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One Madison Avenue New York Reducing Reserve Variance.

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Presentation on theme: "One Madison Avenue New York Reducing Reserve Variance."— Presentation transcript:

1 One Madison Avenue New York Reducing Reserve Variance

2 Guy Carpenter 2 Issues One aspect of testing reserve models is goodness of fit compared to other models But add penalty for number of parameters Can base on variance Parameter and process variance Or information criteria Done with MLE estimates AIC original but some new ideas

3 Guy Carpenter 3 Reducing Variance of Reserves 1. Find better fitting models Will reduce process variance Also improves goodness of fit 2. Use fewer parameters Will reduce parameter variance Also reduces MLE parameter penalties 3. Include exposure information Possibly can eliminate some parameters May give better fit as well

4 Alternative Model of Development Factors

5 Guy Carpenter 5 Poisson – Constant Severity PCS Model Assumes aggregate losses in each incremental cell of development triangle all have a Poisson frequency and the same constant severity b. Cell means are modeled as products of row and column parameters – such as estimated ultimate for row and fraction to emerge in column

6 Guy Carpenter 6 Poisson – Constant Severity Distribution For loss X, X/b is Poisson in EX = b Variance = b 2 Variance/Mean = b Also called over-dispersed Poisson: ODP But that makes it sound like frequency

7 Guy Carpenter 7 Modeling with Row and Column Factors Assume there are n+1 rows and columns in a triangle, numbered 0, …, n For accident year w and delay d, denote incremental losses by q w,d Let U w be the estimated ultimate for accident year w and g d be the fraction of losses that go to delay d Model: b d,w = U w g d

8 Guy Carpenter 8 Estimating Parameters by MLE Poisson distribution can be used to build likelihood function Answer: b is not determinable by MLE – higher b always gives higher likelihood – but other parameters do not depend on b U w is last diagonal grossed up by chain- ladder development factor g d is emergence pattern from development factors

9 Guy Carpenter 9 PCS Estimate is Chain Ladder Result Proven by Hachemeister and Stanard (1975) for Poisson case Good write-up in Clarke (2003) CAS Forum But uses (apparently) more parameters Fitted values are U w g d so fraction of ultimate for that column (like in BF) Basically back down from last diagonal by development factors So not chain ladder fitted values

10 Guy Carpenter 10 What is Variance of PCS Estimate? Process variance for ultimate is just b times ultimate mean using N observations, p parameters Clarke suggests parameter variance from delta method

11 Guy Carpenter 11 Delta Method (review of Part 4) Information matrix is negative of matrix of 2 nd derivatives of log-likelihood wrt all the parameters Matrix inverse of information matrix is covariance matrix of parameters Variance of function of the parameters takes vector of 1 st derivatives of function and right and left multiplies covariance matrix by it

12 Guy Carpenter 12 Sample Triangle from Taylor-Ashe

13 Guy Carpenter 13 Estimates from Triangle Reserve by chain ladder or PCS is 18,681,000 Standard deviation of prediction: Chain ladder PCS 2,447,000 2,827,000 PCS a much better fit – process standard deviation lower by half But parameter standard deviation 70% higher

14 Guy Carpenter 14 Fitting Example: 0-1 Incremental

15 Guy Carpenter 15 Testing Diagonals Diagonal Average Residual Fraction Positive 0 87,787 1 of 1 1 35,158 1 of 2 2 (76,176) 0 of 3 3 (74,853) 1 of 4 4 100,127 4 of 5 5 (26,379) 2 of 6 6 103,695 5 of 7 7 (115,163) 1 of 8 8 (17,945) 3 of 9 9 38,442 6 of 10

16 Guy Carpenter 16 Modeling Diagonal Effects In chain ladder can make one big regression, with incrementals all in one column as dependent variable Each previous cumulative is an independent variable = 0 except for corresponding points of incrementals Dummy variables pick out each diagonal More variance and independence issues – whole triangle not just each column

17 Guy Carpenter 17 Diagonal Effects in PCS Include factor h j for j th diagonal Model: b d,w = U w g d h w+d Iterative MLE estimation of parameters:

18 Guy Carpenter 18 But First, How to Compare MLE Fits Use information criteria Compare loglikelihoods penalized for number of parameters AIC – penalize by 1 for each parameter HQIC – penalize by ln ln N (N=55  1.388) Small sample AIC (AIC c ), per-parameter penalty is N/[N – p – 1]

19 Guy Carpenter 19 Loglikelihood with Diagonal Factors Tried original model with no diagonals, that plus 7 th diagonal, and that plus 6 th 19, 20 and 21 parameters Loglikelihoods: -149.11; -145.92; -145.03 @ 1.388 ppp 6 th and 7 th better than none, but worse than 7 th alone AIC c penalty for 20 th and 21 st parameters is 2.5 and 2.65 so both worse than none

20 Guy Carpenter 20 Reducing Parameters Adding 7 th diagonal improves fit but now 20 parameters Maybe set some the same, others as trends between starting and ending, etc

21 Guy Carpenter 21 Example Model 3 accident year parameters: most years at level U a, U 0 lower, U 7 higher, and U 6 average of U a and U 7 2 payout % parameters – high or low Delay 0: low, 1 – 3: high, 5 – 8: low, 4: average of high and low, 9: 1 – sum of others 1 diagonal parameter c with all factors either 1, 1+c, or 1–c ; 7 th low, 4 th & 6 th high

22 Guy Carpenter 22 Fit of Example Model Likelihood of -146.66 worse than 20 parameter model at -145.92 But AIC c penalty lower by 25.5 HQIC penalty lower by 19.4 Standard deviation 1,350,000 compared to 2,447,000 of chain ladder and 2,827,000 of original PCS Reserve about 5% higher with all models that include diagonal effects ParameterU0U0 U7U7 UaUa gaga gbgb c Estimate 3,810,000 7,113,775 5,151,1800.06790.17400.1985 Std Error 372,849 698,091 220,5080.00340.00560.0569

23 Guy Carpenter 23 Variance Comparison Model.…Original 19 Parameter6 Parameter Parameter Variance 7,009,527,908,8111,103,569,529,544 Process Variance 982,638,439,386718,924,545,072 Total Variance 7,992,166,348,1981,822,494,074,616 Parameter Std Dev 2,647,5511,050,509 Process Std Dev 991,281847,894 Standard Deviation 2,827,0421,349,998  Fit better with diagonals; Many fewer parameters

24 Guy Carpenter 24 Testing Variance Assumption If variance  mean 2, standardized residuals (divided by b ½ ) would tend to increase with fitted Probably ok

25 Guy Carpenter 25 Testing Poisson Assumption Computed Poisson probability of q w,d /b for each point. Sorted these and gave empirical probability of 1/56 to each. Comparison reasonable

26 Guy Carpenter 26 Issues No claim that this is the best model Can try other distribution assumptions and compare loglikelihoods Ignoring issue of model risk, which is probably large But getting better fits with diagonal effects and eliminating unneeded parameters can reduce variance

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