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upper X 1 equals StartLayout Enlarged left-brace 1st Row 1st Column 100 2nd Column 0 less-than-or-equal-to omega less-than 90 2nd Row 1st Column 1000 2nd Column 90 less-than-or-equal-to omega less-than 95 3rd Row 1st Column 0 2nd Column 95 less-than-or-equal-to omega less-than 100 EndLayout and upper X 2 equals StartLayout Enlarged left-brace 1st Row 1st Column 100 2nd Column 0 less-than-or-equal-to omega less-than 90 2nd Row 1st Column 0 2nd Column 90 less-than-or-equal-to omega less-than 95 3rd Row 1st Column 1000 2nd Column 95 less-than-or-equal-to omega less-than 100 EndLayout

      with sum

upper X equals StartLayout Enlarged left-brace 1st Row 1st Column 200 2nd Column 0 less-than-or-equal-to omega less-than 90 2nd Row 1st Column 1000 2nd Column 90 less-than-or-equal-to omega less-than 100 period EndLayout

      1 Create the model in a spreadsheet and confirm E[X]=28 and E[Xi]=14.

      2 Plot X1, X2, and X as functions of ω=0,1,…,99.

      3 Plot the survival functions, as functions of the outcome x.

      4 Plot the Lee diagrams, as functions of probability p.

      5 Are the random variables different? The survival functions? The Lee diagrams?

      We return to this example in Chapter 15.

      Figure 3.5 Random variables, functions of an explicit state.

      Figure 3.6 Survival functions of the outcome.

      Figure 3.7 Lee diagrams, function of a dual implicit state.

      StartLayout 1st Row 1st Column Blank 2nd Column equals sigma-summation Underscript i greater-than-or-equal-to 1 Endscripts x Subscript i Baseline f left-parenthesis x prime Subscript i right-parenthesis left-parenthesis x Subscript i Baseline minus x Subscript i minus 1 Baseline right-parenthesis EndLayout (3.4)

      StartLayout 1st Row 1st Column Blank 2nd Column almost-equals integral Subscript 0 Superscript normal infinity Baseline x f left-parenthesis x right-parenthesis d x comma EndLayout (3.5)

      using Taylor’s theorem to write S(xi−1)−S(xi)=S(xi−(xi−xi−1))−S(xi)=−S′(xi′)(xi−xi−1)=f(xi′)(xi−xi−1), for some xi−1≤xi′≤xi.

      Exercise 21 Confirm the change in indexing between Eq. 3.2 and Eq. 3.3 is correct by looking at panels (d) and (e).

      Technical Remark 22. In addition to the outcome-probability and survival function forms, there is a third, dual implicit outcome expression

sans-serif upper E left-bracket upper X right-bracket equals integral Subscript 0 Superscript 1 Baseline upper F Superscript negative 1 Baseline left-parenthesis p right-parenthesis d p

      by change of variable substitution F(x)=p, f(x)dx=dp. This view replaces the probability defined by X with the uniform probability dp on [0,1].

      3.5.3 Layer Notation

      It is common to use limits and deductibles to transform the insured loss. If X is a loss random variable, then applying a deductible d transforms it into

left-parenthesis upper X minus d right-parenthesis Superscript plus Baseline equals StartLayout Enlarged left-brace 1st Row 1st Column 0 2nd Column upper X less-than-or-equal-to d 2nd Row 1st Column upper X minus d 2nd Column upper X greater-than d EndLayout

      and applying a limit of l transforms it to

upper X logical-and l equals StartLayout Enlarged left-brace 1st Row 1st Column upper X 2nd Column upper X less-than-or-equal-to l 2nd Row 1st Column l 2nd Column upper X greater-than l period EndLayout

      These notations are shorthand: for example, X∧l is the random variable with outcome (X∧l)(ω)=X(ω)∧l at sample point ω∈Ω.

      When a policy has both a limit and a deductible, the limit is applied after the deductible. Applying a limit and a deductible creates what is called a limited excess of loss layer or simply a layer. Many reinsurance contracts and specialty lines policies are tranched into a coverage tower consisting of multiple layers, written by multiple insurers. (A tranche means a piece cut off or a slice.) In this context, a layer is sometimes identified with its limit and the deductible is called the attachment of the layer. A layer that attaches at 0 is called ground-up; all others are excess. Layers in a tower are typically arranged with no gaps.

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