On a Sparre Andersen Risk Model with Time-Dependent Claim Sizes and Jump-Diffusion Perturbation

Zhang, Zhimin; Yang, Hailiang; Yang, Hu

doi:10.1007/s11009-011-9215-1

Cited by 17 publications

(6 citation statements)

References 26 publications

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“…For the study of ruin-related quantities in dependent Sparre Andersen models under specific distributional assumptions on the interclaim time V and/or the claim severity Y , we refer interested readers to e.g. Boudreault et al (2006), Cossette et al (2008Cossette et al ( , 2010, Ambagaspitiya (2009), Badescu et al (2009), Chadjiconstantinidis and Vrontos (2012), Willmot and Woo (2012), Zhang et al (2012), and Landriault et al (2013). In this paper, we are mostly concerned with the dependency structure proposed by Willmot and Woo (2012), who assumed that the joint density of the generic pair (V, Y ) at (t, y) admits the factorization form…”

Section: Introductionmentioning

confidence: 99%

On the discounted aggregate claim costs until ruin in dependent Sparre Andersen risk processes

Cheung

Woo

2014

Scandinavian Actuarial Journal

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In this paper, a dependent Sparre Andersen risk process in which the joint density of the interclaim time and the resulting claim severity satisfies the factorization as in Willmot and Woo (2012) is considered. We study a generalization of the Gerber-Shiu function (i) whose penalty function further depends on the surplus level immediately after the second last claim before ruin (Cheung et al. (2010a)); and (ii) which involves the moments of the discounted aggregate claim costs until ruin. The generalized discounted density with a moment-based component proposed in Cheung (2013) plays a key role in deriving recursive defective renewal equations. We pay special attention to the case where the marginal distribution of the interclaim times is Coxian, and the required components in the recursion are obtained. A reverse type of dependency structure where the claim severities follow a combination of exponentials is also briefly discussed, and this leads to a nice explicit expression for the expected discounted aggregate claims until ruin. Our results are applied to generate some numerical examples involving (i) the covariance of the time of ruin and the discounted aggregate claims until ruin; and (ii) the expectation, variance and third central moment of the discounted aggregate claims until ruin.

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Section: Introductionmentioning

confidence: 99%

On the discounted aggregate claim costs until ruin in dependent Sparre Andersen risk processes

Cheung

Woo

2014

Scandinavian Actuarial Journal

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“…For instance, several cases of the Sparre Andersen model were considered by Dickson and Qazvini (2016), Landriault and Willmot (2008), Li and Garrido (2004), Li and Sendova (2015), Lin et al (2003), Schmidli (1999), Willmot and Dickson (2003). Properties of the Gerber-Shiu function in the risk renewal models perturbed by diffusion were investigated by Chi et al (2010), Tsai (2003), Tsai and Willmot (2002), Xu et al (2014), Zhang and Cheung (2016), Zhang et al (2012Zhang et al ( , 2017bZhang et al ( , 2014. The Gerber-Shiu function of the risk models with various special strategies were considered by Avram et al (2015), Bratiichuk (2012), Cheung and Liu (2016), Cheung et al (2015), Dong et al (2009), Lin and Pavlova (2006), Lin and Sendova (2008), Liu et al (2015), Marciniak and Palmowski (2016), Shi et al (2013), Shiraishi (2016), Woo et al (2017), Zhang et al (2017a), Zhou et al (2015).…”

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confidence: 99%

The Gerber–Shiu Discounted Penalty Function for the Bi-Seasonal Discrete Time Risk Model

Navickienė¹,

Sprindys²,

Šiaulys³

2018

Informatica

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In this work, the discrete time risk model with two seasons is considered. In such model, the claims repeat with time periods of two units, i.e. claim distributions coincide at all even instants and at all odd instants. Our purpose is to derive an algorithm for calculating the values of the particular case of the Gerber-Shiu discounted penalty function E(e −δT 1 {T <∞}), where T is the time of ruin, and δ is a constant nonnegative force of interest. Theoretical results are illustrated by some numerical examples.

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“…As for the claim size, one finds models with arbitrary interclaim time distribution and a Coxian claim-size distribution [96], and phase-type interclaim times and claim-size distributions in the rational family [150] with an additional multi-layer dividend strategy [79]. Additional features have been introduced into the risk model, such as dependent interclaim times and claim amounts with perturbation [199], stochastic premium income [201], stochastic interest force modeled by drifted Brownian model in combination with Poisson-Geometric process [72], and two classes of claims modelled by compound Poisson and Erlang(2) renewal risk processes with a two-step premium rate under a threshold dividend strategy [121].…”

Section: Advanced Modelsmentioning

confidence: 99%

“…Defective renewal equations can be found for the compound binomial model [93] and for a general Sparre-Andersen model with both positive and negative claim values [91]. Renewal type equations are derived even when additional structural features are introduced, for example, a Sparre-Andersen model involving a multi-layer dividend policy [180], random claims or income modeled by a compound Poisson process [29,201] along with perturbation and dependence between interclaim times and claim amounts [199], a two-step premium rate under a threshold dividend strategy [121], and a stochastic discount rate modeled by a Brownian motion and a Poisson-Geometric process [72]. Defective renewal equations are derived for variants of the Gerber-Shiu function driven by a Sparre-Andersen process, such as (2.10) with general interclaim times [35], the formulation (2.11) with Coxian-distributed interclaim times and mixed Erlang-distributed claim amounts [170] or with two-sided jumps [195], and the formulation (2.13) with dependent interclaim times and claim sizes [40].…”

Section: Sparre-andersen Modelsmentioning

confidence: 99%

The Gerber-Shiu discounted penalty function: A review from practical perspectives

He¹,

Kawai²,

Shimizu³

et al. 2022

Preprint

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The Gerber-Shiu function provides a unified framework for the evaluation of a variety of risk quantities. Ever since its establishment, it has attracted constantly increasing interests in actuarial science, whereas the conventional research has been focused on finding analytical or semi-analytical solutions, either of which is rarely available, except for limited classes of penalty functions on rather simple risk models. In contrast to its great generality, the Gerber-Shiu function does not seem sufficiently prevalent in practice, largely due to a variety of difficulties in numerical approximation and statistical inference. To enhance research activities on such implementation aspects, we provide a full review of existing formulations and underlying surplus processes, as well as an extensive survey of analytical, semi-analytical and asymptotic methods for the Gerber-Shiu function, which altogether shed fresh light on its numerical methods and statistical inference for further developments. On the basis of an exhaustive collection of 207 references, the present survey can serve as an insightful guidebook to model and method selection from practical perspectives as well.

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On a Sparre Andersen Risk Model with Time-Dependent Claim Sizes and Jump-Diffusion Perturbation

Cited by 17 publications

References 26 publications

On the discounted aggregate claim costs until ruin in dependent Sparre Andersen risk processes

On the discounted aggregate claim costs until ruin in dependent Sparre Andersen risk processes

The Gerber–Shiu Discounted Penalty Function for the Bi-Seasonal Discrete Time Risk Model

The Gerber-Shiu discounted penalty function: A review from practical perspectives

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