DOCSLIB.ORG

Ming Hsieh Department of Electrical Engineering

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Ming Hsieh Department of Electrical Engineering UNIVERSITY OF SOUTHERN CALIFORNIA VITERBI SCHOOL OF ENGINEERING MING HSIEH DEPARTMENT OF ELECTRICAL ENGINEERING 2011 RESEARCH BOOK First Annual Electrical Engineering Research Festival sponsored by the Ming Hsieh Institute April 29, 2011 http://mhi.usc.edu WELCOME FROM THE MING HSIEH INSTITUTE DIRECTOR April 29, 2011 On behalf of the Ming Hsieh Institute (MHI), my co-directors, Hossein Hashemi, Bhaskar Krishnamachari and I are pleased to welcome you to review the outstanding research of our Ph.D. students and postdoctoral scholars in the Ming Hsieh Department of Electrical Engineering. The Ming Hsieh Institute in the Ming Hsieh Department of Electrical Engineering was launched in July 2010, after a generous endowment gift of $35 million dollars from Mr. Ming Hsieh, an alumnus of the department. One of the main goals of the institute is to position the Electrical Engineering Department at the forefront in thought leadership in the world in the area of electrical engineering, and specifically in the development of intelligent technologies to empower mankind. The vision for our Institute is to create a vibrant intellectual environment at USC where world-class researches in Electrical Engineering and related fields can come together and engage in the development of new ideas. The first annual Electrical Engineering Research Festival that we are hosting today is a step in this direction. We hope you enjoy your day and have great conversations with our students and faculty regarding their research. To learn more about the Ming Hsieh Institute and its future events, please visit us at http://mhi.usc.edu. We thank you for your participation today, and hope for your continued engagement and participation in the institute’s activities. Sincerely, Shrikanth S. (Shri) Narayanan Andrew Viterbi Professor of Engineering; Professor of Electrical Engineering, Computer Science, Linguistics and Psychology 2011 USC EE Research Book Welcome from the Ming Hsieh Institute Director 2 MESSAGE FROM THE MING HSIEH ELECTRICAL ENGINEERING DEPARTMENT CHAIRS Welcome to the Ming Hsieh Department of Electrical Engineering! USC began teaching electrical engineering more than a century ago, when the field was widely considered a subset of physics. Today our work is vitally important and critical to the advancement of the information age. As our department charges into its second century of excellence, we are defining the forefront of research in a number of important areas. These include: circuits; antennas; wireless communications; bio-signal processing; computer architecture; very large-scale integration and computer-aided design; computer networks; control systems; high-speed switching architectures; signal, image and multimedia processing; nanotechnology; optical communications; photonics; and quantum information processing. Among our distinguished faculty are the visionary leaders of the university, including USC President Max Nikias and President Emeritus Steven Sample. We are also proud that Qualcomm and Linkabit co- founder Andrew J. Viterbi is a faculty member. In 2008, he received the National Medal of Science and was a Laureate of the Millenium Technology Prize Foundation of Finland, and in 2010, he received the IEEE Medal of Honor. The School of Engineering school bears his name. Our department is also home to thirteen other National Academy of Engineering members. We’re proud of our department’s distinguished history and our vital and innovative faculty and Ph.D. students. Please take a few minutes to explore some of the highlights of their work, compiled in this Research Book. Alexander A. Sawchuk Eun Sok Kim Leonard M. Silverman Chair Professor and Chair of Professor andChair of Electrical Engineering-Electrophysics Electrical Engineering-Systems 2011 USC EE Research Book Message from the Electrical Engineering Department Chairs 3 TABLE OF CONTENTS LETTER FROM THE MING HSIEH INSTITUTE DIRECTOR ………………………………………………………………………… 2 LETTER FROM THE DEPARTMENT CHAIRS …………………………………………………………………………………………. 3 ELECTRICAL ENGINEERING FACULTY ………………………………………………………………………………………………. 5 PH.D. STUDENT RESEARCH SUMMARIES ……………………………………………………………………………………….. 19 APPLIED ELECTROMAGNETICS …………………………………………………………………………………………. 20 BIO-ELECTRONICS AND BIO-OPTICS …………………………………………………………………………………. 23 COMMUNICATIONS ………………………………………………………………………………………………………. 26 COMPUTER ARCHITECTURE …………………………………………………………………………………………….. 43 CONTROLS …………………………………………………………………………………………………………………. 58 INTEGRATED CIRCUITS AND SYSTEMS ………………………………………………………………………………… 67 NANO-SCIENCE, NANO-TECHNOLOGY, AND MEMS ……………………………………………………………. 78 NETWORKS ……………………………………………………………………………………………………………….. 97 PHOTONICS ……………………………………………………………………………………………………………….. 118 SIGNAL PROCESSING ……………………………………………………………………………………………………. 128 VLSI/CAD ……………………………………………………………………………………………………………….. 173 MHI PH.D. SCHOLARS ……………………………………………………………………………………………………………. 184 2010 PH.D. DISSERTATIONS ……………………………………………………………………………………………………. 186 INDEX OF NAMES ……………….……………………………………………………………………………………………………. 190 2011 USC EE Research Book Table of Contents 4 ELECTRICAL ENGINEERING FACULTY Murali Annavaram Assistant Professor; Ph.D., University of Michigan, 2001. Computer architecture, 3D stacking, mobiquitous computing. EEB 232, (213) 740-3299, [email protected] Student pages: 46, 48, 54, 56, 117 Michael A. Arbib University Professor, Professor of Electrical Engineering, Fletcher Jones Professor of Computer Science, Professor of Biological Sciences, Biomedical Engineering, Neuroscience, and Psychology; Ph.D., MIT, 1963. Neural networks, brain theory, neuroinformatics, neural simulation, visuomotor coordination in animals and robots analysis of the evolution of brain mechanisms underlying language. HNB 03, (213) 740-9220, [email protected] Andrea Armani Assistant Professor of Chemical Engineering and Electrical Engineering; Ph.D., California Institute of Technology, 2007. Optical biological and chemical sensors; integration of microfluidics. VHE 712, (213) 740-4428, [email protected] Peter A. Beerel Associate Professor; Ph.D., Stanford University, 1994. Design, synthesis, analysis, and formal verification of mixed asynchronous and synchronous architectures. EEB 350, (213) 740-4481, [email protected] Melvin A. Breuer Professor, Charles Lee Powell Chair in Electrical Engineering and Computer Science; Ph.D., UC, Berkeley, 1965. Computer-aided design for digital systems, design-for-test, built-in self-test, and VLSI circuits. EEB 300C, (213) 740-4469, [email protected] Todd Brun Associate Professor; Ph.D., Caltech, 1994. Quantum information theory and quantum computation. EEB 502, (213) 740-3503, [email protected] Student pages: 34, 41 Giuseppe Caire Professor; Ph.D., Politencnico di Torino, 1994. Information theory, Coding theory. EEB 540, (213) 740-4683, [email protected] Student pages: 27, 28, 32, 33, 38, 100 2011 USC EE Research Book Electrical Engineering Faculty 6 Mike S.W. Chen Assistant Professor; Ph.D., University of California, Berkeley, 2006. Analog and mixed-signal integrated circuits; digital signal processing techniques to alleviate circuit and system constraints; wireless and wireline communication systems design and implementation; circuits for emerging applications. PHE 622, (213) 740-4691, [email protected] T.C. Cheng Professor, Lloyd F. Hunt Chair in Electrical Power; Sc.D., MIT, 1974. Power devices and systems; neural network based analysis of power system reliability, power system contingency planning during earthquakes. PHE 634, (213) 740-4712, [email protected] Elaine Chew Associate Professor Industrial and Systems Engineering; Associate Professor of Electrical Engineering; Ph.D., MIT, 2000. Computational music cognition: automated music analysis and visualization, expressive performance analysis and synthesis, and applications in music information retrieval and distributed performance. Chamber and solo performances of eclectic post-tonal contemporary music compositions. GER 241, (213) 821-2414, [email protected] John Choma Professor; Ph.D., U. of Pittsburgh, 1969. Devices & circuits high frequency, ultralinear, low-noise active integrated circuit filters modeling of CMOS & bipolar devices for RF circuits. PHE 604, (213) 740-4692, [email protected] Student pages: 72, 76 Keith M. Chugg Professor; Ph.D., USC, 1995. iterative detection, coding and modulation, and algorithm-architecture trade- offs for digital hardware implementation. EEB 502, (213)740-7294, [email protected] Student pages: 35 Stephen Cronin Associate Professor; Ph.D., MIT, 2002. Optics and electronics of carbon nanotubes, nanowires and other nm-scale systems. PHE 624, [email protected] Student pages: 80, 89 P. Daniel (Dan) Dapkus W. M. Keck Professor of Engineering; Ph.D., U. of Illinois, Urbana-Champaign, 1970. Photonics, MOCVD & III-V materials vertical cavity surface emitting lasers, novel photonic devices. VHE 314, (213) 740-4414, [email protected] Student pages: 84, 94, 125, 150 2011 USC EE Research Book Electrical Engineering Faculty 7 Alexandros G. Dimakis Assistant Professor; Ph.D., UC Berkeley, 2008. Coding theory and communications, message-passing algorithms, network coding, large scale distributed storage and inference systems. EEB 532, (213) 740-9264, [email protected] Student pages: 36, 38 Jeffrey (Jeff) Draper Project Leader/Research Associate Professor; Ph.D., University of Texas, 1993. Computer Engineering ISI Marina del Rey, (310) 448-8750, [email protected] Student pages: 45, 49, 50, 51, 57, 145, 176, 181 Michel Dubois Professor; Ph.D., Purdue, 1982. Computer architecture, microarchitecture,
Load more

Recommended publications
  • Role of Nonlinear Dynamics and Chaos in Applied Sciences
    v.;.;.:.:.:.;.;.^ ROLE OF NONLINEAR DYNAMICS AND CHAOS IN APPLIED SCIENCES by Quissan V. Lawande and Nirupam Maiti Theoretical Physics Oivisipn 2000 Please be aware that all of the Missing Pages in this document were originally blank pages BARC/2OOO/E/OO3 GOVERNMENT OF INDIA ATOMIC ENERGY COMMISSION ROLE OF NONLINEAR DYNAMICS AND CHAOS IN APPLIED SCIENCES by Quissan V. Lawande and Nirupam Maiti Theoretical Physics Division BHABHA ATOMIC RESEARCH CENTRE MUMBAI, INDIA 2000 BARC/2000/E/003 BIBLIOGRAPHIC DESCRIPTION SHEET FOR TECHNICAL REPORT (as per IS : 9400 - 1980) 01 Security classification: Unclassified • 02 Distribution: External 03 Report status: New 04 Series: BARC External • 05 Report type: Technical Report 06 Report No. : BARC/2000/E/003 07 Part No. or Volume No. : 08 Contract No.: 10 Title and subtitle: Role of nonlinear dynamics and chaos in applied sciences 11 Collation: 111 p., figs., ills. 13 Project No. : 20 Personal authors): Quissan V. Lawande; Nirupam Maiti 21 Affiliation ofauthor(s): Theoretical Physics Division, Bhabha Atomic Research Centre, Mumbai 22 Corporate authoifs): Bhabha Atomic Research Centre, Mumbai - 400 085 23 Originating unit : Theoretical Physics Division, BARC, Mumbai 24 Sponsors) Name: Department of Atomic Energy Type: Government Contd...(ii) -l- 30 Date of submission: January 2000 31 Publication/Issue date: February 2000 40 Publisher/Distributor: Head, Library and Information Services Division, Bhabha Atomic Research Centre, Mumbai 42 Form of distribution: Hard copy 50 Language of text: English 51 Language of summary: English 52 No. of references: 40 refs. 53 Gives data on: Abstract: Nonlinear dynamics manifests itself in a number of phenomena in both laboratory and day to day dealings.
    [Show full text]
  • Instructional Experiments on Nonlinear Dynamics & Chaos (And
    Bibliography of instructional experiments on nonlinear dynamics and chaos Page 1 of 20 Colorado Virtual Campus of Physics Mechanics & Nonlinear Dynamics Cluster Nonlinear Dynamics & Chaos Lab Instructional Experiments on Nonlinear Dynamics & Chaos (and some related theory papers) overviews of nonlinear & chaotic dynamics prototypical nonlinear equations and their simulation analysis of data from chaotic systems control of chaos fractals solitons chaos in Hamiltonian/nondissipative systems & Lagrangian chaos in fluid flow quantum chaos nonlinear oscillators, vibrations & strings chaotic electronic circuits coupled systems, mode interaction & synchronization bouncing ball, dripping faucet, kicked rotor & other discrete interval dynamics nonlinear dynamics of the pendulum inverted pendulum swinging Atwood's machine pumping a swing parametric instability instabilities, bifurcations & catastrophes chemical and biological oscillators & reaction/diffusions systems other pattern forming systems & self-organized criticality miscellaneous nonlinear & chaotic systems -overviews of nonlinear & chaotic dynamics To top? Briggs, K. (1987), "Simple experiments in chaotic dynamics," Am. J. Phys. 55 (12), 1083-9. Hilborn, R. C. (2004), "Sea gulls, butterflies, and grasshoppers: a brief history of the butterfly effect in nonlinear dynamics," Am. J. Phys. 72 (4), 425-7. Hilborn, R. C. and N. B. Tufillaro (1997), "Resource Letter: ND-1: nonlinear dynamics," Am. J. Phys. 65 (9), 822-34. Laws, P. W. (2004), "A unit on oscillations, determinism and chaos for introductory physics students," Am. J. Phys. 72 (4), 446-52. Sungar, N., J. P. Sharpe, M. J. Moelter, N. Fleishon, K. Morrison, J. McDill, and R. Schoonover (2001), "A laboratory-based nonlinear dynamics course for science and engineering students," Am. J. Phys. 69 (5), 591-7. http://carbon.cudenver.edu/~rtagg/CVCP/Ctr_dynamics/Lab_nonlinear_dyn/Bibex_nonline..
    [Show full text]
  • International Journal of Engineering and Advanced Technology (IJEAT)
    IInntteerrnnaattiioonnaall JJoouurrnnaall ooff EEnnggiinneeeerriinngg aanndd AAddvvaanncceedd TTeecchhnnoollooggyy ISSN : 2249 - 8958 Website: www.ijeat.org Volume-2 Issue-5, June 2013 Published by: Blue Eyes Intelligence Engineering and Sciences Publication Pvt. Ltd. ced Te van ch d no A l d o n g y a g n i r e e IJEat n i I E n g X N t P e L IO n O E T r R A I V n NG NO f IN a o t l i o a n n r a u l J o www.ijeat.org Exploring Innovation Editor In Chief Dr. Shiv K Sahu Ph.D. (CSE), M.Tech. (IT, Honors), B.Tech. (IT) Director, Blue Eyes Intelligence Engineering & Sciences Publication Pvt. Ltd., Bhopal (M.P.), India Dr. Shachi Sahu Ph.D. (Chemistry), M.Sc. (Organic Chemistry) Additional Director, Blue Eyes Intelligence Engineering & Sciences Publication Pvt. Ltd., Bhopal (M.P.), India Vice Editor In Chief Dr. Vahid Nourani Professor, Faculty of Civil Engineering, University of Tabriz, Iran Prof.(Dr.) Anuranjan Misra Professor & Head, Computer Science & Engineering and Information Technology & Engineering, Noida International University, Noida (U.P.), India Chief Advisory Board Prof. (Dr.) Hamid Saremi Vice Chancellor of Islamic Azad University of Iran, Quchan Branch, Quchan-Iran Dr. Uma Shanker Professor & Head, Department of Mathematics, CEC, Bilaspur(C.G.), India Dr. Rama Shanker Professor & Head, Department of Statistics, Eritrea Institute of Technology, Asmara, Eritrea Dr. Vinita Kumari Blue Eyes Intelligence Engineering & Sciences Publication Pvt. Ltd., India Dr. Kapil Kumar Bansal Head (Research and Publication), SRM University, Gaziabad (U.P.), India Dr.
    [Show full text]
  • Control of Chaos: Methods and Applications
    Automation and Remote Control, Vol. 64, No. 5, 2003, pp. 673{713. Translated from Avtomatika i Telemekhanika, No. 5, 2003, pp. 3{45. Original Russian Text Copyright c 2003 by Andrievskii, Fradkov. REVIEWS Control of Chaos: Methods and Applications. I. Methods1 B. R. Andrievskii and A. L. Fradkov Institute of Mechanical Engineering Problems, Russian Academy of Sciences, St. Petersburg, Russia Received October 15, 2002 Abstract|The problems and methods of control of chaos, which in the last decade was the subject of intensive studies, were reviewed. The three historically earliest and most actively developing directions of research such as the open-loop control based on periodic system ex- citation, the method of Poincar´e map linearization (OGY method), and the method of time- delayed feedback (Pyragas method) were discussed in detail. The basic results obtained within the framework of the traditional linear, nonlinear, and adaptive control, as well as the neural network systems and fuzzy systems were presented. The open problems concerned mostly with support of the methods were formulated. The second part of the review will be devoted to the most interesting applications. 1. INTRODUCTION The term control of chaos is used mostly to denote the area of studies lying at the interfaces between the control theory and the theory of dynamic systems studying the methods of control of deterministic systems with nonregular, chaotic behavior. In the ancient mythology and philosophy, the word \χαωσ" (chaos) meant the disordered state of unformed matter supposed to have existed before the ordered universe. The combination \control of chaos" assumes a paradoxical sense arousing additional interest in the subject.
    [Show full text]
  • Math Morphing Proximate and Evolutionary Mechanisms
    Curriculum Units by Fellows of the Yale-New Haven Teachers Institute 2009 Volume V: Evolutionary Medicine Math Morphing Proximate and Evolutionary Mechanisms Curriculum Unit 09.05.09 by Kenneth William Spinka Introduction Background Essential Questions Lesson Plans Website Student Resources Glossary Of Terms Bibliography Appendix Introduction An important theoretical development was Nikolaas Tinbergen's distinction made originally in ethology between evolutionary and proximate mechanisms; Randolph M. Nesse and George C. Williams summarize its relevance to medicine: All biological traits need two kinds of explanation: proximate and evolutionary. The proximate explanation for a disease describes what is wrong in the bodily mechanism of individuals affected Curriculum Unit 09.05.09 1 of 27 by it. An evolutionary explanation is completely different. Instead of explaining why people are different, it explains why we are all the same in ways that leave us vulnerable to disease. Why do we all have wisdom teeth, an appendix, and cells that if triggered can rampantly multiply out of control? [1] A fractal is generally "a rough or fragmented geometric shape that can be split into parts, each of which is (at least approximately) a reduced-size copy of the whole," a property called self-similarity. The term was coined by Beno?t Mandelbrot in 1975 and was derived from the Latin fractus meaning "broken" or "fractured." A mathematical fractal is based on an equation that undergoes iteration, a form of feedback based on recursion. http://www.kwsi.com/ynhti2009/image01.html A fractal often has the following features: 1. It has a fine structure at arbitrarily small scales.
    [Show full text]
  • Chaos Theory: the Essential for Military Applications
    U.S. Naval War College U.S. Naval War College Digital Commons Newport Papers Special Collections 10-1996 Chaos Theory: The Essential for Military Applications James E. Glenn Follow this and additional works at: https://digital-commons.usnwc.edu/usnwc-newport-papers Recommended Citation Glenn, James E., "Chaos Theory: The Essential for Military Applications" (1996). Newport Papers. 10. https://digital-commons.usnwc.edu/usnwc-newport-papers/10 This Book is brought to you for free and open access by the Special Collections at U.S. Naval War College Digital Commons. It has been accepted for inclusion in Newport Papers by an authorized administrator of U.S. Naval War College Digital Commons. For more information, please contact [email protected]. The Newport Papers Tenth in the Series CHAOS ,J '.' 'l.I!I\'lt!' J.. ,\t, ,,1>.., Glenn E. James Major, U.S. Air Force NAVAL WAR COLLEGE Chaos Theory Naval War College Newport, Rhode Island Center for Naval Warfare Studies Newport Paper Number Ten October 1996 The Newport Papers are extended research projects that the editor, the Dean of Naval Warfare Studies, and the President of the Naval War CoJIege consider of particular in terest to policy makers, scholars, and analysts. Papers are drawn generally from manuscripts not scheduled for publication either as articles in the Naval War CollegeReview or as books from the Naval War College Press but that nonetheless merit extensive distribution. Candidates are considered by an edito­ rial board under the auspices of the Dean of Naval Warfare Studies. The views expressed in The Newport Papers are those of the authors and not necessarily those of the Naval War College or the Department of the Navy.
    [Show full text]
  • Fractional-Order Control for a Novel Chaotic System Without Equilibrium Shu-Yi Shao and Mou Chen Member, IEEE
    IEEE/CAA JOURNAL OF AUTOMATICA SINICA 1 Fractional-Order Control for a Novel Chaotic System without Equilibrium Shu-Yi Shao and Mou Chen Member, IEEE, Abstract—The control problem is discussed for a chaotic sys- portant results have been reported. In the early 1990s, the tem without equilibrium in this paper. On the basis of the linear synchronization of chaotic systems was achieved by Pecora mathematical model of the two-wheeled self-balancing robot, a and Carroll[14;15], which was a trailblazing result, and the novel chaotic system which has no equilibrium is proposed. The basic dynamical properties of this new system are studied via result promoted the development of chaos control and chaos [16;17] Lyapunov exponents and Poincare´ map. To further demonstrate synchronization . In recent years, different chaos control the physical realizability of the presented novel chaotic system, a and chaos synchronization strategies have been developed chaotic circuit is designed. By using fractional-order operators, for chaotic systems. The sliding mode control method was a controller is designed based on the state-feedback method. applied to chaos control[18;19] and chaos synchronization[20]. According to the Gronwall inequality, Laplace transform and Mittag-Leffler function, a new control scheme is explored for the In [21], the feedback control method and the adaptive control whole closed-loop system. Under the developed control scheme, method were used to realize chaos control for the energy the state variables of the closed-loop system are controlled to resource chaotic system. The chaos control problems were stabilize them to zero. Finally, the numerical simulation results investigated for Lorenz system, Chen system and Lu¨ system of the chaotic system with equilibrium and without equilibrium based on backstepping design method in [22].
    [Show full text]
  • Program of CHAOS2011 Conference
    4th Chaotic Modeling and Simulation International Conference (CHAOS2011) May 31 - June 3, 2011 Agios Nikolaos Crete Greece Program Session / Date / Time Event Talk Title / Event Room Hermes 17.00-20.00 Monday May 30 Registration Hermes 8.30-10.00 Tuesday May 31 Registration Room 1 10.00-10.40 Opening Ceremony Keynote Session (Chair: D. Sotiropoulos) Room 1 10.40-11.30 Extension of Poincare's program for integrability and chaos in Hamiltonian systems Professor Ferdinand Verhulst Room 1 11.30-12.00 Coffee Break SCS1 SPECIAL AND CONTRIBUTED SESSIONS SCS1 Room 1 31.05.11: 12.00-13.40 Chair: G. I. Burde Chaos and solitons Spontaneous generation of solitons from steady state {exact solutions to the higher order KdV G.I. Burde equations on a half-line} Posadas-Castillo C., Garza-González E., Cruz- Chaotic synchronization of complex networks with Rössler oscillators in Hamiltonian form like Hernández C., Alcorta-García E., Díaz-Romero D.A. nodes Vladimir L. Kalashnikov Dissipative solitons: the structural chaos and the chaos of destruction V.Yu.Novokshenov Tronqu'ee solutions of the Painleve' II equation Stefan C. Mancas, Harihar Khanal 2D Erupting Solitons in Dissipative Media Room 2 31.05.11: 12.00-13.40 Chair: G. Feichtinger CHAOS and Applications in social and economic life Gustav Feichtinger Multiple Equilibria, Binges, and Chaos in Rational Addiction Models David Laroze, J. Bragard, H Pleiner Chaotic dynamics of a biaxial anisotropic magnetic particle Oleksander Pokutnyi Chaotic maps in cybernetics Room 3 31.05.11: 12.00-13.40 Chair: D. Sotiropoulos Chaos and time series analysis Hannah M.
    [Show full text]
  • Fourth SIAM Conference on Applications of Dynamical Systems
    Utah State University DigitalCommons@USU All U.S. Government Documents (Utah Regional U.S. Government Documents (Utah Regional Depository) Depository) 5-1997 Fourth SIAM Conference on Applications of Dynamical Systems SIAM Activity Group on Dynamical Systems Follow this and additional works at: https://digitalcommons.usu.edu/govdocs Part of the Physical Sciences and Mathematics Commons Recommended Citation Final program and abstracts, May 18-22, 1997 This Other is brought to you for free and open access by the U.S. Government Documents (Utah Regional Depository) at DigitalCommons@USU. It has been accepted for inclusion in All U.S. Government Documents (Utah Regional Depository) by an authorized administrator of DigitalCommons@USU. For more information, please contact [email protected]. tI...~ Confers ~'t' '"' \ 1I~c9 ~ 1'-" ~ J' .. c "'. to APPLICAliONS cJ May 18-22, 1997 Snowbird Ski and Summer Resort • Snowbird, Utah Sponsored by SIAM Activity Group on Dynamical Systems Conference Themes The themes of the 1997 conference will include the following topics. Principal Themes: • Dynamics in undergraduate education • Experimental studies of nonlinear phenomena • Hamiltonian systems and transport • Mathematical biology • Noise in dynamical systems • Patterns and spatio-temporal chaos Applications in • Synchronization • Aerospace engineering • Biology • Condensed matter physics • Control • Fluids • Manufacturing • Me;h~~~~nograPhY 19970915 120 • Lasers and o~ • Quantum UldU) • 51a m.@ Society for Industrial and Applied Mathematics http://www.siam.org/meetingslds97/ds97home.htm 2 " DYNAMICAL SYSTEMS Conference Prl Contents A Message from the Conference Chairs ... Get-Togethers 2 Dear Colleagues: Welcoming Message 2 Welcome to Snowbird for the Fourth SIAM Conference on Applications of Dynamica Systems. Organizing Committee 2 This highly interdisciplinary meeting brings together a diverse group of mathematicians Audiovisual Notice 2 scientists, and engineers, all working on dynamical systems and their applications.
    [Show full text]
  • Frequently Asked Questions About Nonlinear Science J.D
    Frequently Asked Questions about Nonlinear Science J.D. Meiss Sept 2003 [1] About Sci.nonlinear FAQ This is version 2.0 (Sept. 2003) of the Frequently Asked Questions document for the newsgroup s ci.nonlinear. This document can also be found in Html format from: http://amath.colorado.edu/faculty/jdm/faq.html Colorado, http://www-chaos.engr.utk.edu/faq.html Tennessee, http://www.fen.bris.ac.uk/engmaths/research/nonlinear/faq.html England, http://www.sci.usq.edu.au/mirror/sci.nonlinear.faq/faq.html Australia, http://www.faqs.org/faqs/sci/nonlinear-faq/ Hypertext FAQ Archive Or in other formats: http://amath.colorado.edu/pub/dynamics/papers/sci.nonlinearFAQ.pdf PDF Format, http://amath.colorado.edu/pub/dynamics/papers/sci.nonlinearFAQ.rtf RTF Format, http://amath.colorado.edu/pub/dynamics/papers/sci.nonlinearFAQ.tex old version in TeX, http://www.faqs.org/ftp/faqs/sci/nonlinear-faq the FAQ's site, text version ftp://rtfm.mit.edu/pub/usenet/news.answers/sci/nonlinear-faq text format. This FAQ is maintained by Jim Meiss [email protected]. Copyright (c) 1995-2003 by James D. Meiss, all rights reserved. This FAQ may be posted to any USENET newsgroup, on-line service, or BBS as long as it is posted in its entirety and includes this copyright statement. This FAQ may not be distributed for financial gain. This FAQ may not be in cluded in commercial collections or compilations without express permission from the author. [1.1] What's New? Fixed lots of broken and outdated links. A few sites seem to be gone, and some new sites appeare d.
    [Show full text]
  • Control of Chaos in Strongly Nonlinear Dynamic Systems
    Control of Chaos in Strongly Nonlinear Dynamic Systems Lev F. Petrov Plekhanov Russian University of Economics Stremianniy per., 36, 115998, Moscow, Russia [email protected] Abstract We consider the dynamic processes models based on strongly nonlin- ear systems of ordinary differential equations and various stable and unstable solutions of such systems. The behavior and evolution of so- lutions are studied when the system parameters and external influences change. As a tool for controlling the behavior of solutions is considered a system parameters change. Particular attention is paid to the param- eter of dissipation as a tool for controlling chaos. For simple systems, a controlled transition from stable solutions to chaos and back is consid- ered. The generalization of the solutions chaotic behavior for complex systems and the criteria for optimal level of chaos in such systems are discussed. 1 Introduction For complex systems such as Economics, social relations, communication, chaos is a natural form of behavior. For these systems mathematical models allow qualitatively, but not quantitatively evaluate the system behavior. In real complex systems, both a regular ordered behavior and chaotic states of systems are observed. Complete elimination of chaos in a complex system, as a rule, leads to system degradation. For the economy this is stagnation, lack of competition, initiatives and new prospective. For social relations, this is the lack of democracy. For information transfer systems, this is regulated and metered information and misinformation, information vacuum, the lack of the possibility of obtaining information from alternative sources. The lack of complex systems regulation leads to an excessive level of chaos.
    [Show full text]
  • Control of Chaotic Systems - A.L
    CONTROL SYSTEMS, ROBOTICS, AND AUTOMATION - Vol. XIII- Control of Chaotic Systems - A.L. Fradkov CONTROL OF CHAOTIC SYSTEMS A.L. Fradkov Institute for Problems of Mechanical Engineering, Russian Academy of Sciences, St. Petersburg, RUSSIA Keywords: Chaos, chaotization, nonlinear systems, nonlinear control, partial stability, recurrence, stabilization, feedforward control, periodic excitation, Melnikov function, controlled Poincaré map, Ott-Grebogi-Yorke (OGY) method, Pyragas method, delayed feedback, Lurie system, Lyapunov function, synchronization Contents 1. Introduction 2. Notion of chaos 3. Models of controlled systems and control goals 4. Methods of controlling chaos: continuous-time systems 4.1. Feedforward Control by Periodic Signal 4.2. Linearization of Poincaré Map (OGY Method) 4.3. Delayed Feedback 4.4. Linear and Nonlinear Control 4.5. Adaptive Control 5. Discrete-time Control 6. Neural networks 7. Fuzzy systems 8. Control of chaos in distributed systems 9. Chaotic mixing 10. Generation of chaos (chaotization) 11. Other problems 12. Conclusions Acknowledgements Glossary Bibliography Biographical Sketch Summary UNESCO – EOLSS The field related to control of chaotic systems was rapidly developing during the 1990s. Its state-of-the-artSAMPLE in the beginning of the 21stCHAPTERS century is presented in this article. Necessary preliminary material is given related to notion and properties of chaotic systems, models of the controlled plants and control goals. Several major branches of research are discussed in detail: feedforward or “nonfeedback” control (based on periodic excitation of the system); OGY method (based on linearization of Poincaré map); Pyragas method (based on time-delay feedback); traditional control engineering methods of linear, nonlinear and adaptive control; neural networks; fuzzy control. Some unsolved problems concerning the justification of chaos control methods are presented.
    [Show full text]