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Run the following code In Mathematica:

r=6197/3122;
p[k_,w_]:=Sqrt[w^2/r^2-k^2];q[k_,w_]:=Sqrt[w^2-k^2];
a[k_,w_,p_,q_]:=(k^2-q^2)^2 Sin[p]Cos[q]+4k^2 p q Cos[p]Sin[q]
a[k_,w_]:=a[k,w,p[k,w],q[k,w]];
ContourPlot[a[k,w]==0,{w,0,6},{k,0,14}]

This gives me very inaccurate curves:

The curves obtained from the code above are very inaccurate

I have tried setting the PlotPoints and WorkingPrecision options of ContourPlot to 30 and 20 respectively, to no avail. You will also notice that the only numerical parameter, r, is an exact rational number. I don't know what else to try. Thanks.

Edit: The curves I expect to get are the three black ones (marked A1, A2, and A3) on the following picture

Expected curves (the black ones)

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Maybe you can ask it at math.stackexchange.com –  plaes Aug 17 '11 at 6:20
4  
@plaes: This is not a question about Mathematics. It is a question about Mathematica. –  becko Aug 17 '11 at 6:23
    
Can you include a picture of roughly what you expect? –  Mr.Wizard Aug 17 '11 at 6:28
    
@Mr.Wizard: Done. –  becko Aug 17 '11 at 6:32
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5 Answers

up vote 6 down vote accepted

Are you sure about the picture and/or the definition for a? From the definition of a it follows that a[k,w]==0 on k==w but that curve doesn't appear in your picture.

Anyway, assuming that the definition of a is right, the problem with plotting the contours is that in the domain w^2/r^2-k^2<0, both p[k,w] and Sin[p[k,w]] become purely imaginary which means that a[k,w] becomes purely imaginary as well. Since ContourPlot doesn't like complex valued functions only the parts of the contours in the domain w^2/r^2>=k^2 are plotted.

Not that Sin[p[k,w]]/p[k,w] is real for all values of k and w (and it's nicely behaved in the limit p[k,w]->0). Therefore, to get around the problem of a becoming complex you could plot the contours a[k,w]/p[k,w]==0 instead:

ContourPlot[a[k, w]/p[k, w] == 0, {w, 0, 6}, {k, 0, 14}]

Result

contour plot of a/p==0

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You were right. I had a mistake in the definition of a. I fixed it. Thanks. –  becko Aug 18 '11 at 1:42
    
Dividing by p fixed it. I didn't even have to set PlotPoints, or anything! Thanks! –  becko Aug 18 '11 at 1:45
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I have got something very similar to what you expect by separate plotting of real and imaginary parts of the l.h.s. of the equation:

ContourPlot[{Re@a[k, w] == 0, Im@a[k, w] == 0}, {w, 0, 6}, {k, 0, 14},
  MaxRecursion -> 7]

enter image description here

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Your function gives complex numbers in the region of the contour lines you show. Is that what you expect? You can see the region that is real here:

ContourPlot[a[k, w], {w, 0, 6}, {k, 0, 14}]

enter image description here

I get something in some ways closer to your lines if I use:

ContourPlot[a[w, k] == 0, {w, 0, 6}, {k, 0, 14}]

enter image description here

Is it possible there is a transcription error?

(My apologies if this is unhelpful.)

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There was a transcription error (pointed out by Heike in the answer above) and it's fixed now. However, it is a[k,w], not a[w,k], and there's no error there. Thanks anyway. –  becko Aug 18 '11 at 1:47
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p ans q will be real valued only if w^2 - k^2 and w^2/r^2 - k^2 are both nonnegative. w^2 / r^2 - k^2 will only be nonnegative in the following area of your plot region:

enter image description here

Therefore everything else will be cut off by ContourPlot. Perhaps you need to make some corrections to the equations (you only need the real part? magnitude?) I don't believe the curves Mathematica gives you are very inaccurate. Otherwise the way to go to increase accuracy of the contours if increasing PlotPoints and MaxRecursion (say, to 50 and 4).

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Try to play with the parametrization of your equations. For example, define a=w^2-k^2 and b=w^2/r^2-k^2, then solve for a and b and map them onto k and w

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