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I am very new to Mathematica, and I am trying to solve the following problem.

  1. I have a cubic equation of the form Z = aZ^3 + bZ^2 + a + b. The first thing I want to do is to get a function that solves this analytically for Z and chooses the minimal positive root for that, as a function of a and b.

I thought that in order to get the root I could use:

Z = Solve[z == az^3 + bz^2 + a + b, z];

It seems like I am not quite getting the roots, as I would expect using the general cubic equation solution formula.

  1. I want to integrate the minimal positive root of Z over a and b (again, preferably analytically) from 0 to 1 for a and for a to 1 for b.

I tried

Y = Integrate[Z, {a, 0, 1}, {b, a, 1}];

and that does not seem to give any formula or numerical value, but just returns an integral. (Notice I am not even sure how to pick the minimal positive root, but I am playing around with Mathematica to try to figure it out.)

Any ideas on how to do this?

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2 Answers 2

Spaces between a or b and z are important. You can get the roots by:

sol = z /. Solve[z == a z^3 + b z^2 + a + b, z]

However, are you sure this expression has a solution as you expect? For a=0.5 and b=0.5, the only real root is negative.

sol /. {a->0.5, b->0.5}
{-2.26953,0.634765-0.691601 I,0.634765+0.691601 I}
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thanks! that works. How would I pick from sol, as a function of p and q, the smallest positive root? –  kloop Apr 18 '13 at 20:07
    
Good question. I've been thinking about it. The long, secure way I can think of is something like Select[Sort[sol /. {a->0,5, b->0.5}], Element[#, Reals] && # >= 0 &, 1] that you could put in some function. However, it will return {} if there are no positive roots. I suppose there are better ways, I'm not an expert myself. It won't give you a analytical solution, in any case. –  siritinga Apr 18 '13 at 20:09
    
I tried Min[Select[sol, Positive]], but the select statements ignores anything that has a and b in it, and only looks for positive numbered values. I would like a function of a and b that does that. –  kloop Apr 18 '13 at 20:14
    
Yes, you can do that only after you have numbers (a and b replaced by a numerica value). –  siritinga Apr 18 '13 at 20:15
sol = z /. Solve[z == a z^3 + b z^2 + a + b, z];
zz[a0_ /; NumericQ[a0], b0_ /; NumericQ[b0]] := 
        Min[Select[ sol /. {a -> a0, b -> b0} , 
                 Element[#, Reals] && # > 0 & ]]

This returns -infinty when there are no solutions. As sirintinga noted your example integration limits are not valid..

RegionPlot[NumericQ[zz[a, b] ] , {a, -1, .5}, {b, -.5, 1}]

enter image description here

but you can numerically integrate if you have a valid region..

NIntegrate[zz[a, b], {a, -.5, -.2}, {b, .8, .9}]  ->> 0.0370076

Edit ---

there is a bug above Select in Reals is throwin away real solutions with an infinitesimal complex part.. fix as:..

zz[a0_ /; NumericQ[a0], b0_ /; NumericQ[b0]] := 
        Min[Select[ Chop[ sol /. {a -> a0, b -> b0} ], 
                 Element[#, Reals] && # > 0 & ]]

Edit2, a cleaner approach if you dont find Chop satisfyting..

zz[a0_ /; NumericQ[a0], b0_ /; NumericQ[b0]] := 
     Module[{z, a, b}, 
          Min[z /. Solve[ 
             Reduce[(z > 0 && z == a z^3 + b z^2 + a + b /.
                  { a -> a0, b -> b0}), {z}, Reals]]]]
RegionPlot[NumericQ[zz[a, b] ] , {a, -2, 2}, {b, -2, 2}]

enter image description here

NIntegrate[zz[a, b], {a, 0, .5}, {b, 0, .5 - a}]  -> 0.0491321
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