RHS: Renshaw-Haberman model
In demofit: Parametric Mortality Curve Fitting and Mortality Forecasting Tools
RHS R Documentation
Renshaw-Haberman model
Description
Fits and forecasts mortality rates using Renshaw-Haberman model.
Usage
RHS(
x,
M,
curve = c("gompertz", "makeham", "oppermann", "thiele", "wittsteinbumsted", "perks",
"weibull", "vandermaen", "beard", "heligmanpollard", "rogersplanck", "siler",
"martinelle", "thatcher", "gompertz2", "makeham2", "oppermann2", "thiele2",
"wittsteinbumsted2", "perks2", "weibull2", "vandermaen2", "beard2",
"heligmanpollard2", "rogersplanck2", "siler2", "martinelle2", "thatcher2"),
h = 10,
jumpoff = 1
)
Arguments
x
vector of ages.
M
matrix of mortality rates (rows as years and columns as ages).
curve
name of mortality curve for smoothing forecasted mortality rates (including gompertz, makeham, oppermann, thiele, wittsteinbumsted, perks, weibull, vandermaen, beard, heligmanpollard, rogersplanck, siler, martinelle, thatcher, gompertz2, makeham2, oppermann2, thiele2, wittsteinbumsted2, perks2, weibull2, vandermaen2, beard2, heligmanpollard2, rogersplanck2, siler2, martinelle2, thatcher2, where first 14 curves' parameters are unconstrained and last 14 curves' parameters are generally restricted to be positive).
h
forecast horizon (default = 10).
jumpoff
if 1, forecasts are based on estimated parameters only; if 2, forecasts are anchored to observed mortality rates in final year (default = 1).
Details
The Renshaw-Haberman (RH) model is specified as
ln(m_{x,t}) = \alpha_x + \beta_x \kappa_t + \gamma_{t-x} + \epsilon_{x,t}.
The model is estimated by Newton updating scheme and is forecasted by ARIMA applied to \kappa_t and \gamma_c. Constraints include sum of \beta_x is one, sum of \kappa_t is zero, and sum of \gamma_c is zero. It can be applied to whole age range.
Value
An object of class RHS with associated S3 methods coef, forecast, plot, and residuals.
References
Haberman, S. and Renshaw, A. (2011). A comparative study of parametric mortality projection models. Insurance: Mathematics and Economics, 48(1), 35-55.
Examples
x <- 60:89
a <- c(-4.8499,-4.7676,-4.6719,-4.5722,-4.4847,-4.3841,-4.2813,-4.1863,-4.0861,-3.9962,
-3.8885,-3.7896,-3.6853,-3.5737,-3.4728,-3.3718,-3.2586,-3.1474,-3.0371,-2.9206,
-2.7998,-2.6845,-2.5653,-2.4581,-2.3367,-2.2159,-2.1017,-1.9941,-1.8821, -1.7697)
b <- c(0.0283,0.0321,0.0335,0.0336,0.0341,0.0358,0.0368,0.0403,0.0392,0.0395,
0.0396,0.0399,0.0397,0.0386,0.039,0.0375,0.0367,0.0368,0.035,0.0354,
0.0336,0.0323,0.0313,0.0295,0.0282,0.0265,0.024,0.0226,0.0219,0.0183)
k <- c(12.11,10.69,11.18,9.64,9.35,8.21,6.89,5.74,4.56,3.6,
3.27,2.04,1.11,-0.44,-1.05,-1.03,-1.84,-2.9,-4.03,-4.12,
-5.18,-5.64,-6,-6.51,-6.91,-6.9,-8.32,-8.53,-9.69,-9.31)
set.seed(123)
M <- exp(outer(k,b)+matrix(a,nrow=30,ncol=30,byrow=TRUE)+rnorm(900,0,0.035))
fit <- RHS(x=x,M=M,curve="makeham",h=30,jumpoff=2)
coef(fit)
forecast::forecast(fit)
plot(fit)
residuals(fit)
demofit documentation built on April 9, 2026, 5:09 p.m.
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| RHS | R Documentation |
Renshaw-Haberman model
Description
Fits and forecasts mortality rates using Renshaw-Haberman model.
Usage
RHS(
x,
M,
curve = c("gompertz", "makeham", "oppermann", "thiele", "wittsteinbumsted", "perks",
"weibull", "vandermaen", "beard", "heligmanpollard", "rogersplanck", "siler",
"martinelle", "thatcher", "gompertz2", "makeham2", "oppermann2", "thiele2",
"wittsteinbumsted2", "perks2", "weibull2", "vandermaen2", "beard2",
"heligmanpollard2", "rogersplanck2", "siler2", "martinelle2", "thatcher2"),
h = 10,
jumpoff = 1
)
Arguments
x |
vector of ages. |
M |
matrix of mortality rates (rows as years and columns as ages). |
curve |
name of mortality curve for smoothing forecasted mortality rates (including gompertz, makeham, oppermann, thiele, wittsteinbumsted, perks, weibull, vandermaen, beard, heligmanpollard, rogersplanck, siler, martinelle, thatcher, gompertz2, makeham2, oppermann2, thiele2, wittsteinbumsted2, perks2, weibull2, vandermaen2, beard2, heligmanpollard2, rogersplanck2, siler2, martinelle2, thatcher2, where first 14 curves' parameters are unconstrained and last 14 curves' parameters are generally restricted to be positive). |
h |
forecast horizon (default = 10). |
jumpoff |
if 1, forecasts are based on estimated parameters only; if 2, forecasts are anchored to observed mortality rates in final year (default = 1). |
Details
The Renshaw-Haberman (RH) model is specified as
ln(m_{x,t}) = \alpha_x + \beta_x \kappa_t + \gamma_{t-x} + \epsilon_{x,t}.
The model is estimated by Newton updating scheme and is forecasted by ARIMA applied to \kappa_t and \gamma_c. Constraints include sum of \beta_x is one, sum of \kappa_t is zero, and sum of \gamma_c is zero. It can be applied to whole age range.
Value
An object of class RHS with associated S3 methods coef, forecast, plot, and residuals.
References
Haberman, S. and Renshaw, A. (2011). A comparative study of parametric mortality projection models. Insurance: Mathematics and Economics, 48(1), 35-55.
Examples
x <- 60:89
a <- c(-4.8499,-4.7676,-4.6719,-4.5722,-4.4847,-4.3841,-4.2813,-4.1863,-4.0861,-3.9962,
-3.8885,-3.7896,-3.6853,-3.5737,-3.4728,-3.3718,-3.2586,-3.1474,-3.0371,-2.9206,
-2.7998,-2.6845,-2.5653,-2.4581,-2.3367,-2.2159,-2.1017,-1.9941,-1.8821, -1.7697)
b <- c(0.0283,0.0321,0.0335,0.0336,0.0341,0.0358,0.0368,0.0403,0.0392,0.0395,
0.0396,0.0399,0.0397,0.0386,0.039,0.0375,0.0367,0.0368,0.035,0.0354,
0.0336,0.0323,0.0313,0.0295,0.0282,0.0265,0.024,0.0226,0.0219,0.0183)
k <- c(12.11,10.69,11.18,9.64,9.35,8.21,6.89,5.74,4.56,3.6,
3.27,2.04,1.11,-0.44,-1.05,-1.03,-1.84,-2.9,-4.03,-4.12,
-5.18,-5.64,-6,-6.51,-6.91,-6.9,-8.32,-8.53,-9.69,-9.31)
set.seed(123)
M <- exp(outer(k,b)+matrix(a,nrow=30,ncol=30,byrow=TRUE)+rnorm(900,0,0.035))
fit <- RHS(x=x,M=M,curve="makeham",h=30,jumpoff=2)
coef(fit)
forecast::forecast(fit)
plot(fit)
residuals(fit)
R Package Documentation
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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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