On Estimation of a Functional of a Probability Density Function

The problem of estimating the integral of the square of a probability density function is considered, It is shown that under some regularity conditions the kernel estimate of this functional is asymptotically normally distributed. An expression for the smoothing parameter that minimizes the mean square error of the estimate is derived. Results of simulation studies are included. AMS (1980) Subject Classification: Primary 62G07 Secondary 60FOS.

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Effects of the Fractional Laplacian Order on the Nonlocal Elastic Rod Response

ASCE-ASME J Risk and Uncert in Engrg Sys Part B Mech Engrg ◽

10.1115/1.4036806 ◽

2017 ◽

Vol 3 (3) ◽

Cited By ~ 3

Author(s):

Giuseppina Autuori ◽

Federico Cluni ◽

Vittorio Gusella ◽

Patrizia Pucci

Keyword(s):

Probability Density Function ◽

Probability Density ◽

Density Function ◽

Coefficient Of Variation ◽

Fractional Laplacian ◽

Numerical Procedure ◽

Elastic Rod ◽

The Mean ◽

Distributed Forces ◽

Nonlinear Fashion

In this paper, we yield with a nonlocal elastic rod problem, widely studied in the last decades. The main purpose of the paper is to investigate the effects of the statistic variability of the fractional operator order s on the displacements u of the rod. The rod is supposed to be subjected to external distributed forces, and the displacement field u is obtained by means of numerical procedure. The attention is particularly focused on the parameter s, which influences the response in a nonlinear fashion. The effects of the uncertainty of s on the response at different locations of the rod are investigated by the Monte Carlo simulations. The results obtained highlight the importance of s in the probabilistic feature of the response. In particular, it is found that for a small coefficient of variation of s, the probability density function of the response has a unique well-identifiable mode. On the other hand, for a high coefficient of variation of s, the probability density function of the response decreases monotonically. Finally, the coefficient of variation and, to a small extent, the mean of the response tend to increase as the coefficient of variation of s increases.

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An improved energy envelope stochastic averaging method and its application to a nonlinear oscillator

Journal of Vibration and Control ◽

10.1177/1077546315575471 ◽

2016 ◽

Vol 23 (1) ◽

pp. 119-130 ◽

Cited By ~ 2

Author(s):

Yaping Zhao

Keyword(s):

Steady State ◽

Probability Density Function ◽

Probability Density ◽

Averaging Method ◽

Stochastic Averaging ◽

Stochastic Averaging Method ◽

System Response ◽

Mean Square ◽

Fpk Equation ◽

The Mean

An improved stochastic averaging method of the energy envelope is proposed, whose application sphere is extensive and whose implementation is convenient. An oscillating system with both nonlinear damping and stiffness is taken into account. Its averaged Fokker-Planck-Kolmogorov (FPK) equation in respect of the transition probability density function of the energy envelope is deduced by virtue of the method mentioned above. Under the initial and boundary conditions, the joint probability density function as to the displacement and velocity of the system is worked out in closed form after solving the averaged FPK equation by right of a technique based on the integral transformation. With the aid of the special functions, the transient solutions of the probabilistic characteristics of the system response are further derived analytically, including the probability density functions and the mean square values. A simple approach to generate the ideal white noise is drastically ameliorated in order to produce the stationary wide-band stochastic external excitation for the Monte Carlo simulating investigation of the nonlinear system. Both the theoretical solution and the numerical solution of the probabilistic properties of the system response are obtained, which are extremely coincident with each other. The numerical simulation and the theoretical computation all show that the time factor has a certain influence on the probability characteristics of the response. For example, the probabilistic distribution of the displacement tends to be scattered and the mean square displacement trends toward its steady-state value as time goes by. Of course the transient process to reach the steady-state value will obviously be shorter if the damping of the system is greater.

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Stochastic Response and Stability Analysis of Two-Point Mooring System

Volume 6: Ocean Engineering ◽

10.1115/omae2011-49714 ◽

2011 ◽

Cited By ~ 1

Author(s):

A. K. Banik ◽

T. K. Datta

Keyword(s):

Stability Analysis ◽

Probability Density Function ◽

Probability Density ◽

Mooring System ◽

Mean Square ◽

Stochastic Response ◽

Sea State ◽

Mean Square Response ◽

Linear Damping ◽

The Mean

The stochastic response and stability of a two-point mooring system are investigated for random sea state represented by the P-M sea spectrum. The two point mooring system is modeled as a SDOF system having only stiffness nonlinearity; drag nonlinearity is represented by an equivalent linear damping. Since no parametric excitation exists and only the linear damping is assumed to be present in the system, only a local stability analysis is sufficient for the system. This is performed using a perturbation technique and the Infante’s method. The analysis requires the mean square response of the system, which may be obtained in various ways. In the present study, the method using van-der-Pol transformation and F-P-K equation is used to obtain the probability density function of the response under the random wave forces. From the moment of the probability density function, the mean square response is obtained. Stability of the system is represented by an inequality condition expressed as a function of some important parameters. A two point mooring system is analysed as an illustrative example for a water depth of 141.5 m and a sea state represented by PM spectrum with 16 m significant height. It is shown that for certain combinations of parameter values, stability of two point mooring system may not be achieved.

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A New Microcontact Model Developed for Variable Fractal Dimension, Topothesy, Density of Asperity, and Probability Density Function of Asperity Heights

Journal of Applied Mechanics ◽

10.1115/1.2338059 ◽

2006 ◽

Vol 74 (4) ◽

pp. 603-613 ◽

Cited By ~ 13

Author(s):

Jeng Luen Liou ◽

Jen Fin Lin

Keyword(s):

Fractal Dimension ◽

Probability Density Function ◽

Probability Density ◽

Density Function ◽

Gaussian Distribution ◽

Fractal Theory ◽

Radius Of Curvature ◽

The Mean ◽

Contact Surfaces ◽

Non Gaussian

In the present study, the fractal theory is applied to modify the conventional model (the Greenwood and Williamson model) established in the statistical form for the microcontacts of two contact surfaces. The mean radius of curvature (R) and the density of asperities (η) are no longer taken as constants, but taken as variables as functions of the related parameters including the fractal dimension (D), the topothesy (G), and the mean separation of two contact surfaces. The fractal dimension and the topothesy varied by differing the mean separation of two contact surfaces are completely obtained from the theoretical model. Then the mean radius of curvature and the density of asperities are also varied by differing the mean separation. A numerical scheme is thus developed to determine the convergent values of the fractal dimension and topothesy corresponding to a given mean separation. The topographies of a surface obtained from the theoretical prediction of different separations show the probability density function of asperity heights to be no longer the Gaussian distribution. Both the fractal dimension and the topothesy are elevated by increasing the mean separation. The density of asperities is reduced by decreasing the mean separation. The contact load and the total contact area results predicted by variable D, G*, and η as well as non-Gaussian distribution are always higher than those forecast with constant D, G*, η, and Gaussian distribution.

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Bifurcation Analysis of an Energy Harvesting System with Fractional Order Damping Driven by Colored Noise

International Journal of Bifurcation and Chaos ◽

10.1142/s0218127421502230 ◽

2021 ◽

Vol 31 (15) ◽

Author(s):

Yong-Ge Yang ◽

Ya-Hui Sun ◽

Wei Xu

Keyword(s):

Probability Density Function ◽

Probability Density ◽

Density Function ◽

Fractional Order ◽

Colored Noise ◽

Energy Harvester ◽

Advanced Materials ◽

Vibration Energy ◽

Vibration Energy Harvester ◽

The Mean

Vibration energy harvester, which can convert mechanical energy to electrical energy so as to achieve self-powered micro-electromechanical systems (MEMS), has received extensive attention. In order to improve the efficiency of vibration energy harvesters, many approaches, including the use of advanced materials and stochastic loading, have been adopted. As the viscoelastic property of advanced materials can be well described by fractional calculus, it is necessary to further discuss the dynamical behavior of the fractional-order vibration energy harvester. In this paper, the stochastic P-bifurcation of a fractional-order vibration energy harvester subjected to colored noise is investigated. Variable transformation is utilized to obtain the approximate equivalent system. Probability density function for the amplitude of the system response is derived via the stochastic averaging method. Numerical results are presented to verify the proposed method. Critical conditions for stochastic P-bifurcation are provided according to the change of the peak number for the probability density function. Then bifurcation diagrams in the parameter planes are analyzed. The influences of parameters in the system on the mean harvested power are discussed. It is found that the mean harvested power increases with the enhancement of the noise intensity, while it decreases with the increase of the fractional order and the correlation time.

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Flexible Power-Normal Models with Applications

Mathematics ◽

10.3390/math9243183 ◽

2021 ◽

Vol 9 (24) ◽

pp. 3183

Author(s):

Guillermo Martínez-Flórez ◽

Diego I. Gallardo ◽

Osvaldo Venegas ◽

Heleno Bolfarine ◽

Héctor W. Gómez

Keyword(s):

Probability Density Function ◽

Probability Density ◽

Density Function ◽

Gaussian Model ◽

Real Data ◽

Simulation Studies ◽

New Model ◽

Asymmetric Model

The main object of this paper is to propose a new asymmetric model more flexible than the generalized Gaussian model. The probability density function of the new model can assume bimodal or unimodal shapes, and one of the parameters controls the skewness of the model. Three simulation studies are reported and two real data applications illustrate the flexibility of the model compared with traditional proposals in the literature.

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Mixing and combustion at low heat release in large eddy simulations of a reacting shear layer

Theoretical and Computational Fluid Dynamics ◽

10.1007/s00162-021-00573-z ◽

2021 ◽

Author(s):

J. X. Huang ◽

W. A. McMullan

Keyword(s):

Probability Density Function ◽

Heat Release ◽

Shear Layer ◽

Probability Density ◽

Density Function ◽

Temperature Rise ◽

Mixing Layer ◽

Large Eddy ◽

Inflow Condition ◽

The Mean

AbstractIn this paper, the mixing and combustion at low-heat release in a turbulent mixing layer are studied numerically using large eddy simulation. The primary aim of this paper is to successfully replicate the flow physics observed in experiments of low-heat release reacting mixing layers, where a duty cycle of hot structures and cool braid regions was observed. The nature of the imposed inflow condition shows a dramatic influence on the mechanisms governing entrainment, and mixing, in the shear layer. An inflow condition perturbed by Gaussian white noise produces a shear layer which entrains fluid through a nibbling mechanism, which has a marching scalar probability density function where the most probable scalar value varies across the layer, and where the mean-temperature rise is substantially over-predicted. A more sophisticated inflow condition produced by a recycling and rescaling method results in a shear layer which entrains fluid through an engulfment mechanism, which has a non-marching scalar probability density function where a preferred scalar concentration is present across the thickness of the layer, and where the mean-temperature rise is predicted to a good degree of accuracy. The latter simulation type replicates all of the flow physics observed in the experiment. Extensive testing of subgrid-scale models, and simple combustion models, shows that the WALE model coupled with the Steady Laminar Flamelet model produces reliable predictions of mixing layer diffusion flames undergoing with fast chemistry.

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