I have a dataframe with observed and modelled data, and I would like to calculate the R2 value. I expected there to be a function I could call for this, but can't locate one. I know I can write my own and apply it, but am I missing something obvious? I want something like

obs <- 1:5
mod <- c(0.8,2.4,2,3,4.8)
df <- data.frame(obs, mod)

R2 <- rsq(df)
# 0.85
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    And the inevitable - "what about Adjusted R^2?" question is addressed here - stats.stackexchange.com/questions/48703/… – thelatemail Dec 1 '16 at 2:22
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    You may need to specify how this "modelled data" was created. The r.squared is reported by summary functions associated with regression functions. But only when such an estiamte is statsitically justified. – IRTFM Dec 1 '16 at 2:22
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    I have several different models, but it's not simply the output of a regression model such as lm, so the summary functions don't work. Basically I need to be able to compare between two vectors (Zheyuan Li's suggestion works perfectly for this) – Esme_ Dec 1 '16 at 3:06

You need a little statistical knowledge to see this. R squared between two vectors is just the square of their correlation. So you can define you function as:

rsq <- function (x, y) cor(x, y) ^ 2

Sandipan's answer will return you exactly the same result (see the following proof), but as it stands it appears more readable (due to the evident $r.squared).

Let's do the statistics

Basically we fit a linear regression of y over x, and compute the ratio of regression sum of squares to total sum of squares.

lemma 1: a regression y ~ x is equivalent to y - mean(y) ~ x - mean(x)

lemma 1

lemma 2: beta = cov(x, y) / var(x)

lemma 2

lemma 3: R.square = cor(x, y) ^ 2

lemma 3


R squared between two arbitrary vectors x and y (of the same length) is just a goodness measure of their linear relationship. Think twice!! R squared between x + a and y + b are identical for any constant shift a and b. So it is a weak or even useless measure on "goodness of prediction". Use MSE or RMSE instead:

I agree with 42-'s comment:

The R squared is reported by summary functions associated with regression functions. But only when such an estimate is statistically justified.

R squared can be a (but not the best) measure of "goodness of fit". But there is no justification that it can measure the goodness of out-of-sample prediction. If you split your data into training and testing parts and fit a regression model on the training one, you can get a valid R squared value on training part, but you can't legitimately compute an R squared on the test part. Some people did this, but I don't agree with it.

Here is very extreme example:

preds <- 1:4/4
actual <- 1:4

The R squared between those two vectors is 1. Yes of course, one is just a linear rescaling of the other so they have a perfect linear relationship. But, do you really think that the preds is a good prediction on actual??

In reply to wordsforthewise

Thanks for your comments 1, 2 and your answer of details.

You probably misunderstood the procedure. Given two vectors x and y, we first fit a regression line y ~ x then compute regression sum of squares and total sum of squares. It looks like you skip this regression step and go straight to the sum of square computation. That is false, since the partition of sum of squares does not hold and you can't compute R squared in a consistent way.

As you demonstrated, this is just one way for computing R squared:

preds <- c(1, 2, 3)
actual <- c(2, 2, 4)
rss <- sum((preds - actual) ^ 2)  ## residual sum of squares
tss <- sum((actual - mean(actual)) ^ 2)  ## total sum of squares
rsq <- 1 - rss/tss
#[1] 0.25

But there is another:

regss <- sum((preds - mean(preds)) ^ 2) ## regression sum of squares
regss / tss
#[1] 0.75

Also, your formula can give a negative value (the proper value should be 1 as mentioned above in the Warning section).

preds <- 1:4 / 4
actual <- 1:4
rss <- sum((preds - actual) ^ 2)  ## residual sum of squares
tss <- sum((actual - mean(actual)) ^ 2)  ## total sum of squares
rsq <- 1 - rss/tss
#[1] -2.375

Final remark

I had never expected that this answer could eventually be so long when I posted my initial answer 2 years ago. However, given the high views of this thread, I feel obliged to add more statistical details and discussions. I don't want to mislead people that just because they can compute an R squared so easily, they can use R squared everywhere.

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    There are some assumptions that must be met for that to be true: win-vector.com/blog/2011/11/correlation-and-r-squared I want to use it for KNN but I'm not sure the assumptions hold. Will have to check if this is actually the same as conventionally-calculated R^2 – wordsforthewise Jan 18 '18 at 6:10
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    The answer from the correlation ^2 approach and the conventional 1 - SSE/SST is not the same. In the example I am using, I got 0.756388 from the corr^2 and 0.7531449 from the normal r^2 equation. Small difference but still, maybe it would model for hyperparameter selection, etc. – wordsforthewise Jan 19 '18 at 0:52
  • maybe it would matter, not model – wordsforthewise Sep 3 '18 at 23:55
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    In multiple linear regression, R-squared is the squared correlation between response vector and fitted values. Try model <- lm(trees); cor(trees[[1]], model$fitted.values) ^ 2. Compare this with summary(model)$r.squared – 李哲源 Nov 22 '18 at 17:05
  • Thanks for the reply in your answer, but I'm still confused why we can't go straight to the RSS calculation. I will have to meditate on the partition SS for a while. I also don't see any reason R2 can't be negative -- doesn't that effectively mean our predictions are worse than using the average value of the targets for predcitions? – wordsforthewise Mar 13 '19 at 16:40

Why not this:

rsq <- function(x, y) summary(lm(y~x))$r.squared
rsq(obs, mod)
#[1] 0.8560185
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You can also use the summary for linear models:

summary(lm(obs ~ mod, data=df))$r.squared 
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It is not something obvious, but the caret package has a function postResample() that will calculate "A vector of performance estimates" according to the documentation. The "performance estimates" are

  • RMSE
  • Rsquared
  • mean absolute error (MAE)

and have to be accessed from the vector like this

vect1 <- c(1, 2, 3)
vect2 <- c(3, 2, 2)
res <- caret::postResample(vect1, vect2)
rsq <- res[2]

However, this is using the correlation squared approximation for r-squared as mentioned in another answer. I'm not sure why Max Kuhn didn't just use the conventional 1-SSE/SST.

caret also has an R2() method, although it's hard to find in the documentation.

The way to implement the normal coefficient of determination equation is:

preds <- c(1, 2, 3)
actual <- c(2, 2, 4)
rss <- sum((preds - actual) ^ 2)
tss <- sum((actual - mean(actual)) ^ 2)
rsq <- 1 - rss/tss

Not too bad to code by hand of course, but why isn't there a function for it in a language primarily made for statistics? I'm thinking I must be missing the implementation of R^2 somewhere, or no one cares enough about it to implement it. Most of the implementations, like this one, seem to be for generalized linear models.

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  • This should be higher up. Also: r2_general <-function(preds,actual){ return(1- sum((preds - actual) ^ 2)/sum((actual - mean(actual))^2))} – JoeTheShmoe Sep 2 at 23:56

Here is the simplest solution based on [https://en.wikipedia.org/wiki/Coefficient_of_determination]

# 1. 'Actual' and 'Predicted' data
df <- data.frame(
  y_actual = c(1:5),
  y_predicted  = c(0.8, 2.4, 2, 3, 4.8))

# 2. R2 Score components

# 2.1. Average of actual data
avr_y_actual <- mean(df$y_actual)

# 2.2. Total sum of squares
ss_total <- sum((df$y_actual - avr_y_actual)^2)

# 2.3. Regression sum of squares
ss_regression <- sum((df$y_predicted - avr_y_actual)^2)

# 2.4. Residual sum of squares
ss_residuals <- sum((df$y_actual - df$y_predicted)^2)

# 3. R2 Score
r2 <- 1 - ss_residuals / ss_total
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Not sure why this isn't implemented directly in R, but this answer is essentially the same as Andrii's and Wordsforthewise, I just turned into a function for the sake of convenience if somebody uses it a lot like me.

r2_general <-function(preds,actual){ 
  return(1- sum((preds - actual) ^ 2)/sum((actual - mean(actual))^2))
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