# Polynomial regression equation

I am trying to correlate two sediment cores as I have different samples at varying depths within the cores. I have used the ggplot 2 function to plot a 5th order polynomial regression, displaying the equation and r2 value on the graph.

The issue I am having is with the equation itself, the r2 value is correct but the equation is not. I think this is to do with lm_eq referring to linear regression but I am not too sure.

Any help or direction would be greatly appreciated. I am happy with the graph itself but any suggestions on how to clean up my code would also be greatly appreciated.

I have tried googling other functions on how to show the equation but have not found a solution.

``````long_data <- gather(Correlations, key = "Core", value = "Depth",
#Reshapes my data frame
LC1U, LC3U)
df <- data.frame("x"=long_data\$Sample, "y"=long_data\$Depth)

lm_eqn = function(df){   m=lm(y ~ poly(x, 5), df)#3rd degree polynomial   eq <- substitute(italic(y) == a + b %.% italic(x)*","~~italic(r)^2~"="~r2,
list(a = format(coef(m), digits = 2),
b = format(coef(m), digits = 2),
r2 = format(summary(m)\$r.squared, digits = 4)))   as.character(as.expression(eq)) }

p1 <- ggplot(long_data, aes(x=Sample,y=Depth)) + geom_point(aes(color=Core)) +
labs(x ='Sample N.', y ='Depth (mm)', title = 'Core Correlation of Lake Nganoke') +
ylim(1,800)

p1 + stat_smooth(method = "lm", formula = y~poly(x,5, raw = TRUE), size = 1) +
annotate("text", x = 0, y = 800, label = lm_eqn(df), hjust=0, family="Times", parse = TRUE) + #Add polynomial regression
scale_y_continuous(trans = "reverse", breaks = c(0,100,200,300,400,500,600,700,800))
`````` • Not sure why you have been down voted as a first poster. You do seem to have done some homework and new to posting culture of SO. Unfortunately, while new myself to GGPLOT, can not offer you a solution. Hope someone can. If you find a solution do post the answer to your question. – Cam_Aust Sep 5 at 6:27
• Try setting `raw` to TRUE. `lm(y ~ poly(x, 5, raw = TRUE), data = df)` – Tony Ladson Sep 5 at 10:18

Your problem is that the `lm_eqn` is tailored to show the equation of a linear regression, i.e. the polynomial of the first degree. I've modified it to show the equation of a polynomial of the Nth degree. Since you haven't posted your data (sth you should do in the future and prob why your question was initially down voted), I've used the `cars` data set from `datasets`.

``````library(datasets)
library(ggplot2)

lm_eqn <- function(df, degree, raw=TRUE){
m <- lm(y ~ poly(x, degree, raw=raw), df)  # get the fit
cf <- round(coef(m), 2)  # round the coefficients
r2 <- round(summary(m)\$r.squared, 4)  # round the r.squared
powers <- paste0("^", seq(length(cf)-1))  # create the powers for the equation
powers <- ""  # remove the first one as it's redundant (x^1 = x)
# first check the sign of the coefficient and assign +/- and paste it with
# the appropriate *italic(x)^power. collapse the list into a string
pcf <- paste0(ifelse(sign(cf[-1])==1, " + ", " - "), abs(cf[-1]),
paste0("*italic(x)", powers), collapse = "")
# paste the rest of the equation together
eq <- paste0("italic(y) == ", cf, pcf, "*','", "~italic(r)^2==", r2)
eq
}

df <- data.frame("x" = cars\$speed, "y" = cars\$dist)
ggplot(cars, aes(x = speed, y = dist)) +
geom_point() +
stat_smooth(method = "lm", formula = y ~ poly(x, 5, raw = TRUE), size = 1) +
annotate("text", x = 0, y = 100, label = lm_eqn(df, 5, raw = TRUE),
hjust = 0, family = "Times", parse = TRUE)
`````` Here is an alternative answer. I observed that the endpoints of the polynomial in your plot exhibit curvature that does not apper to follow the shape of the data (Runge's phenomenon) so I extracted the data from your scatterplot and made an equation search. The best candidate I can find appears to be "y = C/(1.0 + exp((x-A)/B)) + D * exp((x-B)/E)" as shown below with the Y axis plotted in the normal fashion. For the parameters

``````A =  4.1190742945259711E+00
B = -6.4849391432073888E-01
C =  3.5527347656282654E+02
D =  1.7759549500121045E+02
E =  2.1295437650578787E+01
``````

I obtain R-squared = 0.9604 and RMSE = 36.37 and note the plotted extremes of the equation do not exhibit the curvature shown for the polynomial. If this might be useful, you would need to re-fit using the actual study data with these parameter values as the initial parameter estimates for the non-linear solver. • You are right, the data was a mock dataset I had created roughly. I should have stated that I did not expect it to follow a polynomial trend from the start. – Jake Parrish Sep 12 at 23:48
• No problem. Any time I get to use the phrase "Runge's phenomenon" it is worth it. – James Phillips Sep 13 at 1:14

Thank you Arienhood for the help! It turned out that my data in this sequence didn't follow a polynomial trend however further use of this code will. (Will definitely post my dataset in the future)

``````library(ggplot2)

lm_eqn <- function(df, degree, raw=TRUE){
m <- lm(y ~ poly(x, degree, raw=raw), df)
cf <- round(coef(m), 2)
r2 <- round(summary(m)\$r.squared, 4)
powers <- paste0("^", seq(length(cf)-1))
powers <- ""

pcf <- paste0(ifelse(sign(cf[-1])==1, " + ", " - "), abs(cf[-1]),
paste0("*italic(x)", powers), collapse = "")

eq <- paste0("italic(y) == ", cf, pcf, "*','", "~italic(r)^2==", r2)
eq
}

df <- data.frame("x"=Correlations\$LC3U, "y"=Correlations\$LC1U)

p2 <- ggplot(df, aes(x = x, y = y)) +
geom_point() +
labs(x ='LC3U', y ='LC1U', title = 'Core Correlation of Lake Nganoke') +
stat_smooth(method = "lm", formula = y ~ poly(x, 1, raw = TRUE), size = 1) +
annotate("text", x = 10, y = 10, label = lm_eqn(df, 1, raw = TRUE),
hjust = 0, family = "Times", parse = TRUE) +
scale_y_continuous(breaks = c(0,10,20,30,40,50,60,70,80)) +
scale_x_continuous(breaks = c(0,10,20,30,40,50,60,70,80))

p2
`````` 