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Load the packages we’ll use here:
library(nestedLogit) # Nested Dichotomy Logistic Regression Models
library(knitr) # A General-Purpose Package for Dynamic Report Generation in R
library(dplyr) # A Grammar of Data Manipulation
library(tidyr) # Tidy Messy Data
library(ggplot2) # Create Elegant Data Visualisations Using the Grammar of Graphics
library(geomtextpath) # Curved Text in 'ggplot2'
The main vignette illustrated the basic plot method,
plot.nestedLogit()
in the package. However, for better
control of the details and possibly more pleasing graphs, it is useful
to describe how graphs can be constructed using ggplot2
(Wickham et al., 2023). We’ll use the same
example of women’s labor force participation, using the original
dichotomies:
data(Womenlf, package = "carData")
comparisons <- logits(work=dichotomy("not.work", c("parttime", "fulltime")),
full=dichotomy("parttime", "fulltime"))
wlf.nested <- nestedLogit(partic ~ hincome + children,
dichotomies = comparisons,
data=Womenlf)
The advantages of this approach are that
As we will illustrate, this provides a nice visual interpretation of
the alternative specification of dichotomies for the
Womenlf
data discussed in the section “Alternative models
for the Womenlf
data” of the main vignette.
To draw a plot, it is sufficient to calculate predicted probabilities
over a grid of values of the predictor variables. Here, we select a
range of 0 - 45 in steps of 5, combined with the two values of
children
.
new <- expand.grid(hincome=seq(0, 45, by = 5),
children=c("absent", "present"))
pred.nested <- predict(wlf.nested, newdata = new)
names(pred.nested)
#> [1] "p" "logit" "se.p" "se.logit" ".data"
As explained in help(predict.nestedLogit)
, the predict
method returns a complicated structure – a list of four data frames
corresponding to the predicted probabilities for the response
categories, the corresponding logits, and each of their standard
errors.
head(pred.nested[["p"]])
#> not.work parttime fulltime
#> 1 0.2082 0.02372 0.7681
#> 2 0.2452 0.03785 0.7169
#> 3 0.2864 0.05907 0.6545
#> 4 0.3315 0.08936 0.5791
#> 5 0.3800 0.12944 0.4906
#> 6 0.4309 0.17691 0.3922
However, ggplot
wants the data in long format. This is
easily done using the as.data.frame()
method, which also
includes the values of the predictors in the newdata
data
set:
plotdata <- as.data.frame(pred.nested, newdata=new)
head(plotdata)
#> hincome children response p se.p logit se.logit
#> 1 0 absent not.work 0.20820 0.06326 -1.3358 0.3838
#> 2 0 absent parttime 0.02372 0.01775 -3.7176 0.7666
#> 3 0 absent fulltime 0.76809 0.06386 1.1975 0.3585
#> 4 5 absent not.work 0.24522 0.05799 -1.1243 0.3133
#> 5 5 absent parttime 0.03785 0.02222 -3.2356 0.6101
#> 6 5 absent fulltime 0.71694 0.05933 0.9293 0.2923
ggplot2
Then we can plot probability against one predictor, use
color
to distinguish the levels of the response
(partic
) and facet the plot by children
. The
point-wise standard errors are drawn in a 68% confidence envelope using
geom_ribbon()
. We’ve also plotted the predicted values as
points to show where the predictions are obtained.
theme_set(theme_bw(base_size = 14))
gg1 <- ggplot(plotdata,
aes(x=hincome, y=p, color=response)) +
geom_line(linewidth = 2) +
geom_point(size = 1.5, shape = 16, color = "black") +
labs(x="Husband's Income", y= "Probability") +
facet_wrap(~ children, labeller = label_both) +
geom_ribbon(aes(ymin=p - se.p,
ymax=p + se.p,
fill = response), alpha = 0.3)
gg1
It is noteworthy that the confidence envelopes are wider for not-working women at higher levels of husband’s income, where there are fewer observations.
Plot legends are somewhat hard to read and take up unnecessary space
in the plot, so it is often better to label the curves directly. The
geomtextpath
package (Cameron &
van den Brand, 2022) produces a nicer plot.
gg1 + geom_textline(aes(label = response),
hjust = -0.01, vjust=-0.5, size=5) +
theme(legend.position = "none")
The advantage of the data structure returned by
as.data.frame()
is that you can just as easily plot the
predicted probabilities on the scale of log-odds (\(\text{logit}(p) = \log(p / (1-p))\)), using
the logit
and logit.se
components.
ggplot(plotdata,
aes(x=hincome, y=logit, color=response)) +
geom_line(linewidth = 2) +
geom_point(size = 1.5, shape = 16, color = "black") +
labs(x="Husband's Income", y= "Log Odds") +
facet_wrap(~ children, labeller = label_both) +
geom_ribbon(aes(ymin=logit - se.logit,
ymax=logit + se.logit,
fill = response), alpha = 0.3) +
geom_textline(aes(label = response),
hjust = -0.01, vjust=-0.5, size=5) +
theme(legend.position = "none")
The nested logit model wlf.nested
comprises the two
binary logistic regression models for the work
and
full
dichotomies. We can plot these as follows.
The predict()
method can also generate predicted values
and their standard errors for the logits of these dichotomies, using the
model = "dichotomies"
argument:
pred.dichot <- predict(wlf.nested, newdata = new,
model = "dichotomies")
str(pred.dichot)
#> List of 3
#> $ work :'data.frame': 20 obs. of 3 variables:
#> ..$ fit : num [1:20] 1.336 1.124 0.913 0.701 0.49 ...
#> ..$ se.fit : num [1:20] 0.384 0.313 0.262 0.242 0.261 ...
#> ..$ residual.scale: num [1:20] 1 1 1 1 1 1 1 1 1 1 ...
#> $ full :'data.frame': 20 obs. of 3 variables:
#> ..$ fit : num [1:20] 3.48 2.94 2.41 1.87 1.33 ...
#> ..$ se.fit : num [1:20] 0.767 0.613 0.489 0.423 0.443 ...
#> ..$ residual.scale: num [1:20] 1 1 1 1 1 1 1 1 1 1 ...
#> $ .data:'data.frame': 20 obs. of 2 variables:
#> ..$ hincome : num [1:20] 0 5 10 15 20 25 30 35 40 45 ...
#> ..$ children: Factor w/ 2 levels "absent","present": 1 1 1 1 1 1 1 1 1 1 ...
#> ..- attr(*, "out.attrs")=List of 2
#> .. ..$ dim : Named int [1:2] 10 2
#> .. .. ..- attr(*, "names")= chr [1:2] "hincome" "children"
#> .. ..$ dimnames:List of 2
#> .. .. ..$ hincome : chr [1:10] "hincome= 0" "hincome= 5" "hincome=10" "hincome=15" ...
#> .. .. ..$ children: chr [1:2] "children=absent" "children=present"
#> - attr(*, "model")= chr "wlf.nested"
#> - attr(*, "dichotomies")= chr [1:2] "work" "full"
#> - attr(*, "class")= chr "predictDichotomies"
Transforming this to a data frame, we get an analogous result for plotting:
plotlogit <- as.data.frame(pred.dichot, newdata = new)
head(plotlogit)
#> hincome children response logit se.logit
#> 1 0 absent work 1.3358 0.3838
#> 2 5 absent work 1.1243 0.3133
#> 3 10 absent work 0.9127 0.2620
#> 4 15 absent work 0.7012 0.2422
#> 5 20 absent work 0.4897 0.2613
#> 6 25 absent work 0.2781 0.3121
Then, plot the logit
vs. husband’s income, with separate
curves for the two sub-models:
ggplot(plotlogit,
aes(x=hincome, y=logit, color=response)) +
geom_line(linewidth = 2) +
geom_point(size = 1.5, shape = 16, color = "black") +
labs(x="Husband's Income", y= "Log Odds") +
facet_wrap(~ children, labeller = label_both) +
geom_ribbon(aes(ymin=logit - se.logit,
ymax=logit + se.logit,
fill = response), alpha = 0.3) +
geom_textline(aes(label = response),
hjust = -0.01, vjust=-0.5, size=5) +
theme(legend.position = "none")
Or, interchanging the roles of children
and
response
, we can plot these the other way, faceting by
response
.
ggplot(plotlogit,
aes(x=hincome, y=logit, color=children)) +
geom_line(linewidth = 2) +
geom_point(size = 1.5, shape = 16, color = "black") +
labs(x="Husband's Income", y= "Log Odds") +
facet_wrap(~ response, labeller = label_both) +
geom_ribbon(aes(ymin=logit - se.logit,
ymax=logit + se.logit,
fill = children), alpha = 0.3) +
geom_textline(aes(label = children),
hjust = -0.01, vjust=-0.5, size=5) +
theme(legend.position = "none")
This nicely illustrates the nature of the fitted logit models: The
lines in each panel have the same slopes for the two levels of
children
, differing only in their intercepts. The
full
distinction between working full-time vs. part-time
decreases faster with husband’s income than for the work
dichotomy between not working at all and working either part-time or
full-time.
In the main vignette we mentioned that an alternative set of nested dichotomies first contrasts full-time work with the other categories, {full-time} vs. {not working, part-time}, and then {not working} vs. {part-time}.
wlf.nested.alt <- nestedLogit(partic ~ hincome + children,
logits(full=dichotomy(nonfulltime=c("not.work", "parttime"), "fulltime"),
part=dichotomy("not.work", "parttime")),
data=Womenlf)
Proceeding in the same way as above, we get predicted logits and standard errors for each of the dichotomies.
pred.dichot.alt <- predict(wlf.nested.alt, newdata = new,
model = "dichotomies")
plotlogit.alt <- as.data.frame(pred.dichot.alt, newdata = new)
head(plotlogit.alt)
#> hincome children response logit se.logit
#> 1 0 absent full 1.7696 0.4690
#> 2 5 absent full 1.2762 0.3577
#> 3 10 absent full 0.7827 0.2723
#> 4 15 absent full 0.2893 0.2421
#> 5 20 absent full -0.2042 0.2852
#> 6 25 absent full -0.6976 0.3772
Plotting these as before:
ggplot(plotlogit.alt,
aes(x=hincome, y=logit, color=children)) +
geom_line(linewidth = 2) +
geom_point(size = 1.5, shape = 16, color = "black") +
labs(x="Husband's Income", y= "Log Odds") +
facet_wrap(~ response, labeller = label_both) +
geom_ribbon(aes(ymin=logit - se.logit,
ymax=logit + se.logit,
fill = children), alpha = 0.3) +
geom_textline(aes(label = children),
hjust = -0.01, vjust=-0.5, size=5) +
theme(legend.position = "none")
It’s apparent that the alternative model produces a simpler description of the data: The predictors husband’s income and presence of children affect the decision to work full-time, but not the decision to work part-time among those who aren’t engaged in full-time work. In particular it is clear that neither husband’s income nor having young children has any effect on the decision to work part-time.
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.
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