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Transcript
INTRODUCTION TO NONLINEAR DYNAMICS AND CHAOS by Bruce A. Mork Michigan Technological University Presented for EE 5320 Course Michigan Technological University March 27, 2001 NONLINEARITIES - EXAMPLES • CHEMISTRY AND PHYSICS – – – – CHEMICAL REACTIONS (KINETICS) THIN FILM DEPOSITION (LASER DEPOSITION) TURBULENT FLUID FLOWS CRYSTALLINE GROWTH • MEDICAL & BIOLOGICAL – – – – – HEART DISORDERS (ARRHYTHMIA, FIBRILLATION) BRAIN AND NERVOUS SYSTEM POPULATION DYNAMICS EPIDEMIOLOGY FORECASTING (FLU, DISEASES) FOOD SUPPLY (VS. WEATHER & POPULATION) • ECONOMY – STOCK MARKET – WORLD ECONOMY NONLINEARITIES - EXAMPLES • ENGINEERING – STRUCTURES: BUILDINGS, BRIDGES – HIGH VOLTAGE TRANSMISSION LINES - WIND-INDUCED VIBRATIONS - GALLOPING – MAGNETIC CIRCUITS – COMMUNICATIONS SCRAMBLING - CHAOS GENERATOR – POWER SYSTEMS LOAD FLOW - VOLTAGE COLLAPSE – NONLINEAR CONTROLS – SIMPLE PENDULUM - LINEAR FOR SMALL SWINGS, BECOMES NONLINEAR FOR LARGE ANGLE OSCILLATIONS • KEY REALIZATIONS – NONLINEARITY IS THE RULE, NOT THE EXCEPTION ! – LINEARIZATION OR REDUCED-ORDER MODELING MAY ONLY BE VALID FOR A SMALL RANGE OF SYSTEM OPERATION (I.E. SMALL-SIGNAL RESPONSE) ……… BE CAREFUL ! DUFFING’S OSCILLATOR A SIMPLE NONLINEAR SYSTEM FERRORESONANCE IN WYE-CONNECTED SYSTEMS X1 VC A H1 B H2 VA VB X2 X3 C H3 X0 BACKFED VOLTAGE DEPENDS ON CORE CONFIGURATION TRIPLEX WOUND OR STACKED 3-LEG STACKED CORE SHELL FORM 5-LEG STACKED CORE 5-LEG WOUND CORE 4-LEG STACKED CORE NONLINEAR DYNAMICAL SYSTEMS: BASIC CHARACTERISTICS • MULTIPLE MODES OF RESPONSE POSSIBLE FOR IDENTICAL SYSTEM PARAMETERS. • STEADY STATE RESPONSES MAY BE OF DIFFERENT PERIOD THAN FORCING FUNCTION, OR NONPERIODIC (CHAOTIC). • STEADY STATE RESPONSE MAY BE EXTREMELY SENSITIVE TO INITIAL CONDITIONS OR PERTURBATIONS . • BEHAVIORS CANNOT PROPERLY BE PREDICTED BY LINEARIZED OR REDUCED ORDER MODELS. • THEORY MATURED IN LATE 70s, EARLY 80s. • PRACTICAL APPLICATIONS FROM LATE 80s. EXPERIMENTAL PROCEDURE: CATEGORIZATION OF MODES OF FERRORESONANCE BEHAVIOR • FULL SCALE LABORATORY TESTS. • 5-LEG WOUND CORE, RATED 75-kVA, WINDINGS: 12,470GY/7200 - 480GY/277 (TYPICAL IN 80% OF U.S. SYSTEMS). • RATED VOLTAGE APPLIED. • ONE OR TWO PHASES OPEN-CIRCUITED. • CAPACITANCE(S) CONNECTED TO OPEN PHASE(S) TO SIMULATE CABLE. • VOLTAGE WAVEFORMS ON OPEN PHASE(S) RECORDED AS CAPACITANCE IS VARIED. VOLTAGE X1-X0 C = 9 F X2, X3 ENERGIZED X1 OPEN “ PERIOD ONE ” PHASE PLANE DIAGRAM FOR VX1 VOLTAGE X1-X0 C = 9 F X2, X3 ENERGIZED X1 OPEN “ PERIOD ONE ” DFT FOR VX1 ONLY ODD HARMONICS VOLTAGE X1-X0 C = 10 F X2, X3 ENERGIZED X1 OPEN “ PERIOD TWO ” PHASE PLANE DIAGRAM FOR VX1 VOLTAGE X1-X0 C = 10 F X2, X3 ENERGIZED X1 OPEN “ PERIOD TWO ” DFT FOR VX1 HARMONICS AT MULTIPLES OF 30 Hz. VOLTAGE X1-X0 C = 15 F X2, X3 ENERGIZED X1 OPEN “ TRANSITIONAL CHAOS ” PHASE PLANE DIAGRAM FOR VX1 TRAJECTORY DOES NOT REPEAT. VOLTAGE X1-X0 C = 15 F X2, X3 ENERGIZED X1 OPEN “ TRANSITIONAL CHAOS ” DFT FOR VX1 NOTE: DISTRIBUTED SPECTRUM. VOLTAGE X1-X0 C = 17 F X2, X3 ENERGIZED X1 OPEN “ PERIOD FIVE ” PHASE PLANE DIAGRAM FOR VX1 VOLTAGE X1-X0 C = 17 F X2, X3 ENERGIZED X1 OPEN “ PERIOD FIVE ” DFT FOR VX1 HARMONICS AT “ODD ONE-FIFTH” SPACINGS. i.e. 12, 36, 60, 84... VOLTAGE X1-X0 C = 18 F X2, X3 ENERGIZED X1 OPEN “ TRANSITIONAL CHAOS ” PHASE PLANE DIAGRAM FOR VX1 NOTE: TRAJECTORY DOES NOT REPEAT. VOLTAGE X1-X0 C = 18 F X2, X3 ENERGIZED X1 OPEN “ TRANSITIONAL CHAOS ” DFT FOR VX1 NOTE: DISTRIBUTED SPECTRUM. VOLTAGE X1-X0 C = 25 F X2, X3 ENERGIZED X1 OPEN “ PERIOD THREE ” PHASE PLANE DIAGRAM FOR VX1 VOLTAGE X1-X0 C = 25 F X2, X3 ENERGIZED X1 OPEN “ PERIOD THREE ” DFT FOR VX1 HARMONICS AT “ODD ONE-THIRD” SPACINGS. i.e. 20, 60, 100... VOLTAGE X1-X0 C = 40 F X2, X3 ENERGIZED X1 OPEN “ CHAOS ” POINCARÉ SECTION FOR VX1 ONE POINT PER CYCLE SAMPLED FROM PHASE PLANE TRAJECTORY. VOLTAGE X1-X0 C = 40 F X2, X3 ENERGIZED X1 OPEN “ CHAOS ” DFT FOR VX1 NOTE: DISTRIBUTED FREQUENCY SPECTRUM. SPONTANEOUS TRANSITION BETWEEN MODES OF PERIOD ONE. C = 20 F X1, X3 ENERGIZED X2 OPEN BLURRED AREAS SHOW MODE TRANSITION. SPONTANEOUS TRANSITION BETWEEN MODES OF PERIOD ONE. C = 14 F X1 ENERGIZED X2 OPEN BLURRED AREAS SHOW MODE TRANSITION. SPONTANEOUS TRANSITION BETWEEN MODES OF PERIOD ONE. C = 14 F X1 ENERGIZED X2 OPEN BLURRED AREAS SHOW MODE TRANSITION. INTERMITTENCY X2 & X3 ENERGIZED, X1 OPEN, C = 45 F GLOBAL PREDICTION OF FERRORESONANCE • PREDICTION APPEARS DIFFICULT DUE TO WIDE RANGE OF POSSIBLE BEHAVIORS. • A TYPE OF BIFURCATION DIAGRAM, AS USED TO STUDY NONLINEAR SYSTEMS, IS INTRODUCED FOR THIS PURPOSE. • MAGNITUDES OF VOLTAGES FROM SIMULATED POINCARÉ SECTIONS ARE PLOTTED AS THE CAPACITANCE IS SLOWLY VARIED (BOTH UP AND DOWN). • POINTS ARE SAMPLED ONCE EACH 60-Hz CYCLE. • AN “ADEQUATE ” MODEL IS REQUIRED. CAPACITANCE VARIED 0 - 30 F MODES: 1-2-C-5-C-3-C BIFURCATION DIAGRAMS: ENERGIZE X2, X3. X1 LEFT OPEN. CAPACITANCE VARIED 30 - 0 F CONCLUSIONS • FERRORESONANT BEHAVIOR IS TYPICAL OF NONLINEAR DYNAMICAL SYSTEMS. • RESPONSES MAY BE PERIODIC OR CHAOTIC. • MULTIPLE MODES OF RESPONSE ARE POSSIBLE FOR THE SAME PARAMETERS. • STEADY STATE RESPONSES CAN BE SENSITIVE TO INITIAL CONDITIONS OR PERTURBATIONS. • SPONTANEOUS TRANSITIONS FROM ONE MODE TO ANOTHER ARE POSSIBLE. • WHEN SIMULATING, THERE MAY NOT BE “ONE CORRECT” RESPONSE. CONCLUSIONS (CONT’D) • BIFURCATIONS OCCUR AS CAPACITANCE IS VARIED UPWARD OR DOWNWARD. • PLOTTING Vpeak vs. CAPACITANCE OR OTHER VARIABLES GIVES DISCONTINUOUS OR MULTI-VALUED FUNCTIONS. • THEREFORE, SUPPOSITION OF TRENDS BASED ON LINEARIZING A LIMITED SET OF DATA IS PARTICULARLY PRONE TO ERROR. • BIFURCATION DIAGRAMS PROVIDE A ROAD MAP, AVOIDING NEED TO DO SEPARATE SIMULATIONS AT DISCRETE VALUES OF CAPACITANCE AND INITIAL CONDITIONS. CONCLUSIONS (CONT’D) • DFTs ARE USEFUL FOR CATEGORIZING THE DIFFERENT MODES OF FERRORESONANCE. • PHASE PLANE DIAGRAMS PROVIDE A UNIQUE SIGNATURE OF PERIODIC RESPONSES. • PHASE PLANE TRAJECTORIES PROVIDE THE DATA FOR POINCARÉ SECTIONS, FRACTAL DIMENSION, AND LYAPUNOV EXPONENTS. • CATEGORIZATION OF RESPONSES CAN BE MORE CLEARLY DONE USING THE SYNTAX OF NONLINEAR DYNAMICS. CONTINUING WORK • THE AUTHORS ARE CONTINUING THIS WORK UNDER SEPARATE FUNDING. – IMPROVEMENT OF LUMPED PARAMETER TRANSFORMER MODELING. – CONTINUED APPLICATION OF NONLINEAR DYNAMICS AND CHAOS TO LOW-FREQUENCY TRANSIENTS. • ACKNOWLEDGEMENTS – National Science Foundation RIA Grant – BONNEVILLE POWER ADMINISTRATION. – AREA UTILITIES, NRECA, AND CONSULTANTS. COMMENTS? QUESTIONS?
