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I'd like to display a directed circular arc in Mathematica, using something as simple as Arrow. The best I have been able to come up with is this example that nails an Arrow onto one end of a circular arc. But I suspect there is a more direct way to achieve the same effect.

   Arrow[{{Cos[\[Theta] + If[\[Theta] < start, .01, -.01]], 
           Sin[\[Theta] + If[\[Theta] < start, .01, -.01]]}, 
          {Cos[\[Theta]], Sin[\[Theta]]}}],
   Circle[{0, 0}, 1, {start, \[Theta]}]},
PlotRange -> 2], 
{{\[Theta], .7 start}, 0, 2 start} 


Arrow accepts BSplineCurves and BezierCurvesbut I can't get them to stay on a circular arc. Tube accepts the formula for a curve in 3D but I can't figure out how to get it to work in 2D.

All suggestions are welcome. If your solution works for any *2D curve*, all the better!


I learned quite a bit from the suggestions: Mark McClure showed that Arrow itself can handle the demands when given a list of points.

yoda gave a fairly general solution using ParametricPlot.

I ended up finding belisarius' suggestions the most helpful. His approach was to work on minor variations of familiar graphical objects. In the end, I cautiously chose to define a new object, arcArrow, that employs the parameters of Circle: center, radius, {start,finish}. Unprotect still scares me! Anyway, here's what I settled with. I also stubbornly held on to some features of my original approach.

   arcArrow[center, radius, {start, end}],
   PointSize[Large], Blue, If[showCenter, Point[center]]},
  PlotRange -> p, ImageSize -> 250],
 {{start, \[Pi]/2}, -2 \[Pi], 2 \[Pi], ImageSize -> Small},
 {{end, 0}, -2 \[Pi], 2 \[Pi], ImageSize -> Small},
 {{radius, 1}, 1/2, 4, ImageSize -> Small},
 {{center, {0, 0}}, {-p, -p}, {p, p}, Slider2D},
 {showCenter, {True, False}},

 Initialization :> {p = 3;
   arcArrow[a_, r_, {start_, end_}] :=
    {Circle[a, r, {start, end}], 
     Arrow[{a + r {Cos[end + If[end < start, .01, -.01]], 
                   Sin[end + If[end < start, .01, -.01]]}, 
            a + r {Cos[end], Sin[end]}}]} }]

final version

share|improve this question
This link might be of interest, in particular the workaround by Bill Rowe. – TomD Apr 18 '11 at 16:40
@TomD Yes. They are discussing just the issue I raised. One of the solutions corresponds to what I came up with. Another matches Mark McClure's suggestion. Funny, but when I thought of Line (or Arrow) very segmented images came to mind. I didn't think about really tiny segments! – DavidC Apr 18 '11 at 17:07
up vote 5 down vote accepted

Using Circle[ ]:

f[s_Circle] := 
 s /. Circle[a_, r_, {start_, end_}] :>
      ({s,Arrow[{# - r/10^6 {-Sin@end, Cos@end}, #}]} &[a+r {Cos@end, Sin@end}]) 

Graphics@f[Circle[{0, 0}, 1, {4 Pi/3, 2 Pi}]]

enter image description here


Redefining the default Circle[ ] behavior:

Circle[a_: {0, 0}, r_: 1, {start_, end_}] :=
  Block[{$inMsg = True},
    {Circle[a, r, {start, end}],
     Circle[a, r, {start, end}] /. 
        ar_, {astart_, aend_}] :> (Arrow[If[start < end, #, Reverse@#]] &@
             {# - r/10^6 {-Sin@end, Cos@end}, #} &
               [aa + ar {Cos@aend, Sin@aend}])}
    ] /; ! TrueQ[$inMsg];

enter image description here

share|improve this answer
A very straightforward, clean approach. You hand f a graphics object (a circular arc). It returns the arc with an arrowhead. – DavidC Apr 18 '11 at 19:05
@David That's the idea. if you have your program structured with Circle[ ], you don't have to change that. And you may also redefine Circle[ ] to do this automagically – Dr. belisarius Apr 18 '11 at 19:09
@David See edit for redefining the default Circle[ ] behavior – Dr. belisarius Apr 18 '11 at 19:28
@belisarius The format is certainly more natural than f[]. I'm wondering, however: why not use circle rather than Circle? Don't you risk messing up the definition of Circle? – DavidC Apr 18 '11 at 19:44
@David I did exactly that. I redefined Circle[ ] so that all your arcs will show arrows without any other program modification :) – Dr. belisarius Apr 18 '11 at 19:55

You can also add an arrow to the end point of an arc like so:

circle[x_] = {Cos[x], Sin[x]};
ParametricPlot[{0.9 circle[x], 0.7 circle[x + Pi/3], 0.4 circle[-x]}, 
 {x, Pi/4, Pi/2}, PlotRange -> {-1, 1}, Axes -> False] 
/.Line[x__] :> Sequence[Arrowheads[.03], Arrow[x]]

enter image description here

This is probably much easier to control, as you can set the radius and arc length programmatically and just replace the arrows in the end.

You should also take a look at the discussion on adding arrows at the edges of a curve. There are a lot of good approaches there, perhaps better than this one. I personally found Simon's answer to his own question to be a pretty nifty little function that I have in my little 'functions from the internet' collection, and have used it more than once to place arrows on graphs that continue outside the plot.


The way I've defined it above, it places an arrow at the end of the line. For e.g., if you plot a line from L to R, it places it on the right and left otherwise. So in the example, positive increase in x is counter-clockwise and hence the arrows in that direction. Increase in the negative dir will produce a clockwise arrow. To avoid a second plot command, I simply changed x to -x in the third function in the list, which produced the same effect in the golden colored curve.

More generally, you can change orientation of the arrows by changing the inputs to Arrowheads as follows:

Arrows going the other way round

enter image description here

Arrows on both ends

enter image description here

Inverted arrowheads

enter image description here

share|improve this answer
Very nice! It handles any parametric plot. I couldn't figure out what the delayed replacement rule was doing until I looked under the hood with InputForm@ParametricPlot[{0.9 circle[x], 0.7 circle[x + Pi/3], 0.4 circle[-x]}, {x, Pi/4, Pi/2}, PlotRange -> {-1, 1},Axes -> True] and found Line. Thanks also for the interesting link on arrows. – DavidC Apr 18 '11 at 19:30
The arrows seem to work only in counter-clockwise direction. – DavidC Apr 18 '11 at 23:52
@David: Pl. see my edit. – abcd Apr 19 '11 at 0:39

Arrow accepts a list of points of arbitrary length. Thus, perhaps something like so.

  Arrow[Table[{Cos[t], Sin[t]}, {t, 0, T, Sign[T] Pi/100}]],
  PlotRange -> 1.1], {{T, 0}, -2 Pi, 2 Pi}]
share|improve this answer
@Mark Thanks. That's certainly more elegant than my approach. – DavidC Apr 18 '11 at 16:10
The path I want to implement is actually a chain of circular arcs in which the center and radius change parameters every so often. A table can easily accumulate such changes; it just takes more points (although ones that have been produced by a slightly different set of parameters). – DavidC Apr 18 '11 at 18:59
@Mark Only counter-clockwise arrows? – DavidC Apr 18 '11 at 23:51
@David Why only clock-wise? If you place a minus sign in front of the Sin[t], you'll find that the arrow travels in the other direction. You can replace {Cos[t],Sin[t]} with any formula you want to generate all manner of curves. – Mark McClure Apr 19 '11 at 2:38
@Mark. Yes, I see. But because I'd like to control it via a slider, it's not clear how to implement it. Thanks for your help. – DavidC Apr 19 '11 at 11:32

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