# What is the difference between Multiple R-squared and Adjusted R-squared in a single-variate least squares regression?

Could someone explain to the statistically naive what the difference between `Multiple R-squared` and `Adjusted R-squared` is? I am doing a single-variate regression analysis as follows:

`````` v.lm <- lm(epm ~ n_days, data=v)
print(summary(v.lm))
``````

Results:

``````Call:
lm(formula = epm ~ n_days, data = v)

Residuals:
Min      1Q  Median      3Q     Max
-693.59 -325.79   53.34  302.46  964.95

Coefficients:
Estimate Std. Error t value Pr(>|t|)
(Intercept)  2550.39      92.15  27.677   <2e-16 ***
n_days        -13.12       5.39  -2.433   0.0216 *
---
Signif. codes:  0 ‘***’ 0.001 ‘**’ 0.01 ‘*’ 0.05 ‘.’ 0.1 ‘ ’ 1

Residual standard error: 410.1 on 28 degrees of freedom
Multiple R-squared: 0.1746,     Adjusted R-squared: 0.1451
F-statistic: 5.921 on 1 and 28 DF,  p-value: 0.0216
``````
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StatsOverflow is an excellent idea. I hope someone has suggested it as a new StackExchange site. –  neilfws May 20 '10 at 4:53
Go and vote for it at: meta.stackexchange.com/questions/5547/… –  fmark May 20 '10 at 7:27
You mean crossvalidated.com (aka stats.stackexchange.com)? –  Brandon Bertelsen Nov 2 '12 at 8:56
@BrandonBertelsen I didn't then, because it didn't exist yet! –  fmark Nov 3 '12 at 20:20
–  Jeromy Anglim Jul 2 '13 at 6:50

The "adjustment" in adjusted R-squared is related to the number of variables and the number of observations.

If you keep adding variables (predictors) to your model, R-squared will improve - that is, the predictors will appear to explain the variance - but some of that improvement may be due to chance alone. So adjusted R-squared tries to correct for this, by taking into account the ratio (N-1)/(N-k-1) where N = number of observations and k = number of variables (predictors).

It's probably not a concern in your case, since you have a single variate.

Some references:

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The Adjusted R-squared is close to, but different from, the value of R2. Instead of being based on the explained sum of squares SSR and the total sum of squares SSY, it is based on the overall variance (a quantity we do not typically calculate), s2T = SSY/(n - 1) and the error variance MSE (from the ANOVA table) and is worked out like this: adjusted R-squared = (s2T - MSE) / s2T.

This approach provides a better basis for judging the improvement in a fit due to adding an explanatory variable, but it does not have the simple summarizing interpretation that R2 has.

If I haven't made a mistake, you should verify the values of adjusted R-squared and R-squared as follows:

``````s2T <- sum(anova(v.lm)[[2]]) / sum(anova(v.lm)[[1]])
MSE <- anova(v.lm)[[3]][2]
adj.R2 <- (s2T - MSE) / s2T
``````

On the other side, R2 is: SSR/SSY, where SSR = SSY - SSE

``````attach(v)
SSE <- deviance(v.lm) # or SSE <- sum((epm - predict(v.lm,list(n_days)))^2)
SSY <- deviance(lm(epm ~ 1)) # or SSY <- sum((epm-mean(epm))^2)
SSR <- (SSY - SSE) # or SSR <- sum((predict(v.lm,list(n_days)) - mean(epm))^2)
R2 <- SSR / SSY
``````
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The R-squared is not dependent on the number of variables in the model. The adjusted R-squared is.

The adjusted R-squared adds a penalty for adding variables to the model that are uncorrelated with the variable your trying to explain. You can use it to test if a variable is relevant to the thing your trying to explain.

Adjusted R-squared is R-squared with some divisions added to make it dependent on the number of variables in the model.

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Note: Adding a predictor to a regression will almost always increase r-squared, even if only by a little bit due to random sampling. –  Jeromy Anglim May 20 '10 at 13:36
ty Jeromy, I meant to say "go down" instead of go up. The R-squared will never fall as a result of adding a new variable to the model. The adjusted R-squared can go up or down if a new variable is added. It was a bad example, so I removed it. –  Jay May 20 '10 at 17:20

Note that, in addition to number of predictive variables, the formula also adjusts for sample size. A small sample will give a deceptively large R-squared.

Ping Yin & Xitao Fan, J. of Experimental Education 69(2): 203-224, "Estimating R-squared shrinkage in multiple regression", compares different methods for adjusting r-squared and concludes that the commonly-used ones quoted above are not good. They recommend the Olkin & Pratt formula.

However, I've seen some indication that population size has a much larger effect than any of these formulas indicate. I am not convinced that any of these formulas are good enough to allow you to compare regressions done with very different sample sizes (e.g., 2,000 vs. 200,000 samples; the standard formulas would make almost no sample-size-based adjustment). I would do some cross-validation to check the r-squared on each sample.

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