MinimalPolynomial[] for expressions containing symbols

I’m using Mathematica to solve some simple equations relating to geometry, and subsequently hard-coding those solutions in a different language†. Rather than have many pages of code, it would be more concise to code the solutions as a root of a polynomial.

Let’s take:

``````Solve[{
dist^2 == xstep^2 + ((h - 2 r)/(NR - 1))^2,
dist^2 == (w - 2 r - NC xstep)^2 + (h/2 - r - dist/2)^2
},{xstep, dist}]
``````

That generates a “very large output”, heavy with fractions and square roots and fourth roots. Obviously the two solved variables are the roots of quartic equations.

Please, is there a version of MinimalPolynomial[] that will work on expressions containing symbols? All that’s wanted is the five coefficients of dist’s quartic.

Thank you.

† The “different language” is PostScript, and I really don’t have the expertise to write a //PostScriptForm function. Indeed, finding the optimal balance between recomputing repeated expressions and using “… dup … roll” would, in the general case, be slow.

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why are you solving for xx which isnt in the expression? – agentp Jun 18 '13 at 19:56
Editing error: substitute xstep. Sorry. – jdaw1 Jun 18 '13 at 20:26

I wrote a package called "Substitutions" (archived here), which pulls out a hierarchy of sub-expressions, minimizing the coding for complex expressions. It was included in the old MathSource library. Here's the description:

It is often useful, especially when using Mathematica for software development, to apply substitutions to complex expressions to reduce their form. For large expressions, this task can become tedious. Substitutions[] was designed help with the process of finding a useful set of substitutions to simplify an expression.

It is quite old now, but should still work.

-

Reduce may be what you want:

I've consolodated some of your symbol groups into A,B,C (not nesesary, makes it fit on screen)

``````Reduce[{dist^2 == xstep^2 + (A)^2 &&
dist^2 == (C - NC xstep)^2 + (B - dist/2)^2 , {xstep, dist}]]
``````

this produces a fairly large output with a bunch of conditions.

If you have known constraints that preclude various degenrate cases it helps to specify (I made these up)

``````\$Assumptions = B != 0  && B^2 != 3 C^2  && NC^2 != 3/4;
``````

note \$Assumptions is used by Simplify, but you need to explicitly add it to the Reduce expression..

``````Simplify[Reduce[{dist^2 == xstep^2 + (A)^2 &&
dist^2 == (C - NC xstep)^2 + (B - dist/2)^2  && \$Assumptions }, {xstep, dist}]]
``````

output.. not too unwiledy .. The Root expression contains the coefficients you seek..

`````` (xstep ==
Root[9 A^4 - 40 A^2 B^2 + 16 B^4 - 24 A^2 C^2 + 32 B^2 C^2 +
16 C^4 + (48 A^2 C NC - 64 B^2 C NC -
64 C^3 NC) #1 + (18 A^2 - 40 B^2 - 24 C^2 - 24 A^2 NC^2 +
32 B^2 NC^2 + 96 C^2 NC^2) #1^2 + (48 C NC -
64 C NC^3) #1^3 + (9 - 24 NC^2 + 16 NC^4) #1^4 &, 1] ||
xstep ==
Root[9 A^4 - 40 A^2 B^2 + 16 B^4 - 24 A^2 C^2 + 32 B^2 C^2 +
16 C^4 + (48 A^2 C NC - 64 B^2 C NC -
64 C^3 NC) #1 + (18 A^2 - 40 B^2 - 24 C^2 - 24 A^2 NC^2 +
32 B^2 NC^2 + 96 C^2 NC^2) #1^2 + (48 C NC -
64 C NC^3) #1^3 + (9 - 24 NC^2 + 16 NC^4) #1^4 &, 2] ||
xstep ==
Root[9 A^4 - 40 A^2 B^2 + 16 B^4 - 24 A^2 C^2 + 32 B^2 C^2 +
16 C^4 + (48 A^2 C NC - 64 B^2 C NC -
64 C^3 NC) #1 + (18 A^2 - 40 B^2 - 24 C^2 - 24 A^2 NC^2 +
32 B^2 NC^2 + 96 C^2 NC^2) #1^2 + (48 C NC -
64 C NC^3) #1^3 + (9 - 24 NC^2 + 16 NC^4) #1^4 &, 3] ||
xstep ==
Root[9 A^4 - 40 A^2 B^2 + 16 B^4 - 24 A^2 C^2 + 32 B^2 C^2 +
16 C^4 + (48 A^2 C NC - 64 B^2 C NC -
64 C^3 NC) #1 + (18 A^2 - 40 B^2 - 24 C^2 - 24 A^2 NC^2 +
32 B^2 NC^2 + 96 C^2 NC^2) #1^2 + (48 C NC -
64 C NC^3) #1^3 + (9 - 24 NC^2 + 16 NC^4) #1^4 &, 4]) &&
3 A^2 + 4 B dist + xstep (8 C NC + 3 xstep) ==
4 (B^2 + C^2 + NC^2 xstep^2)
``````
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Hmmm. Progress, thank you. That’s different to Solve[]. In particular, it gives a Root[…] for xstep, but not for dist. One could solve the xstep polynomial, and then solve for dist, but there should be a direct one-step Root[…] for dist. Please, is that reachable? – jdaw1 Jun 18 '13 at 23:06
try changing the order of the solution variables ( `{ dist,xstep}` ). – agentp Jun 19 '13 at 14:01
Thank you, but that doesn’t work in the likes of: \$Assumptions=(H[Element]Reals&&H>0&&W[Element]Reals&&W>H&&NR[Element]Integers‌​&&NR>0&&NC[Element]Integers&&NC>0&&R[Element]Reals&&R>0); Simplify[Reduce[{(W==2R+(NC-1)XX) && (H==R(2NR-4)+2YY) && (4R^2==XX^2+YY^2) &&\$Assumptions},{R,XX,YY}]] – jdaw1 Jun 28 '13 at 22:34
(Sorry, failed to get double-space line-breaks to work.) – jdaw1 Jun 28 '13 at 22:40
PS: I know that, in this example, the R polynomial is easy to find. But the question asks how can I most reliably and idiomatically get Mathematica to do the work? – jdaw1 Jun 28 '13 at 22:54