# How can I classify post-hoc test results in R?

I am trying to understand how to work with ANOVAs and post-hoc tests in R. So far, I have used aov() and TukeyHSD() to analyse my data. Example:

``````uni2.anova <- aov(Sum_Uni ~ Micro, data= uni2)

uni2.anova

Call:
aov(formula = Sum_Uni ~ Micro, data = uni2)

Terms:
Micro  Residuals
Sum of Squares  0.04917262 0.00602925
Deg. of Freedom         15         48

Residual standard error: 0.01120756
Estimated effects may be unbalanced
``````

My problem is, now I have a huge list of pairwise comparisons but cannot do anything with it:

`````` TukeyHSD(uni2.anova)
Tukey multiple comparisons of means
95% family-wise confidence level

Fit: aov(formula = Sum_Uni ~ Micro, data = uni2)

\$Micro
Act_Glu2-Act_Ala2     -0.0180017863 -0.046632157  0.0106285840 0.6448524
Ana_Ala2-Act_Ala2     -0.0250134285 -0.053643799  0.0036169417 0.1493629
NegI_Ala2-Act_Ala2     0.0702274527  0.041597082  0.0988578230 0.0000000
``````

This dataset has 40 rows... Idealy, I would like to get a dataset that looks something like this:

• Act_Glu2 : a
• Act_Ala2 : a
• NegI_Ala2: b...

I hope you get the point. So far, I have found nothing comparable online... I also tried to select only significant pairs in the file resulting from TukeyHSD, but the file does not "acknowlegde" that it is made up of rows & columns, making selecting impossible...

Maybe there is something fundamentally wrong with my approach?

-
What does "Act_Glu2:a" mean? How is it different from "Act_Glu2-Act_Ala2" –  John Nov 2 '11 at 15:45
@John Ohh we might be off. The OP mentions "classify" in the title, but nowhere in the post. If she really wants to classify (cluster?) then she might be writing this to show she wants a list of the amino acids and the cluster they were assigned to (i.e. Act_Glu2 and Act_Ala2 are both in cluster "a"). I don't know though I could be totally wrong. At any rate, Carolin, can you clarify some on these points? –  John Colby Nov 2 '11 at 16:08
@ John Colby: Yes, I think you understand what I mean. Act_Glu2 and Act_Ala2 show no significant difference in the Tukey test, hence they would be classified (or clustered, if that is the correct term) into the same group. NegI_Ala is significantly different to at least one of them, so if I plot the data, I would show this significance by adding "a" to the first two and "b" to the third data point. But as there are so many datasets, I would rather not do this manually... –  Carolin Nov 2 '11 at 16:33

I think the OP wants the letters to get a view of the comparisons.

``````library(multcompView)
multcompLetters(extract_p(TukeyHSD(uni2.anova)))
``````

That will get you the letters.

You can also use the multcomp package

``````library(multcomp)
cld(glht(uni2.anova, linct = mcp(Micro = "Tukey")))
``````

I hope this is what you need.

-
With Carolin's clarification, I think this is the right track. –  John Colby Nov 2 '11 at 20:19
Perfect! This is exactly what I was looking for! Thank you very much. –  Carolin Nov 3 '11 at 10:13
With a little correction :) `hsd <- TukeyHSD(uni2.anova)` `multcompLetters(extract_p(hsd\$Micro))` Because TukeyHSD(uni2.anova) results in more than just the list of pairwise comparisions & in this case hsd\$Micro is just the list. –  Carolin Nov 3 '11 at 10:34

The results from the TukeyHSD are a list. Use `str` to look at the structure. In your case you'll see that it's a list of one item and that item is basically a matrix. So, to extract the first column you'll want to save the TukeyHSD result

``````hsd <- TukeyHSD(uni2.anova)
``````

If you look at `str(hsd)` you can that you can then get at bits...

``````hsd\$Micro[,1]
``````

That will give you the column of your differences. You should be able to extract what you want now.

-
Oh great! I have tried something like: `TukeyHSD(uni2.anova)[4,]` which returned "Wrong number of dimensions"... Thank you! –  Carolin Nov 2 '11 at 16:24
Hm, if I want to select rows with specific attributes like this: `hsd\$Micro[hsd\$Micro[,4] < 0.05]` I don't get all the columns of hsd\$Micro, just the 4th. –  Carolin Nov 2 '11 at 17:08
Fixed it! `hsd\$Micro[hsd\$Micro[,4] < 0.05,]` –  Carolin Nov 2 '11 at 17:09
ha, glad you fixed it :) –  John Nov 2 '11 at 18:32

Hard to tell without example data, but assuming `Micro` is just a factor with 4 levels and `uni2` looks something like

``````n = 40
Micro = c('Act_Glu2', 'Act_Ala2', 'Ana_Ala2', 'NegI_Ala2')[sample(4, 40, rep=T)]
Sum_Uni = rnorm(n, 5, 0.5)
Sum_Uni[Micro=='Act_Glu2'] = Sum_Uni[Micro=='Act_Glu2'] + 0.5

uni2 = data.frame(Sum_Uni, Micro)
``````
``````> uni2
Sum_Uni     Micro
1 4.964061  Ana_Ala2
2 4.807680  Ana_Ala2
3 4.643279 NegI_Ala2
4 4.793383  Act_Ala2
5 5.307951 NegI_Ala2
6 5.171687  Act_Glu2
...
``````

then I think what you're actually trying to get at is the basic multiple regression output:

``````fit = lm(Sum_Uni ~ Micro, data = uni2)

summary(fit)
anova(fit)
``````
``````> summary(fit)

Call:
lm(formula = Sum_Uni ~ Micro, data = uni2)

Residuals:
Min       1Q   Median       3Q      Max
-1.26301 -0.35337 -0.04991  0.29544  1.07887

Coefficients:
Estimate Std. Error t value Pr(>|t|)
(Intercept)      4.8364     0.1659  29.157  < 2e-16 ***
MicroAct_Glu2    0.9542     0.2623   3.638 0.000854 ***
MicroAna_Ala2    0.1844     0.2194   0.841 0.406143
MicroNegI_Ala2   0.1937     0.2158   0.898 0.375239
---
Signif. codes:  0 ‘***’ 0.001 ‘**’ 0.01 ‘*’ 0.05 ‘.’ 0.1 ‘ ’ 1

Residual standard error: 0.4976 on 36 degrees of freedom
Multiple R-squared: 0.2891, Adjusted R-squared: 0.2299
F-statistic:  4.88 on 3 and 36 DF,  p-value: 0.005996

> anova(fit)
Analysis of Variance Table

Response: Sum_Uni
Df Sum Sq Mean Sq F value   Pr(>F)
Micro      3 3.6254 1.20847  4.8801 0.005996 **
Residuals 36 8.9148 0.24763
---
Signif. codes:  0 ‘***’ 0.001 ‘**’ 0.01 ‘*’ 0.05 ‘.’ 0.1 ‘ ’ 1
``````

You can access the numbers in any of these tables like, for example,

``````> summary(fit)\$coef[2,4]
[1] 0.0008536287
``````

To see the list of what is stored in each object, use `names()`:

``````> names(summary(fit))
[1] "call"          "terms"         "residuals"     "coefficients"
[5] "aliased"       "sigma"         "df"            "r.squared"
In addition to the `TukeyHSD()` function you found, there are many other options for looking at the pairwise tests further, and correcting the p-values if desired. These include `pairwise.table()`, `estimable()` in `gmodels`, the `resampling` and `boot` packages, and others...