# Plotting arrows at the edges of a curve

Inspired by this question at ask.sagemath, what is the best way of adding arrows to the end of curves produced by `Plot`, `ContourPlot`, etc...? These are the types of plots seen in high school, indicating the curve continues off the end of the page.

After some searching, I could not find a built-in way or up-to-date package to do this. (There is ArrowExtended, but it's quite old).

The solution given in the ask.sagemath question relies on the knowledge of the function and its endpoints and (maybe) the ability to take derivatives. Its translation into Mathematica is

``````f[x_] := Cos[12 x^2]; xmin = -1; xmax = 1; small = .01;
Plot[f[x],{x,xmin,xmax}, PlotLabel -> y==f[x], AxesLabel->{x,y},
Epilog->{Blue,
Arrow[{{xmin,f[xmin]},{xmin-small,f[xmin-small]}}],
Arrow[{{xmax,f[xmax]},{xmax+small,f[xmax+small]}}]
}]
``````

An alternative method is to simply replace the `Line[]` objects generate by `Plot[]` with `Arrow[]`. For example

``````Plot[{x^2, Sin[10 x], UnitStep[x]}, {x, -1, 1},
PlotStyle -> {Red, Green, {Thick, Blue}},
(*AxesStyle -> Arrowheads[.03],*) PlotRange -> All] /.
``````

But this has the problem that any discontinuities in the lines generate arrow heads where you don't want them (this can often be fixed by the option `Exclusions -> None`). More importantly, this approach is hopeless with `CountourPlot`s. Eg try

``````ContourPlot[x^2 + y^3 == 1, {x, -2, 2}, {y, -2, 1}] /.
``````

(the problems in the above case can be fixed by the rule, e.g., `{a___, l1_Line, l2_Line, b___} :> {a, Line[Join[l2[[1]], l1[[1]]]], b}` or by using appropriate single headed arrows.).

As you can see, neither of the above (quick hacks) are particularly robust or flexible. Does anyone know an approach that is?

-
I can suggest to find points generated by Plot lying on/out – Alexey Popkov Feb 22 '11 at 12:51
@Alexey: I'm not quite sure what you're suggesting... – Simon Feb 22 '11 at 21:17
@Simon I apologize, the sentence is incomplete. In the case of discontinuities I can suggest to find points lying on the edges of `PlotRange`. For example: `xmin = -2 Pi; xmax = Pi; Plot[Tan[x], {x, xmin, xmax}, Exclusions -> {Cos[x] == 0}] /. {x_Line?(Abs[#[[1, 1, 1]] - xmin] < 1*^-6 && Abs[#[[1, -1, 1]] - xmax] < 1*^-6 &) :> Sequence[Arrowheads[{-.04, .04}], Arrow[x]], x_Line?(Abs[#[[1, 1, 1]] - xmin] < 1*^-6 &) :> Sequence[Arrowheads[{-.04, 0}], Arrow[x]], x_Line?(Abs[#[[1, -1, 1]] - xmax] < 1*^-6 &) :> Sequence[Arrowheads[{0, .04}], Arrow[x]] }`. – Alexey Popkov Feb 23 '11 at 2:43
@Alexey: I thought that was what you meant. Thanks for the code - if you put it in an answer, I'll vote it up. It's something I also thought of, but what happens if the plot range means that a line exits the plot at the top or bottom instead of the sides? You'd have to extract the PlotRange from the generated plot and use that in the rules... – Simon Feb 27 '11 at 6:24
@Simon Recently found this users.dimi.uniud.it/~gianluca.gorni/Mma/Mma.html (not tested) – Dr. belisarius Jun 9 '11 at 3:25

The following seems to work, by sorting the segments first:

``````f[x_] := {E^-x^2, Sin[10 x], Sign[x], Tan[x], UnitBox[x],
IntegerPart[x], Gamma[x],
Piecewise[{{x^2, x < 0}, {x, x > 0}}], {x, x^2}};

arrowPlot[f_] :=
Plot[{#}, {x, -2, 2}, Axes -> False, Frame -> True, PlotRangePadding -> .2] /.

{Hue[qq__], a___, x___Line} :> {Hue[qq], a, SortBy[{x}, #[[1, 1, 1]] &]} /.

{a___,{Line[x___], d___, Line[z__]}} :>

{a___,{Line[x__]}}:> List[Arrowheads[{-.06, 0.06}], a, Arrow[x]] & /@ f[x];

arrowPlot[f]
``````

-
@belisarius : there was a question/answer few months ago how to make traditional 3d axes with arrows in Mathematica and I can't find it anymore, do you remember any keywords from it? – Yaroslav Bulatov Feb 26 '11 at 4:34
@Yaro found it math.stackexchange.com/questions/16498/… – Dr. belisarius Feb 26 '11 at 5:19
ahh, it's on different site, that's why I couldn't find it...thanks! – Yaroslav Bulatov Feb 26 '11 at 5:45
@belisarius: I completely missed your series of revisions, thanks for all of the effort. It's looking good! Unfortunately, your sort fails for the `ContourPlot` given in the question, since it is constructed using a `GraphicsComplex` object. This can be fixed by using `Normal`. But then you still run into the problem that your rules don't like plots with 'Tooltip'... – Simon Feb 27 '11 at 6:38
@belisarius: I figured out what's wrong. The `Sequence[]` makes the `Tooltip` get way too many arguments. Replace `Sequence[]` with `List[]` and it's all good. – Simon Feb 27 '11 at 6:46

Inspired by both Alexey's comment and belisarius's answers, here's my attempt.

``````makeArrowPlot[g_Graphics, ah_: 0.06, dx_: 1*^-6, dy_: 1*^-6] :=
Module[{pr = PlotRange /. Options[g, PlotRange], gg, lhs, rhs},
gg = g /. GraphicsComplex -> (Normal[GraphicsComplex[##]] &);
lhs := Or@@Flatten[{Thread[Abs[#[[1, 1, 1]] - pr[[1]]] < dx],
Thread[Abs[#[[1, 1, 2]] - pr[[2]]] < dy]}]&;
rhs := Or@@Flatten[{Thread[Abs[#[[1, -1, 1]] - pr[[1]]] < dx],
Thread[Abs[#[[1, -1, 2]] - pr[[2]]] < dy]}]&;
gg = gg /. x_Line?(lhs[#]&&rhs[#]&) :> {Arrowheads[{-ah, ah}], Arrow@@x};
gg = gg /. x_Line?lhs :> {Arrowheads[{-ah, 0}], Arrow@@x};
gg = gg /. x_Line?rhs :> {Arrowheads[{0, ah}], Arrow@@x};
gg
]
``````

We can test this on some functions

``````Plot[{x^2, IntegerPart[x], Tan[x]}, {x, -3, 3}, PlotStyle -> Thick]//makeArrowPlot
``````

And on some contour plots

``````ContourPlot[{x^2 + y^2 == 1, x^2 + y^2 == 6, x^3 + y^3 == {1, -1}},
{x, -2, 2}, {y, -2, 2}] // makeArrowPlot
``````

One place where this fails is where you have horizontal or vertical lines on the edge of the plot;

``````Plot[IntegerPart[x],{x,-2.5,2.5}]//makeArrowPlot[#,.03]&
``````

This can be fixed by options such as `PlotRange->{-2.1,2.1}` or `Exclusions->None`.

Finally, it would be nice to add an option so that each "curve" can arrow heads only on their boundaries. This would give plots like those in Belisarius's answer (it would also avoid the problem mentioned above). But this is a matter of taste.

-
"It's full of arrows!" :) – Dr. belisarius Feb 27 '11 at 7:58

The following construct has the advantage of not messing with the internal structure of the Graphics structure, and is more general than the one suggested in ask.sagemath, as it manage PlotRange and infinities better.

``````f[x_] = Gamma[x]

{plot, evals} =
Reap[Plot[f[x], {x, -2, 2}, Axes -> False, Frame -> True,
PlotRangePadding -> .2, EvaluationMonitor :> Sow[{x, f[x]}]]];

{{minX, maxX}, {minY, maxY}} = Options[plot, PlotRange] /. {_ -> y_} -> y;
ev = Select[evals[[1]], minX <= #[[1]] <= maxX && minY <= #[[2]] <= maxY &];
seq = SortBy[ev, #[[1]] &];
arr = {Arrow[{seq[[2]], seq[[1]]}], Arrow[{seq[[-2]], seq[[-1]]}]};
``````

``````Show[plot, Graphics[{Red, arr}]]
``````

Edit

As a function:

``````arrowPlot[f_, interval_] := Module[{plot, evals, within, seq, arr},
within[p_, r_] :=
r[[1, 1]] <= p[[1]] <= r[[1, 2]] &&
r[[2, 1]] <= p[[2]] <= r[[2, 2]];

{plot, evals} = Reap[
Plot[f[x], Evaluate@{x, interval /. List -> Sequence},
Axes -> False,
Frame -> True,
EvaluationMonitor :> Sow[{x, f[x]}]]];

seq = SortBy[Select[evals[[1]],
within[#,
Options[plot, PlotRange] /. {_ -> y_} -> y] &], #[[1]] &];

arr = {Arrow[{seq[[2]], seq[[1]]}], Arrow[{seq[[-2]], seq[[-1]]}]};
Show[plot, Graphics[{Red, arr}]]
];

arrowPlot[Gamma, {-3, 4}]
``````

Still thinking what is better for ListPlot & al.

-
Cool! How would this generalize, to say, a `ListPlot` of experimental data? (assuming you were lazy and didn't put the data into an interpolating function and then use `Plot` like above)? – Simon Feb 27 '11 at 21:30