This vignette presents the fitMWD() function, which is
used to estimate the parameters of the Modified Weibull Distribution
(MWD) using several estimation methods, including maximum likelihood
(ML), least squares (LS), weighted least squares (WLS), and maximum
product of spacings (MPS).
The MWD, introduced by Lai et al. (2003), has been widely used in
reliability and survival analysis. A random variable \(X\) is said to follow an MWD if its
cumulative distribution function (CDF) and probability density function
(PDF) are given by \[
F(x) = 1- \exp \big( -a x^b e^{\lambda x} \big),
\] and \[
f(x) = a (b + \lambda x) x^{b-1} e^{\lambda x} \exp \big( -a x^b
e^{\lambda x} \big),
\]
where \(x>0\), \(a>0\) is the scale parameter, \(b \ge 0\) is a shape parameter, and \(\lambda \ge 0\) is an acceleration or
flexibility parameter controlling the rate of hazard growth.
Let a random sample from \(X \sim MWD(a, b,
\lambda)\) are observed as \(x_i, \;
i=1,\dots, n\). For all estimation methods, optimization is
performed using stats::optim.
The MLEs are obtained by maximizing the log-likelihood function: \[ \ell(a,b,\lambda; \mathbf{x}) = \sum_{i=1}^{n} \log \big(a (b + \lambda x_i) x_i^{b-1} e^{\lambda x_i} \big) - a \sum_{i=1}^{n} x_i^b e^{\lambda x_i}. \]
The LSE is obtained by minimizing the squared differences between the theoretical and empirical CDF values at the ordered sample points.
Let \(x_{(1)}<x_{(2)}< \dots < x_{(n)}\) denote the ordered samples. The objective function is: \[ Q(a,b,\lambda) = \sum_{i=1}^n \bigg( F(x_{(i)};a,b,\lambda) - \frac{i-0.3}{n+0.4} \bigg)^2. \]
The WLSE extends LSE by introducing weights: \[ Q^W(a,b,\lambda) = \sum_{i=1}^n w_i \bigg( F(x_{(i)};a,b,\lambda) - \frac{i-0.3}{n+0.4} \bigg)^2, \] where \(w_i = \frac{(n+1)^2(n+2)}{i(n-i+1)}, \; i=1,\dots,n.\)
The MPS estimates are obtained by maximizing: \[ M(a,b,\lambda) = \sum_{i=1}^{n+1} \frac{1}{n+1} \log \big( F(x_{(i)};a,b,\lambda) - F(x_{(i-1)};a,b,\lambda) \big), \] where \(F(x_{(0)};a,b,\lambda) = 0\) and \(F(x_{(n+1)};a,b,\lambda) = 1\).
fitMWD()To illustrate the use of fitMWD(), we consider a
simulated example.
# Load the package
library(SSReliabilityClaytonMWD)
# generate data from MWD(a, b, lambda)
n <- 100
a <- 0.75; b <- 1.25; lambda <- 0.60
# set seed
set.seed(123)
dat <- rMweibull(n, a, b, lambda)
# random initial points
init <- runif(3)MLE of the parameters:
# Fit MWD to `dat`
fit.mle <- fitMWD(data = dat, est.method = "mle", opt.method = "L-BFGS-B", starts = init,
lower = c(1e-05,1e-05,1e-05), upper = c(Inf,Inf,Inf), hessian = FALSE )
fit.mle$estimates
#> a b lambda
#> 0.7231634 1.2600843 0.6559157LSE of the parameters:
fit.lse <- fitMWD(data = dat, est.method = "lse", opt.method = "L-BFGS-B", starts = init,
lower = c(1e-05,1e-05,1e-05), upper = c(Inf,Inf,Inf), hessian = FALSE )
fit.lse$estimates
#> a b lambda
#> 0.9299033 1.4069386 0.4020883WLSE of the parameters:
fit.wlse <- fitMWD(data = dat, est.method = "wlse", opt.method = "L-BFGS-B", starts = init,
lower = c(1e-05,1e-05,1e-05), upper = c(Inf,Inf,Inf), hessian = FALSE )
fit.wlse$estimates
#> a b lambda
#> 0.9220048 1.4228131 0.4207337MPS of the parameters:
Lai, C. D., Xie, M., and Murthy, D. N. P. (2003). A modified Weibull distribution.IEEE Transactions on Reliability, 52(1), 33–37.