In Mathematica, how do you plot a horizontal line at a given number? How do you plot a vertical line at a given number?
5 Answers
If you're actually using Plot (or ListPlot, et c.), the easiest solution is to use the GridLines option, which lets you specify the x and yvalues where you want the lines drawn. For instance:
Plot[Sin[x], {x, 0, 2 \[Pi]},
GridLines > {{0, \[Pi]/2, \[Pi], 3 \[Pi]/2, 2 \[Pi]},
{1, Sqrt[3]/2, 1/2, 0, 1/2, Sqrt[3]/2, 1}}]
EDIT to add:
Of course, this solution works if you just want to draw a line at a single, given number. For instance, if you want to reproduce the second example from dreeve's answer:
Plot[Sin[x], {x, 0, 2 Pi},
GridLines > {{4}, {}}]
For the case of horizontal lines when using Plot
the easiest trick is to just include additional constant functions:
Plot[{Sin[x], .75}, {x, 0, 2Pi}]
For vertical lines, there's the Epilog
option for Plot
and ListPlot
:
Plot[Sin[x], {x, 0, 2Pi}, Epilog>Line[{{4,100}, {4,100}}]]
But probably the best is the GridLines
option given in Pillsy's answer.

1+1: I'd never thought of or come across the first suggestion you make @dreeves. May 25, 2010 at 9:29
One approach would be to add Line
graphic primitives to your graphics:
p1 = Plot[Sin[x], {x, 2*Pi,2*Pi}];
l1 = Graphics@Line[{{2Pi,.75},{2Pi,.75}}]; (* horizontal line at y==.75 *)
Show[p1,l1]
Another approach would be to fiddle around with GridLines
.
Use the Gridlines command like so:
Plot[
1/(15*E^((x  100)^2/450)*Sqrt[2*Pi]),
{x, 55, 145},
GridLines > {{85, 115}, {}}
]
TRANSLATION In the code above I plot a normal curve:
1/(15*E^((x  100)^2/450)*Sqrt[2*Pi])
Then tell the plot what part of the xaxis I want it to display:
{x, 55, 145}
Then I add the vertical gridlines where I want them at 85 and 115.
GridLines > {{85, 115}, {}}
Note you need to provide the blank {} where Gridlines
would expect the horizontal grid lines locations.
An alternative is to think of the vertical line as a straight line of infinite slope. So for a vertical line at located at x=2*pi, we can do something like this:
Plot[{Sin[x], 10^10 (x  2 \[Pi])}, {x, 0, 10}, PlotRange > {1, 1}]
Note that the term 10^10 mimics an infinite slope. If you do not use the option PlotRange > {1, 1}, the "dominant" function is the straight line so the Sin[x] function do effectively appears as an horizontal line.