Model Selection Test for the Heavy-Tailed Distributions under Censored Samples with Application in Financial Data

<p>It has been well documented that the empirical distribution of daily logarithmic returns from financial market variables is characterized by excess kurtosis and skewness. In order to capture such properties in financial data, heavy-tailed and asymmetric distributions are required to overcome shortfalls of the widely exhausted classical normality assumption. In the context of financial forecasting and risk management, the accuracy in modeling the underlying returns distribution plays a vital role. For example, risk management tools such as value-at-risk (VaR) are highly dependent on the underlying distributional assumption, with particular focus being placed at the extreme tails. Hence, identifying a distribution that best captures all aspects of the given financial data may provide vast advantages to both investors and risk managers. In this paper, we investigate major financial indices on the Johannesburg Stock Exchange (JSE) and fit their associated returns to classes of heavy tailed distributions. The relative adequacy and goodness-of-fit of these distributions are then assessed through the robustness of their respective VaR estimates. Our results indicate that the best model selection is not only variant across the indices, but also across different VaR levels and the dissimilar tails of return series.</p>

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A New Class of Heavy-Tailed Distributions: Modeling and Simulating Actuarial Measures

Complexity ◽

10.1155/2021/5580228 ◽

2021 ◽

Vol 2021 ◽

pp. 1-18

Author(s):

Jin Zhao ◽

Zubair Ahmad ◽

Eisa Mahmoudi ◽

E. H. Hafez ◽

Marwa M. Mohie El-Din

Keyword(s):

At Risk ◽

Value At Risk ◽

Weibull Model ◽

Financial Data ◽

Statistical Distributions ◽

New Family ◽

Heavy Tailed Distributions ◽

Beta Power ◽

Heavy Tailed ◽

Modeling Data

Statistical distributions play a prominent role for modeling data in applied fields, particularly in actuarial, financial sciences, and risk management fields. Among the statistical distributions, the heavy-tailed distributions have proven the best choice to use for modeling heavy-tailed financial data. The actuaries are often in search of such types of distributions to provide the best description of the actuarial and financial data. This study presents a new power transformation to introduce a new family of heavy-tailed distributions useful for modeling heavy-tailed financial data. A submodel, namely, heavy-tailed beta-power transformed Weibull model is considered to demonstrate the adequacy of the proposed method. Some actuarial measures such as value at risk, tail value at risk, tail variance, and tail variance premium are calculated. A brief simulation study based on these measures is provided. Finally, an application to the insurance loss dataset is analyzed, which revealed that the proposed distribution is a superior model among the competitors and could potentially be very adequate in describing and modeling actuarial and financial data.

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Heavy-Tailed Distributions, GARCH Model and the Stock Market Returns in South Korea

SSRN Electronic Journal ◽

10.2139/ssrn.3014472 ◽

2017 ◽

Author(s):

Yoon Hong ◽

Ji-chul Lee ◽

Ding Guoping

Keyword(s):

Stock Market ◽

South Korea ◽

Garch Model ◽

Market Returns ◽

Stock Market Returns ◽

Heavy Tailed Distributions ◽

Heavy Tailed

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Probability and Random Processes

10.1093/oso/9780198821939.003.0002 ◽

2018 ◽

Author(s):

Stefan Thurner ◽

Rudolf Hanel ◽

Peter Klimekl

Keyword(s):

Random Processes ◽

Distribution Functions ◽

Basic Logic ◽

Heavy Tailed Distributions ◽

Random Components ◽

Classical Distribution ◽

Heavy Tailed ◽

Basic Facts ◽

Stochastic Events ◽

Stochastic Event

Phenomena, systems, and processes are rarely purely deterministic, but contain stochastic,probabilistic, or random components. For that reason, a probabilistic descriptionof most phenomena is necessary. Probability theory provides us with the tools for thistask. Here, we provide a crash course on the most important notions of probabilityand random processes, such as odds, probability, expectation, variance, and so on. Wedescribe the most elementary stochastic event—the trial—and develop the notion of urnmodels. We discuss basic facts about random variables and the elementary operationsthat can be performed on them. We learn how to compose simple stochastic processesfrom elementary stochastic events, and discuss random processes as temporal sequencesof trials, such as Bernoulli and Markov processes. We touch upon the basic logic ofBayesian reasoning. We discuss a number of classical distribution functions, includingpower laws and other fat- or heavy-tailed distributions.

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Semiparametric Mixed-Effects Ordinary Differential Equation Models with Heavy-Tailed Distributions

Journal of Agricultural Biological and Environmental Statistics ◽

10.1007/s13253-021-00446-2 ◽

2021 ◽

Author(s):

Baisen Liu ◽

Liangliang Wang ◽

Yunlong Nie ◽

Jiguo Cao

Keyword(s):

Differential Equation ◽

Ordinary Differential Equation ◽

Mixed Effects ◽

Heavy Tailed Distributions ◽

Differential Equation Models ◽

Heavy Tailed

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A Method for Confidence Intervals of High Quantiles

Entropy ◽

10.3390/e23010070 ◽

2021 ◽

Vol 23 (1) ◽

pp. 70

Author(s):

Mei Ling Huang ◽

Xiang Raney-Yan

Keyword(s):

Confidence Intervals ◽

Computational Algorithm ◽

Geometric Mean ◽

Asymptotic Properties ◽

Quantile Estimation ◽

Heavy Tailed Distributions ◽

High Quantiles ◽

High Quantile ◽

Heavy Tailed ◽

Infinite Moments

The high quantile estimation of heavy tailed distributions has many important applications. There are theoretical difficulties in studying heavy tailed distributions since they often have infinite moments. There are also bias issues with the existing methods of confidence intervals (CIs) of high quantiles. This paper proposes a new estimator for high quantiles based on the geometric mean. The new estimator has good asymptotic properties as well as it provides a computational algorithm for estimating confidence intervals of high quantiles. The new estimator avoids difficulties, improves efficiency and reduces bias. Comparisons of efficiencies and biases of the new estimator relative to existing estimators are studied. The theoretical are confirmed through Monte Carlo simulations. Finally, the applications on two real-world examples are provided.

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Optimal Randomness for Stochastic Configuration Network (SCN) with Heavy-Tailed Distributions

Entropy ◽

10.3390/e23010056 ◽

2020 ◽

Vol 23 (1) ◽

pp. 56

Author(s):

Haoyu Niu ◽

Jiamin Wei ◽

YangQuan Chen

Keyword(s):

Research Work ◽

Cauchy Distribution ◽

Classification Model ◽

Test Accuracy ◽

Functional Link ◽

Heavy Tailed Distributions ◽

Heavy Tailed ◽

Improved Performance ◽

Hidden Layer ◽

Hidden Nodes

Stochastic Configuration Network (SCN) has a powerful capability for regression and classification analysis. Traditionally, it is quite challenging to correctly determine an appropriate architecture for a neural network so that the trained model can achieve excellent performance for both learning and generalization. Compared with the known randomized learning algorithms for single hidden layer feed-forward neural networks, such as Randomized Radial Basis Function (RBF) Networks and Random Vector Functional-link (RVFL), the SCN randomly assigns the input weights and biases of the hidden nodes in a supervisory mechanism. Since the parameters in the hidden layers are randomly generated in uniform distribution, hypothetically, there is optimal randomness. Heavy-tailed distribution has shown optimal randomness in an unknown environment for finding some targets. Therefore, in this research, the authors used heavy-tailed distributions to randomly initialize weights and biases to see if the new SCN models can achieve better performance than the original SCN. Heavy-tailed distributions, such as Lévy distribution, Cauchy distribution, and Weibull distribution, have been used. Since some mixed distributions show heavy-tailed properties, the mixed Gaussian and Laplace distributions were also studied in this research work. Experimental results showed improved performance for SCN with heavy-tailed distributions. For the regression model, SCN-Lévy, SCN-Mixture, SCN-Cauchy, and SCN-Weibull used less hidden nodes to achieve similar performance with SCN. For the classification model, SCN-Mixture, SCN-Lévy, and SCN-Cauchy have higher test accuracy of 91.5%, 91.7% and 92.4%, respectively. Both are higher than the test accuracy of the original SCN.

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