Comment on \Bouncing ball with nite restitution: Chattering, locking, and chaos" Nicholas B. Tullaro

Similar documents
Laboratory Investigation of the Dynamics of the Inelastic Bouncing Ball

Dynamics of a bouncing ball

Rotational Number Approach to a Damped Pendulum under Parametric Forcing

Strange dynamics of bilinear oscillator close to grazing

Period doubling boundaries of a bouncing ball

Chaotic motion. Phys 750 Lecture 9

Dynamical behaviour of a controlled vibro-impact system

Vertical chaos and horizontal diffusion in the bouncing-ball billiard

Two Methods for Determining Impact Time in the Bouncing Ball System

A simple electronic circuit to demonstrate bifurcation and chaos

Chapter 1. Introduction

Chaotic motion. Phys 420/580 Lecture 10

Antimonotonicity in Chua s Canonical Circuit with a Smooth Nonlinearity

Consequences of Quadratic Frictional Force on the One Dimensional Bouncing Ball Model

Simple approach to the creation of a strange nonchaotic attractor in any chaotic system

Irregular diffusion in the bouncing ball billiard

Oscillatory Motion. Simple pendulum: linear Hooke s Law restoring force for small angular deviations. small angle approximation. Oscillatory solution

Oscillatory Motion. Simple pendulum: linear Hooke s Law restoring force for small angular deviations. Oscillatory solution

The behavior of bouncing disks and pizza tossing

Spiral modes in the diffusion of a single granular particle on a vibrating surface

Vertical and Horizontal Stability of a Bouncing Ball on an Oscillating Surface. by Eric Bell

Newton s laws. Chapter 1. Not: Quantum Mechanics / Relativistic Mechanics

Phase Desynchronization as a Mechanism for Transitions to High-Dimensional Chaos

Chaotic Vibrations. An Introduction for Applied Scientists and Engineers

TORSION PENDULUM: THE MECHANICAL NONLINEAR OSCILLATOR

INTRODUCTION TO CHAOS THEORY T.R.RAMAMOHAN C-MMACS BANGALORE

PERTURBATIONS. Received September 20, 2004; Revised April 7, 2005

INTEGRAL BACKSTEPPING SLIDING MODE CONTROL OF CHAOTIC FORCED VAN DER POL OSCILLATOR

arxiv: v1 [nlin.cd] 7 Jun 2010

Stabilization of Hyperbolic Chaos by the Pyragas Method

Bifurcation and Chaos in Coupled Periodically Forced Non-identical Duffing Oscillators

arxiv:chao-dyn/ v1 5 Mar 1996

More Details Fixed point of mapping is point that maps into itself, i.e., x n+1 = x n.

Synchronization and control in small networks of chaotic electronic circuits

The phenomenon: complex motion, unusual geometry

Multistability in the Lorenz System: A Broken Butterfly

REGULAR AND CHAOTIC DYNAMICS IN BOUNCING BALL MODELS

Igor A. Khovanov,Vadim S. Anishchenko, Astrakhanskaya str. 83, Saratov, Russia

arxiv: v1 [nlin.cd] 13 Jul 2011

The nonsmooth pitchfork bifurcation. Glendinning, Paul. MIMS EPrint: Manchester Institute for Mathematical Sciences School of Mathematics

Genesis and Catastrophe of the Chaotic Double-Bell Attractor

On the dynamics of a vertically driven damped planar pendulum

MULTISTABILITY IN A BUTTERFLY FLOW

Simplest Chaotic Flows with Involutional Symmetries

Lyapunov exponent calculation of a two-degreeof-freedom vibro-impact system with symmetrical rigid stops

NONLINEAR DYNAMICS PHYS 471 & PHYS 571

IMPACT Today s Objectives: In-Class Activities:

Periodic windows within windows within windows

Modeling chaotic motions of a string from experimental data. Kevin Judd and Alistair Mees. The University of Western Australia.

Deterministic Chaos Lab

S12 PHY321: Practice Final

Midterm EXAM PHYS 401 (Spring 2012), 03/20/12

Co-existence of Regular and Chaotic Motions in the Gaussian Map

Maps and differential equations

IMPACT (Section 15.4)

16 Period doubling route to chaos

550 XU Hai-Bo, WANG Guang-Rui, and CHEN Shi-Gang Vol. 37 the denition of the domain. The map is a generalization of the standard map for which (J) = J

The Completely Inelastic Bouncing Ball

A damped pendulum forced with a constant torque

GIANT SUPPRESSION OF THE ACTIVATION RATE IN DYNAMICAL SYSTEMS EXHIBITING CHAOTIC TRANSITIONS

Multistability and Self-Similarity in the Parameter-Space of a Vibro-Impact System

From Last Time. Gravitational forces are apparent at a wide range of scales. Obeys

RELAXATION AND TRANSIENTS IN A TIME-DEPENDENT LOGISTIC MAP

Introduction to Dynamical Systems Basic Concepts of Dynamics

Analysis of Hermite s equation governing the motion of damped pendulum with small displacement

One Dimensional Dynamical Systems

Symbolic dynamics and chaos in plane Couette flow

Handling of Chaos in Two Dimensional Discrete Maps

Another Method to get a Sine Wave. X = A cos θ V = Acc =

MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question.

Chaos suppression of uncertain gyros in a given finite time

The Time to Synchronization for N Coupled Metronomes

Mechanical Resonance and Chaos

Controlling chaos in random Boolean networks

Lecture 1: A Preliminary to Nonlinear Dynamics and Chaos

Contents Dynamical Systems Stability of Dynamical Systems: Linear Approach

Basins of Attraction Plasticity of a Strange Attractor with a Swirling Scroll

ONE DIMENSIONAL CHAOTIC DYNAMICAL SYSTEMS

Controlling the cortex state transitions by altering the oscillation energy

A Highly Chaotic Attractor for a Dual-Channel Single-Attractor, Private Communication System

Finding numerically Newhouse sinks near a homoclinic tangency and investigation of their chaotic transients. Takayuki Yamaguchi

Analysis of Neural Networks with Chaotic Dynamics

ABOUT UNIVERSAL BASINS OF ATTRACTION IN HIGH-DIMENSIONAL SYSTEMS

Nonlinear Dynamics and Chaos Summer 2011

Synchronization of metronomes. Luis Jover, 1 Bradford Taylor, 1 Jeff Tithof, 1 and Vlad Levenfeld 2 USA USA

SPATIOTEMPORAL CHAOS IN COUPLED MAP LATTICE. Itishree Priyadarshini. Prof. Biplab Ganguli

Chaotic Photoconductivity K. G. Kyritsi 1, L. Gallos 1, A. N. Anagnostopoulos 1, A. Cenys 2, and G. L. Bleris 3

A New Dynamic Phenomenon in Nonlinear Circuits: State-Space Analysis of Chaotic Beats

M. van Berkel DCT

Role of multistability in the transition to chaotic phase synchronization

2007 Problem Topic Comment 1 Kinematics Position-time equation Kinematics 7 2 Kinematics Velocity-time graph Dynamics 6 3 Kinematics Average velocity

Double Transient Chaotic Behaviour of a Rolling Ball

898 IEEE TRANSACTIONS ON ROBOTICS AND AUTOMATION, VOL. 17, NO. 6, DECEMBER X/01$ IEEE

Sync or anti-sync dynamical pattern selection in coupled self-sustained oscillator systems

Chaos and Cryptography

Computer arithmetic and sensitivity of natural measure

gr-qc/ Sep 1995

FUZZY CONTROL OF CHAOS

Electronic Circuit Simulation of the Lorenz Model With General Circulation

The Stick-Slip Vibration and Bifurcation of a Vibro-Impact System with Dry Friction

Transcription:

Comment on \Bouncing ball with nite restitution: Chattering, locking, and chaos" Nicholas B. Tullaro Center for Nonlinear Studies and Theoretical Division, MS-B258, Los lamos National Laboratories Los lamos, New Mexico 87545 US (28 February 994) Some statements by Luck and Mehta [Phys. Rev. E 48, 3988 (993)] drawn from their analysis of the \exact" onedimensional model of a bouncing ball system are either misleading or incorrect. In particular, in agreement with previous theoretical and experimental studies, the bouncing ball system does exhibit chaotic orbits for a wide range of experimentally accessible parameters. The \sticking solutions" with long transients analyzed by Luck and Mehta are also observed and usually easily distinguished from the chaotic orbits. 46.0.+z, 03.20.+i, 05.45.+b Several researchers have studied one-dimensional models of the bouncing ball system which include the coef- cient of restitution (0 ), and many have also noted the existence of the large class of eventually periodic orbits known as \sticking solutions" []. More references can be found in Ref. [2]. ll these models which are equivalent to the dynamical equations described by Luck and Mehta have been termed the \exact" onedimensional model of the bouncing ball system [2]. The phrase \one-dimensional" refers to the number of degrees of freedom the ball moves in and not to the dimension of the phase space model. To x a notation which allows an easier comparison with experiments, recall that the dynamics of the bouncing ball system can be found by solving the (implicit) nonlinear coupled algebraic equations known as the phase map, [sin( k ) + ] + v k! ( k+, k ), 2 g! ( k+, k ) 2, [sin( k+ )+]=0 () and the velocity map, ( + )! cos( k+ ), v k, g! ( k+, k ) = v k+ (2) where k =!t + 0 and v k are the phase and velocity of the k-th impact between the ball and oscillating table, and! are the table's amplitude and angular frequency, is the coecient of restitution, and g is the gravitational acceleration. The implicit phase map and explicit velocity map constitute the exact model of the bouncing ball system. Earlier experimental studies showed an excellent correspondence between the exact model and the dynamics of an experimental bouncing ball system, all the major bifurcations predicted by the exact model occurred within the experimental system [3]. Observations between the model and experiment agreed to within %2 with no tted parameters. public domain program, the Bouncing Ball Simulation System, has also been available since 986 which simulates the exact model [2]. We use this program to obtain the results presented here. Experiments illustrating chaos in the bouncing ball system usually proceed along the following lines. The amplitude the table driving the ball is slowly increased while monitoring the dynamics of the bouncing ball through an experimental impact map, which is similar to a next return map [2]. In essence, an experimental bifurcation diagram is created. The coecient of restitution can be changed from around 0.2 to 0.8 by using dierent materials for the ball (eg., wood, plastic, steel). Experimentally, it is observed that a chaotic invariant set is seen at the end of the period doubling cascade, but for a further increase in the driving amplitude, the strange attractor is destroyed by a crisis. The dynamics of the ball after this crisis can result in motion which can quickly approach a periodic sticking solution (generally speaking, for smaller values of ), or can exhibit long transients sometimes called `transient chaos' [5] following the \shadow of the strange attractor" (generally speaking, for larger values of ). It is the dynamics of this transient chaos when is close to one that Luck and Mehta analyze [6]. Direct simulation of the \exact" model exhibits a similar behavior. Figure presents a bifurcation diagram showing a period doubling route to chaos for =0:5. Note that this strange attractor is approached in exactly the same way asitwould be in an experiment, namely, by slowly scanning the amplitude until the end of the period doubling cascade is reached and a non-periodic orbit is observed. In simulations ( = 0:02) the strange attractor is found to be stable for over 0 6 impacts. Between =0:02 and =0:022 a crisis occurs which destroys this strange attractor. For >0:022 the orbit follows the shadow of the strange attractor for a number of impacts but eventually converges to a sticking solution (typically after 0 2 to 0 3 impacts). In both experiments and simulations, the pre-crisis (chaotic) dynamics and post-crisis (eventually periodic) dynamics are usually easy to distinguish because the range of impact phases

explored by the ball suddenly widens after the crisis. In the simulation shown in Figure, the chaotic dynamics is conned to a phase between,0: <=2<0:3 where as the post-crisis dynamics explores almost the entire range of phases available. This feature provides a nice signature to distinguish the pre- and post-crisis dynamics in both experiments and simulations. This general scenario of period-doubling, chaos, crisis, and sticking solutions (possibly with transient chaos) is not conned to a few selected parameter values but is generally observed for a wide range of. For instance, Fig. 2 shows this same scenario for =0:, and Fig. 3 for = 0:8. Figure 3, though, also illustrates that the amplitude range where a strange attractor is observed shrinks as approaches one, which is perhaps the reason why Luck and Mehta did not notice this scenario, especially if they conned their simulations and analysis to the regime where. We conclude by stating that in our opinion earlier theory and experiments did not take a \rather cavalier" attitude toward models including a nite coecient of restitution, but that when presenting results of earlier experiments [3,7] the experimenters where fully aware of the coexistence of strange attractors and sticking solutions, and how to experimentally distinguish both types of invariant sets. Further, while we agree that one-dimensional maps are in general a good qualitative rst step in modeling dynamical systems which are inherently two-dimensional, we must also disagree with the statement that the completely inelastic ( = 0) model is \a good qualitative indicator for the dynamics of the ball with nite restitution up to values close to." Rather, our experiments and simulations show signicant new behavior in the exact model which is not predicted by the completely inelastic model for moderate inelasticity (say, = 0:5). Finally, we nd that a strange attractor is easy to observe in both experiments and simulations for realistic and experimentally accessible parameter values. In a future communication we will actually use topological methods to \prove" the existence of a chaotic invariant set in the exact one-dimensional model of the bouncing ball system [8]. Engrs. 75, 982 (987). [6] J. M. Luck and. Mehta, Phys. Rev. E 48, 3988 (993). [7] N. B. Tullaro and. M. lbano, m. J. Phys. 54, 939 (986); T. M. Mello and N. B. Tullaro, m. J. Phys. 55, 36 (987); K. Wiesenfeld and N. B. Tullaro, Physica D 26, 32 (987). [8] N. B. Tullaro, \Braid analysis of a bouncing ball," (Physical Review E, 994). FIG.. Bifurcation diagram for the exact one-dimensional model of the bouncing ball system with damping = 0:5. The table amplitude () is measured in centimeters. Diagram generated with the Bouncing Ball Simulation System. For more details about the program see Ref. [2]. FIG. 2. Bifurcation diagram for the exact one-dimensional model of the bouncing ball system with damping = 0:. Diagram generated with the Bouncing Ball Simulation System [2]. FIG. 3. Bifurcation diagram for the exact one-dimensional model of the bouncing ball system with damping = 0:8. Diagram generated with the Bouncing Ball Simulation System [2]. Internet: nbt@reed.edu. [] C. N. Bapat, S. Shankar, and N. Popplewell, J. Sound Vib. 08, 99 (986). [2] N. B. Tullaro, T.. bbott, and J. P. Reilly, n experimental approach to nonlinear dynamics and chaos (ddison-wesley, Reading, M, 992). [3] N. B. Tullaro et. al., J. Phys. France 47, 477 (986). [4] C. Grebogi, E. Ott, and J.. Yorke, Physica D 7, 8 (983). [5] T. S. Parker and L. O. Chua, Proc. Inst. Elect. Electron. 2

α = 0.5 Crisis with sticking solution Figure. Tufillaro: Comment on Bouncing ball with finite restitution: Chattering, locking, and chaos

α = 0. Crisis leading to periodic sticking solution Figure 2. Tufillaro: Comment on Bouncing ball with finite restitution: Chattering, locking, and chaos

α = 0.8 Figure 3. Tufillaro: Comment on Bouncing ball with finite restitution: Chattering, locking, and chaos

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