is the author of over 80 papers, abstracts and patents in the field of Microwave Physics and High-Speed Electronics. He has pursued investigations in the field of super high speed signal processing, the theory of boundary problems of electromagnetism, CAD of 3D ICs and information physics of bioelectromagnetic fields. He has received four research grants from the Russian Ministry of Science and Technology and the Russian Foundation for Basic Research. Professor Kouzaev is a member of the Russian Society of Inventors, the Scientific and Technical A S Popov Society for Radio Engineering, Electronics and Telecommunications (Russia), the Black Sea Scientific Union of Applied Electromagnetism (Greece), the Research Grant Commission of the Moscow State Institution of Electronics and Mathematics. He is also on the editorial board of the "Journal for Wave Physics and Radiotechnical Systems" (Russia). Professor Kouzaev's professional achievements have been recognised by national awards, in 1990 he was awarded the Lenin-Komsomol Prize for Young Scientists and in 1997 the Russian Government Prize in the field of Science and Engineering. Prof. G. Kouzaev is a Co-Chair of the International Symposium on Terahertz and Gigahertz Photonics (1999 Denver, Colorado, USA).

Topological Field Signal Processing

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Theory

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Bibliography

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Laboratory Equipment Computers Software

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Laboratory Achievements and Research Plans

One from final stages of development of the electronic integrated circuits is the transition to three-dimensional "medium" for processing electromagnetic signals of the complicated spatially - temporary form. Indications of this tendency is the minimization of interelement distances in VLSI of a three-dimensional configuration, diminution of sizes of active elements and magnification of velocity of their work. The evolution VLSI in this direction is accompanied by growth electromagnetic intercouplunges and thickening of a spatially - temporary structure of impulses owing to a comparability of areas of maximum concentration of fields of signals and distances between components of the integrated circuit.
For correct construction of VLSI architecture and methods of information processing it is obviously important to evaluate space complexity of signals, for example on an amount of conductors per unit of IC volume and on maximum significance of space frequency of signal field. The last magnitude in the three-dimensional circuits can reach tens and hundreds gigahertz on a cubic millimeter. The temporary frequencies can take a band from 0 up to units terahertz. Thus, signals of this kind may represent as coopled spatially - temporary objects. The information can be stored in such field pulses in their discrete structure of topology of force lines. Agrees to earlier conducted researches the separate digital operations can be carried out by passive micron circuits with time delay about 0.1-0.3 picosecond. The super high-speed is caused by using of electromagnetic wave diffraction physics.
The architecture of new VLSI should be constructed on a principle of an impulse pseudo-holography. In these three-dimensional circuits the conductors will play a role of directing spatially - modulated signals, and interchanging fields to execute functions of a diffuse field. The reorganization of the hologram will be carried out at the expense of analog-digital management of active elements. It will allow to unit advantages of the holographic approach with a principle of it active management (change of "frames", selection of modes of "clearness", fulfillment of nonlinear operations with vectorial performances of fields and their spatial distributions etc.).
The VLSI new generation is intended for realization of logic operations of a classical type, fuzzy and quasi-neural logic, and also for a solution of a problem of exponential growth of complexity of calculations.

Web-Designer: Dmitriy D. Krivolapov �[email protected] �