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I should start by saying what I'm trying to do: I want to use the mle function without having to re-write my log likelihood function each time I want to try a different model specification. Because mle is expecting a named list of starting values, you apparently cannot just write the log-likelihood function as taking a vector of parameters. A simple example:

Suppose I want to fit a linear regression model via maximum likelihood and at first, I'm ignoring one of my predictors:

n <- 100
df <- data.frame(x1 = runif(n), x2 = runif(n), y = runif(n))
Y <- df$y
X <- model.matrix(lm(y ~ x1, data = df))

# define log-likelihood function 
ll <- function(beta0, beta1, sigma){
  beta = matrix(NA, nrow=2, ncol=1)
  beta[,1] = c(beta0, beta1)
  -sum(log(dnorm(Y - X %*% beta, 0, sigma)))
}
library(stats4)
mle(ll, start = list(beta0=.1, beta1=.2, sigma=1)

Now, if I want to fit a different model, say:

m <- lm(y ~ x1 + x2, data = df)

I cannot re-use my log-likelihood function--I'd have to re-write it to have the beta3 parameter. What I'd like to do is something like:

ll.flex <- function(theta){
 # theta is a vector that I can use directly 
  ...
}

if I could then somehow adjust the start argument in mle to account for my now vector-input log-likelihood function, or barring that, have a function that constructs the log-likelihood function at run-time, say by constructing the named list of arguments and then using it to define the function e.g., something like this:

X <- model.matrix(lm(y ~ x1 + x2, data = df))
arguments <- rep(NA, dim(X)[2])
names(arguments) <- colnames(X)
ll.magic <- function(bring.this.to.life.as.function.arguments(arguments)){...} 

Update:

I ended up writing a helper function that can add an arbitrary number of named arguments x1, x2, x3... to a passed function f.

add.arguments <- function(f,n){
  # adds n arguments to a function f; returns that new function 
  t = paste("arg <- alist(",
  paste(sapply(1:n, function(i) paste("x",i, "=",sep="")), collapse=","),
  ")", sep="")
  formals(f) <- eval(parse(text=t))
  f
 }

It's ugly, but it got the job done, letting me re-factor my log-likelihood function on the fly.

share|improve this question
    
can't you just used fixed(x2=0)? –  Ben Bolker Sep 27 '11 at 16:12
    
in this particular example, yes, but if you want to be able to try arbitrarily complex specifications (e.g., adding interactions, transforms etc.), this strategy doesn't work. –  John Horton Sep 27 '11 at 16:20
    
out of curiosity, why would you use mle to fit parameters, when lm already does that for you?? –  Ramnath Sep 27 '11 at 17:21
    
oh - my real example is a nasty multinomial logit - I just did a linear regression for demonstration purposes. Btw - thank you for the excellent answer. –  John Horton Sep 27 '11 at 19:28
    
@John check the answer by Ben Bolker. it is very elegant as it automatically computes the likelihood for you based on the specification. –  Ramnath Sep 27 '11 at 19:35

4 Answers 4

up vote 4 down vote accepted

You can use the mle2 function from the package bbmle which allows you to pass vectors as parameters. Here is some sample code.

# REDEFINE LOG LIKELIHOOD
ll2 = function(params){
  beta = matrix(NA, nrow = length(params) - 1, ncol = 1)
  beta[,1] = params[-length(params)] 
  sigma    = params[[length(params)]]
  minusll  = -sum(log(dnorm(Y - X %*% beta, 0, sigma)))
  return(minusll)
}

# REGRESS Y ON X1
X <- model.matrix(lm(y ~ x1, data = df))
mle2(ll2, start = c(beta0 = 0.1, beta1 = 0.2, sigma = 1), 
  vecpar = TRUE, parnames = c('beta0', 'beta1', 'sigma'))

# REGRESS Y ON X1 + X2

X <- model.matrix(lm(y ~ x1 + x2, data = df))
mle2(ll2, start = c(beta0 = 0.1, beta1 = 0.2, beta2 = 0.1, sigma = 1), 
      vecpar = TRUE, parnames = c('beta0', 'beta1', 'beta2', 'sigma'))

This gives you

Call:
mle2(minuslogl = ll2, start = c(beta0 = 0.1, beta1 = 0.2, beta2 = 0.1, 
    sigma = 1), vecpar = TRUE, parnames = c("beta0", "beta1", 
    "beta2", "sigma"))

Coefficients:
     beta0      beta1      beta2      sigma 
 0.5526946 -0.2374106  0.1277266  0.2861055
share|improve this answer
    
thanks Ramnath. I was going to say something along those lines but couldn't be bothered/didn't have time to do the examples. –  Ben Bolker Sep 27 '11 at 17:45
    
i thought so, since you were the author of bbmle. i had some thoughts on added functionality to bbmle with some improvements to the vignette. let me know if you want to talk about it sometime. –  Ramnath Sep 27 '11 at 17:53
    
sure. send me an e-mail? –  Ben Bolker Sep 27 '11 at 17:57
    
@Ramnath shouldn't it be parnames(ll2) <- c('beta0', 'beta1', 'sigma') before the mle2 call? –  Andy Apr 11 '13 at 23:07

It might be easier to use optim directly; that's what mle is using anyway.

ll2 <- function(par, X, Y){
  beta <- matrix(c(par[-1]), ncol=1)
  -sum(log(dnorm(Y - X %*% beta, 0, par[1])))
}
getp <- function(X, sigma=1, beta=0.1) {
  p <- c(sigma, rep(beta, ncol(X)))
  names(p) <- c("sigma", paste("beta", 0:(ncol(X)-1), sep=""))
  p
}

set.seed(5)
n <- 100
df <- data.frame(x1 = runif(n), x2 = runif(n), y = runif(n))
Y <- df$y
X1 <- model.matrix(y ~ x1, data = df) 
X2 <- model.matrix(y ~ x1 + x2, data = df)
optim(getp(X1), ll2, X=X1, Y=Y)$par
optim(getp(X2), ll2, X=X2, Y=Y)$par

With the output of

> optim(getp(X1), ll2, X=X1, Y=Y)$par
      sigma       beta0       beta1 
 0.30506139  0.47607747 -0.04478441 
> optim(getp(X2), ll2, X=X2, Y=Y)$par
      sigma       beta0       beta1       beta2 
 0.30114079  0.39452726 -0.06418481  0.17950760 
share|improve this answer
    
nice one. but the reason people prefer to use mle is that in addition to the parameter estimates it returns a ton-load of useful information like standard errors, AIC etc. which are useful. it can be done using optim, but would need more code. –  Ramnath Sep 27 '11 at 17:17
    
True, though if it weren't for Ben, one would have to choose between using this and writing more code to get the useful information, or writing more code to make all the models. Thanks for the pointer to bbmle, @Ramnath ; it's new to me. –  Aaron Sep 27 '11 at 20:23
    
I agree. bbmle is a beautiful package that solves many of the common mle jobs. Another package for distribution fitting that is neat is fitdistrplus. –  Ramnath Sep 27 '11 at 20:43

It might not be what you're looking for, but I would do this as follows:

mle2(y ~ dnorm(mu, sigma),parameters=list(mu~x1 + x2), data = df,
    start = list(mu = 1,sigma = 1))

mle2(y ~ dnorm(mu,sigma), parameters = list(mu ~ x1), data = df,
    start = list(mu=1,sigma=1))

You might be able to adapt this formulation for a multinomial, although dmultinom might not work -- you might need to write a Dmultinom() that took a matrix of multinomial samples and returned a (log)probability.

share|improve this answer
    
i think it should be start = list(mu = 1, sigma = 1), and x1, x2 instead of y1, y1. moreover, the data = df argument needs to be added. i took the liberty of making these edits, but please feel free to roll back as appropriate. –  Ramnath Sep 27 '11 at 17:58
    
yes, thanks, guess I'm in a hurry/sloppy today. –  Ben Bolker Sep 27 '11 at 18:47

The R code that Ramnath provided can also be applied to the optim function because it takes vectors as parameters also.

share|improve this answer

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