The Statistical Distribution of Annual Maximum Rainfall in ...
Jrothenb – 1 Joerg Rothenbuehler. jrothenb – 2 The distribution of the Maximum:
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Transcript of Jrothenb – 1 Joerg Rothenbuehler. jrothenb – 2 The distribution of the Maximum:
jrothenb – 1
Joerg Rothenbuehler
jrothenb – 2
The distribution of the Maximum:
).1)(,sup(
where, a.s. M e,consequenc a As
(x).Fx]P[MThen
).,....,,( maxMLet
F(x). cdf with variablesrandom iid be ,....),(Let
n
nn
21n
21
xFxx
x
XXX
XX
F
F
n
jrothenb – 3
Fisher-Tippett Theorem
holds. (1) if MDA(H) F :Notation
(EVD). onsDistributi
Value Extreme called are onsdistributi These
Gumbel.or Weibull,Frechet,either is HThen
(1) )(c
)d-(M
:such that
H, df degenerate-non a andd 0,c Suppose
n
n n
n n
xHD
jrothenb – 4
The Extreme Value Distributions
with xdistr. edlight tail oflimit theis
R x),eexp(Λ(x):Gumbel
with xdistr. oflimit theis
0α 0, x),exp(-(-x)(x)Ψ :Weibull
xas cxF(x)-1 :αindex tail with
onsdistributi edheavy tail oflimit theis
0α 0,x),xexp((x)Φ :Frechet
F
x
F
αα
α
αα
jrothenb – 5
The three EVD can be represented by a single three parameter distribution, called the GENERALIZED EVD (GEV):
0-x
ξ1 where
0ξ if -x
exp(-- exp
0ξ if -x
ξ1- exp
(x)H
ξ/1
,ξ,
Generalized Extreme Value Distribution (GEV)
jrothenb – 6
The function of the parameters
parameter. shape theisparameter crucial The
dataset. a toGEV the
fitting of purpose for the introduced are and
theis 0
theis R
1/α- ξ with dist. Weibull the toscorrespond H :0 ξ
dist. Gumbel the toscorrespond H :0 ξ
1/α ξ with dist.Frechet the toscorrespond H :0 ξ
: thecalled is R
parameterscaling
parameter location
parametershape
jrothenb – 7
Excesses over high thresholds
(x)G]aXaP[X β(a)ξ,
jrothenb – 8
Generalized Pareto Distribution (GPD)
0ξ if ξ/βx0
0ξ if 0 x where
ξ and 0 :parameterswith
0ξ if ) exp(-x/β -1
0ξ if β
xξ1 -1(x)G
-1/ξ
βξ,
R
jrothenb – 9
Properties of GPD
β/ξendpoint xright finite has isG :0 ξ
edlight tail isG :0 ξ
1/ξindex with tailedheavy tail isG :0 ξ
1
0ξaβ ,ξ-1
ξaβ]aXaE[Xe(a)
: xafor then β, and 1 with GPD ~ X If F
jrothenb – 10
The Empirical Mean Excess Function
The empirical mean excess function of a GPD with
1β .2,ξ
jrothenb – 11
Modeling Extreme Events:
The number of exceedances of a high threshold follows a Poisson process (iid exp. distributed interarrival times)
Excesses over a high threshold can be modeled by a GPD An appropriate value of the high threshold can be found
by plotting the empirical mean excess function. The distribution of the maximum of a Poisson number of
iid excesses over a high threshold is a GEV with the same shape parameter as the corresponding GPD.
jrothenb – 12
Extremal Index of a Stationary Time Series The extremal index measures the dependence
of the data in the tails. can be interpreted as the average cluster size in the
tails: High values appear in clusters of size means there is no clustering in the tails. If the data does not show strong long range dependence,
but has extremal index , its maxima has distribution
, where H is the GEV of iid data with the same marginal distribution.
GPD analysis may not be appropriate for data with
1 θ0
1/θ
1 θ )(Hθ x
1 θ
1 θ
1/θ
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The Data: Surveyor Project
One way delays of probe packets during one week Packets sent according to a Poisson process with a rate of
2/sec Packet is time-stamped to measure delay If delay >10 sec, packet assumed lost, discarded Saturday and Sunday excluded for analysis More details:
http://telesto.advanced.org/~kalidindi/papers/INET/inet99.html
jrothenb – 14
Time-Series Plot Colorado-Harvard
Monday 12:00am - Friday 8:00 pm
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ACF and Ex. Index Estimation
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Empirical Mean Excess Function
jrothenb – 17
Estimation of Shape Parameter as a function the used threshold using GPD
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Result of the GPD Fit
jrothenb – 19
Fit of a GPD-Distr. for Colorado-Harvard
threshold = 107.774 Quantile of threshold = 0.9993536 Number of exceedances = 500 Parameter estimates and Standard Errors
xi beta
-0.3319409 86.50868
0.03683419 4.844786
jrothenb – 20
Estimations based on GPD Fit
p quantile sfall empirical quantile0.99940 114.13890 177.50201 115.6380.99950 129.06973 188.71184 130.8681 0.99960 146.15561 201.53964 147.7083 0.99970 166.39564 216.73554 165.8802 0.99980 191.83186 235.83264 190.7157 0.99990 228.12013 263.07730 229.9743 0.99995 256.94996 284.72227 252.47050.99999 303.07272 319.35051 311.11221.00000 368.3887 368.3887 329.237
jrothenb – 21
Quantile estimation as a function of the threshold
Empirical quantile
99.995% Estimate
jrothenb – 22
Fitting a GEV to block wise maxima
Block 1 Block 2 Block 3 Block 4 Block 5
jrothenb – 23
GEV-Fit Results for different Block sizes
Block size = 7200 : 108 Blocks
xi sigma mu
Estimation -0.3375603 59.75591 197.1503
Std. Error 0.0734163 4.69351 6.4305
Block size = 14400 : 54 Blocks
xi sigma mu
Estimation -0.4346847 51.7389 235.2513
Std. Error 0.1256784 6.2025 8.0083
jrothenb – 24
High Level Estimation
Level exceeded during 1 of 50 hours
Block size Lower Estimate Upper 1h 314.8669 326.7487 355.9581
1.5 h 318.4539 327.3824 357.6406
2h 315.7877 324.6415 352.1868
Level exceeded during 1 of 100 hours
Block size Lower Estimate Upper 1h 322.4220 336.7065 371.3975
1.5h 325.7779 335.4343 371.0107
2h 324.3893 332.4487 365.1899
jrothenb – 25
Does GPD always work? The Army-Lab. – Univ. of. Virginia dataset
Time Series Plot
ACF Plot, Lags:5-1000PACF Plot, Lags: 1-1000
ACF Plot, Lags:1-1000
jrothenb – 26
What goes wrong beyond the LRD:
Empirical Mean Excess Function
Shape Parameter
jrothenb – 27
Non-Stationarity: Harvard to Army- Lab.Time Series Plot: Monday 12 am – Friday 8 pm
jrothenb – 28
Pick a few hours per day!Mean Excess Plot11am – 4pm Mon - Fri
Empirical Tail Distr.
Shape Parameter Estimation
jrothenb – 29
Single Outlier: Virginia - HarvardEmpirical Tail Distr.
ACF, Lag 3-1000
Estimation of Extremal Index
Monday 12am – Friday 8pm
jrothenb – 30
The effect of the outlier on GEV
Fit Without outlier:
Block size = 14400 53 Blocks
xi sigma mu
-0.4988539 45.08995 117.2362 x1=280.101
0.09091089 5.217626 6.735118
Fit With outlier
Block size = 14400 53 Blocks
xi sigma mu
-0.09130441 44.97725 109.3819 x1=1242.969
0.06274905 4.576706 6.716929
jrothenb – 31
The effect of the single outlier on GPD:Analysis with outlier
Analysis without outlier
jrothenb – 32
Conclusions:
The GPD is a model that can be fitted to the tails of a distribution. The quality of the fit can be checked with various methods. From the model, we can gain quantile estimates at the edge of or outside the data range. However, a good fit is often not possible.
The GEV provides a model for the distribution of block wise Maxima. Its use is supported by EVT for stationary time series without strong LRD, while GPD is only supported in the iid case. The quality of fit can be checked with similar tools as in the GPD model. Certain problems remain, and reliable quantile estimates are not available.
jrothenb – 33
Acknowledgements:
•Applied Research Group at Telcordia:–E. van den Berg
–K. Krishnan
–J. Jerkins
–A. Neidhardt
–Y. Chandramouli
•Cornell University:–Prof. G. Samorodnitsky