ExcessSplice: Estimates for excess-loss premiums using splicing

Description

Estimate premiums of excess-loss reinsurance with retention $R$ and limit $L$ using fitted spliced distribution.

Usage

ExcessSplice(R, L=Inf, splicefit)

Arguments

The retention level of the (re-)insurance or a vector of retention levels for the (re-)insurance.

The limit for the (re-)insurance or a vector of limits for the (re-)insurance, default is Inf.

splicefit

A SpliceFit object, e.g. output from SpliceFitPareto, SpliceFiticPareto or SpliceFitGPD.

Value

An estimate for the premium is returned (for every value of R).

Details

The premium for the excess-loss insurance with retention $R$ and limit $L$ is given by $$E(\min{(X-R)_+, L}) = \Pi(R) - \Pi(R+L)$$ where $\Pi(u)=E((X-u)_+)=\int_u^{\infty} (1-F(z)) dz$ is the premium of the excess-loss insurance with retention $u$. When $L=\infty$, the premium is equal to $\Pi(R)$.

See Reynkens et al. (2017) and Section 4.6 of Albrecher et al. (2017) for more details.

References

Albrecher, H., Beirlant, J. and Teugels, J. (2017). Reinsurance: Actuarial and Statistical Aspects, Wiley, Chichester.

Reynkens, T., Verbelen, R., Beirlant, J. and Antonio, K. (2017). "Modelling Censored Losses Using Splicing: a Global Fit Strategy With Mixed Erlang and Extreme Value Distributions". Insurance: Mathematics and Economics, 77, 65--77.

Verbelen, R., Gong, L., Antonio, K., Badescu, A. and Lin, S. (2015). "Fitting Mixtures of Erlangs to Censored and Truncated Data Using the EM Algorithm." Astin Bulletin, 45, 729--758

Examples

Run this code

# NOT RUN {
# Pareto random sample
X <- rpareto(1000, shape = 2)

# Splice ME and Pareto
splicefit <- SpliceFitPareto(X, 0.8)

# Excess-loss premium 
ExcessSplice(R=2, splicefit=splicefit)
# }

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