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This vignette shows how to use the multpois
package for
analyzing nominal response data. Nominal responses, sometimes called
multinomial responses, are unordered categories. In certain experiments
or surveys, the dependent variable can be one of N categories.
For example, we might ask people what their favorite ice cream flavor
is: vanilla, chocolate, or strawberry. This four-category response would
be a polytomous dependent variable. Perhaps we wish to ask adults and
children about their favorite ice cream to see if there is a difference
by age group. We would then have a two-level between-subjects factor. If
we ask each respondent only once, this data set would represent a
one-way between-subjects design. But perhaps we ask each participant
once each season—in fall, winter, spring, and summer—to see if
their responses change. Now we would have a four-level within-subjects
factor, i.e., repeated measures.
The multpois
package helps us analyze this type of data,
where the dependent variable is nominal. It does so by modeling nominal
responses as counts of category choices and uses (mixed) Poisson
regression to analyze these counts (Baker 1994, Chen & Kuo 2001).
This technique is known as the multinomial-Poisson transformation
(Guimaraes 2004) or trick (Lee et al. 2017).
R already provides options for the following situations:
If the response is dichotomous, and the factors are only
between-subjects, we can build a model using glm
with
family=binomial
from the base stats
package.
The Anova
function from the car
package can be
used to produce main effects and interactions. The emmeans
function from the emmeans
package can be used to produce
post hoc pairwise comparisons.
If the response is polytomous, and the factors are only
between-subjects, we can build a model using multinom
from
the nnet
package. The Anova
function from the
car
package can be used to produce main effects and
interactions. However, we cannot use the emmeans
function
from the emmeans
package in the usual fashion. An approach
to this issue by emmeans
package author Russ Lenth is
offered below.
If the response is dichotomous, and one or more factors is
within-subjects, we can build a model using glmer
with
family=binomial
from the lme4
package. The
Anova
function from the car
package can be
used to produce main effects and interactions. The emmeans
function from the emmeans
package can be used to produce
post hoc pairwise comparisons.
If the response is polytomous, and one or more factors is
within-subjects, there is no easy option similar to the three above. The
multinom
function in nnet
cannot take random
factors to handle repeated measures, and the glmer
function
in lme4
does not offer a family=multinomial
option. It is this case in particular that this package was created to
address, although it can address the above three scenarios,
also.
The first four analyses below illustrate 2×2 designs having between-
and within-subjects factors and dichotomous and polytomous responses.
(The functions in multpois
are not limited to 2×2 designs;
any number of between- and within-subjects factors can be used.) The
first three examples first use existing R solutions to which the results
from multpois
functions can be compared.
The fifth example returns to our ice cream scenario, above, and
analyzes a mixed factorial design with one between-subjects factor
(Age
) and one within-subjects factor
(Season
).
bs2
data set.bs3
data set.ws2
data set.ws3
data set.icecream
data set.Baker, S.G. (1994). The multinomial-Poisson transformation. The Statistician 43 (4), pp. 495-504. https://doi.org/10.2307/2348134
Chen, Z. and Kuo, L. (2001). A note on the estimation of the multinomial logit model with random effects. The American Statistician 55 (2), pp. 89-95. https://www.jstor.org/stable/2685993
Guimaraes, P. (2004). Understanding the multinomial-Poisson transformation. The Stata Journal 4 (3), pp. 265-273. https://www.stata-journal.com/article.html?article=st0069
Lee, J.Y.L., Green, P.J.,and Ryan, L.M. (2017). On the “Poisson trick” and its extensions for fitting multinomial regression models. arXiv preprint available at https://doi.org/10.48550/arXiv.1707.08538
These are the libraries needed for running the code in this vignette:
Let’s also load our library:
Let’s load and prepare our first data set, a 2×2 between-subjects
design with a dichotomous response. Factor X1
has levels
{a, b}
, factor X2
has levels
{c, d}
, and response Y
has categories
{yes, no}
.
data(bs2, package="multpois")
bs2$PId = factor(bs2$PId)
bs2$Y = factor(bs2$Y)
bs2$X1 = factor(bs2$X1)
bs2$X2 = factor(bs2$X2)
contrasts(bs2$X1) <- "contr.sum"
contrasts(bs2$X2) <- "contr.sum"
Let’s visualize this data set using a mosaic plot:
xt = xtabs( ~ X1 + X2 + Y, data=bs2)
mosaicplot(xt, main="Y by X1, X2", las=1, col=c("pink","lightgreen"))
Given X1
and X2
are both between-subjects
factors, and Y
is a dichotomous response, we can analyze
this data set using conventional logistic regression:
m1 = glm(Y ~ X1*X2, data=bs2, family=binomial)
Anova(m1, type=3)
#> Analysis of Deviance Table (Type III tests)
#>
#> Response: Y
#> LR Chisq Df Pr(>Chisq)
#> X1 4.4440 1 0.03502 *
#> X2 0.7513 1 0.38606
#> X1:X2 4.4440 1 0.03502 *
#> ---
#> Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
emmeans(m1, pairwise ~ X1*X2, adjust="holm")$contrasts
#> contrast estimate SE df z.ratio p.value
#> a c - b c -2.398 0.870 Inf -2.755 0.0352
#> a c - a d -1.705 0.801 Inf -2.129 0.1661
#> a c - b d -1.705 0.801 Inf -2.129 0.1661
#> b c - a d 0.693 0.847 Inf 0.819 1.0000
#> b c - b d 0.693 0.847 Inf 0.819 1.0000
#> a d - b d 0.000 0.775 Inf 0.000 1.0000
#>
#> Results are given on the log odds ratio (not the response) scale.
#> P value adjustment: holm method for 6 tests
We can also analyze this data set using the multinomial-Poisson trick, which converts nominal responses to category counts and analyzes these counts using Poisson regression:
m2 = glm.mp(Y ~ X1*X2, data=bs2)
Anova.mp(m2, type=3)
#> Analysis of Deviance Table (Type III tests)
#>
#> Response: Y
#> via the multinomial-Poisson trick
#> Chisq Df N Pr(>Chisq)
#> X1 4.4440 1 60 0.03502 *
#> X2 0.7513 1 60 0.38606
#> X1:X2 4.4440 1 60 0.03502 *
#> ---
#> Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
glm.mp.con(m2, pairwise ~ X1*X2, adjust="holm")
#> $heading
#> [1] "Pairwise comparisons via the multinomial-Poisson trick"
#>
#> $contrasts
#> Contrast Chisq Df N p.value
#> 1 a.c - a.d 4.962518 1 30 0.129510
#> 2 a.c - b.c 9.045871 1 30 0.015798
#> 3 a.c - b.d 4.962518 1 30 0.129510
#> 4 a.d - b.c 0.687412 1 30 1.000000
#> 5 a.d - b.d 0.000000 1 30 1.000000
#> 6 b.c - b.d 0.687412 1 30 1.000000
#>
#> $notes
#> [1] "P value adjustment: holm method for 6 tests"
The omnibus results from logistic regression and from the multinomial-Poisson trick match, and the results from the post hoc pairwise comparisons are quite similar.
Let’s load and prepare our second data set, a 2×2 between-subjects
design with a polytomous response. Factor X1
has levels
{a, b}
, factor X2
has levels
{c, d}
, and response Y
has categories
{yes, no, maybe}
.
data(bs3, package="multpois")
bs3$PId = factor(bs3$PId)
bs3$Y = factor(bs3$Y)
bs3$X1 = factor(bs3$X1)
bs3$X2 = factor(bs3$X2)
contrasts(bs3$X1) <- "contr.sum"
contrasts(bs3$X2) <- "contr.sum"
Let’s again visualize the data using a mosaic plot:
xt = xtabs( ~ X1 + X2 + Y, data=bs3)
mosaicplot(xt, main="Y by X1, X2", las=1, col=c("lightyellow","pink","lightgreen"))
Given X1
and X2
are both between-subjects
factors, and Y
is a polytomous response, we might wish that
glm
had a family=multinomial
option analogous
to its family=binomial
option, but it does not.
Fortunately, we can analyze polytomous response data for (only)
between-subjects factors using the multinom
function from
the nnet
package:
m3 = multinom(Y ~ X1*X2, data=bs3, trace=FALSE)
Anova(m3, type=3)
#> Analysis of Deviance Table (Type III tests)
#>
#> Response: Y
#> LR Chisq Df Pr(>Chisq)
#> X1 3.5327 2 0.17096
#> X2 7.8081 2 0.02016 *
#> X1:X2 4.0039 2 0.13507
#> ---
#> Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
Unfortunately, emmeans
does not work straightforwardly
with multinom
models. A solution to this issue from Russ
Lenth, lead author of emmeans
, was posted
on StackExchange:
e0 = emmeans(m3, ~ X1*X2 | Y, mode="latent")
c0 = contrast(e0, method="pairwise", ref=1)
test(c0, joint=TRUE, by="contrast")
#> contrast df1 df2 F.ratio p.value note
#> a c - b c 2 8 3.017 0.1056 d
#> a c - a d 2 8 4.552 0.0479 d
#> a c - b d 2 8 4.610 0.0466 d
#> b c - a d 2 8 0.688 0.5298 d
#> b c - b d 2 8 0.611 0.5661 d
#> a d - b d 2 8 1.308 0.3224 d
#>
#> d: df1 reduced due to linear dependence
We can also analyze this data set using the multinomial-Poisson trick:
m4 = glm.mp(Y ~ X1*X2, data=bs3)
Anova.mp(m4, type=3)
#> Analysis of Deviance Table (Type III tests)
#>
#> Response: Y
#> via the multinomial-Poisson trick
#> Chisq Df N Pr(>Chisq)
#> X1 3.5327 2 60 0.17096
#> X2 7.8081 2 60 0.02016 *
#> X1:X2 4.0039 2 60 0.13507
#> ---
#> Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
glm.mp.con(m4, pairwise ~ X1*X2, adjust="holm")
#> $heading
#> [1] "Pairwise comparisons via the multinomial-Poisson trick"
#>
#> $contrasts
#> Contrast Chisq Df N p.value
#> 1 a.c - a.d 12.172660 2 30 0.013644
#> 2 a.c - b.c 6.990329 2 30 0.121376
#> 3 a.c - b.d 11.647010 2 30 0.014785
#> 4 a.d - b.c 1.425017 2 30 0.980826
#> 5 a.d - b.d 2.804595 2 30 0.738093
#> 6 b.c - b.d 1.252756 2 30 0.980826
#>
#> $notes
#> [1] "P value adjustment: holm method for 6 tests"
Again, the results from multinomial logistic regression and from the multinomial-Poisson trick match. The results from the post hoc pairwise comparisons are fairly similar.
Let’s load and prepare our third data set, a 2×2 within-subjects
design with a dichotomous response. Factor X1
has levels
{a, b}
, factor X2
has levels
{c, d}
, and response Y
has categories
{yes, no}
. Now the PId
factor is repeated
across rows, indicating participants were measured repeatedly.
data(ws2, package="multpois")
ws2$PId = factor(ws2$PId)
ws2$Y = factor(ws2$Y)
ws2$X1 = factor(ws2$X1)
ws2$X2 = factor(ws2$X2)
contrasts(ws2$X1) <- "contr.sum"
contrasts(ws2$X2) <- "contr.sum"
Let’s visualize this data set using a mosaic plot:
xt = xtabs( ~ X1 + X2 + Y, data=ws2)
mosaicplot(xt, main="Y by X1, X2", las=1, col=c("pink","lightgreen"))
Given X1
and X2
are both within-subjects
factors, and Y
is a dichotomous response, we can analyze
this using mixed-effects logistic regression. The function
glmer
from the lme4
package provides this for
us:
m5 = glmer(Y ~ X1*X2 + (1|PId), data=ws2, family=binomial)
Anova(m5, type=3)
#> Analysis of Deviance Table (Type III Wald chisquare tests)
#>
#> Response: Y
#> Chisq Df Pr(>Chisq)
#> (Intercept) 0.8553 1 0.355052
#> X1 0.8553 1 0.355052
#> X2 6.6368 1 0.009989 **
#> X1:X2 4.3758 1 0.036452 *
#> ---
#> Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
emmeans(m5, pairwise ~ X1*X2, adjust="holm")$contrasts
#> contrast estimate SE df z.ratio p.value
#> a c - b c 0.693 0.847 Inf 0.819 0.8258
#> a c - a d 2.773 0.913 Inf 3.037 0.0143
#> a c - b d 0.981 0.833 Inf 1.177 0.7176
#> b c - a d 2.079 0.847 Inf 2.456 0.0702
#> b c - b d 0.288 0.760 Inf 0.378 0.8258
#> a d - b d -1.792 0.833 Inf -2.150 0.1262
#>
#> Results are given on the log odds ratio (not the response) scale.
#> P value adjustment: holm method for 6 tests
We can also analyze this data set using the multinomial-Poisson trick, now with an underlying mixed-effects Poisson regression model:
m6 = glmer.mp(Y ~ X1*X2 + (1|PId), data=ws2)
Anova.mp(m6, type=3)
#> Analysis of Deviance Table (Type III Wald chisquare tests)
#>
#> Response: Y
#> via the multinomial-Poisson trick
#> Chisq Df N Pr(>Chisq)
#> X1 0.8553 1 60 0.355052
#> X2 6.6368 1 60 0.009989 **
#> X1:X2 4.3758 1 60 0.036452 *
#> ---
#> Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
glmer.mp.con(m6, pairwise ~ X1*X2, adjust="holm")
#> $heading
#> [1] "Pairwise comparisons via the multinomial-Poisson trick"
#>
#> $contrasts
#> Contrast Chisq Df N p.value
#> 1 a.c - a.d 9.224694 1 30 0.014328
#> 2 a.c - b.c 0.670400 1 30 0.825824
#> 3 a.c - b.d 1.385318 1 30 0.717591
#> 4 a.d - b.c 6.033595 1 30 0.070180
#> 5 a.d - b.d 4.622979 1 30 0.126184
#> 6 b.c - b.d 0.143240 1 30 0.825824
#>
#> $notes
#> [1] "P value adjustment: holm method for 6 tests"
The results from mixed-effects logistic regression and results from the multinomial-Poisson trick match, including the results from the post hoc pairwise comparisons.
This fourth example is the reason that the multpois
package was created. Unlike the three examples above, there are not
straightforward options for analyzing nominal responses with repeated
measures and obtaining ANOVA-style results. Some functions do offer
mixed-effects multinomial regression modeling, such as
mblogit
in the mclogit
package, but they do
not enable ANOVA-style output. Other advanced methods exist, such as
Markov chain Monte Carlo (MCMC) methods in the MCMCglmm
library, which does have a family=multinomial
option, but
these methods are complex and deviate from the approaches illustrated
above. Fortunately, we can again use the multinomial-Poisson trick.
Let’s load and prepare our fourth data set, a 2×2 within-subjects
design with a polytomous response. Factor X1
has levels
{a, b}
, factor X2
has levels
{c, d}
, and response Y
has categories
{yes, no, maybe}
. Again, the PId
factor is
repeated across rows, indicating participants were measured
repeatedly.
data(ws3, package="multpois")
ws3$PId = factor(ws3$PId)
ws3$Y = factor(ws3$Y)
ws3$X1 = factor(ws3$X1)
ws3$X2 = factor(ws3$X2)
contrasts(ws3$X1) <- "contr.sum"
contrasts(ws3$X2) <- "contr.sum"
Let’s visualize this data set using a mosaic plot:
xt = xtabs( ~ X1 + X2 + Y, data=ws3)
mosaicplot(xt, main="Y by X1, X2", las=1, col=c("lightyellow","pink","lightgreen"))
Because multinom
from the nnet
package
cannot handle random factors, it cannot model repeated measures. And
because glmer
from the lme4
package has no
family=multinomial
option, it cannot model polytomous
responses. Fortunately, with the multinomial-Poisson trick, we can
analyze polytomous responses from repeated measures:
m7 = glmer.mp(Y ~ X1*X2 + (1|PId), data=ws3)
Anova.mp(m7, type=3)
#> Analysis of Deviance Table (Type III Wald chisquare tests)
#>
#> Response: Y
#> via the multinomial-Poisson trick
#> Chisq Df N Pr(>Chisq)
#> X1 6.6707 2 60 0.0356 *
#> X2 6.6707 2 60 0.0356 *
#> X1:X2 0.5508 2 60 0.7593
#> ---
#> Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
glmer.mp.con(m7, pairwise ~ X1*X2, adjust="holm")
#> $heading
#> [1] "Pairwise comparisons via the multinomial-Poisson trick"
#>
#> $contrasts
#> Contrast Chisq Df N p.value
#> 1 a.c - a.d 6.033961 2 30 0.244745
#> 2 a.c - b.c 6.033962 2 30 0.244745
#> 3 a.c - b.d 10.679680 2 30 0.028782
#> 4 a.d - b.c 0.000000 2 30 1.000000
#> 5 a.d - b.d 1.589577 2 30 1.000000
#> 6 b.c - b.d 1.589578 2 30 1.000000
#>
#> $notes
#> [1] "P value adjustment: holm method for 6 tests"
This fifth and final example is also the reason that the
multpois
package was created, since we have a polytomous
response, one between-subjects factor, and one within-subjects factors.
This mixed factorial design is also known as a split-plot design.
This fictional data is based on the scenario at the beginning of this
vignette. Forty respondents, half adults and half children, were
surveyed for their favorite ice cream four times, once per season. Thus,
Age
is a between-subjects factor with two levels
{adult, child}
and Season
is a within-subjects
factor with four levels {fall, winter, spring, summer}
. The
polytomous response, Pref
, has three categories:
{vanilla, chocolate, strawberry}
. The PId
factor is repeated across rows, indicating respondents were queried four
times each.
Let’s load and prepare this data set:
data(icecream, package="multpois")
icecream$PId = factor(icecream$PId)
icecream$Pref = factor(icecream$Pref)
icecream$Age = factor(icecream$Age)
icecream$Season = factor(icecream$Season)
contrasts(icecream$Age) <- "contr.sum"
contrasts(icecream$Season) <- "contr.sum"
Let’s visualize this data set using a mosaic plot:
xt = xtabs( ~ Age + Season + Pref, data=icecream)
mosaicplot(xt, main="Pref by Age, Season", las=1, col=c("tan","pink","beige"))
As in the previous example, we can use the multinomial-Poisson trick to analyze repeated measures data with polytomous responses:
m8 = glmer.mp(Pref ~ Age*Season + (1|PId), data=icecream)
Anova.mp(m8, type=3)
#> Analysis of Deviance Table (Type III Wald chisquare tests)
#>
#> Response: Pref
#> via the multinomial-Poisson trick
#> Chisq Df N Pr(>Chisq)
#> Age 8.9838 2 160 0.011199 *
#> Season 12.4522 6 160 0.052609 .
#> Age:Season 18.3118 6 160 0.005498 **
#> ---
#> Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
We have a main effect of Age
and an
Age
×Season
interaction but no main effect of
Season
. We can explore this further by graphically
depicting response proportions in each age group:
xt = xtabs( ~ Age + Pref, data=icecream)
mosaicplot(xt, main="Pref by Age", las=1, col=c("tan","pink","beige"))
The different proportions by Age
clearly emerge,
explaining the main effect. Let’s also graphically depict the
proportions by Season
:
xt = xtabs( ~ Season + Pref, data=icecream)
mosaicplot(xt, main="Pref by Season", las=1, col=c("tan","pink","beige"))
Finally, we can again conduct post hoc pairwise comparisons. Note, however, there are many such possible comparisons, and best practice would require us to only conduct those comparisons driven by hypotheses or planned in advance. For example, we might wish to limit our pairwise comparisons to adults vs. children in each season, not across all seasons. In any case, we first conduct all pairwise comparisons for illustration:
glmer.mp.con(m8, pairwise ~ Age*Season, adjust="holm")
#> $heading
#> [1] "Pairwise comparisons via the multinomial-Poisson trick"
#>
#> $contrasts
#> Contrast Chisq Df N p.value
#> 1 adult.fall - adult.spring 9.050033 2 40 0.260040
#> 2 adult.fall - adult.summer 0.425905 2 40 1.000000
#> 3 adult.fall - adult.winter 4.152565 2 40 1.000000
#> 4 adult.fall - child.fall 8.128466 2 40 0.377872
#> 5 adult.fall - child.spring 1.222474 2 40 1.000000
#> 6 adult.fall - child.summer 2.136526 2 40 1.000000
#> 7 adult.fall - child.winter 3.642131 2 40 1.000000
#> 8 adult.spring - adult.summer 7.606838 2 40 0.447111
#> 9 adult.spring - adult.winter 14.904790 2 40 0.015820
#> 10 adult.spring - child.fall 14.957210 2 40 0.015820
#> 11 adult.spring - child.spring 13.775910 2 40 0.026520
#> 12 adult.spring - child.summer 13.630850 2 40 0.027425
#> 13 adult.spring - child.winter 8.577377 2 40 0.315629
#> 14 adult.summer - adult.winter 3.697246 2 40 1.000000
#> 15 adult.summer - child.fall 7.059709 2 40 0.556871
#> 16 adult.summer - child.spring 2.676089 2 40 1.000000
#> 17 adult.summer - child.summer 2.026498 2 40 1.000000
#> 18 adult.summer - child.winter 1.974120 2 40 1.000000
#> 19 adult.winter - child.fall 1.368365 2 40 1.000000
#> 20 adult.winter - child.spring 3.817680 2 40 1.000000
#> 21 adult.winter - child.summer 0.429745 2 40 1.000000
#> 22 adult.winter - child.winter 2.355143 2 40 1.000000
#> 23 child.fall - child.spring 7.698949 2 40 0.447111
#> 24 child.fall - child.summer 2.978168 2 40 1.000000
#> 25 child.fall - child.winter 4.252012 2 40 1.000000
#> 26 child.spring - child.summer 2.069326 2 40 1.000000
#> 27 child.spring - child.winter 6.222224 2 40 0.801918
#> 28 child.summer - child.winter 2.136527 2 40 1.000000
#>
#> $notes
#> [1] "P value adjustment: holm method for 28 tests"
If we did wish to compare adults vs. children in each season (fall, winter, spring, and summer), we would first conduct all pairwise comparisons, leaving them uncorrected…
glmer.mp.con(m8, pairwise ~ Age*Season, adjust="none")
#> $heading
#> [1] "Pairwise comparisons via the multinomial-Poisson trick"
#>
#> $contrasts
#> Contrast Chisq Df N p.value
#> 1 adult.fall - adult.spring 9.050033 2 40 0.010835
#> 2 adult.fall - adult.summer 0.425905 2 40 0.808195
#> 3 adult.fall - adult.winter 4.152565 2 40 0.125396
#> 4 adult.fall - child.fall 8.128466 2 40 0.017176
#> 5 adult.fall - child.spring 1.222474 2 40 0.542679
#> 6 adult.fall - child.summer 2.136526 2 40 0.343605
#> 7 adult.fall - child.winter 3.642131 2 40 0.161853
#> 8 adult.spring - adult.summer 7.606838 2 40 0.022294
#> 9 adult.spring - adult.winter 14.904790 2 40 0.000580
#> 10 adult.spring - child.fall 14.957210 2 40 0.000565
#> 11 adult.spring - child.spring 13.775910 2 40 0.001020
#> 12 adult.spring - child.summer 13.630850 2 40 0.001097
#> 13 adult.spring - child.winter 8.577377 2 40 0.013723
#> 14 adult.summer - adult.winter 3.697246 2 40 0.157454
#> 15 adult.summer - child.fall 7.059709 2 40 0.029309
#> 16 adult.summer - child.spring 2.676089 2 40 0.262358
#> 17 adult.summer - child.summer 2.026498 2 40 0.363038
#> 18 adult.summer - child.winter 1.974120 2 40 0.372671
#> 19 adult.winter - child.fall 1.368365 2 40 0.504502
#> 20 adult.winter - child.spring 3.817680 2 40 0.148252
#> 21 adult.winter - child.summer 0.429745 2 40 0.806644
#> 22 adult.winter - child.winter 2.355143 2 40 0.308026
#> 23 child.fall - child.spring 7.698949 2 40 0.021291
#> 24 child.fall - child.summer 2.978168 2 40 0.225579
#> 25 child.fall - child.winter 4.252012 2 40 0.119313
#> 26 child.spring - child.summer 2.069326 2 40 0.355346
#> 27 child.spring - child.winter 6.222224 2 40 0.044551
#> 28 child.summer - child.winter 2.136527 2 40 0.343605
#>
#> $notes
#> [1] "P value adjustment: none method for 28 tests"
…and then we would extract the relevant comparisons (rows 4, 22, 11, and 17, respectively), and manually correct their p-values to guard against Type I errors, like so:
p.adjust(c(0.017176, 0.308026, 0.001020, 0.363038), method="holm")
#> [1] 0.051528 0.616052 0.004080 0.616052
Thus, after correction using Holm’s sequential Bonferroni procedure (Holm 1979), we see that adults vs. children in spring are significantly different (p < .05). Looking again at Figure 5 visually confirms this result.
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