The `theta`

value of 30 arc degrees is a data-space angle. It is only appropriate for use in data-space calculations such as in your call to `segments()`

that draws the diagonal lines.

The `srt`

graphical parameter specifies text rotation in device-space, meaning the text will be rendered to follow the specified angle on the physical device, regardless of the aspect ratio of the underlying plot area.

The relationship between the data and device spaces is determined dynamically and is influenced by a number of factors:

- The device dimensions (GUI window client area size or destination file size).
- Figure multiplicity (if using a multifigure plot; see the
`mfrow`

and `mfcol`

graphical parameters).
- Any inner and outer margins (most plots have inner margins, outer is rare).
- Any internal spacing (see the
`xaxs`

and `yaxs`

graphical parameters).
- The plot range (
`xlim`

and `ylim`

).

The correct way to do what you want is to (1) dynamically query for the data-space aspect ratio as measured in device-space distance units and (2) use it to transform `theta`

from a data-space angle to a device-space angle.

**1: Query for aspect ratio**

We can calculate the aspect ratio by finding the device-space equivalent of 1 data-space unit along the x-axis, do the same for the y-axis, and then take the ratio `y/x`

. The functions `grconvertX()`

and `grconvertY()`

are made for this purpose.

```
calcAspectRatio <- function() abs(diff(grconvertY(0:1,'user','device'))/diff(grconvertX(0:1,'user','device')));
```

The conversion functions operate on individual coordinates, not distances. But they are vectorized, so we can pass `0:1`

to convert two coordinates that are 1 unit apart in the input coordinate system and then take a `diff()`

to get the equivalent unit distance in the output coordinate system.

You may be wondering why the `abs()`

call was necessary. For many graphics devices, the y-axis increases downwards rather than upwards, so lesser data-space coordinates will convert to greater device-space coordinates. Thus the result of the first `diff()`

call in these cases will be negative. Theoretically this should never happen with the x-axis, but we may as well wrap the entire quotient in the `abs()`

call just in case.

**2: Transform theta from data-space to device-space**

There are several mathematical approaches that could be taken here, but I think the simplest is to take the `tan()`

of the angle to get the trigonometric `y/x`

ratio, multiply it by the aspect ratio, and then convert back to an angle using `atan2()`

.

```
dataAngleToDevice <- function(rad,asp) {
rad <- rad%%(pi*2); ## normalize to [0,360) to make following ops easier
y <- abs(tan(rad))*ifelse(rad<=pi,1,-1)*asp; ## derive y/x trig ratio with proper sign for y and scale by asp
x <- ifelse(rad<=pi/2 | rad>=pi*3/2,1,-1); ## derive x component with proper sign
atan2(y,x)%%(pi*2); ## use atan2() to derive result angle in (-180,180], and normalize to [0,360)
}; ## end dataAngleToDevice()
```

As a brief aside, I find this to be a very interesting mathematical transformation. Angles 0, 90, 180, and 270 are not affected, which makes sense; a change in aspect ratio should not affect those angles. A vertical elongation pulls angles towards the y-axis, and a horizontal elongation pulls angles towards the x-axis. At least that's how I visualize it.

So, putting this all together, we have the below solution. Note that I rewrote your code for more concision and made a few minor changes, but mostly it's the same. Obviously the most important change is that I added a call to `dataAngleToDevice()`

around `theta`

, with the second argument passing `calcAspectRatio()`

. Additionally I used smaller (fontwise) but longer (stringwise) column names to more clearly demonstrate the angle of the text, I moved the text closer to the diagonal lines, I stored `theta`

in radians from the beginning, and I reordered things a bit.

```
nRows <- 5;
nColumns <- 3;
theta <- 30*pi/180;
rowLabels <- paste0('row',1:5);
colLabels <- do.call(paste,rep(list(paste0('col',1:3)),5L));
plot.new();
par(mar=c(1,8,5,1),xpd=NA);
plot.window(xlim=c(0,nColumns),ylim=c(0,nRows));
segments(0:nColumns,0,0:nColumns,nRows,lwd=0.5);
segments(0,0:nRows,nColumns,0:nRows,lwd=0.5);
text(0,seq(0.5,nRows,1),rowLabels,pos=2);
## column name separators
segments(0:(nColumns-1),nRows,1:nColumns,nRows+tan(theta),lwd=0.5);
text(seq(0.3,nColumns,1),nRows+0.1,colLabels,pos=4,srt=dataAngleToDevice(theta,calcAspectRatio())*180/pi);
```

Here's a demo with a roughly square aspect ratio:

Wide:

And tall:

I made a plot of the transformation:

```
xlim <- ylim <- c(0,360);
xticks <- yticks <- seq(0,360,30);
plot(NA,xlim=xlim,ylim=ylim,xlab='data',ylab='device',axes=F);
box();
axis(1L,xticks);
axis(2L,yticks);
abline(v=xticks,col='grey');
abline(h=yticks,col='grey');
lineParam <- data.frame(asp=c(1/1,1/2,2/1,1/4,4/1),col=c('black','darkred','darkblue','red','blue'),stringsAsFactors=F);
for (i in seq_len(nrow(lineParam))) {
x <- 0:359;
y <- dataAngleToDevice(x*pi/180,lineParam$asp[i])*180/pi;
lines(x,y,col=lineParam$col[i]);
};
with(lineParam[order(lineParam$asp),],
legend(310,70,asp,col,title=expression(bold(aspect)),title.adj=c(NA,0.5),cex=0.8)
);
```

`asp`

works. From the`plot.window`

help file: "If asp is a finite positive value then the window is set up so that one data unit in the x direction is equal in length to asp * one data unit in the y direction" Now, if you don't specify asp,`y1 = nRows + tan(theta * pi/180)`

breaks, because the radians depends on the radius which is being scaled through window resizing independent of the angle (which remains constant). So, I don't se a solution in base R, but again, I'd love to be proven otherwise!`asp`

and scale`theta`

by it long with`x1 = 1:nColumns * asp`

when you make the header lines