Lorenz System Vanessa Salas

Slides:

Advertisements

Similar presentations

Polynomial Inequalities in One Variable

Advertisements

Lecture III of VI (Claudio Piani) Rotation, vorticity, geostrophic adjustment, inertial oscillations, gravity waves with rotation.

Strange Attractors From Art to Science

7.4 Predator–Prey Equations We will denote by x and y the populations of the prey and predator, respectively, at time t. In constructing a model of the.

Related Rates Kirsten Maund Dahlia Sweeney Background Calculus was invented to predict phenomena of change: planetary motion, objects in freefall, varying.

1 MECH 221 FLUID MECHANICS (Fall 06/07) Tutorial 6 FLUID KINETMATICS.

Chaos in Dynamical Systems Baoqing Zhou Summer 2006.

Deterministic Chaos PHYS 306/638 University of Delaware ca oz.

CS 6825: Motion Part 2 – Optical Flow Recall: Optical Flow is an approximation of the 2D motion field. is an approximation of the 2D motion field. Motion.

1 6.3 Separation of Variables and the Logistic Equation Objective: Solve differential equations that can be solved by separation of variables.

Use intercepts to graph an equation

Euler’s Equation in Fluid Mechanics. What is Fluid Mechanics? Fluid mechanics is the study of the macroscopic physical behavior of fluids. Fluids are.

Strange Attractors and Lorenz Equations

The Lorenz Equations Erik Ackermann & Emma Crow- Willard.

Simple Chaotic Systems and Circuits

Linear Inequalities Foundation Part I. An INEQUALITY shows a relationship between two variables, usually x & y Examples –y > 2x + 1 –y < x – 3 –3x 2 +

Chaos and Strange Attractors

Renormalization and chaos in the logistic map. Logistic map Many features of non-Hamiltonian chaos can be seen in this simple map (and other similar one.

1 GEM2505M Frederick H. Willeboordse Taming Chaos.

Class 5: Question 1 Which of the following systems of equations can be represented by the graph below?

Strange Attractors From Art to Science J. C. Sprott Department of Physics University of Wisconsin - Madison Presented to the Society for chaos theory in.

Ch 9.8: Chaos and Strange Attractors: The Lorenz Equations

Eurocode 1: Actions on structures – Part 1–2: General actions – Actions on structures exposed to fire Part of the One Stop Shop program Annex A (informative)

10.1 Parametric Functions. In chapter 1, we talked about parametric equations. Parametric equations can be used to describe motion that is not a function.

Chaos Theory MS Electrical Engineering Department of Engineering

Chaos in a Pendulum Section 4.6 To introduce chaos concepts, use the damped, driven pendulum. This is a prototype of a nonlinear oscillator which can.

SOLUTION STEP 1 Use intercepts to graph an equation EXAMPLE 2 Graph the equation x + 2y = 4. x + 2y = 4 x =  x- intercept 4 Find the intercepts. x + 2(0)

Some figures adapted from a 2004 Lecture by Larry Liebovitch, Ph.D. Chaos BIOL/CMSC 361: Emergence 1/29/08.

Introduction to Chaos Clint Sprott Department of Physics University of Wisconsin - Madison Presented to Physics 311 at University of Wisconsin in Madison,

Nonlinear Oscillations; Chaos Mainly from Marion, Chapter 4 Confine general discussion to oscillations & oscillators. Most oscillators seen in undergrad.

Dynamical Systems 4 Deterministic chaos, fractals Ing. Jaroslav Jíra, CSc.

Simple Chaotic Systems and Circuits J. C. Sprott Department of Physics University of Wisconsin - Madison Presented at the University of Augsburg on October.

1 Challenge the future Chaotic Invariants for Human Action Recognition Ali, Basharat, & Shah, ICCV 2007.

Section 3 Arc Length. Definition Let x = f(t), y = g(t) and that both dx/dt and dy/dt exist on [t 1,t 2 ] The arc length of the curve having the above.

A Simple 2-Dimensional Chaotic Thunderstorm Model with Rain Gushes Stanley David Gedzelman Department of Earth and Atmospheric Sciences and NOAA CREST.

HW/Tutorial # 1 WRF Chapters 14-15; WWWR Chapters ID Chapters 1-2

Unit 2: Heat Chapter 5 Section 5.3: Changes of State (Slide Show #2)

Controlling Chaos Journal presentation by Vaibhav Madhok.

Wednesday, March 2, 2016MAT 145. Wednesday, March 2, 2016MAT 145 Ripples on the Pond.

Simple Chaotic Systems and Circuits

Introduction to Chaos Clint Sprott

PLOT ANY POINT Solutions To Linear Equations.

Analyzing Stability in Dynamical Systems

Quick Graphs of Linear Equations

GENERAL & RECTANGULAR COMPONENTS

A Simple Circuit Implementation of Op-Amp Based Lorenz Attractor

Calculus with Parametric Curves

Extended Surface Heat Transfer

Complex Behavior of Simple Systems

Strange Attractors From Art to Science

rectangular coordinate system spherical coordinate system

כתיבה מדעית והצגת מצגת הרצאה במסגרת קורס פרוייקט לשנה ג בגיאופיסיקה

Solubility Curves.

Solubility Curves.

Ch 1.1: Basic Mathematical Models; Direction Fields

Solve the differential equation. {image}

Background Calculus was invented to predict phenomena of change: planetary motion, objects in freefall, varying populations, etc. In many practical applications,

Differentiate. f (x) = x 3e x

8 Planet Solar System in 4D with Drag

Differentiate the function: {image}

Lecture 2 Ordinary Differential Equations fall semester

Which equation does the function {image} satisfy ?

Graphing with X- and Y-Intercepts

“Teach A Level Maths” Vol. 1: AS Core Modules

States of Matter Solid Liquid Gas Plasma Catalyst Fixed Shape?

Localizing the Chaotic Strange Attractors of Multiparameter Nonlinear Dynamical Systems using Competitive Modes A Literary Analysis.

Derivatives Integrals Differential equations Series Improper

Presentation transcript:

Lorenz System Vanessa Salas a slide with the title, your name, and a large, descriptive still image. Lorenz System Vanessa Salas

LORENZ Attractor The Lorenz system is a ODE – Ordinary differential equation first studied by Edward Lorenz. Which describes the motion of a fluid between two layers at different temperature. Specifically, the fluid is heated uniformly from below and cooled uniformly from above. While the Lorenz attractor is a set of solution that looks pretty chaotic it is a DETERMINISTIC system and not solutions are chaotic. Sensitive to the initial conditions, two initial states no matter how close will diverge, usually sooner rather than later. 1. 3 differential equations: dx/dt = σ * (y-x) dy/dt = x * (⍴-z) - y dz/dt = x * y – b * z 2. Set starting pts & take Lorenz derivative over time t 3. Set up arrays for the lines and pts & set up axis 4. Plot the background for each frame. 5. Animate it, 2 time steps per frame means that trajectories cannot cross or merge, hence the two surfaces of the strange attractor can only appearto merge. A fractal is a set of points with zero volume but infinite surface area https://en.wikipedia.org/wiki/Lorenz_system http://dis.unal.edu.co/~gjhernandezp/sim/lectures/DeterministicModelsAndChaos/lorenz.pdf

.