# Adding a 3rd order polynomial and its equation to a ggplot in r

I have plotted the following data and added a loess smoother. I would like to add a 3rd order polynomial and its equation (incl. the residual) to the plot. Any advice?

``````set.seed(1410)
dsmall<-diamonds[sample(nrow(diamonds), 100), ]
df<-data.frame("x"=dsmall\$carat, "y"=dsmall\$price)

p <-ggplot(df, aes(x, y))
p <- p + geom_point(alpha=2/10, shape=21, fill="blue", colour="black", size=5)

p<- p + geom_smooth(method="loess",se=TRUE)
``````

How can I add a 3rd order polynomial? I have tried:

``````p<- p + geom_smooth(method="lm", se=TRUE, fill=NA,formula=lm(y ~ poly(x, 3, raw=TRUE)),colour="red")
``````

Finally how can I add the 3rd order polynomial equation and the residual to the graph? I have tried:

`````` lm_eqn = function(df){
m=lm(y ~ poly(x, 3, df))#3rd degree polynomial
eq <- substitute(italic(y) == a + b %.% italic(x)*","~~italic(r)^2~"="~r2,
list(a = format(coef(m)[1], digits = 2),
b = format(coef(m)[2], digits = 2),
r2 = format(summary(m)\$r.squared, digits = 3)))
as.character(as.expression(eq))
}

data.label <- data.frame(x = 1.5,y = 10000,label = c(lm_eqn(df)))

p<- p + geom_text(data=data.label,aes(x = x, y = y,label =label), size=8,family="Times",face="italic",parse = TRUE)
``````

Part 1: to fit a polynomial, use the arguments:

• `method=lm` - you did this correctly
• `formula=y ~ poly(x, 3, raw=TRUE)` - i.e. don't wrap this in a call to `lm`

The code:

``````p + stat_smooth(method="lm", se=TRUE, fill=NA,
formula=y ~ poly(x, 3, raw=TRUE),colour="red")
``````

Part 2: To add the equation:

• Modify your function`lm_eqn()` to correctly specify the data source to `lm` - you had a closing parentheses in the wrong place
• Use `annotate()` to position the label, rather than `geom_text`

The code:

``````lm_eqn = function(df){
m=lm(y ~ poly(x, 3), df)#3rd degree polynomial
eq <- substitute(italic(y) == a + b %.% italic(x)*","~~italic(r)^2~"="~r2,
list(a = format(coef(m)[1], digits = 2),
b = format(coef(m)[2], digits = 2),
r2 = format(summary(m)\$r.squared, digits = 3)))
as.character(as.expression(eq))
}

p + annotate("text", x=0.5, y=15000, label=lm_eqn(df), hjust=0, size=8,
family="Times", face="italic", parse=TRUE)
``````

• `lm_eqn` function is for linear regression, not for third degree polynomials
– Tung
Commented Feb 13, 2019 at 18:33
• One thing that tripped me up - `formula` needs to refer to `y` and `x` rather than the variable names in the data.frame. Confusing that the variable names happen to be `x` and `y` in the OP's example.
– jay
Commented Jul 22, 2019 at 23:54

Answer 1, is a good start but it is not for a 3rd degree polynomial as asked, and can not properly deal with negative values for parameter estimates. Easiest is to use package `polynom`. I will show a version without defining a function, because really one should use a ggplot `stat_` in a case like this.

Below I show how to generate the text to be used as the parsed label for polynomials of any degree. I use `signif()` instead of `format()` as this is more useful for parameter estimates. Also note that `face` is no longer needed. Using `family = "Times"` is not portable, and the same effect can be achieved with `"serif"`. All the hard work is done by `as.character.polynomial()`!

``````library(polynom)
library(ggplot2)

set.seed(1410)
dsmall <- diamonds[sample(nrow(diamonds), 100), ]
df <- data.frame("x"=dsmall\$carat, "y"=dsmall\$price)

my.formula <- y ~ poly(x, 3, raw = TRUE)
p <- ggplot(df, aes(x, y))
p <- p + geom_point(alpha=2/10, shape=21, fill="blue", colour="black", size=5)
p <- p + geom_smooth(method = "lm", se = FALSE,
formula = my.formula,
colour = "red")

m <- lm(my.formula, df)
my.eq <- as.character(signif(as.polynomial(coef(m)), 3))
label.text <- paste(gsub("x", "~italic(x)", my.eq, fixed = TRUE),
paste("italic(R)^2",
format(summary(m)\$r.squared, digits = 2),
sep = "~`=`~"),
sep = "~~~~")

p + annotate(geom = "text", x = 0.2, y = 15000, label = label.text,
family = "serif", hjust = 0, parse = TRUE, size = 4)
``````

A final note: variance increases with the mean, so using `lm()` and a 3rd degree polynomial model is probably not the best approach for the analysis of these data.

• I found that there is a ggplot2 FAQ on this subject. However, the approach in my answer is different. Commented Jan 9, 2016 at 23:22