Sign up ×
Stack Overflow is a community of 4.7 million programmers, just like you, helping each other. Join them, it only takes a minute:

Anyone have a good reference for how to do a multivariate ordinary linear regression without saving the input data (and get the R-squared of the result). The use case is a data set with too many rows to store. The regression can be obtained by accumulating x[i]*x[j] and y * x[i], and then doing the matrix math from there, but I can't find a similar formula to get the statistics when I'm done (R-squared for starters). Thanks.

share|improve this question

1 Answer 1

up vote 1 down vote accepted

I don't have a good reference, but the way I'd approach it is to expand out the sum-of-squared expressions, and write them in terms of the expectations that you are accumulating.

  • I use <.> to indicate averaging over rows of data, so that <y> is the average of the y-values, and so on

  • at any point we can obtain the regression coefficients a[i] and b from the matrix <x[i]*x[j]> and the vector <y*x[i]> as you indicated in your question

  • below I'll use sum_i{ a[i]*x[i] } to indicate a sum over the components that comprise the independent variables.
  • Let N be the number of data rows used

A way to compute the explained mean-squared deviation is:

SS_reg/N = < (f -<y> )^2 >    

         = < ( sum_i {a[i]*x[i] } + b - <y> )^2 > 
         = < sum_i { a[i]^2*x[i]^2}  +b^2 +<y>^2 +sum_i{ 2*b*a[i]*x[i]}-2*<y>* sum_i{a[i]*x[i]}-2*b*<y> >
         = sum_i { a[i]^2*<x[i]*x[i]> } +
           b^2 +
           <y>^2 + 
           2*b*sum_i{a[i]*<x[i]>} -
           2*<y>*sum_i{ a[i]*<x[i]>} -

You already maintain <x[i]*x[i]> as the diagonal elements of the matrix for deriving the regression coefficients. You will also need to maintain the averages of the independent variables (<x[i]> for each i) as well as for the dependent variable (<y>)

Similar expansions can carried out for either the total or residual mean squared errors, and then used to compute the R^2 value.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.