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I am converting a SAS PROC GENMOD example into R, using glm in R. The SAS code was:

proc genmod data=data0 namelen=30;
model boxcoxy=boxcoxxy ~ AGEGRP4 + AGEGRP5 + AGEGRP6 + AGEGRP7 + AGEGRP8 + RACE1 + RACE3 + WEEKEND + 

My R code is:

parmsg2 <- glm(boxcoxxy ~ AGEGRP4 + AGEGRP5 + AGEGRP6 + AGEGRP7 + AGEGRP8 + RACE1 + RACE3 + WEEKEND + 
SEQ , data=data0, family=gaussian, weights = REPLICATE_VAR)

When I use summary(parmsg2) I get the same coefficient estimates as in SAS, but my standard errors are wildly different.

The summary output from SAS is:

Name         df   Estimate      StdErr    LowerWaldCL  UpperWaldCL      ChiSq   ProbChiSq
Intercept    1   6.5007436    .00078884      6.4991975    6.5022897    67911982 0
agegrp4      1   .64607262    .00105425      .64400633    .64813891   375556.79 0
agegrp5      1    .4191395    .00089722      .41738099    .42089802   218233.76 0
agegrp6      1  -.22518765    .00083118     -.22681672   -.22355857   73401.113 0
agegrp7      1  -1.7445189    .00087569     -1.7462352   -1.7428026   3968762.2 0
agegrp8      1  -2.2908855    .00109766     -2.2930369   -2.2887342   4355849.4 0
race1        1  -.13454883    .00080672     -.13612997   -.13296769    27817.29 0
race3        1  -.20607036    .00070966     -.20746127   -.20467944   84319.131 0
weekend      1    .0327884    .00044731       .0319117    .03366511   5373.1931 0
seq2          1 -.47509583    .00047337     -.47602363   -.47416804   1007291.3 0
Scale         1 2.9328613     .00015586      2.9325559    2.9331668     -127

The summary output from R is:

            Estimate Std. Error t value Pr(>|t|)    
(Intercept)  6.50074    0.10354  62.785  < 2e-16 
AGEGRP4      0.64607    0.13838   4.669 3.07e-06 
AGEGRP5      0.41914    0.11776   3.559 0.000374 
AGEGRP6     -0.22519    0.10910  -2.064 0.039031  
AGEGRP7     -1.74452    0.11494 -15.178  < 2e-16
AGEGRP8     -2.29089    0.14407 -15.901  < 2e-16
RACE1       -0.13455    0.10589  -1.271 0.203865    
RACE3       -0.20607    0.09315  -2.212 0.026967 
WEEKEND      0.03279    0.05871   0.558 0.576535 
SEQ         -0.47510    0.06213  -7.646 2.25e-14

The importance of the difference in the standard errors is that the SAS coefficients are all statistically significant, but the RACE1 and WEEKEND coefficients in the R output are not. I have found a formula to calculate the Wald confidence intervals in R, but this is pointless given the difference in the standard errors, as I will not get the same results.

Apparently SAS uses a ridge-stabilized Newton-Raphson algorithm for its estimates, which are ML. The information I read about the glm function in R is that the results should be equivalent to ML. What can I do to change my estimation procedure in R so that I get the equivalent coefficents and standard error estimates that were produced in SAS?

To update, thanks to Spacedman's answer, I used weights because the data are from individuals in a dietary survey, and REPLICATE_VAR is a balanced repeated replication weight, that is an integer (and quite large, in the order of 1000s or 10000s). The website that describes the weight is here. I don't know why the FREQ rather than the WEIGHT command was used in SAS. I will now test by expanding the number of observations using REPLICATE_VAR and rerunning the analysis.

Thanks to Ben's answer below, the code I am using now is:

parmsg2 <- coef(summary(glm(boxcoxxy ~ AGEGRP4 + AGEGRP5 + AGEGRP6 + AGEGRP7 + AGEGRP8 + RACE1 + RACE3 
+ WEEKEND + SEQ , data=data0, family=gaussian, weights = REPLICATE_VAR)))
#clean up the standard errors
parmsg2[,"Std. Error"] <- parmsg2[,"Std. Error"]/sqrt(mean(data0$REPLICATE_VAR)) 
parmsg2[,"t value"] <- parmsg2[,"Estimate"]/parmsg2[,"Std. Error"] 
#note: using the t-distribution for p-values, correct the t-values
allsummary <- summary.glm(glm(boxcoxxy ~ AGEGRP4 + AGEGRP5 + AGEGRP6 + AGEGRP7 + AGEGRP8 + RACE1 +
RACE3 + WEEKEND + SEQ , data=data0, family=gaussian, weights = REPLICATE_VAR))
parmsg2[,"Pr(>|t|)"] <- 2*pt(-abs(parmsg2[,"t value"]),df=allsummary$df.resid)
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Your R standard errors are all about 131.25 times the SAS standard errors, if that's at all enlightening. For more enlightenment I'd simplify the problem to one variable and see what happens. –  Spacedman Nov 28 '11 at 0:01
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2 Answers

up vote 1 down vote accepted

edit: reading the SAS documentation for FREQ and your responses above and below, here's what I think you should try: use weights=REPLICATE_VAR in the glm statement to adjust the relative weighting of the groups (the equality of coefficients you found above suggests that this is the right way to go), then use N=sum(REPLICATE_VAR) in the adjustment suggested below (I also think you could be using lm instead of glm for this problem ... it won't make much difference but should be a tiny bit faster and more robust.) Something like:

s <- coef(summary(lm(y~x,data=data2, weights=REPLICATE_VAR)))
s[,"Std. Error"] <- s[,"Std. Error"]/sqrt(sum(data2$REPLICATE_VAR))
s[,"t value"] <- s[,"Estimate"]/s[,"Std. Error"]
s[,"Pr(>|t|)"] <- 2*pt(abs(s[,"t value"]),df=g$df.resid)
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We are now very close, SE estimates differing by a factor of 100 (R estimates now 100 times smaller). If they were the same level of magnitude, the differences would be at the 5th decimal place, which I wouldn't care about. –  Michelle Nov 29 '11 at 2:36
Exactly a factor of 100? Or just approximately? –  Ben Bolker Nov 29 '11 at 2:39
A bit of a stab in the dark, but what does dividing by sqrt(data2$REPLICATE_VAR) (rather than sqrt(sum(data2$REPLICATE_VAR)) do ... ? –  Ben Bolker Nov 29 '11 at 2:42
Weird. Any chance you can post your data somewhere, or we can work with a subset? Debugging by remote control is tiring ... If you're off by a factor of exactly 100 then I don't think that dividing by individual REPLICATE_VAR factor is going to be the way to go ... –  Ben Bolker Nov 29 '11 at 3:20
Hmmm. I'm glad it works, but I would love to see you replicate the SAS to R correspondence with a different data set, or with a subset of this data set, to make sure that it really works the way you think it does. –  Ben Bolker Nov 29 '11 at 21:13
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FREQ in SAS is not the same as weights in R's glm. In SAS, its the number of occurrences of that event. For R, its "that each response y_i is the mean of w_i unit-weight observations". These two things are not the same.

If you want R to give the same output as SAS (can't think why) then you probably need to repeat each row in your data frame 'weight' number of times.

Here, data is 10 rows with all weights=2, and data2 is 20 rows (2 copies of each row of data) with all weights=1:

> summary(glm(y~x,data=data2,weights=weights))$coef
              Estimate Std. Error   t value   Pr(>|t|)
(Intercept) 0.32859847 0.13413683 2.4497259 0.02475748
x           0.01540002 0.02161811 0.7123667 0.48537003
> summary(glm(y~x,data=data,weights=weights))$coef
              Estimate Std. Error   t value  Pr(>|t|)
(Intercept) 0.32859847 0.20120525 1.6331506 0.1410799
x           0.01540002 0.03242716 0.4749111 0.6475449

Handwaving a bit, N observations of the same value have less fuzziness than saying this observation is the mean of N observations, so the SE with the repeated observations will have a smaller SE than the mean one.

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I have tried to use expand.dft() from the vcdExtra package, having removed all objects barring the one being used in the glm but R is now crashing on me. I'm using 64-bit 3.14.0 in a Windows 7 Vmware link. The number of rows would be 177,050,435, taken from the sum of REPLICATE_VAR. Apparently this would be the number of males aged 9 years and up in the US population. –  Michelle Nov 29 '11 at 1:26
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