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I am trying to do fixed effects with R. My data looks like this dte, yr, id, v1, v2 and has daily date values. I would like to include dummy variables for id and for yr where dte is the date. If i try to use plm and specify the index as index=c("id, "yr") and do a within model with any sort of effects I get the error that (yr, id) is not unique, which is true since my data is daily.

I then decided to simply do this by making yr a factor and using lm:

lm(v1 ~ factor(yr) + v2 - 1, data=df)

However, this seems to run out of memory. I have 20 levels in my factor and df is 14 mil rows which takes about 2 gigs to store, I am running this on a machine with 22 gigs dedicated to this process. I then decided to try things the old fashioned way: create dummy variables for each of my years t1 to t20 by doing:

df$t1 <- 1*(df$yr==1)
df$t2 <- 1*(df$yr==2)
df$t3 <- 1*(df$yr==3)


and simply compute:

solve(t(x) %*% x) %*% t(x) %*% y

This runs without a problem and produces the answer almost right away. What is it in the lm function that is making this regression impossible to run and requires so much memory?

EDIT: I am specifically curious what is it about lm that makes it run out of memory when I can compute the coefficients just fine?


share|improve this question
why don't you try lm.fit instead of lm to narrow down the problem? lm.fit just does more-or-less "raw" linear model fitting via the QR decomposition -- none of the extraneous stuff about model matrix creation, etc.. If you also get memory problems with lm.fit, then @Jake's answer would seem to be the issue (QR vs normal equations). – Ben Bolker Apr 26 '12 at 15:54
up vote 7 down vote accepted

lm does much more than just find the coefficients for your input features. For example, it provides diagnostic statistics that tell you more about the coefficients on your independent variables including the standard error and t value of each of your independent variables.

I think that understanding these diagnostic statistics is important when running regressions to understand how valid your regression is.

These additional calculations cause lm to be slower than simply doing solving the matrix equations for the regression.

For example, using the mtcars dataset:

>lm_cars <- lm(mpg~., data=mtcars)

lm(formula = mpg ~ ., data = mtcars)                          

    Min      1Q  Median      3Q     Max                       
-3.4506 -1.6044 -0.1196  1.2193  4.6271                       

            Estimate Std. Error t value Pr(>|t|)              
(Intercept) 12.30337   18.71788   0.657   0.5181              
cyl         -0.11144    1.04502  -0.107   0.9161              
disp         0.01334    0.01786   0.747   0.4635              
hp          -0.02148    0.02177  -0.987   0.3350              
drat         0.78711    1.63537   0.481   0.6353              
wt          -3.71530    1.89441  -1.961   0.0633 .            
qsec         0.82104    0.73084   1.123   0.2739              
vs           0.31776    2.10451   0.151   0.8814              
am           2.52023    2.05665   1.225   0.2340              
gear         0.65541    1.49326   0.439   0.6652              
carb        -0.19942    0.82875  -0.241   0.8122              
Signif. codes:  0 ‘***’ 0.001 ‘**’ 0.01 ‘*’ 0.05 ‘.’ 0.1 ‘ ’ 1

Residual standard error: 2.65 on 21 degrees of freedom        
Multiple R-squared: 0.869,      Adjusted R-squared: 0.8066    
F-statistic: 13.93 on 10 and 21 DF,  p-value: 3.793e-07       
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yes, that's the true. but none of those other activities would cause lm to run out of memory – Alex Apr 26 '12 at 15:43

In addition to what idris said, it's also worth pointing out that lm() does not solve for the parameters using the normal equations like you illustrated in your question, but rather uses QR decomposition, which is less efficient but tends to produce more numerically accurate solutions.

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You might want to consider using the biglm package. It fits lm models by using smaller chunks of data.

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To elaborate on Jake's point. Let's say your regression is trying to solve: y = Ax ( A is the design matrix ). With m observations and n independent variables A is a mxn matrix. Then cost of QR is ~ m*n^2. In your case it looks like m = 14x10^6 and n = 20 . So m*n^2 = 14*10^6*400 is a significant cost.

However with the normal equations you are trying to invert A'A (' indicates transpose ), which is square and of size nxn. The solve is usually done using LU which costs n^3 = 8000. This is much smaller than the computational cost of QR. Of course this doesn't include the cost of the matrix multiply.

Further if the QR routine tries to store the Q matrix which is of size mxm=14^2*10^12 (!), then your memory will be insufficient. It is possible to write QR to not have this problem. It would be interesting to know what version of QR, is actually being used. And why exactly the lm call runs out of memory.

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