I had some fun with this one. My strategy involves plotting the first, last and intermediate plots with slightly different settings in order to get the borders to line up. I also define some functions to ensure that all the plot colors will indeed be different unless you have upwards of ~16 million data sets to plot.

```
### indices: change this parameter to equal the number of data sets to be plotted
indices = 8
# h: height of output in pixels
h = 150.0*indices
# d: top and bottom margin in pixels
d = 75.0
### define functions to help set top/bottom margins
top(i,n,h,d) = 1.0 - (d+(h-2*d)*(i-1)/n)/h
bot(i,n,h,d) = 1.0 - (d+(h-2*d)*i/n)/h
### define some fun RGB code converter functions
# round: crude rounding function (gnuplot doesn't have this?)
# assumes a float, returns an int
round(x) = x-int(x)>=0.5?ceil(x):floor(x)
# i2h: converts a (decimal) integer between 0 and 15 to hex.
# returns a string, 0-F corresponding to 0-15
i2h(i) = i==10?'A':i==11?'B':i==12?'C':i==13?'D':i==14?'E':i==15?'F':sprintf('%d',i)
# i2r: converts an integer to an RGB code.
# returns a string (RGB code) of length 6, 000000-FFFFFF corresponding to 0-16777215
# changing the last division to 15 instead of 16 prevents colors being too faint
i2r5(i) = i2h(i/(15**5))
i2r4(i) = i2h(i%(16**5)/(15**4))
i2r3(i) = i2h(i%(16**5)%(16**4)/(15**3))
i2r2(i) = i2h(i%(16**5)%(16**4)%(16**3)/(15**2))
i2r1(i) = i2h(i%(16**5)%(16**4)%(16**3)%(16**2)/(15**1))
i2r0(i) = i2h(i%(16**5)%(16**4)%(16**3)%(16**2)%(16**1))
i2r(i) = i2r5(i).i2r4(i).i2r3(i).i2r2(i).i2r1(i).i2r0(i)
# rgb_iter: returns the i-th of n RGB codes, evenly spaced across the spectrum
rgb_iter(i, n) = '#'.i2r(round((i-1)*(16777215.0/(n-1))))
### first set up some basic plot parameters
set term png enhanced size 800,h font 'Courier-Bold,14'
set output 'waves.png'
set title 'Wave propagation by geophones'
set ylabel 'Wave'
set xrange [1400:]
set yrange [-0.15:0.15]
set ytics ('-0.1' -0.1, '0.0' 0.0, '0.1' 0.1)
set key out right
### now make plots
set multiplot layout indices,1
### first plot
set border 14
set tmargin at screen top(1,indices,h,d)
set bmargin at screen bot(1,indices,h,d)
unset xtics
plot 'temp.dat' index 0 w lines lw 3 lc rgb rgb_iter(1,indices) title 'Geophone 1'
unset title
### intermediate plots
set border 10
unset xlabel
do for [i=1:indices-2] {
set tmargin at screen top(i+1,indices,h,d)
set bmargin at screen bot(i+1,indices,h,d)
plot 'temp.dat' index i w lines lw 3 lc rgb rgb_iter(i+1,indices) title sprintf('Geophone %d', i + 1)
}
### last plot
set border 11
set tmargin at screen top(indices,indices,h,d)
set bmargin at screen bot(indices,indices,h,d)
set xtics nomirror
set xlabel 'Iterations'
plot 'temp.dat' index (indices-1) w lines lw 3 lc rgb rgb_iter(indices,indices) title sprintf('Geophone %d', indices)
unset multiplot
```

The output on your sample data set looks like this:

The sizes of the top/bottom plots aren't quite perfect, and as mgilson said it would probably take some fiddling with `set xmargin at screen ...`

commands to make all the plot sizes equal.

(If nothing else those int->RGB converter can be handy for specialized applications; I also have functions going from RGB codes to ints.)

EDIT: I updated the script so all the plots will have the same height.