Fluctuations and chaos in a multimode solid state laser system

Bracikowski, Christopher

08 1900

No description available.

Dynamics

Chaotic behavior in systems

Electrical chaoization and its application in industrial mixing

Ye, Shuang.

January 2007

Thesis (Ph. D.)--University of Hong Kong, 2008. / Also available in print.

Chaotic behavior in systems.

Analysis of observed chaotic data/

Çek, Mehmet Emre. Savacı, Ferit Acar

January 2004

Thesis (Master)--İzmir Institute of Technology, İzmir, 2004. / Includes bibliographical references (leaves. 86).

Chaotic behavior in systems

The recategorization of "chaos" : a case study of language change and theory change /

Glenn, Tracy A.,

January 1990

Thesis (M.S.)--Virginia Polytechnic Institute and State University, 1990. / Vita. Abstract. Includes bibliographical references (leaves 113-122). Also available via the Internet.

Chaotic behavior in systems

Some problems in the theory of open dynamical systems and deterministic walks in random environments

Yurchenko, Aleksey.

January 2008

Thesis (Ph.D)--Mathematics, Georgia Institute of Technology, 2009. / Committee Chair: Bunimovich, Leonid; Committee Member: Bakhtin, Yuri; Committee Member: Cvitanovic, Predrag; Committee Member: Houdre, Christian; Committee Member: Weiss, Howard. Part of the SMARTech Electronic Thesis and Dissertation Collection.

Chaotic behavior in systems. Dynamics.

On fractals, chaos and the Hailstone numbers.

Black, Robert D. (Robert Douglas), Carleton University. Dissertation. Computer Science.

January 1992

Thesis (M.C.S.)--Carleton University, 1992. / Also available in electronic format on the Internet.

Fractals. Chaotic behavior in systems.

Multi-mode optical resonators and wave chaos /

Dingjan, Jos,

January 1900

Thesis (doctoral)--Universiteit Leiden, 2003. / Stellingen (2 p.) inserted.

Lasers Chaotic behavior in systems.

Control and estimation of a chaotic system

Ghofranih, Jahangir

January 1990

A class of deterministic nonlinear systems known as ”chaotic” behaves similar to noise-corrupted systems. As a specific example, Duffing equation, a nonlinear oscillator representing the roll dynamics of a vessel, was chosen for the study. State estimation and control of such systems in the presence of measurement noise is the prime goal of this research. A nonlinear estimation suitable for chaotic systems was evaluated against conventional methods based on linear equivalent model, and proved to be very efficient. A state feedback controller and a sliding mode controller were applied to the chaotic system and both techniques provided satisfactory results. Investigating the persistence of chaotic behavior of the controlled system is a secondary goal. Simulation results showed that the chaotic behavior persisted in case of the linear feedback controller, while in case of the sliding mode controller the system did not exhibit any chaotic behavior. / Applied Science, Faculty of / Electrical and Computer Engineering, Department of / Graduate

Chaotic behavior in systems

Characterizing chaos in a hybrid optically bistable device.

Kaplan, David Louis.

January 1988

Turbulence and periodic oscillations are easily seen with an optically bistable device with a delay in the feedback. The device is a hybrid, having both optical and electronic components. The details of the time-dependent output are investigated. In particular, as the input intensity is increased, the device output goes through a series of second-order nonequilibrium phase transitions or bifurcations. A truncated period-doubling sequence is observed prior to the onset of turbulence or chaos. The truncation is shown to be due to a noise-induced bifurcation gap. Within the chaotic regime, the device largely follows the reverse bifurcation scheme of Lorenz. In addition, there is a small domain of frequency-locked behavior that exists within the chaotic domain. These frequency-locked waveforms represent an alternate path to chaos. With the route to choas well understood, it remained to characterize the erratic motion itself. Dimension and correlation entropy are measured for various settings of our hybrid device. The measured dimension is found to be significantly less than dimensions consistent with a conjecture due to Kaplan and Yorke. The standard method of determining correlation entropy is shown to yield more than one value.

Chaotic behavior in systems.

Optical bistability.

OBSERVATION OF CHAOS IN A HYBRID OPTICAL BISTABLE DEVICE (PERIOD-DOUBLING).

DERSTINE, MATTHEW WILLIAM.

January 1985

An analog of an optically bistable device made constructed from both optical and electronic components is used to study chaos. This hybrid optically bistable system has a delay in the feedback so that the response time of the electronics is much faster than the feedback time. Such a system is unstable and shows pulsations and chaos. The character of the pulsations change as the gain of the amplifier or the input laser power is increased. These changes make up the period doubling route to chaos. Not all of the waveforms of an ideal period doubling sequence are observed. This truncation of the period-doubling sequence in the device is investigated as a function of the noise present in the system. Increasing the noise level decreases the number of period doublings observed. In the chaotic regime waveforms other than those predicted are observed. These waveforms are the frequency-locked waveforms seen in an earlier experiment which we find to be modified versions of the typical period-doubled waveforms. The transitions between these waveforms are discontinuous, and show hysteresis loops. By the introduction of an external locking signal, we are able to stabilize waveforms in the neighborhood of the discontinuous transitions. By so doing we show that the transitions among the branches are due to their lack of stability. The transitions are thus not strictly first-order nonequilibrium phase transitions, since in that case the branches cease to exist at the transition point. Since the path to chaos is nonunique, the types of chaos that are observable are also nonunique. To suggest a way to distinguish between different types of chaos and also to provide a tool for the study of chaos in other systems, we propose an operational test for chaos which leads to a straightforward experimental distinction between chaos and noise. We examine this test using the hybrid device to show that the method works. The test involves repeated measurement of the initial transient of a system whose initial condition is fixed. This method could be used to determine the existence of chaos in faster optical systems.

Chaotic behavior in systems.

Optical bistability.