Coefficient of determination (R-squared) indicates the proportionate
amount of variation in the response variable *y* explained
by the independent variables *X* in the linear regression
model. The larger the R-squared is, the more variability is explained
by the linear regression model.

R-squared is the proportion of the total sum of squares explained
by the model. `Rsquared`

, a property of the fitted
model, is a structure with two fields:

`Ordinary`

— Ordinary (unadjusted) R-squared$${R}^{2}=\frac{SSR}{SST}=1-\frac{SSE}{SST}.$$

`Adjusted`

— R-squared adjusted for the number of coefficients$${R}_{adj}^{2}=1-\left(\frac{n-1}{n-p}\right)\frac{SSE}{SST}.$$

*SSE*is the sum of squared error,*SSR*is the sum of squared regression,*SST*is the sum of squared total,*n*is the number of observations, and*p*is the number of regression coefficients. Note that*p*includes the intercept, so for example,*p*is 2 for a linear fit. Because R-squared increases with added predictor variables in the regression model, the adjusted R-squared adjusts for the number of predictor variables in the model. This makes it more useful for comparing models with a different number of predictors.

After obtaining a fitted model, say, `mdl`

,
using `fitlm`

or `stepwiselm`

, you
can obtain either R-squared value as a scalar by indexing into the
property using dot notation, for example,

mdl.Rsquared.Ordinary mdl.Rsquared.Adjusted

You can also obtain the SSE, SSR, and SST using the properties with the same name.

mdl.SSE mdl.SSR mdl.SST

This example shows how to display R-squared (coefficient of determination) and adjusted R-squared. Load the sample data and define the response and independent variables.

```
load hospital
y = hospital.BloodPressure(:,1);
X = double(hospital(:,2:5));
```

Fit a linear regression model.

mdl = fitlm(X,y)

mdl = Linear regression model: y ~ 1 + x1 + x2 + x3 + x4 Estimated Coefficients: Estimate SE tStat pValue _________ ________ ________ __________ (Intercept) 117.4 5.2451 22.383 1.1667e-39 x1 0.88162 2.9473 0.29913 0.76549 x2 0.08602 0.06731 1.278 0.20438 x3 -0.016685 0.055714 -0.29947 0.76524 x4 9.884 1.0406 9.498 1.9546e-15 Number of observations: 100, Error degrees of freedom: 95 Root Mean Squared Error: 4.81 R-squared: 0.508, Adjusted R-Squared: 0.487 F-statistic vs. constant model: 24.5, p-value = 5.99e-14

The R-squared and adjusted R-squared values are 0.508 and 0.487, respectively. Model explains about 50% of the variability in the response variable.

Access the R-squared and adjusted R-squared values using the property of the fitted `LinearModel`

object.

mdl.Rsquared.Ordinary

ans = 0.5078

mdl.Rsquared.Adjusted

ans = 0.4871

The adjusted R-squared value is smaller than the ordinary R-squared value.

`LinearModel`

| `anova`

| `fitlm`

| `stepwiselm`