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I'm trying to plot a parametric equation that was partially obtained using NSolve. Here's my attempted code:

VolumeDiff[v_] = 1.7 - v
SolveR[ v_] = 
 Re[NSolve[16 v^2 - 16 v*(r^3) + 3 (r^2) + 1 == 0, r, Reals]]
EnergyPos[r_] = r/2 (r + Sqrt[r^2 - 1])
EnergyNet[r_] = EnergyPos[SolveR[r]] + EnergyPos[SolveR[VolumeDiff[r]]]
ParametricPlot[{Re[EnergyNet[x]], 1.7 - 2. x}, {x, .1, 1.6}]

Basically, I have a cubic with two variables, I solve for one given the other and try to plot two parametric equations based on that original given variable. This is supposed to be a graph of energy vs. volume difference of two bubbles attached together. However, my axis are blank. I used NSolve to isolate the real root of the cubic equation and I guess Mathematica has a problem graphing with NSolve involved. I looked all over the internet but I couldn't find any answers to this. thanks for any help! David

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You can make some progress changing the definition SolveR[v_?NumericQ] := NSolve[16 v^2 - 16 v*(r^3) + 3 (r^2) + 1 == 0, r, Reals][[1, 1, 2]]. The outer Re[] seems redundant. –  b.gatessucks Jun 13 '12 at 19:34
    
Thanks. I actually didn't have Re[] before but I figured it wouldn't hurt when trying to graph the real part of the answer. If you don't mind my asking, what does the [[1,1,2]] do at the end there? –  user1454550 Jun 13 '12 at 20:13
    
It picks the first solution, as your equation is quadratic. –  b.gatessucks Jun 13 '12 at 20:16
    
@b.gatessucks The equation is cubic as far as I see, with only one real root in the interval of interest –  belisarius Jun 13 '12 at 22:43
    
@belisarius You are right, my mistake. Thanks. –  b.gatessucks Jun 14 '12 at 7:49

1 Answer 1

up vote 3 down vote accepted

Several errors corrected. You should read about how SetDelayed ( := ) and Solve[] work.

VolumeDiff[v_] := 1.7 - v
SolveR[v_] := NSolve[16 v^2 - 16 v*(r^3) + 3 (r^2) + 1 == 0, r, Reals][[1]]
EnergyPos[r_] := r/2 (r + Sqrt[r^2 - 1])
EnergyNet[r_] := EnergyPos[r /. SolveR[r]]+EnergyPos[r /. SolveR[VolumeDiff[r]]]
ParametricPlot[{EnergyNet[x], 1.7 - 2. x}, {x, .1, 2}]

enter image description here

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Thank you so much for the help. –  user1454550 Jun 14 '12 at 14:18

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