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==Deductibles== | |||
In an [[wikipedia:insurance|insurance]] policy, the '''deductible''' is the amount of expenses that must be paid [[wikipedia:Out-of-pocket expenses|out of pocket]] before an insurer will pay any expenses.<ref>{{cite book |last = Sullivan |first = arthur |author2=Steven M. Sheffrin |title = Economics: Principles in action |publisher = Pearson Prentice Hall |year = 2003 |location = Upper Saddle River, New Jersey 07458 |page = 524 |url = http://www.pearsonschool.com/index.cfm?locator=PSZ3R9&PMDbSiteId=2781&PMDbSolutionId=6724&PMDbCategoryId=&PMDbProgramId=12881&level=4 | isbn = 0-13-063085-3}}</ref> In general usage, the term '''deductible''' may be used to describe one of several types of clauses that are used by insurance companies as a threshold for policy payments. | |||
Deductibles are typically used to deter the large number of claims that a consumer can be reasonably expected to bear the cost of. By restricting its coverage to events that are significant enough to incur large costs, the insurance firm expects to pay out slightly smaller amounts much less frequently, incurring much higher savings. As a result, [[wikipedia:insurance premium|insurance premium]]s are typically cheaper when they involve higher deductibles. | |||
When a policy contains a deductible, the ultimate claim amount will depend on the ''type'' of deductible in question. There are generally two types of deductibles: an '''ordinary deductible''' and a '''franchise deductible'''. In what follows, we let <math>d</math> denote the deductible and let <math>X</math> the loss incurred by the insured. | |||
====Ordinary Deductible ==== | |||
When the deductible is ordinary, the claim amount is: | |||
<math display="block"> | |||
\begin{equation*} | |||
(X-d)^+ = | |||
\begin{cases} | |||
X-d & \text{if}\,\, X \geq d \\ | |||
0 & \text{otherwise} | |||
\end{cases} | |||
\end{equation*} | |||
</math> | |||
===Franchise Deductible === | |||
A franchise deductible is similar to an ordinary deductible except that the total loss to the insured can be claimed when that loss exceeds the deductible. More precisely, the claim amount is: | |||
<math display="block"> | |||
\begin{align*} | |||
X & \quad \text{if}\,\, X\geq d \\ | |||
0 & \quad \text{otherwise} | |||
\end{align*} | |||
</math> | |||
==Policy Limits== | |||
Policy limits simply set a limit on the amount of the claim. More precisely, if <math>l</math> is the policy limit then the claim amount is: | |||
<math display="block"> | |||
\begin{equation*} | |||
X \wedge l = | |||
\begin{cases} | |||
l & \text{if}\,\, X \gt l \\ | |||
X & \text{if}\,\, X \leq l | |||
\end{cases} | |||
\end{equation*} | |||
</math> | |||
==Coinsurance== | |||
This usually means that the loss to the insurer is a fraction of what it would be without coinsurance. The fraction is usually called the '''coinsurance factor''' and is expressed in %. For instance, if a policy has a deductible <math>d</math>, a limit <math>l</math> and a coinsurance factor <math>f</math>, then the claim amount is: | |||
<math display ="block"> | |||
\begin{equation*} | |||
f \cdot \left[(X-d)^+ -(X-l)^+ \right]. | |||
\end{equation*} | |||
</math> | |||
==Effects of Coverage Modifications and Inflation == | |||
How is the ''expected'' loss on a policy affected by coverage modifications and inflation? | |||
===Loss Elimination Ratio === | |||
Loss elimination ratios are useful to quantify the impact of coverage modifications on the insurer. Let <math>X</math> represent the loss to the insured and let <math>L</math> represent loss to the insurer. If <math>M</math> represents some coverage modification, then we let <math>L_M</math> represent the loss to the insurer if <math>M</math> is in effect. For any modification <math>M</math>, the loss elimination ratio equals | |||
<math display="block"> | |||
\begin{equation}\operatorname{LER}(M) = \frac{\operatorname{E}[L_{M}] - \operatorname{E}[L]}{\operatorname{E}[L]}. \end{equation} | |||
</math> | |||
===Deductible === | |||
If <math>M</math> denotes the modification corresponding to adding an ''ordinary'' deductible <math>d</math> to the policy, then the expected loss to the insurer can equal any of the following expressions: | |||
<math display="block"> | |||
\operatorname{E}[(L-d)^+] = \operatorname{E}[L] - \operatorname{E}[L \wedge d] = S(d) \cdot m(d) | |||
</math> | |||
The loss elimination ratio equals | |||
<math display="block"> | |||
\operatorname{LER}(M) = \frac{\operatorname{E}[L \wedge d]}{\operatorname{E}[L]}\,. | |||
</math> | |||
If <math>M</math> denotes the modification corresponding to adding a ''franchise'' deductible <math>d</math> to the policy, then the expected loss to the insurer equals any of the following expressions: | |||
<math display="block"> | |||
\operatorname{E}[L \cdot \operatorname{1}_{L \gt d}] = \int_{0}^{\infty}S(d +t) \,dt = S(d) \cdot (m(d) + d). | |||
</math> | |||
The loss elimination ratio equals any of the following expressions (<math>f(x)</math> is the density function for the loss): | |||
<math display = "block"> | |||
\frac{\operatorname{E}[L \cdot \operatorname{1}_{L \leq u}]}{\operatorname{E}[L]} = \frac{\int_{0}^{u}S(t)\, dt}{\int_{0}^{ | |||
\infty}S(t)\,dt} = \frac{\int_{0}^{u}x f(x) dx}{\int_{0}^{\infty}x f(x) dx}. | |||
</math> | |||
===Limit === | |||
If <math>M</math> denotes the modification corresponding to adding a limit <math>u</math> to the policy, then the expected loss equals any of the following expressions: | |||
<math display = "block"> | |||
\operatorname{E}[L \wedge u] = \int_{0}^{u}S(t)\, dt + S(u)\cdot u = \int_{0}^{u}x f(x) \, dx + S(u)\cdot u. | |||
</math> | |||
The loss elimination ratio equals any of the following expressions: | |||
<math display="block"> | |||
\frac{\operatorname{E}[L] - \operatorname{E}[L \wedge u]}{\operatorname{E}[L]} = \frac{\operatorname{E}[(L-u)^+] }{\operatorname{E}[L]} = \frac{S(u) \cdot m(u)}{\operatorname{E}[L]}. | |||
</math> | |||
===Coinsurance=== | |||
If <math>M</math> denotes the modification corresponding to adding a coinsurance factor <math>\alpha</math> to the policy, then | |||
<math display="block"> | |||
\operatorname{E}[L_M] = \alpha \cdot \operatorname{E}[L],\ \ \operatorname{LER}(M) =\alpha. | |||
</math> | |||
===Inflation=== | |||
The loss to the insured may be subject to inflation from one period to another. For instance, if the loss <math>X</math> to the insured is inflated by <math>r</math>, how does it affect the loss variable for the insurer? | |||
If the policy has an ordinary deductible <math>d</math>, then the loss to the insurer equals | |||
<math display="block"> | |||
L = (1+r)\left[X-d/(1+r)\right]^+ | |||
</math> | |||
and the expected loss equals | |||
<math display="block"> | |||
\operatorname{E}[L] = (1+r) \cdot \left(\operatorname{E}[X] - \operatorname{E}[X \wedge \frac{d}{1+r} ] \right). | |||
</math> | |||
If the policy has a limit <math>u</math>, then the loss to the insurer equals | |||
<math display="block"> | |||
L = (1+r)\left[X\wedge\frac{u}{1+r}\right] | |||
</math> | |||
and the expected loss equals | |||
<math display="block"> | |||
\operatorname{E}[L] = (1+r) \cdot \operatorname{E}\left[X \wedge \frac{u}{1+r} \right]. | |||
</math> | |||
Finally, suppose the policy has a regular deductible <math>d</math>, a limit <math>u</math> (greater than <math>d</math>) and a coinsurance factor <math>\alpha</math>, then the loss to the insurer equals | |||
<math display="block"> | |||
L = \alpha (1 + r)\left[ X \wedge \frac{u}{1+r} - X \wedge \frac{d}{1+r} \right]. | |||
</math> | |||
==References== | |||
{{reflist}} | |||
==Wikipedia References== | |||
*{{cite web |url= https://en.wikipedia.org/w/index.php?title=Deductible&oldid=882377957 |title= Deductible | author = Wikipedia contributors |website= Wikipedia |publisher= Wikipedia |access-date = 7 June 2019 }} | |||
*{{cite web |url = https://en.wikipedia.org/w/index.php?title=Co-insurance&oldid=900881744 |title= Co-insurance | author = Wikipedia contributors |website= Wikipedia |publisher= Wikipedia |access-date = 7 June 2019 }} |
Latest revision as of 16:59, 27 February 2023
Deductibles
In an insurance policy, the deductible is the amount of expenses that must be paid out of pocket before an insurer will pay any expenses.[1] In general usage, the term deductible may be used to describe one of several types of clauses that are used by insurance companies as a threshold for policy payments.
Deductibles are typically used to deter the large number of claims that a consumer can be reasonably expected to bear the cost of. By restricting its coverage to events that are significant enough to incur large costs, the insurance firm expects to pay out slightly smaller amounts much less frequently, incurring much higher savings. As a result, insurance premiums are typically cheaper when they involve higher deductibles.
When a policy contains a deductible, the ultimate claim amount will depend on the type of deductible in question. There are generally two types of deductibles: an ordinary deductible and a franchise deductible. In what follows, we let [math]d[/math] denote the deductible and let [math]X[/math] the loss incurred by the insured.
Ordinary Deductible
When the deductible is ordinary, the claim amount is:
Franchise Deductible
A franchise deductible is similar to an ordinary deductible except that the total loss to the insured can be claimed when that loss exceeds the deductible. More precisely, the claim amount is:
Policy Limits
Policy limits simply set a limit on the amount of the claim. More precisely, if [math]l[/math] is the policy limit then the claim amount is:
Coinsurance
This usually means that the loss to the insurer is a fraction of what it would be without coinsurance. The fraction is usually called the coinsurance factor and is expressed in %. For instance, if a policy has a deductible [math]d[/math], a limit [math]l[/math] and a coinsurance factor [math]f[/math], then the claim amount is:
Effects of Coverage Modifications and Inflation
How is the expected loss on a policy affected by coverage modifications and inflation?
Loss Elimination Ratio
Loss elimination ratios are useful to quantify the impact of coverage modifications on the insurer. Let [math]X[/math] represent the loss to the insured and let [math]L[/math] represent loss to the insurer. If [math]M[/math] represents some coverage modification, then we let [math]L_M[/math] represent the loss to the insurer if [math]M[/math] is in effect. For any modification [math]M[/math], the loss elimination ratio equals
Deductible
If [math]M[/math] denotes the modification corresponding to adding an ordinary deductible [math]d[/math] to the policy, then the expected loss to the insurer can equal any of the following expressions:
The loss elimination ratio equals
If [math]M[/math] denotes the modification corresponding to adding a franchise deductible [math]d[/math] to the policy, then the expected loss to the insurer equals any of the following expressions:
The loss elimination ratio equals any of the following expressions ([math]f(x)[/math] is the density function for the loss):
Limit
If [math]M[/math] denotes the modification corresponding to adding a limit [math]u[/math] to the policy, then the expected loss equals any of the following expressions:
The loss elimination ratio equals any of the following expressions:
Coinsurance
If [math]M[/math] denotes the modification corresponding to adding a coinsurance factor [math]\alpha[/math] to the policy, then
Inflation
The loss to the insured may be subject to inflation from one period to another. For instance, if the loss [math]X[/math] to the insured is inflated by [math]r[/math], how does it affect the loss variable for the insurer?
If the policy has an ordinary deductible [math]d[/math], then the loss to the insurer equals
and the expected loss equals
If the policy has a limit [math]u[/math], then the loss to the insurer equals
and the expected loss equals
Finally, suppose the policy has a regular deductible [math]d[/math], a limit [math]u[/math] (greater than [math]d[/math]) and a coinsurance factor [math]\alpha[/math], then the loss to the insurer equals
References
- Sullivan, arthur; Steven M. Sheffrin (2003). Economics: Principles in action. Upper Saddle River, New Jersey 07458: Pearson Prentice Hall. p. 524. ISBN 0-13-063085-3.CS1 maint: location (link)
Wikipedia References
- Wikipedia contributors. "Deductible". Wikipedia. Wikipedia. Retrieved 7 June 2019.
- Wikipedia contributors. "Co-insurance". Wikipedia. Wikipedia. Retrieved 7 June 2019.