# The Problem

I have data that I would like to plot in a line-graph with a log-scale on the y-axis using ggplot2. Unfortunately, some of my values go all the way down to zero. The data represents relative occurences of a feature in dependence of some parameters. The value zero occurs when that feature is not observed in a sample, which means that it occurs very seldomly, or indeed never. These zero values cause a problem in the log plot.

The following code illustrates the problem on a simplified data set. In reality the data set consists of more points, so the curve looks smoother, and also more values for the parameter `p`.

``````library(ggplot2)

dat <- data.frame(x=rep(c(0, 1, 2, 3), 2),
y=c(1e0, 1e-1, 1e-4, 0,
1e-1, 1e-3, 0, 0),
p=c(rep('a', 4), rep('b', 4)))
qplot(data=dat, x=x, y=y, colour=p, log="y", geom=c("line", "point"))
``````

Given the data above, we would expect two lines, the first one should have three finite points on a log plot, the second one should have only two finite points on a log plot. However, as you can see this produces a very misleading plot. It looks like the blue and red line are both converging to a value between 1e-4 and 1e-3. The reason is that `log(0)` gives `-Inf`, which ggplot just puts on the lower axis.

# My Question

What's the best way to deal with this in R with ggplot2? By best I mean in terms of efficiency, and being ideomatic R (I'm fairly new to R).

The plot should indicate that these curves go down to "very small" after x=2 (red), or x=1 (blue), respectively. Ideally, with a vertical line downwards from the last finite point. What I mean by that is demonstrated in the following.

# My Attempt

Here I'll describe what I've come up with. However, given that I'm fairly new to R, I suspect that there might a much better way.

``````library(ggplot2)
library(scales)

dat <- data.frame(x=rep(c(0, 1, 2, 3), 2),
y=c(1e0, 1e-1, 1e-4, 0,
1e-1, 1e-3, 0, 0),
p=c(rep('a', 4), rep('b', 4)))
``````

Same data as above.

Now, I'm going through each unique parameter `p`, find the x coordinate of the last finite point, and assign it to the x coordinates of all points where y is zero. That is to achieve a vertical line.

``````for (p in unique(dat\$p)) {
dat\$x[dat\$p == p & dat\$y == 0] <- dat\$x[head(which(dat\$p == p & dat\$y == 0), 1) - 1]
}
``````

At this point the plot looks as follows. The vertical lines are there. However, there are also points. These are misleading as they indicate that there was an actual data point there, which is not true.

To remove the points I duplicate the y data (seems wasteful), let's call it `yp`, and replace zero by `NA`. Then I use that new `yp` as the y aesthetics for `geom_point`.

``````dat\$yp <- dat\$y
dat\$yp[dat\$y == 0] <- NA

ggplot(dat, aes(x=x, y=y, colour=p)) +
geom_line() +
geom_point(aes(y=dat\$yp)) +
scale_y_continuous(trans=log10_trans(),
breaks = trans_breaks("log10", function(x) 10^x),
labels = trans_format("log10", math_format(10^.x)))
``````

Where I've used `ggplot` instead of `qplot` so that I can give different aesthetics to `geom_line` and `geom_point`.

Finally, the plot looks like this. What is the right way to do this?

• The idiomatic way of dealing with this is not to plot zero values on a log scale. A way around this problem is to use a transformation such as `log(y + 1)` instead. Oct 24, 2016 at 13:32
• Have you considered alternative transformations? A higher order n-th root would not have the same issues. Oct 24, 2016 at 13:32
• Unfortunately, it has to be a log scale to base 10. I need to compare my data to an existing plot. Oct 24, 2016 at 13:40

For me, I use

``````+ scale_y_continuous(trans=scales::pseudo_log_trans(base = 10))
``````

If you're using ggplot, you can use `scales::pseudo_log_trans()` as your transformation object. This will replace your -inf with 0.

From the docs (https://scales.r-lib.org/reference/pseudo_log_trans.html),

A transformation mapping numbers to a signed logarithmic scale with a smooth transition to linear scale around 0.

`pseudo_log_trans(sigma = 1, base = exp(1))`

For example, my scale expression looks like this:

``````+ scale_fill_gradient(name = "n occurrences", trans="pseudo_log")
``````

Unconfirmed, but you probably need to include the scales library:

``````require("scales")
``````

The simplest way would be to add a small value to each of the numbers. Example,

``````df <- mutate(df, log_var = log(var + 0.01))
ggplot(df, aes(x = log_var)) + geom_histogram()
``````