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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.

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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

2 Answers 2

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.

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+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

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.

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1  
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

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