Outline. Learning Objectives. References. Lecture 2: Second-order Systems

Similar documents
EE222 - Spring 16 - Lecture 2 Notes 1

Section 5.4 (Systems of Linear Differential Equation); 9.5 Eigenvalues and Eigenvectors, cont d

Stability lectures. Stability of Linear Systems. Stability of Linear Systems. Stability of Continuous Systems. EECE 571M/491M, Spring 2008 Lecture 5

Nonlinear dynamics & chaos BECS

E209A: Analysis and Control of Nonlinear Systems Problem Set 3 Solutions

Nonlinear Autonomous Dynamical systems of two dimensions. Part A

Problem set 7 Math 207A, Fall 2011 Solutions

6.3. Nonlinear Systems of Equations

An Undergraduate s Guide to the Hartman-Grobman and Poincaré-Bendixon Theorems

8.1 Bifurcations of Equilibria

Math 3301 Homework Set Points ( ) ( ) I ll leave it to you to verify that the eigenvalues and eigenvectors for this matrix are, ( ) ( ) ( ) ( )

1 The pendulum equation

MCE693/793: Analysis and Control of Nonlinear Systems

Math 312 Lecture Notes Linearization

Physics: spring-mass system, planet motion, pendulum. Biology: ecology problem, neural conduction, epidemics

Local Phase Portrait of Nonlinear Systems Near Equilibria

= F ( x; µ) (1) where x is a 2-dimensional vector, µ is a parameter, and F :

BIFURCATION PHENOMENA Lecture 1: Qualitative theory of planar ODEs

7 Planar systems of linear ODE

2.10 Saddles, Nodes, Foci and Centers

3.5 Competition Models: Principle of Competitive Exclusion

10 Back to planar nonlinear systems

Math 266: Phase Plane Portrait

Classification of Phase Portraits at Equilibria for u (t) = f( u(t))

Introduction to Dynamical Systems

Nonlinear Control Lecture 2:Phase Plane Analysis

Phase Portraits of Nonlinear Differential Equations

B5.6 Nonlinear Systems

4 Second-Order Systems

Lotka Volterra Predator-Prey Model with a Predating Scavenger

DIFFERENTIAL GEOMETRY APPLIED TO DYNAMICAL SYSTEMS

Dynamics of a Population Model Controlling the Spread of Plague in Prairie Dogs

Math 232, Final Test, 20 March 2007

Dynamics and Bifurcations in Predator-Prey Models with Refuge, Dispersal and Threshold Harvesting

LECTURE 8: DYNAMICAL SYSTEMS 7

APPPHYS217 Tuesday 25 May 2010

Mathematical Modeling I

+ i. cos(t) + 2 sin(t) + c 2.

CHAPTER 6 HOPF-BIFURCATION IN A TWO DIMENSIONAL NONLINEAR DIFFERENTIAL EQUATION

Introduction to Applied Nonlinear Dynamical Systems and Chaos

MATH 215/255 Solutions to Additional Practice Problems April dy dt

Fundamentals of Dynamical Systems / Discrete-Time Models. Dr. Dylan McNamara people.uncw.edu/ mcnamarad

GLOBAL DYNAMICS OF A LOTKA VOLTERRA MODEL WITH TWO PREDATORS COMPETING FOR ONE PREY JAUME LLIBRE AND DONGMEI XIAO

2D-Volterra-Lotka Modeling For 2 Species

Continuous time population models

Def. (a, b) is a critical point of the autonomous system. 1 Proper node (stable or unstable) 2 Improper node (stable or unstable)

Problem Set Number 5, j/2.036j MIT (Fall 2014)

B5.6 Nonlinear Systems

College of Natural Science Department of Mathematics

EN Nonlinear Control and Planning in Robotics Lecture 3: Stability February 4, 2015

DIFFERENTIAL EQUATIONS, DYNAMICAL SYSTEMS, AND AN INTRODUCTION TO CHAOS

Dynamical Systems: Ecological Modeling

Chapter 7. Nonlinear Systems. 7.1 Introduction

Section 9.3 Phase Plane Portraits (for Planar Systems)

EG4321/EG7040. Nonlinear Control. Dr. Matt Turner

Calculus and Differential Equations II

Bifurcation and Stability Analysis of a Prey-predator System with a Reserved Area

Mathematical Foundations of Neuroscience - Lecture 7. Bifurcations II.

Nonlinear Control Lecture 2:Phase Plane Analysis

Stability of Dynamical systems

The Dynamic Behaviour of the Competing Species with Linear and Holling Type II Functional Responses by the Second Competitor

DIFFERENTIAL EQUATIONS, DYNAMICAL SYSTEMS, AND AN INTRODUCTION TO CHAOS

Lecture 38. Almost Linear Systems

DYNAMICAL SYSTEMS. I Clark: Robinson. Stability, Symbolic Dynamics, and Chaos. CRC Press Boca Raton Ann Arbor London Tokyo

Qualitative Analysis of Tumor-Immune ODE System

3 Stability and Lyapunov Functions

MATH 614 Dynamical Systems and Chaos Lecture 24: Bifurcation theory in higher dimensions. The Hopf bifurcation.

154 Chapter 9 Hints, Answers, and Solutions The particular trajectories are highlighted in the phase portraits below.

Constructing a chaotic system with any number of equilibria

Global Stability Analysis on a Predator-Prey Model with Omnivores

Practice Problems for Final Exam

Problem set 6 Math 207A, Fall 2011 Solutions. 1. A two-dimensional gradient system has the form

Stability Analysis of Predator- Prey Models via the Liapunov Method

Continuous Threshold Policy Harvesting in Predator-Prey Models

Lecture - 11 Bendixson and Poincare Bendixson Criteria Van der Pol Oscillator

Stable Coexistence of a Predator-Prey model with a Scavenger

Math 312 Lecture Notes Linear Two-dimensional Systems of Differential Equations

Stability and bifurcation in a two species predator-prey model with quintic interactions

B5.6 Nonlinear Systems

M.5 Modeling the Effect of Functional Responses

7.7 LOTKA-VOLTERRA M ODELS

Entrance Exam, Differential Equations April, (Solve exactly 6 out of the 8 problems) y + 2y + y cos(x 2 y) = 0, y(0) = 2, y (0) = 4.

Elements of Applied Bifurcation Theory

A Discrete Model of Three Species Prey- Predator System

Hyperbolic Dynamics. Todd Fisher. Department of Mathematics University of Maryland, College Park. Hyperbolic Dynamics p.

Lecture 3. Dynamical Systems in Continuous Time

1. < 0: the eigenvalues are real and have opposite signs; the fixed point is a saddle point

Local Stability Analysis of a Mathematical Model of the Interaction of Two Populations of Differential Equations (Host-Parasitoid)

Qualitative Analysis of Tumor-Immune ODE System

Hamiltonian Dynamics In The Theory of Abstraction

Lab 5: Nonlinear Systems

Math 5490 November 5, 2014

Research Article Global Dynamics of a Competitive System of Rational Difference Equations in the Plane

We have two possible solutions (intersections of null-clines. dt = bv + muv = g(u, v). du = au nuv = f (u, v),

April 13, We now extend the structure of the horseshoe to more general kinds of invariant. x (v) λ n v.

Solutions to Dynamical Systems 2010 exam. Each question is worth 25 marks.

TWELVE LIMIT CYCLES IN A CUBIC ORDER PLANAR SYSTEM WITH Z 2 -SYMMETRY. P. Yu 1,2 and M. Han 1

Is chaos possible in 1d? - yes - no - I don t know. What is the long term behavior for the following system if x(0) = π/2?

Dynamical Analysis of a Harvested Predator-prey. Model with Ratio-dependent Response Function. and Prey Refuge

A plane autonomous system is a pair of simultaneous first-order differential equations,

Transcription:

Outline Lecture 2: Second-order Systems! Techniques based on linear systems analysis! Phase-plane analysis! Example: Neanderthal / Early man competition! Hartman-Grobman theorem -- validity of linearizations! Example: Duffing s equation Dr. Meeko Oishi Electrical and Computer Engineering University of British Columbia, BC http://courses.ece.ubc.ca/571m moishi@ece.ubc.ca 1! Nonlinear analysis of 2 nd order systems! Closed orbits! Bendixon s theorem! Limit cycles! Index theory and Poincare theorem! Poincare-Bendixon theorem 2 Learning Objectives References! Stability through linearization! Compute the similarity transformation that results in a Jordanform state matrix! Analyze a linear system in modal coordinates and relate to stability of nonlinear system near an equilibrium point (Hartmann-Grobman)! Closed orbits and limit cycles in 2D! Distinguish between a closed orbit and a limit cycle! Determine whether a closed orbit exists (Bendixson s)! Determine whether a closed orbit exists in a given set of the state-space (Poincare-Bendixson)! Use Index theory to determine how many equilibria exist in a region of the state-space (n-dimensions)! Khalil! Section 1.2! Section 2.1, 2.3-2.6! Sastry! Section 2.2, 2.3 3 4

! Goal: Determine stability of the nonlinear system around a given equilibrium point.! Method: Analyze the linear system (an easy problem) and use Hartman-Grobman Theorem to make claims about the nonlinear system (a harder problem)! Any linear system can be transformed via a similarity transformation into real Jordan form Nonlinear system Linearization about an equilibrium point Linear system (dynamics of deviations from the equilibrium point)! The phase portrait of the system in modal coordinates depends on the form of J! The catch: Cannot apply blindly! 5 6! Case 1a:! 1!! 2! Case 1b:! 1 =0 or! 2 =0! Case 2:! Case 3: (dependent eigenvectors)! Case 1c:! 1 =! 2 =! (independent eigenvectors) 7 8

Ex. #3: Neanderthal extinction Ex. #3: Neanderthal extinction! Similar to Lotka-Volterra competition equations! Neanderthals competed with Early Modern Man approximately 50,000 years ago! Parameters! Birth rate A! Death rate B (Neanderthals), s!b (Early Man)! Competition coefficient D! Similarity parameter s! J. C. Flores, A Mathematical Model for Neanderthal Extinction, Journal of Theoretical Biology, Volume 191, Issue 3, 7 April 1998, Pages 295-298.! Show that the equilibria are! (0,0),! (0,(A-sB)/D),! ((A-B)/D, 0)! Compute the eigenvalues of the Jacobian matrix at each isolated equilibium point.! Show that the only stable equilibrium point corresponds to Neanderthals extinction and a surviving population of Early Modern Man. 9 10 Hartman-Grobman Theorem Heart Rhythms: stable foci If the linearization about equilibrium point x* of the nonlinear system (1) (2) Has no eigenvalues on the imaginary axis, then there exists a continuous map h (that has a continuous inverse), Which takes trajectories from (2) and maps them onto those of (1). 11 12

Lotka Volterra Competition ("V,"W around (1,0) ) ("V,"W around (0,1) ) 13 14 ("V,"W around (0,0) ) ("V,"W around (2/11,3/11) ) 15 16

Non-hyperbolic eq. pt (x 1, x 2 ) #>0 (x 1, x 2 ) #<0 17 18 Phase-plane analysis! Process for each equilibrium point:! Linearize nonlinear system about equilibrium point.! Compute eigenvalues and eigenvectors of D f.! Create similarity transformation.! Sketch phase-plane plot in transformed coordinates.! If eigenvalues do NOT have 0 real part, stability of linear system is same as stability of nonlinear system near the equilibrium point.! Note that pplane5 plots are simulations. They do not provide any guarantees of the actual system s behavior.! Closed orbits vs. limit cycles! Bendixon s theorem! Absence of closed orbits! Poincare-Bendixson theorem! Existence of closed orbits within an invariant set! Index theory! Poincare theorem! # of equilibria within a closed orbit 19 20

Definition: Closed orbit! A closed orbit $ of the planar system is the trace of the trajectory of a non-trivial periodic solution. Definition: Limit cycle! A limit cycle is a closed orbit g such that there is a such that (stable) (unstable) Notes:! An equilibrium point cannot be a closed orbit! For any point, there exists a finite value T such that 21 Note:! All limit cycles are closed orbits, but not all closed orbits are limit cycles.! The theorems to follow concern closed orbits, not limit cycles necessarily. 22! Bendixson s theorem Suppose D is a simply connected region in R 2, such that and div(f) does not change sign in D. Then D contains no closed orbits of! Poincare-Bendixson Theorem Consider the planar dynamical system Every closed, bounded, non-empty, positively invariant set contains an equilibrium point or a closed orbit. Notes:! Simply connected means one region with no holes.! Proves the absence of closed orbits 23 Notes:! If K contains equilibrium points, K may also contain a union of trajectories connecting these equilibrium points, but this is not create a closed orbit.! An open set U that is enclosed by a closed orbit contains an eq. point and possibly a closed orbit. 24

Index theory! Definition: The index of a region D with respect to f(x) is defined as with! Notes:! % f is the angle made by f(x) with the x 1 axis.! I f (D) is an integer! For D that contains a single equilibrium point x 0, we refer to the index of the equilibrium point at I f (x 0 ) Index theory! Poincare theorem: Let N represent the number of nodes, centers, and foci enclosed by a closed orbit, and let S represent the number of enclosed saddle points. Then N = S + 1! Notes:! Index theory predicts the existence of equilibrium points without doing detailed calculations. 25 26

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback