Nice solution. I'm surprised ggplot doesn't have a function built in to do this... I needed to display equations and R2 values from polynomial fits (generated by the ns(x,order) function in the splines package), and have expanded your lm_eqn function to accomodate polynomials of varying orders.

Disclaimer: I'm still quite new to R coding, and I'm aware that this code is very messy. There must be a nicer way to do it, and I'm going to start another thread to ask people to refine the code, and possibly expand it to other fit models... You can follow it here: https://groups.google.com/forum/?fromgroups#!forum/ggplot2

```
lm_eqn = function(df,x.var,y.var,signif.figs,eq.plot=T,model.type,order){
if(missing(x.var) | missing(y.var) | class(x.var)!='character' | class(y.var)!='character') stop('x.var and y.var must be the names of the columns you want to use as x and y as a character string.' )
if(missing(model.type)) stop("model.type must be 'lin' (linear y~x model) or 'poly' (polynomial y~ns(x,order) model, generated by splines package).")
if(model.type=='poly' & missing(order)) stop("order must be specified if poly method is used.")
if(eq.plot==T) {
# Linear y=mx+c equation
if(model.type=='lin') {
fit = lm(df[[y.var]] ~ df[[x.var]]);
eq <- substitute(italic(y) == c + m %.% italic(x)*","~~italic(r)^2~"="~r2,
list(c = signif(coef(fit)[1], signif.figs),
m = signif(coef(fit)[2], signif.figs),
r2 = signif(summary(fit)$r.squared, signif.figs)))
as.character(as.expression(eq));
}
# polynomial expression generated with the ns(x,order) function [splines package]
if(model.type=='poly') {
fit = lm(df[[y.var]] ~ ns(df[[x.var]],order));
base = gsub('!c!',signif(coef(fit)[1],signif.figs),"italic(y) == !c! + ")
element.1 = "!m! %.% italic(x)~"
element.2 = " + !m! %.% italic(x)^!o!~"
element.r2 = gsub('!r2!',signif(summary(fit)$r.squared,signif.figs),"~~italic(r)^2~\"=\"~!r2!")
eq=""
for(o in 1:(order)) {
if(o==1) {
if(coef(fit)[(o+1)]<0) tmp=gsub("[+]","",base) else tmp=base
eq=paste(tmp,gsub('!m!',signif(coef(fit)[(o+1)],signif.figs),element.1),sep="")
}
if(o>1) {
if(coef(fit)[(o+1)]<0) tmp=gsub("[+]","",element.2) else tmp=element.2
eq=paste(eq,gsub('!o!',o,gsub('!m!',signif(coef(fit)[(o+1)],signif.figs),tmp)),sep="")
}
if(o==(order)) eq=paste(eq,"\",\"",element.r2,sep="")
}
}
}
if(eq.plot==F) {
# Linear y=mx+c equations
if(model.type=='lin') {
fit = lm(df[[y.var]] ~ df[[x.var]]);
eq <- substitute(italic(r)^2~"="~r2,
list(r2 = signif(summary(fit)$r.squared, signif.figs)))
as.character(as.expression(eq));
}
# polynomial expression generated with the ns() function [splines package]
if(model.type=='poly') {
fit = lm(df[[y.var]] ~ ns(df[[x.var]],order));
eq = gsub('!r2!',signif(summary(fit)$r.squared,signif.figs),"italic(r)^2~\"=\"~!r2!")
}
}
return(eq)
}
```

`ddply`

and the function from Ramnath's answer in that other question to create a data frame with both your faceting variables, x and y variables (locations for eqn in each panel) and a character variable for the eqn itself. Then just pass that data frame to`geom_text`

. – joran Mar 13 '12 at 14:17