容量的随机排序及其在财务优化问题中的应用

IF 1.3 Q2 STATISTICS & PROBABILITY

Statistics & Risk Modeling Pub Date : 2014-06-28 DOI:10.1515/strm-2013-1151

Miryana Grigorova

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引用次数: 10

摘要

通过类比概率测度的经典情况，我们将凸(凹)随机优势关系递增的概念推广到归一化单调(但不一定是加性)集合函数也称为容量的情况。我们给出了这种关系的不同表征，建立了关于给定容量的分布函数和分位数函数概念的联系。Choquet积分作为一种工具被广泛使用。在本文的第二部分中，我们给出了约束用关于容量的凸递增随机优势关系表示的财务优化问题的一个应用。在其他工具中，通过使用我们以前工作中建立的结果来解决这个问题，即经典上限的新版本。(下)Hardy-Littlewood不等式推广到下凹连续的情况。凸)能力。优化问题的价值函数用风险度量(或溢价原则)来解释。

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Stochastic orderings with respect to a capacity and an application to a financial optimization problem

Abstract By analogy with the classical case of a probability measure, we extend the notion of increasing convex (concave) stochastic dominance relation to the case of a normalized monotone (but not necessarily additive) set function also called a capacity. We give different characterizations of this relation establishing a link to the notions of distribution function and quantile function with respect to the given capacity. The Choquet integral is extensively used as a tool. In the second part of the paper, we give an application to a financial optimization problem whose constraints are expressed by means of the increasing convex stochastic dominance relation with respect to a capacity. The problem is solved by using, among other tools, a result established in our previous work, namely a new version of the classical upper (resp. lower) Hardy–Littlewood's inequality generalized to the case of a continuous from below concave (resp. convex) capacity. The value function of the optimization problem is interpreted in terms of risk measures (or premium principles).

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来源期刊

Statistics & Risk Modeling STATISTICS & PROBABILITY-

CiteScore

1.80

自引率

6.70%

发文量

期刊介绍： Statistics & Risk Modeling (STRM) aims at covering modern methods of statistics and probabilistic modeling, and their applications to risk management in finance, insurance and related areas. The journal also welcomes articles related to nonparametric statistical methods and stochastic processes. Papers on innovative applications of statistical modeling and inference in risk management are also encouraged. Topics Statistical analysis for models in finance and insurance Credit-, market- and operational risk models Models for systemic risk Risk management Nonparametric statistical inference Statistical analysis of stochastic processes Stochastics in finance and insurance Decision making under uncertainty.