# simulate data from regression line in python

If I have a regression line and an r squared is there a simple numpy (or some other python library) command to randomly draw, say, y values for an x that are consistent with the regression? The same way you could just draw a random value from a distribution?

Thanks!

edit: I have the equation for my regression line and an r^2 value. That r^2 value should provide some information about the distribution of data points around my line, no? If I just call this y=random.gauss()*x+b haven't I lost the information in my r^2? Or would this be incorporated into the stdv, if so how? Sorry, I just haven't worked with regression much before.

-

## migrated from stats.stackexchange.comFeb 24 '12 at 9:54

This question came from our site for people interested in statistics, machine learning, data analysis, data mining, and data visualization.

That's what a gaussian random number generator is for. Are you unclear on gaussian random number generators? Or unclear on the y=mx+b to apply the regression slope and offset to a random value? Or are you looking for a function that combines `y=random.gauss()*x+b` into some kind of generator expression? Can you be more specific about what's confusing you? –  S.Lott Feb 24 '12 at 11:19

If I just call this y=random.gauss()*x+b haven't I lost the information in my r^2?

Clearly.

However.

Reading the documentation, we see that random.gauss takes two arguments. A mean and a standard deviation.

The mean must be zero.

The standard deviation, however, needs to be adjusted to match your r**2.

When r**2 == 0, the standard deviation is high. It should produce any value in the original range of the sample data.

As r**2 approaches 1, the standard deviation gets smaller.

How to compute the standard deviation value that reproduces your r**2?

Brute Force.

``````m, b = regression_model( some_data )
deviations = list( y - m*x+b for x, y in some_data )
``````

This list of deviations is the essential ingredient in the standard deviation formula.

``````sd = math.sqrt( sum( d**2 for d in deviations ) / (len(some_data)-1) )
``````

Now you can use `random.gauss(0,sd)` to reproduce the deviations in your original data.

See @PaulHiemstra's answer for a proper theoretical approach.

-
if you use numpy array there is no need for the list comprehension. If deviations is a numpy array, `sum( deviations^2)` should give the sums of squares. –  Paul Hiemstra Feb 24 '12 at 19:00

Luckily there is no need for brute force :). To get a relationship between the `R^2` and the standard deviation of the residuals it is easiest to start at the definition of the `R^2`:

``````R^2 = SSR / SST    (1)
``````

where `SSR` is the sums of squares of the regression, i.e. `(sum((y'-mean(y))^2)` where `y'` are the values on the regression line, and SST is the total sums of squares, i.e. `sum((y - mean(y))^2)` where `y` are the observations. So effectively the `R^2` is the fraction of between the total amount of variance and the amount of variance explained by the regression model (or line). For our purpose we need to re express `SSR` as `SST - SSE`, where `SSE` are the sums of squares between the regression line and the observations. `SSE` is variance which is not explained by the regression model. Rewriting (1):

``````R^2 = (SST - SSE) / SST = 1 - SSE / SST
``````

expressing for `SSE`:

``````SSE = (1 - R^2) SST
``````

If we note that to go for sums of squares to variance we need to divide by `N-1` this becomes:

``````VAR_E = (1 - R^2) VAR_T
``````

to get the standard deviation of the residuals:

``````SD_E = sqrt((1 - R^2) VAR_T)
``````

and taking the VAR out of the parentheses:

``````SD_E = sqrt(1 - R^2) SD_T
``````

So you need the `R^2` and the total standard deviation of the dataset. To verify this, check any introductory statistics book.

-
+1 Since the total variance is sum( d2 for d in deviations ) (from my answer) there seems the a little brute force in this. But the correct analysis of R2 is very, very helpful. –  S.Lott Feb 24 '12 at 18:12
The sum implies for all residuals, but in pythonanian that is what you say. I'm just to much used to vectorization in R, which should also work on numpy vectors I think... –  Paul Hiemstra Feb 24 '12 at 18:24
Great answer, but the OP only wrote he has a regression line and an r squared, so I presume SD_T is unknown. –  Janne Karila Feb 24 '12 at 20:46
Hmm, good point, maybe the OP should present some more background. If he only has the line and the r squared he has a hard time simulating the exact residuals... –  Paul Hiemstra Feb 24 '12 at 21:48
If the set of `x`'s is known or chosen, one could compute `SSR` and substitute `SSR+SSE` for `SST` in the equations. Unless I made a mistake, the solution is `SD_E = sqrt(1/R^2 - 1) SD_R` –  Janne Karila Feb 25 '12 at 10:56