Abstract
PurposeThis paper generalizes the quadratic framework introduced by Le Courtois (2016) and Sumpf (2018), to obtain new credibility premiums in the balanced case, i.e. under the balanced squared error loss function. More precisely, the authors construct a quadratic credibility framework under the net quadratic loss function where premiums are estimated based on the values of past observations and of past squared observations under the parametric and the non-parametric approaches, this framework is useful for the practitioner who wants to explicitly take into account higher order (cross) moments of past data.Design/methodology/approachIn the actuarial field, credibility theory is an empirical model used to calculate the premium. One of the crucial tasks of the actuary in the insurance company is to design a tariff structure that will fairly distribute the burden of claims among insureds. In this work, the authors use the weighted balanced loss function (WBLF, henceforth) to obtain new credibility premiums, and WBLF is a generalized loss function introduced by Zellner (1994) (see Gupta and Berger (1994), pp. 371-390) which appears also in Dey et al. (1999) and Farsipour and Asgharzadhe (2004).FindingsThe authors declare that there is no conflict of interest and the funding information is not applicable.Research limitations/implicationsThis work is motivated by the following: quadratic credibility premium under the balanced loss function is useful for the practitioner who wants to explicitly take into account higher order (cross) moments and new effects such as the clustering effect to finding a premium more credible and more precise, which arranges both parts: the insurer and the insured. Also, it is easy to apply for parametric and non-parametric approaches. In addition, the formulas of the parametric (Poisson–gamma case) and the non-parametric approach are simple in form and may be used to find a more flexible premium in many special cases. On the other hand, this work neglects the semi-parametric approach because it is rarely used by practitioners.Practical implicationsThere are several examples of actuarial science (credibility).Originality/valueIn this paper, the authors used the WBLF and a quadratic adjustment to obtain new credibility premiums. More precisely, the authors construct a quadratic credibility framework under the net quadratic loss function where premiums are estimated based on the values of past observations and of past squared observations under the parametric and the non-parametric approaches, this framework is useful for the practitioner who wants to explicitly take into account higher order (cross) moments of past data.
Highlights
Introduction and motivationIn the actuarial field, credibility theory is an empirical model used to calculate the premium
Actuaries use credibility theory to determine the expected claims experience of an individual risk when those risks are not homogenous, given that the individual risk belongs to a heterogenous collective
The main objective of this theory is to calculate the weight which should be assigned to the individual risk data to determine a fair premium to be charged
Summary
We assume that the individual risk, X, has a density f ðxj θÞ indexed by a parameter θ ∈ Θ which has a prior distribution with density πðθÞ. [12] is a generalization of Lemma 2 in Ref. Under WBLF and prior π, the risk (individual) and collective premiums are given by. WBLF with respect to to obtain the individual premium. Is obtained replacing πðθÞ by the posterior distribution πðθj xÞ in (4). Under the squared error loss function L1(P, x) , [10] added a quadratic correction in credibility theory to introduce higher order terms in the frame work, he has constructed a new credibility premium. We extend his idea under the balanced squared error loss function.
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