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I am using glm but for some reasons couldnot understant how the p-values are calculated. What is the meaning of Pr(>|z|) here?

I read somewhere that the p-values are calculated as 2*pnorm(z). Considering this formula, my calculations does not result in what the glm is producing.

Call:  glm(formula = fmla, family = binomial(), data = tmpData, na.action = na.exclude)

                 Estimate Std. Error z value Pr(>|z|)    
(Intercept)     -1.122521   0.286475  -3.918 8.91e-05 ***
var1             0.031535   0.001295  24.358  < 2e-16 ***
var2             0.247231   0.013977  17.688  < 2e-16 ***
var3            -0.952158   0.038288 -24.868  < 2e-16 ***

> 2*pnorm(c(-3.918, 24.35,17.68, -24.86))
[1]  8.928671e-05  2.000000e+00  2.000000e+00 2.015988e-136

Why the p-values do not correspong to the glm output

Edit: The summary gives me more detailed result

> summary(modelTmp)$coeff
                   Estimate  Std. Error    z value      Pr(>|z|)
(Intercept)     -1.12252141 0.286475349  -3.918387  8.914334e-05
var1              0.03153534 0.001294648  24.358236 4.742122e-131
var2             0.24723122 0.013977256  17.688109  5.178450e-70
var3            -0.95215794 0.038288424 -24.868037 1.650303e-136

> 2*pnorm(c(-3.918387,-24.868037))
[1]  8.914350e-05 1.650297e-136
> 2*pnorm(c(24.3582,17.688))
[1] 2 2
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Look at the source of printCoefmat. –  Joshua Ulrich Aug 5 '13 at 15:20
Pr(>|z|) here means Pr(computed z (or z value)>absolute value of tabulated z) –  Metrics Aug 5 '13 at 15:21
For negative z-values, the p-values are ok, but for the positive ones, I am getting 2 which in no way even closer to 2e-16 –  learner Aug 5 '13 at 15:34

2 Answers 2

It's calculated as 2 * (1-pnorm(abs(-3.918))), which is twice (two-sided test) the depicted area under the normal distribution. (Actually, it's 2 * pnorm(-abs(-3.918)) in summary.glm, which is theoretically the same but numerically more precise.)

enter image description here

The statistics differ if !family %in% c("poisson","binomial") | !is.null(dispersion).

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The family is binomial, for intercept and var3, the 2*pnorm(z) calculation is exact. the problem is with the var1 and var2 calculation. –  learner Aug 5 '13 at 15:51
@learner - The full z value isn't printed so if you just used the printed z value to get your p-value it will be slightly different than the reported one. You're basically just being REALLY picky if you're calling 1.650303e-136 different from 1.650297e-136 –  Dason Aug 5 '13 at 15:58
@Dason thanks, Actually I am concerned about the p-values of var1 and var2. I just wanted to say that using 2*pnorm(c(-3.918387,-24.868037)) match the glm result while 2*pnorm(c(24.3582,17.688)) giving me a value of 2 which is in now way close to what i get from glm –  learner Aug 5 '13 at 16:21
@learner Oh well Roland already explained that. And p-value calculations literally are probability calculations so you should realize that something is wrong with those p-values since they aren't between 0 and 1. –  Dason Aug 5 '13 at 16:26
@Roland, Can you please explain your last statement in simple terms. "the statistics differs..." –  learner Aug 5 '13 at 16:57

First, as @Roland pointed out, it's not 2 * pnorm(z). It's 2 * (1 - pnorm(abs(z)). This gives the area under both the upper and lower tails of the normal distribution that is a distance of z or more from the origin. That's the textbook definition for a two-tailed P-value. The two expressions happen to be equal for z negative, but not so for z positive (as you discovered).

Second, your Z-statistics for var1 and var2 are large enough that they require special treatment. By default, pnorm calculates the area under the lower tail; that is, the probability Pr(Z < z). If z is sufficiently large, this probability becomes numerically indistinguishable from 1; hence, taking 1 - Pr(Z < z) will return 0. For situations like this, set the lower.tail argument to FALSE; this makes pnorm return the area under the upper tail, ie Pr(Z > z).

> 2*pnorm(24.3582, lower.tail=FALSE)
[1] 4.746252e-131

> 2*(1 - pnorm(24.3582))
[1] 0
share|improve this answer
Or 2 * pnorm(-24.3582) as implemented in summary.glm. However, if you need to distinguish 4.7e-131 from 0, I would first ask why you need that. –  Roland Aug 6 '13 at 5:51

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