Lindley Approximation Technique for the Parameters of Lomax Distribution

A new three-parameter continuous model called the exponentiated half-logistic Lomax distribution is introduced in this paper. Basic mathematical properties for the proposed model were investigated which include raw and incomplete moments, skewness, kurtosis, generating functions, Rényi entropy, Lorenz, Bonferroni and Zenga curves, probability weighted moment, stress strength model, order statistics, and record statistics. The model parameters were estimated by using the maximum likelihood criterion and the behaviours of these estimates were examined by conducting a simulation study. The applicability of the new model is illustrated by applying it on a real data set.

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A New Analytic Approximation Technique for Options in a Regime-Switching Market

SSRN Electronic Journal ◽

10.2139/ssrn.2167394 ◽

2012 ◽

Cited By ~ 1

Author(s):

Melissa Mielkie ◽

Matt Davison

Keyword(s):

Regime Switching ◽

Approximation Technique ◽

Analytic Approximation

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The minimum zone fitting and error evaluation for the logarithmic curve based on geometry optimization approximation algorithm

Transactions of the Institute of Measurement and Control ◽

10.1177/0142331219858855 ◽

2019 ◽

Vol 41 (15) ◽

pp. 4380-4386

Author(s):

Tu Xianping ◽

Lei Xianqing ◽

Ma Wensuo ◽

Wang Xiaoyi ◽

Hu Luqing ◽

...

Keyword(s):

Approximation Algorithm ◽

Evaluation Method ◽

Geometry Optimization ◽

Reference Points ◽

Approximation Technique ◽

Error Evaluation ◽

Iterative Approximation ◽

Logarithmic Curve ◽

Normal Distance ◽

Minimum Zone

The minimum zone fitting and error evaluation for the logarithmic curve has important applications. Based on geometry optimization approximation algorithm whilst considering geometric characteristics of logarithmic curves, a new fitting and error evaluation method for the logarithmic curve is presented. To this end, two feature points, to serve as reference, are chosen either from those located on the least squares logarithmic curve or from amongst measurement points. Four auxiliary points surrounding each of the two reference points are then arranged to resemble vertices of a square. Subsequently, based on these auxiliary points, a series of auxiliary logarithmic curves (16 curves) are constructed, and the normal distance and corresponding range of values between each measurement point and all auxiliary logarithmic curves are calculated. Finally, by means of an iterative approximation technique consisting of comparing, evaluating, and changing reference points; determining new auxiliary points; and constructing corresponding auxiliary logarithmic curves, minimum zone fitting and evaluation of logarithmic curve profile errors are implemented. The example results show that the logarithmic curve can be fitted, and its profile error can be evaluated effectively and precisely using the presented method.

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On the Accuracy of the Sine Power Lomax Model for Data Fitting

Modelling ◽

10.3390/modelling2010005 ◽

2021 ◽

Vol 2 (1) ◽

pp. 78-104

Author(s):

Vasili B. V. Nagarjuna ◽

R. Vishnu Vardhan ◽

Christophe Chesneau

Keyword(s):

Statistical Model ◽

Simulation Study ◽

Statistical Models ◽

Goodness Of Fit ◽

Data Fitting ◽

Applied Science ◽

Survival Distribution ◽

Lomax Distribution ◽

Model Based

Every day, new data must be analysed as well as possible in all areas of applied science, which requires the development of attractive statistical models, that is to say adapted to the context, easy to use and efficient. In this article, we innovate in this direction by proposing a new statistical model based on the functionalities of the sinusoidal transformation and power Lomax distribution. We thus introduce a new three-parameter survival distribution called sine power Lomax distribution. In a first approach, we present it theoretically and provide some of its significant properties. Then the practicality, utility and flexibility of the sine power Lomax model are demonstrated through a comprehensive simulation study, and the analysis of nine real datasets mainly from medicine and engineering. Based on relevant goodness of fit criteria, it is shown that the sine power Lomax model has a better fit to some of the existing Lomax-like distributions.

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Approximation of continuous random variables for the evaluation of the reliability parameter of complex stress–strength models

Annals of Operations Research ◽

10.1007/s10479-021-04010-6 ◽

2021 ◽

Author(s):

Alessandro Barbiero ◽

Asmerilda Hitaj

Keyword(s):

Order Approximation ◽

Linear Optimization ◽

Closed Form Solution ◽

Random Variables ◽

Discrete Distribution ◽

Computation Time ◽

Form Solution ◽

Engineering Problem ◽

Approximation Technique ◽

Reliability Parameter

AbstractIn many management science or economic applications, it is common to represent the key uncertain inputs as continuous random variables. However, when analytic techniques fail to provide a closed-form solution to a problem or when one needs to reduce the computational load, it is often necessary to resort to some problem-specific approximation technique or approximate each given continuous probability distribution by a discrete distribution. Many discretization methods have been proposed so far; in this work, we revise the most popular techniques, highlighting their strengths and weaknesses, and empirically investigate their performance through a comparative study applied to a well-known engineering problem, formulated as a stress–strength model, with the aim of weighting up their feasibility and accuracy in recovering the value of the reliability parameter, also with reference to the number of discrete points. The results overall reward a recently introduced method as the best performer, which derives the discrete approximation as the numerical solution of a constrained non-linear optimization, preserving the first two moments of the original distribution. This method provides more accurate results than an ad-hoc first-order approximation technique. However, it is the most computationally demanding as well and the computation time can get even larger than that required by Monte Carlo approximation if the number of discrete points exceeds a certain threshold.

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Kumaraswamy Generalized Power Lomax Distributionand Its Applications

Stats ◽

10.3390/stats4010003 ◽

2021 ◽

Vol 4 (1) ◽

pp. 28-45

Author(s):

Vasili B.V. Nagarjuna ◽

R. Vishnu Vardhan ◽

Christophe Chesneau

Keyword(s):

Hazard Rate ◽

Real Data ◽

Rate Function ◽

Maximum Likelihood Estimates ◽

Parameter Estimates ◽

Parameter Distribution ◽

Data Sets ◽

Lomax Distribution ◽

Entropy Measures ◽

Modeling Behavior

In this paper, a new five-parameter distribution is proposed using the functionalities of the Kumaraswamy generalized family of distributions and the features of the power Lomax distribution. It is named as Kumaraswamy generalized power Lomax distribution. In a first approach, we derive its main probability and reliability functions, with a visualization of its modeling behavior by considering different parameter combinations. As prime quality, the corresponding hazard rate function is very flexible; it possesses decreasing, increasing and inverted (upside-down) bathtub shapes. Also, decreasing-increasing-decreasing shapes are nicely observed. Some important characteristics of the Kumaraswamy generalized power Lomax distribution are derived, including moments, entropy measures and order statistics. The second approach is statistical. The maximum likelihood estimates of the parameters are described and a brief simulation study shows their effectiveness. Two real data sets are taken to show how the proposed distribution can be applied concretely; parameter estimates are obtained and fitting comparisons are performed with other well-established Lomax based distributions. The Kumaraswamy generalized power Lomax distribution turns out to be best by capturing fine details in the structure of the data considered.

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Treatment of Pediatric Sternotomy Wound Complications: A Minimally Invasive Approach

The Thoracic and Cardiovascular Surgeon ◽

10.1055/s-0040-1722733 ◽

2021 ◽

Author(s):

Taehee Jo ◽

Joon Hur ◽

Eun Key Kim

Keyword(s):

Negative Pressure Wound Therapy ◽

Wound Dehiscence ◽

Surgical Debridement ◽

Wound Complications ◽

Approximation Technique ◽

Invasive Approach ◽

Nonsurgical Management ◽

Single Use ◽

Sternal Wound Infections ◽

Deep Sternal Wound Infections

Abstract Background Pediatric sternal wound complications (SWCs) include sterile wound dehiscence (SWD) and superficial/deep sternal wound infections (SSWI/DSWI), and are generally managed by repetitive debridement and surgical wound approximation. Here, we report a novel nonsurgical management strategy of pediatric sternotomy wound complications, using serial noninvasive wound approximation technique combined with single-use negative pressure wound therapy (PICO) device. Methods Nine children with SWCs were managed by serial approximation with adhesive skin tapes and serial PICO device application. Thorough surgical debridement or surgical approximations were not performed. Results Three patients were clinically diagnosed as SWD, two patients as SSWI, and four patients as DSWI. None of the wounds demonstrated apparent mediastinitis or bone destructions. PICO device was applied at 16.1 days (range: 6–26 days) postoperatively, together with serial wound approximation by skin tapes. The average duration of PICO use was 16.9 days (range: 11–29 days) and the wound approximation was achieved in all patients. None of the patients underwent aggressive surgical debridement or invasive surgical approximation by sutures. Conclusion We report our successful management of selected pediatric SWCs, using serial noninvasive wound approximation technique combined with PICO device.

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Bearing Anomaly Recognition Using an Intelligent Digital Twin Integrated with Machine Learning

Applied Sciences ◽

10.3390/app11104602 ◽

2021 ◽

Vol 11 (10) ◽

pp. 4602

Author(s):

Farzin Piltan ◽

Jong-Myon Kim

Keyword(s):

Machine Learning ◽

Variable Structure ◽

Vibration Signal ◽

Crack Size ◽

Approximation Technique ◽

Digital Twin ◽

Average Accuracy ◽

Machine Learning Approach ◽

The Impact ◽

Signal Approximation

In this study, the application of an intelligent digital twin integrated with machine learning for bearing anomaly detection and crack size identification will be observed. The intelligent digital twin has two main sections: signal approximation and intelligent signal estimation. The mathematical vibration bearing signal approximation is integrated with machine learning-based signal approximation to approximate the bearing vibration signal in normal conditions. After that, the combination of the Kalman filter, high-order variable structure technique, and adaptive neural-fuzzy technique is integrated with the proposed signal approximation technique to design an intelligent digital twin. Next, the residual signals will be generated using the proposed intelligent digital twin and the original RAW signals. The machine learning approach will be integrated with the proposed intelligent digital twin for the classification of the bearing anomaly and crack sizes. The Case Western Reserve University bearing dataset is used to test the impact of the proposed scheme. Regarding the experimental results, the average accuracy for the bearing fault pattern recognition and crack size identification will be, respectively, 99.5% and 99.6%.

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