Multifractal random walk

Bacry, Emmanuel; Delour, J.; Muzy, Jean–François

doi:10.1103/physreve.64.026103

Cited by 425 publications

(504 citation statements)

References 18 publications

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“…More complementary explanations can be found in [13,42,43]. Here we assume that time is a dynamical parameter, therefore x(t) is only taken to be time dependant.…”

Section: Model and Analysismentioning

confidence: 99%

“…For a multiplicative cascading process which starts from a large scale, L, tending to small scales, ℓ, implementation of the multifractal random walk approach enables us to rewrite the increment of fluctuation as ∆ ℓ x(t) ≡ ξ ℓ (t)e ω ℓ (t) , in which ξ ℓ (t) and ω ℓ (t) are independent of each other and have Gaussian distributions with zero means. The corresponding variances are denoted by σ 2 (ℓ) and λ 2 (ℓ) for ξ ℓ (t) and ω ℓ (t), respectively [13]. In this approach, a non-Gaussian probability density function (PDF) with fat tails is expressed by [15] …”

Section: Model and Analysismentioning

confidence: 99%

“…The multifractal formalism provides almost adequate tools for studying the scaling relations and properties of objects possessing a fractal geometry and/or generalized multifractal exponents [10][11][12][13][14]. Once, the infinitely divisible cascades [15][16][17] in hydrodynamic turbulence was confirmed to be statistically scale-invariant, one important motivation for multifractal formulation to become prominent was established [18,19].…”

Section: Introductionmentioning

confidence: 99%

“…This factor only depends on the scale ratio of the processes. In a further study, by developing this theory, it has been shown that a continuous random walk model can posses multifractal properties due to the existence of a correlation in the logarithm of the stochastic variances [13,17]. It is worth noting that a strong log-normal deviation from the normal case leads to a robust state of multifractality or in other words a critical state in the underlying system.…”

Section: Introductionmentioning

confidence: 99%

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Coupled uncertainty provided by a multifractal random walker

et al. 2015

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The aim here is to study the concept of pairing multifractality between time series possessing nonGaussian distributions. The increasing number of rare events creates "criticality". We show how the pairing between two series is affected by rare events, which we call "coupled criticality". A method is proposed for studying the coupled criticality born out of the interaction between two series, using the bivariate multifractal random walk (BiMRW). This method allows studying dependence of the coupled criticality on the criticality of each individual system. This approach is applied to data sets of gold & oil markets, and inflation & unemployment.

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“…More complementary explanations can be found in [13,42,43]. Here we assume that time is a dynamical parameter, therefore x(t) is only taken to be time dependant.…”

Section: Model and Analysismentioning

confidence: 99%

Section: Model and Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Coupled uncertainty provided by a multifractal random walker

et al. 2015

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“…(FI)-GARCH (Baillie et al, 1996), α-ARCH (Diebolt and Guegan, 1991), multifractal 1 (Barral and Mandelbrot, 2002;Mandelbrot et al, 1997;Lux, 2004) or many other stochastic volatility models (Heston, 1993;Taylor, 1994) have been used to describe the nonlinear behavior associated with volatility clustering and long-term memory. Many of the stylized fact of monovariate financial returns can be captured with multiplicative nonlinear processes, of which multifractal stochastic volatility models constitute a prominent example, for instance in the form of the so-called the "multifractal random walk" (Bacry et al, 2001) and its generalizations (Pochard and Bouchaud, 2002;Bacry and Muzy, 2003). See also Muzy et al (2001) for a general multifractal multivariate generalization.…”

Section: Introductionmentioning

confidence: 99%

Properties of a simple bilinear stochastic model: Estimation and predictability

Sornette

Писаренко

2008

Physica D: Nonlinear Phenomena

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We analyze the properties of arguably the simplest bilinear stochastic multiplicative process, proposed as a model of financial returns and of other complex systems combining both nonlinearity and multiplicative noise. By construction, it has no linear predictability (zero two-point correlation) but a certain nonlinear predictability (non-zero three-point correlation). It can thus be considered as a paradigm for testing the existence of a possible nonlinear predictability in a given time series. We present a rather exhaustive study of the process, including its ability to produce fat-tailed distribution from Gaussian innovations, the unstable characteristics of the inversion of the key nonlinear parameters and of the two initial conditions necessary for the implementation of a prediction scheme and an analysis of the associated super-exponential sensitivity of the inversion of the innovations in the presence of a large impulse. Our study emphasizes the conditions under which a degree of predictability can be achieved and describe a number of different attempts, which overall illuminates the properties of the process. In conclusion, notwithstanding its remarkable simplicity, the bilinear stochastic process exhibits remarkably rich and complex behavior, which makes it a serious candidate for the modeling of financial time series among others. IntroductionDaily asset returns in liquid markets exhibit two key statistical properties: (i) price changes are not auto-correlated beyond a few minutes, but (ii) the absolute values of changes are autocorrelated over long time scales leading to long-term persistence of the volatility. Hsieh (1995) noted that nonlinear processes can generate this type of behavior while linear process cannot. Volatility clustering, also called ARCH effect (Engle, 1982) is a clear manifestation of the existence of non-linear dependences between returns observed at different lags. (FI)-GARCH (Baillie et al

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Econophysics

Daniel¹,

Sornette²

2010

Encyclopedia of Quantitative Finance

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Econophysics embodies the recent upsurge of interest by physicists into financial economics, driven by the availability of large amount of data, job shortage in physics and the possibility of applying many-body techniques developed in statistical and theoretical physics to the understanding of the self-organizing economy. This brief historical survey emphasizes that Econophysics has many historical precursors, and is in fact rooted in a continuous cross-fertilization between economics and physics that has been active in the last centuries.

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Multifractal random walk

Cited by 425 publications

References 18 publications

Coupled uncertainty provided by a multifractal random walker

Coupled uncertainty provided by a multifractal random walker

Properties of a simple bilinear stochastic model: Estimation and predictability

Econophysics

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