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README.md
In lite: Likelihood-Based Inference for Time Series Extremes
lite
Likelihood-Based Inference for Time Series Extremes
The lite package performs likelihood-based inference for stationary
time series extremes. The general approach follows Fawcett and Walshaw
(2012). There are 3 independent parts
to the inference.
- A Bernoulli (pu) model for whether a given
observation exceeds the threshold $u$.
- A generalised Pareto, GP (σu,ξ), model for the
marginal distribution of threshold excesses.
- The $K$-gaps model for the extremal index $\theta$, based on
inter-exceedance times.
For parts 1 and 2 it is necessary to adjust the inferences because we
expect that the data will exhibit cluster dependence. This is achieved
using the methodology developed in Chandler and Bate
(2007) to produce a
log-likelihood that is adjusted for this dependence. This is achieved
using the chandwich
package. For part 3, the
methodology described in Süveges and Davison
(2010) is used, implemented by the
function kgaps in the exdex
package. The (adjusted)
log-likelihoods from parts 1, 2 and 3 are combined to make inferences
about return levels.
We illustrate the main functions in lite using the cheeseboro wind
gusts data from the exdex
package, which contains
hourly wind gust data from each January over the 10-year period
2000-2009.
Frequentist inference
The function flite makes frequentist inferences about
$(p_u, \sigma_u, \xi, \theta)$ using maximum likelihood estimation.
First, we make inferences about the model parameters.
library(lite)
cdata <- exdex::cheeseboro
# Each column of the matrix cdata corresponds to data from a different year
# flite() sets cluster automatically to correspond to column (year)
cfit <- flite(cdata, u = 45, k = 3)
summary(cfit)
#>
#> Call:
#> flite(data = cdata, u = 45, k = 3)
#>
#> Estimate Std. Error
#> p[u] 0.02771 0.005988
#> sigma[u] 9.27400 2.071000
#> xi -0.09368 0.084250
#> theta 0.24050 0.023360
Then, we make inferences about the 100-year return level, including 95%
confidence intervals. The argument ny sets the number of observations
per year, which is $31 \times 24 = 744$ for these data.
rl <- returnLevel(cfit, m = 100, level = 0.95, ny = 31 * 24)
rl
#>
#> Call:
#> returnLevel(x = cfit, m = 100, level = 0.95, ny = 31 * 24)
#>
#> MLE and 95% confidence limits for the 100-year return level
#>
#> Normal interval:
#> lower mle upper
#> 69.80 88.62 107.44
#> Profile likelihood-based interval:
#> lower mle upper
#> 75.89 88.62 125.43
Bayesian inference
The function blite performs Bayesian inferences about
$(p_u, \sigma_u, \xi, \theta)$, based on a likelihood constructed from
the (adjusted) log-likelihoods detailed above. First, we sample from the
posterior distribution of the parameters, using the default priors.
cpost <- blite(cdata, u = 45, k = 3, ny = 31 * 24)
summary(cpost)
#>
#> Call:
#> blite(data = cdata, u = 45, k = 3, ny = 31 * 24)
#>
#> Posterior mean Posterior SD
#> p[u] 0.02832 0.006008
#> sigma[u] 10.03000 2.435000
#> xi -0.07196 0.094030
#> theta 0.24250 0.024040
Then, we estimate a 95% highest predictive density (HPD) interval for
the largest value $M_{100}$ to be observed over a future time period of
length $100$ years.
predict(cpost, hpd = TRUE, n_years = 100)$short
#> lower upper n_years level
#> [1,] 73.09008 139.8616 100 95
Objects returned from flite and blite have plot methods to
summarise graphically, respectively, log-likelihoods and posterior
distributions.
Installation
To get the current released version from CRAN:
install.packages("lite")
Vignettes
See vignette("lite-1-frequentist", package = "lite") and
vignette("lite-2-bayesian", package = "lite").
Try the lite package in your browser
Any scripts or data that you put into this service are public.
lite documentation built on Sept. 11, 2024, 6:27 p.m.
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Note that we can't provide technical support on individual packages. You should contact the package authors for that.
lite
Likelihood-Based Inference for Time Series Extremes
The lite package performs likelihood-based inference for stationary time series extremes. The general approach follows Fawcett and Walshaw (2012). There are 3 independent parts to the inference.
- A Bernoulli (pu) model for whether a given observation exceeds the threshold $u$.
- A generalised Pareto, GP (σu,ξ), model for the marginal distribution of threshold excesses.
- The $K$-gaps model for the extremal index $\theta$, based on inter-exceedance times.
For parts 1 and 2 it is necessary to adjust the inferences because we
expect that the data will exhibit cluster dependence. This is achieved
using the methodology developed in Chandler and Bate
(2007) to produce a
log-likelihood that is adjusted for this dependence. This is achieved
using the chandwich
package. For part 3, the
methodology described in Süveges and Davison
(2010) is used, implemented by the
function kgaps in the exdex
package. The (adjusted)
log-likelihoods from parts 1, 2 and 3 are combined to make inferences
about return levels.
We illustrate the main functions in lite using the cheeseboro wind
gusts data from the exdex
package, which contains
hourly wind gust data from each January over the 10-year period
2000-2009.
Frequentist inference
The function flite makes frequentist inferences about
$(p_u, \sigma_u, \xi, \theta)$ using maximum likelihood estimation.
First, we make inferences about the model parameters.
library(lite)
cdata <- exdex::cheeseboro
# Each column of the matrix cdata corresponds to data from a different year
# flite() sets cluster automatically to correspond to column (year)
cfit <- flite(cdata, u = 45, k = 3)
summary(cfit)
#>
#> Call:
#> flite(data = cdata, u = 45, k = 3)
#>
#> Estimate Std. Error
#> p[u] 0.02771 0.005988
#> sigma[u] 9.27400 2.071000
#> xi -0.09368 0.084250
#> theta 0.24050 0.023360
Then, we make inferences about the 100-year return level, including 95%
confidence intervals. The argument ny sets the number of observations
per year, which is $31 \times 24 = 744$ for these data.
rl <- returnLevel(cfit, m = 100, level = 0.95, ny = 31 * 24)
rl
#>
#> Call:
#> returnLevel(x = cfit, m = 100, level = 0.95, ny = 31 * 24)
#>
#> MLE and 95% confidence limits for the 100-year return level
#>
#> Normal interval:
#> lower mle upper
#> 69.80 88.62 107.44
#> Profile likelihood-based interval:
#> lower mle upper
#> 75.89 88.62 125.43
Bayesian inference
The function blite performs Bayesian inferences about
$(p_u, \sigma_u, \xi, \theta)$, based on a likelihood constructed from
the (adjusted) log-likelihoods detailed above. First, we sample from the
posterior distribution of the parameters, using the default priors.
cpost <- blite(cdata, u = 45, k = 3, ny = 31 * 24)
summary(cpost)
#>
#> Call:
#> blite(data = cdata, u = 45, k = 3, ny = 31 * 24)
#>
#> Posterior mean Posterior SD
#> p[u] 0.02832 0.006008
#> sigma[u] 10.03000 2.435000
#> xi -0.07196 0.094030
#> theta 0.24250 0.024040
Then, we estimate a 95% highest predictive density (HPD) interval for the largest value $M_{100}$ to be observed over a future time period of length $100$ years.
predict(cpost, hpd = TRUE, n_years = 100)$short
#> lower upper n_years level
#> [1,] 73.09008 139.8616 100 95
Objects returned from flite and blite have plot methods to
summarise graphically, respectively, log-likelihoods and posterior
distributions.
Installation
To get the current released version from CRAN:
install.packages("lite")
Vignettes
See vignette("lite-1-frequentist", package = "lite") and
vignette("lite-2-bayesian", package = "lite").
Try the lite package in your browser
Any scripts or data that you put into this service are public.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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