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Statistical and Nonlinear Physics

Overview: Unsolved Problems of Noise and Fluctuations

Profile image of Derek AbbottDerek Abbott

2001, Chaos: An Interdisciplinary Journal of Nonlinear …

https://doi.org/10.1063/1.1398543
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This issue compiles papers from the UPoN'99 conference on unresolved issues in noise and fluctuations. It traces the historical context from Robert Brown's early experiments with pollen in water to contemporary theoretical discussions about noise's constructive roles in systems such as neural networks. The discussions underscore the need to explore asymmetries in nature, as opposed to symmetries, to better understand the interactions between disorder and fluctuating systems, thereby addressing intriguing unsolved questions.

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Fluctuations and simple chaotic dynamics
James Crutchfield

Physics Reports, 1982

I. Introduction 47 Appendix A. Fluctuations in a driven anharmonic oscillator 76 2. Dynamics in the absence of fluctuations 48 Appendix B. Characteristic exponents in period-doubling 3. Dynamics in the presence of fluctuations 57 regimes 77 4. Noise as a disordering field 68 Appendix C. Equivalence of parametric and additive noise 80 5. Concluding remarks 74 References 81

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Quantum noise-induced chaotic oscillations
Deb Shankar Ray

Physical Review E, 2000

We examine the weak quantum noise limit of Wigner equation for phase space distribution functions. It has been shown that the leading order quantum noise described in terms of an auxiliary Hamiltonian manifests itself as an additional fluctuational degree of freedom which may induce chaotic and regular oscillations in a nonlinear oscillator.

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Stochastic Resonance in Noisy Nondynamical Systems
Gabriel Gomila

Physical Review Letters, 1998

We have analyzed the effects of the addition of external noise to non-dynamical systems displaying intrinsic noise, and established general conditions under which stochastic resonance appears. The criterion we have found may be applied to a wide class of non-dynamical systems, covering situations of different nature. Some particular examples are discussed in detail.

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Experimental study of stochastic resonance in a Chua’s circuit operating in a chaotic regime
Raul Toral

Physica D: Nonlinear Phenomena, 2006

We present results of an experimental study of stochastic resonance in an electronic Chua's circuit whose dynamics switches between two different stable chaotic attractors when it is driven by a periodic signal and a Gaussian white noise. Due to the internal dynamics of the attractors the minimum amplitude for the external forcing to induce jumps strongly depends on the external frequency. We determine from the Fourier transform of the output signal the amplification factor of the input signal and study its dependence on the external frequency and the noise intensity. We show that the envelope of the distribution of switching times follows a gamma distribution, typical from bistable systems, and that the mean switching time decays exponentially with the noise intensity. We propose a simple method for obtaining the optimal noise intensity from the residence and switching times probability distributions and show that it coincides with the value obtained from the maximum of the amplification factor. (C.R. Mirasso). resonance in deterministic dynamical systems and, since it is induced by the noise, it is called stochastic resonance. The study of stochastic resonance in bistable systems has also been extended to excitable systems having a single rest state and to threshold detectors (a pulse occurs whenever the sum of the signal and the noise at the input crosses a threshold). Since the conditions for the appearance of stochastic resonance do not depend on very specific model details, it has been observed in many different fields such as paleoclimatology, lasers, neurophysiology, electronic detectors, etc. and studies of this phenomenon cross disciplinary boundaries. Various reviews [1-4] address the recent and extensive work on this fascinating subject.

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Beyond the Death of Linear Response: 1/f- noise Resonance
frog kermit, Gerardo Aquino

2010

Non-ergodic renewal processes have recently been shown by several authors to be insensitive to periodic perturbations, thereby apparently sanctioning the death of linear response, a building block of nonequilibrium statistical physics. We show that it is possible to go beyond the ``death of linear response" and establish a permanent correlation between an external stimulus and the response of a complex network generating non-ergodic renewal processes, by taking as stimulus a similar non-ergodic process. We propose a theory for the transport of information through non-ergodic systems that explains why 1/f-noise is an efficient stimulus for complex systems. The ideal condition of 1/f-noise corresponds in fact to a singularity that is expected to be relevant in several experimental conditions of physical and biological interest.

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Noise can reduce disorder in chaotic dynamics
Denis Goldobin

The European Physical Journal Special Topics, 2014

We evoke the idea of representation of the chaotic attractor by the set of unstable periodic orbits and discover a novel noise-induced ordering phenomenon. For long unstable periodic orbits the weights (or natural measure) appear to be highly inhomogeneous over the set either diminishing or enhancing their contribution into system dynamics. We show analytically a weak noise to reduce this inhomogeneity and, additionally to obvious perturbing effect, make a regularizing influence on the chaotic dynamics. We demonstrate this universal effect rooted into the nature of deterministic chaos for the Lorenz system. The effect can be observed as shrinking of the distribution of averages over finite segments of the chaotic trajectory and lead to significant enhancement of the coherence of chaotic oscillations.

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Stochastic resonance in chaotic systems
Vadim Anishchenko

Journal of Statistical Physics, 1993

The phenomenon of stochastic resonance (SR) is investigated for chaotic systems perturbed by white noise and a harmonic force. The bistable discrete map and the Lorenz system are considered as models. It is shown that SR in chaotic systems can be realized via both parameter variation (in the absence of noise) and by variation of the noise intensity with fixed values of the other parameters.

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Stochastic Resonance, Brownian Ratchets, and the Fokker-Planck Equation
Derek Abbott

2003

Our immediate aim is to arrive at quantitative realistic estimates of the optimum noise levels for a complete and feasible Brownian ratchet device. A number of difficult "Unsolved Problems of Noise" naturally arise in the course of this work. We pose a general philosophical question: "Is it is possible to relate stochastic resonance and Brownian ratchets in a formal way, through a consideration of the Fokker-Planck equation?" The evidence suggests that some forms of stochastic resonance can be formulated in terms of a Fokker-Planck equation and some cannot. Stochastic resonance may actually be a collection of similar but distinct phenomena.

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Book review: Noise induced transitions, theory, and applications in physics, chemistry, and biology
Bruce West

Journal of Statistical Physics, 1985

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Stochastic Resonance: A remarkable idea that changed our perception of noise
Eloisa Marchesoni

The European Physical Journal B, 2009

Despite a slow start after being introduced in the 1980's, the idea of Stochastic Resonance spurred since remarkable cross disciplinary interest in natural and social sciences. Ten years after our comprehensive review [Rev. Mod. Phys. 70, 223 (1998)] Stochastic Resonance has become a research field on its own. The present Topical Issue presents the most recent applications and extensions of this surprisingly simple and still powerful idea. PACS. 02.50.Ey Stochastic processes -05.40.-a Brownian motion -05.10.Gg Stochastic analysis methods

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