A `zenplot`

can show the same information as a
`pairs`

plot but with two important display differences.

First, the matrix organization of the `pairs`

layout is
replaced by the “zig-zag” layout of `zenplot`

. Second, the
number of plots produced is about half that of a `pairs`

plot
allowing each plot in a `zenplot`

to be given more visual
space.

`PairViz`

A convenient function to produce all pairs can be found in the
`PairViz`

package found on `cran`

and installed in
`R`

via `install.packages("PairViz")`

.

We will illustrate this functionality and the difference between a
`pairs`

plot and a `zenplot`

by first considering
a small dataset on earthquakes having only a few variates. The
difference between the two plots becomes much more important for data
having larger numbers of variates – we illustrate the difference again
using German data on voting patterns in two elections.

The built-in `R`

data set called `attenu`

contains measurements to estimate the attenuating effect of distance on
the ground acceleration of earthquakes in California.

There are 5 different variates used to describe the peak acceleration of 23 California earthquakes measured at different observation stations. The data set contains 182 different peak acceleration measurements and has some missing data. The first few cases of the data set look like

```
## event mag station dist accel
## 1 1 7.0 117 12 0.359
## 2 2 7.4 1083 148 0.014
## 3 2 7.4 1095 42 0.196
## 4 2 7.4 283 85 0.135
## 5 2 7.4 135 107 0.062
## 6 2 7.4 475 109 0.054
```

Its variates are

`## [1] "event" "mag" "station" "dist" "accel"`

and we are interested in all pairs of these variates.

To get these, first imagine a graph having as its nodes the variates of the data. An edge of this graph connects two nodes and hence represents a pair of variates. If interest lies in all pairs of varates, then the graph is a complete graph – it will have an edge between every pair of nodes. An ordering of variate pairs corresponds to any path on the graph. To have an ordering of all pairs of variates, the path must visit all edges and is called an Eulerian, or Euler path. Such a path always exists for complete graphs on an odd number of nodes; when the number of nodes is even, extra edges must be added to the graph before an Eulerian can exist.

For a complete graph with n nodes, the function `eseq`

(for Euler sequence) function from the `PairViz`

package
returns an order in which the nodes (numbered 1 to n) can be visited to
produce an Euler path. It works as follows.

```
## Since attenu has 5 variates, the complete graph has n=5 nodes
## and an Euler sequence is given as
eseq(5)
```

`## [1] 1 2 3 1 4 2 5 3 4 5 1`

In terms of the variate names of `attenu`

, this is:

```
## [1] "event" "mag" "station" "event" "dist" "mag" "accel"
## [8] "station" "dist" "accel" "event"
```

As can be seen in the corresponding complete graph below, this sequence traces an Eulerian path on the complete graph and so presents every variate next to every other variate somewhere in the order.

`zenpath`

This functionality (and more) from `PairViz`

has been
bundled together in the `zenplots`

package as a single
function `zenpath`

. For example,

`## [1] 5 1 2 3 1 4 2 5 3 4 5`

This sequence, while still Eulerian, is slightly different than that
returned by `eseq(5)`

. The sequence is chosen so that all
pairs involving the first index appear earliest in the sequence, then
all pairs involving the second index, and so on. We call this a “front
loaded” sequence and identify it with the `zenpath`

argument
`method = "front.loaded"`

. Other possibilities are
`method = "back.loaded"`

and `method = "balanced"`

giving the following sequences:

```
## Back loading ensures all pairs appear latest (back) for
## high values of the indices.
zenpath(5, method = "back.loaded")
```

`## [1] 1 2 3 1 4 2 5 3 4 5 1`

```
## Frot loading ensures all pairs appear earliest (front) for
## low values of the indices.
zenpath(5, method = "front.loaded")
```

`## [1] 5 1 2 3 1 4 2 5 3 4 5`

```
## Balanced loading ensures all pairs appear in groups of all
## indices (Hamiltonian paths -> a Hamiltonian decomposition of the Eulerian)
zenpath(5, method = "balanced")
```

`## [1] 1 2 3 5 4 1 3 4 2 5 1`

The differences are easier to see when there are more nodes. Below, we show the index ordering (top to bottom) for each of these three methods when the graph has 15 nodes, here labelled”a” to “o” (to make plotting easier).

Starting from the bottom (the back of the sequence), “back loading”
has the last index, “o”, complete its pairing with every other index
before “n” completes all of its pairings. All of “n”’s pairings complete
before those of “m”, all of “m”’s before “l”, and so on until the last
pairing of “a” and “b” are completed. Note that the last indices still
appear at the end of the sequence (since the sequence begins at the top
of the display and moves down). The term “back loading” is used here in
a double sense - the later (back) indices have their pairings appear as
closely together as possible towards the back of the returned sequence.
A simple reversal, that is
`rev(zenpath(15, method = "back.loaded"))`

, would have them
appear at the beginning of the sequence. In this case the “back loading”
would only be in one sense, namely that the later indexed (back) nodes
appear first in the reversed sequence.

Analogously, “front loading” has the first (front) indices appear at the front of the sequence with their pairings appear as closely together as possible.

The “balanced” case ensures that all indices appear in each block of pairings. In the figure there are 7 blocks.

All three sequences are Eulerian, meaning all pairs appear somewhere in each sequence.

Eulerian sequences can now be used to compare a `pairs`

plot with a `zenplot`

when all pairs of variates are to be
displayed.

First a pairs plot:

```
## We remove the space between plots and suppress the axes
## so as to give maximal space to the individual scatterplots.
## We also choose a different plotting character and reduce
## its size to better distinguish points.
pairs(attenu, oma=rep(0,4), gap=0, xaxt="n", yaxt="n")
```

We now effect a display of all pairs using `zenplot`

.

```
## Plotting character and size are chosen to match that
## of the pairs plot.
## zenpath ensures that all pairs of variates appear
## in the zenplot.
## The last argument, n2dcol, is chosen so that the zenplot
## has the same number of plots across the page as does the
## pairs plot.
zenplot(attenu[, zenpath(ncol(attenu))], n2dcol=4)
```

Each display shows scatterplot of all `choose(5,2) =`

10
pairs of variates for this data. Each display occupies the same total
area.

With `pairs`

each plot is displayed twice and arranged in
a symmetric matrix layout with the variate labels appearing along the
diagonal. This makes for easy look-up but uses a lot of space.

With `zenplot`

, each plot appears only once with its
coordinate defining variates appearing as labels on horizontal (top or
bottom) and vertical (left or right) axis positions. The layout follows
the order of the variates in which the variates appear in the call to
`zenplot`

beginning in the top left corner of the display and
then zig-zagging from top left to bottom right; when the rightmost
boundary or the display is reached, the direction is reversed
horizontally and the zigzag moves from top right to bottom left. The
following display illustrates the pattern (had by simply calling
`zenplot`

):

```
## Call zenplot exactly as before, except that each scatterplot is replaced
## by an arrow that shows the direction of the layout.
zenplot(attenu[, zenpath(ncol(attenu))], plot2d="arrow", n2dcol=4)
```

The zig zag pattern of plots appears as follows.

- The top left plot (of either
`zenplot`

display) has horizontal variate`event`

and vertical variate`mag`

. - To its right is a plot sharing the same vertical variate
`mag`

but now with horizontal variate`station`

. Note that the variate`station`

has some missing values and this is recorded on its label as`station (some NA)`

. - Below this a plot appears with the same horizontal variate
`station`

but now with vertical variate`event`

. Since this is the first repeat appearance of`event`

it appears with a suffix as`event.1`

. - To its right is a plot with shared vertical variate
`event`

and new horizontal variate`dist`

. - Below this is a plot having shared horizontal variate
`dist`

and as vertical variate the first repeat of the variate`mag`

. - To its right is a plot having shared vertical variate
`mag`

and new horizontal variate`accel`

. - The right edge of the display is reached and the zigzag changes horizontal direction repeating the pattern until either the left edge is reached (whereupon the horizontal direction is reversed) or the variates are exhausted.

Like the `pairs`

plot, the `zenplot`

lays its
plots out on a two dimensional grid – the argument `n2dcol=4`

specifies the number of columns for the 2d plots (e.g. scatterplots). As
shown, this can lead to a lot of unused space in the display.

The `zenplot`

layout can be made more compact by different
choices of the argument `n2dcol`

(odd values provide a more
compact layout). For example,

By default, `zenplot`

tries to determine a value for
`n2dcol`

that minimizes the space unused by its zigzag
layout.

with layout directions as

As the direction arrows show, the default layout is to zigzag horizontally first as much as possible.

This is clearly a much more compact display. Again, axes are shared wherever a label appears between plots.

Unless explicitly specified, the value of `n2dcol`

is
determined by the aregument `scaling`

which can either be a
numerical value specifying the ratio of the height to the width of the
`zenplot`

layout or be a string describing a page whose ratio
of height to width will be used. The possible strings are
`letter'' (the default),`

square’‘, `A4'',`

golden’’
(for the golden ratio), or ``legal’’.

The display arrangement of a scatterplot matrix facilitates the lookup of the scatterplot for any particular pair of variates by simply identifying the corresponding row and columns.

The scatterplot matrix also simplifies the visual comparison of the one variate to each of several others by scanning along any single row (or column). Note however that this single row scan does come at the price of doubling the number of scatterplots in the display.

These two visual search facilities are diminished by the layout of a
`zenplot`

. Although the same information is available in a
`zenplot`

the layout does not lend itself to easy lookup from
variates to plots. If the `zenplot`

layout is used in an
interactive graphical system, other means of interaction could be
implemented to have, for example, all plots containing a particular
variate (or pair of variates) distinguish themselves visually by having
their background colour change temporarily.

On the other hand, the reverse lookup from plot to variates is
simpler in a `zenplot`

than in a scatterplot matrix,
particularly for large numbers of variates.

Both layouts allow a visual search for patterns in the point configurations. Having many plots be presented at once enables a quick visual search over a large space for the existence of interesting point configurations (e.g. correlations, outliers, grouping in data, lines, etc.).

When the number of plots is very large, an efficient compact layout
can dramatically increase the size of the visual search space. This is
where `zenplot`

’s zigzag layout outperforms the scatterplot
matrix.

This could be illustrated this on the following example.

In the `zenplots`

package the data set
`de_elect`

contains the district results of two German
federal elections (2002 and 2005) as well as a number of socio-economic
variates as well.

There are 299 districts and 68 variates yielding a possible
`choose(68,2) =`

2278 different scatterplots.

This many scatterplots will overwhelm a `pairs`

plot. In
its most compact form, the pairs plot for the first 34 variates already
occupies a fair bit of space:

(N.B. We do not execute any of these large plots simply to keep the storage needs of this vignette to a minimum. We do encourage the reader to execute the code however on their own.)

If you execute the above code you will see interesting point configurations including: some very strong positive correlations, some positive and negative correlations, non-linear relations, the existence of some outlying points, clustering, striation, etc.

Because this scatterplot matrix is for only half of the variates it
shows `choose(34,2) =`

561 different scatterplots, each one
twice. For a display of 1122 plots, only about one quarter of all 2278
pairwise variate scatterplots available in the data set appear in this
display.

A second scatterplot matrix on the remaining 34 variates would also show only a quarter of the plots. The remaining half, \(34 \times 34 = 1156\) plots, are missing from both plots.

In contrast, the `zenplot`

shows all 2278 plots at once.
In fact, because an Eulerian sequence requires a graph to be even
(i.e. each node has an even number of edges), whenever the number of
variates, \(p\), is even
`zenpath(...)`

will repeat exactly \(p/2\) pairs somewhere in the sequence it
returns.

To produce the `zenplot`

of all pairs of variates on the
German election data we call
`zenplot(de_elect[,zenpath(68)], pch=".")`

. (Again, we don’t
produce it here so as to minimize the storage footprint of this
vignette.)

```
## Try invoking the plot with the following
## zenplot(de_elect[,zenpath(68)], pch=".", n2dcol="square",col=adjustcolor("black",0.5))
```

In approximately the same visual space as the scatterplot matrix
(showing only 561 unique plots), the `zenplot`

has
efficiently and compactly laid out all 2278 different plots plus
`r ncol(de_elect)`

duplicate plots. This efficient layout
means that `zenplot`

can facilitate visual search for
interesting point configurations over much larger collections of variate
pairs – in the case of the German election data, this all possible pairs
of variates are presented simultaneously.

In contrast, all pairs loses most of the detail

Zenplots also accomodate a list of data sets whose pairwise contents are to be displayed. The need for this can arise quite naturally in many applications.

The German election data, for instance, contains socio-economic data whose variates naturally group together. For example, we might gather variates related to education into one group and those related to employment into another.

```
Education <- c("School.finishers",
"School.wo.2nd", "School.2nd",
"School.Real", "School.UED")
Employment <- c("Employed", "FFF", "Industry",
"CTT", "OS" )
```

We could plot all pairs for these two groups in a single
`zenplot`

.

```
EducationData <- de_elect[, Education]
EmploymentData <- de_elect[, Employment]
## Plot all pairs within each group
zenplot(list(Educ= EducationData[, zenpath(ncol(EducationData))],
Empl= EmploymentData[, zenpath(ncol(EmploymentData))]))
```

All pairs of education variates are plotted first in zigzag order followed by a blank plot then continuing in the same zigzag pattern by plots all pairs of employment variates.

In addition to the `Education`

and `Employment`

groups above, a number of different groupings of variates having a
shared context. For example, these might include the following:

```
## Grouping variates in the German election data
Regions <- c("District", "State", "Density")
PopDist <- c("Men", "Citizens", "Pop.18.25", "Pop.25.35",
"Pop.35.60", "Pop.g.60")
PopChange <- c("Births", "Deaths", "Move.in", "Move.out", "Increase")
Agriculture <- c("Farms", "Agriculture")
Mining <- c("Mining", "Mining.employees")
Apt <- c("Apt.new", "Apt")
Motorized <- c("Motorized")
Education <- c("School.finishers",
"School.wo.2nd", "School.2nd",
"School.Real", "School.UED")
Unemployment <- c("Unemployment.03", "Unemployment.04")
Employment <- c("Employed", "FFF", "Industry", "CTT", "OS" )
Voting.05 <- c("Voters.05", "Votes.05", "Invalid.05", "Valid.05")
Voting.02 <- c("Voters.02", "Votes.02", "Invalid.02", "Valid.02")
Voting <- c(Voting.02, Voting.05)
VotesByParty.02 <- c("Votes.SPD.02", "Votes.CDU.CSU.02", "Votes.Gruene.02",
"Votes.FDP.02", "Votes.Linke.02")
VotesByParty.05 <- c("Votes.SPD.05", "Votes.CDU.CSU.05", "Votes.Gruene.05",
"Votes.FDP.05", "Votes.Linke.05")
VotesByParty <- c(VotesByParty.02, VotesByParty.05)
PercentByParty.02 <- c("SPD.02", "CDU.CSU.02", "Gruene.02",
"FDP.02", "Linke.02", "Others.02")
PercentByParty.05 <- c("SPD.05", "CDU.CSU.05", "Gruene.05",
"FDP.05", "Linke.05", "Others.05")
PercentByParty <- c(PercentByParty.02, PercentByParty.05)
```

The groups can now be used to explore internal group relations for many different groups in the same plot. Here the following helper function comes in handy.

```
groups <- list(Regions=Regions, Pop=PopDist,
Change = PopChange, Agric=Agriculture,
Mining=Mining, Apt=Apt, Cars=Motorized,
Educ=Education, Unemployed=Unemployment, Employed=Employment#,
# Vote02=Voting.02, Vote05=Voting.05,
# Party02=VotesByParty.02, Party05=VotesByParty.05,
# Perc02=PercentByParty.02, Perc05=PercentByParty.05
)
group_paths <- lapply(groups, FUN= function(g) g[zenpath(length(g), method = "front.loaded")] )
x <- groupData(de_elect, indices=group_paths)
zenplot(x, pch = ".", cex=0.7, col = "grey10")
```

All pairs within each group are presented following the zigzag
pattern; each group is separated by an empty plot. The
`zenplot`

provides a quick overview of the pairwise
relationships between variates within all groups.

The plot can be improved some by using shorter names for the
variates. With a little work we can replace these within each group of
`x`

.

```
#
## Grouping variates in the German election data
RegionsShort <- c("ED", "State", "density")
PopDistShort <- c("men", "citizen", "18-25", "25-35", "35-60", "> 60")
PopChangeShort <- c("births", "deaths", "in", "out", "up")
AgricultureShort <- c("farms", "hectares")
MiningShort <- c("firms", "employees")
AptShort <- c("new", "all")
TransportationShort <- c("cars")
EducationShort <- c("finishers", "no.2nd", "2nd", "Real", "UED")
UnemploymentShort<- c("03", "04")
EmploymentShort <- c("employed", "FFF", "Industry", "CTT", "OS" )
Voting.05Short <- c("eligible", "votes", "invalid", "valid")
Voting.02Short <- c("eligible", "votes", "invalid", "valid")
VotesByParty.02Short <- c("SPD", "CDU.CSU", "Gruene", "FDP", "Linke")
VotesByParty.05Short <- c("SPD", "CDU.CSU", "Gruene", "FDP", "Linke")
PercentByParty.02Short <- c("SPD", "CDU.CSU", "Gruene", "FDP", "Linke", "rest")
PercentByParty.05Short <- c("SPD", "CDU.CSU", "Gruene", "FDP", "Linke", "rest")
shortNames <- list(RegionsShort, PopDistShort, PopChangeShort, AgricultureShort,
MiningShort, AptShort, TransportationShort, EducationShort,
UnemploymentShort, EmploymentShort, Voting.05Short, Voting.02Short,
VotesByParty.02Short, VotesByParty.05Short, PercentByParty.02Short,
PercentByParty.05Short)
# Now replace the names in x by these.
nGroups <- length(x)
for (i in 1:nGroups) {
longNames <- colnames(x[[i]])
newNames <- shortNames[[i]]
oldNames <- groups[[i]]
#print(longNames)
#print(newNames)
for (j in 1:length(longNames)) {
for (k in 1:length(newNames)) {
if (grepl(oldNames[k], longNames[j])) {
longNames[longNames == longNames[j]] <- newNames[k]
}
}
}
colnames(x[[i]]) <- longNames
}
zenplot(x, pch = ".", cex=0.75)
```