# Step-by-step formula based _R_ codes for GLM and GLMM

I know how to fit generalized linear models (GLMs) and generalized linear mixed models (GLMMs) with `glm` and `glmer` from lme4 package in R. Being a student of statistics, I'm interested in learning how to fit GLM and GLMM following step-by-step formula bases R codes. I'd highly appreciate if you point out any resource and/or reference in this regard. Thanks in advance.

EDiT

I'd like to do GLM and GLMM step by step using formula as we do LM using matrix approach. Is there any R book or tutorial available that use this approach? Thanks

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Do you mean that you want to learn how to write code to fit GLM(M)s? –  Gavin Simpson Aug 3 '11 at 16:41
I think the answer is, in part, "McCullagh and Nelder". Read that, tells you all the algorithms. Start with simple linear Gaussian stuff first though. –  Spacedman Aug 3 '11 at 16:46
@Spacedman Indeed. And the R sources of course. –  Gavin Simpson Aug 3 '11 at 16:48
Crawley's "The R book" has an entire chapter on GLM using `glm`and a 5-page worked example on GLMM usig `lmer` –  Andrie Aug 3 '11 at 16:52
This might belong on CV R tag.... –  Ari B. Friedman Aug 3 '11 at 17:04

"An R Companion to Applied Regression" by Fox and Weisberg, has an excellent guide in chapter 8, with logistic regression as an example. The book also teaches a bit about how to create model functions in general with S3 and S4 objects. In particular, it has good answers to a recent question I'd asked about modeling -- What are the key components and functions for standard model objects in R?.

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This may help
** Poisson regression: GLM**
*Suggested reading: An Introduction to generalized linear model, by Annette J. Dobson, 2nd Edition, Chapter 4, section 4.3 and 4.4 *

``````library(MASS)
poisreg = function(n, b1, y, x1, tolerence) {  # n is the number of iteration
x0 = rep(1, length(x1))
x = cbind(x0, x1)
y = as.matrix(y)
w = matrix(0, nrow = (length(y)), ncol = (length(y)))
b0 = b1
result = b0
for (i in 1:n) {
mu = exp(x %*% b0)
diag(w) = mu
eta = x %*% b0
z = eta + (y - mu) * (1/mu)   # dot product of (y - mu) & (1/mu)
xtwx = t(x) %*% w %*% x
xtwz = t(x) %*% w %*% z
b1 = solve(xtwx, xtwz)
if(sqrt(sum(b0 - b1)^2) > tolerence) (b0 <- b1)
result<- cbind(result,b1) # to get all the iterated values
}
result
}
x1 <- c(-1,-1,0,0,0,0,1,1,1) # x1 is the explanatory variable
y<- c(2,3,6,7,8,9,10,12,15)  # y is the dependent variable
b1 = c(1,2) # initial value
poisreg (10, b1, y, x1, .001)   # Nicely converge after 10 iterations