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I would like to fit weibull parameter using "Method of Moments Estimation" (MME) in R. I know we can estimate these value with Maximum Likelihood Estimation (MLE) using fitdisr() function in MASS package, but I want to know if there is function or package to calculate the parameter with MME.

For example, I want to approximate MME with Monte Carlo method. When I generate 1000 value from uniform distribution, the function that I write for this problem (for estimate of an integral), give me the 0 value. How can I fix this problem?

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closed as off-topic by Ben Bolker, csgillespie, joran, Thomas, Camilo Martin Nov 11 '13 at 21:28

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this is a "give me the code" question ... if you look up the mean and variance of the Weibull distribution, you can use a 2-dimensional root-finder to solve (mean,variance)=(shape,scale) (I think you could do a little bit of algebra to reduce the problem to a slightly simpler form where you might be able to do 1D root-finding, which is much easier) –  Ben Bolker Nov 11 '13 at 15:37
    
thank you @BenBolker, but it's not a simple root-finder for me cause each of two equation must be solve at numerical calculation and I don't know how to solve those equation –  Magicmahdi Nov 11 '13 at 17:19
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1 Answer 1

up vote 2 down vote accepted

Here's one way to use MME for finding the parameters of a Weibull distribution.

# load packages
require(rootSolve)
# generate data
N <- 1000
shape <- 2
scale <- 6
X <- rweibull(n=N, shape=shape, scale=scale)
# range of plausible shapes (for solver)
min_shape <- 0.1
max_shape <- 100 
# bootstraping
Nboot <- 1000
sim <- replicate(Nboot, {
  Xboot <- sample(X, replace=TRUE)
  # find shape
  rt <- 1+(sd(Xboot)/mean(Xboot))^2
  rootFct <- function(k) {
    gamma(1+2/k)/gamma(1+1/k)^2 - rt
  }
  shape_est <- uniroot.all(rootFct, c(min_shape, max_shape))
  if (length(shape_est)!=1) stop("The shape may be outside min_shape and max_shape")
  scale_est <- mean(Xboot)/gamma(1+1/shape_est)
  c(shape=shape_est, scale=scale_est)
})
apply(sim, 1, function(x)
  c(est=mean(x), se=sd(x), quantile(x, c(.025, .5, .975))))
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@ shadow,thank you for your help. –  Magicmahdi Nov 11 '13 at 19:29
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