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msolveRealSolutions -- compute all real solutions to a zero dimensional system using symbolic methods

Description

This functions uses the msolve package to compute the real solutions to a zero dimensional polynomial ideal with either integer or rational coefficients.

The second input is optional, and indicates the alternative ways to provide output either using an exact rational interval QQi, a real interval RRi, or by taking a rational or real approximation of the midpoint of the intervals.

i1 : R = QQ[x,y]

o1 = R

o1 : PolynomialRing
 
i2 : I = ideal {(x-1)*x, y^2-5}

             2       2
o2 = ideal (x  - x, y  - 5)

o2 : Ideal of R
 
i3 : rationalIntervalSols = msolveRealSolutions I

                                5018153033                       
o3 = {{{- ------------------------------------------------------,
          383123885216472214589586756787577295904684780545900544 
     ------------------------------------------------------------------------
                           242583047                            9603838835   
     -----------------------------------------------------}, {- ----------, -
     23945242826029513411849172299223580994042798784118784      4294967296   
     ------------------------------------------------------------------------
     4801919417      8589934591  8589934593      9603838835    4801919417   
     ----------}}, {{----------, ----------}, {- ----------, - ----------}},
     2147483648      8589934592  8589934592      4294967296    2147483648   
     ------------------------------------------------------------------------
                               8005062331                      
     {{- -----------------------------------------------------,
         95780971304118053647396689196894323976171195136475136 
     ------------------------------------------------------------------------
                           5237370551                         4801919417 
     -----------------------------------------------------}, {----------,
     47890485652059026823698344598447161988085597568237568    2147483648 
     ------------------------------------------------------------------------
     9603838835      8589934591  8589934593    4801919417  9603838835
     ----------}}, {{----------, ----------}, {----------, ----------}}}
     4294967296      8589934592  8589934592    2147483648  4294967296

o3 : List
 
i4 : rationalApproxSols = msolveRealSolutions(I, QQ)

                               1136824281                         
o4 = {{- ------------------------------------------------------, -
         766247770432944429179173513575154591809369561091801088   
     ------------------------------------------------------------------------
     19207677669         19207677669  
     -----------}, {1, - -----------},
      8589934592          8589934592  
     ------------------------------------------------------------------------
                            2469678771                        19207677669  
     {------------------------------------------------------, -----------},
      191561942608236107294793378393788647952342390272950272   8589934592  
     ------------------------------------------------------------------------
         19207677669
     {1, -----------}}
          8589934592

o4 : List
 
i5 : floatIntervalSols = msolveRealSolutions(I, RRi)

o5 = {{[-1.3098e-44,1.01307e-44], [-2.23607,-2.23607]}, {[1,1],
     ------------------------------------------------------------------------
     [-2.23607,-2.23607]}, {[-8.35768e-44,1.09361e-43], [2.23607,2.23607]},
     ------------------------------------------------------------------------
     {[1,1], [2.23607,2.23607]}}

o5 : List
 
i6 : floatIntervalSols = msolveRealSolutions(I, RRi_10)

o6 = {{[.999512,1.00049], [-2.23633,-2.23535]}, {[.999512,1.00049],
     ------------------------------------------------------------------------
     [2.23535,2.23633]}, {[-1.23404e-38,1.26848e-38], [-2.23633,-2.23535]},
     ------------------------------------------------------------------------
     {[-8.07936e-45,1.04824e-44], [2.23535,2.23633]}}

o6 : List
 
i7 : floatApproxSols = msolveRealSolutions(I, RR)

o7 = {{1, -2.23607}, {1, 2.23607}, {1.70931e-40, -2.23607}, {1.20156e-45,
     ------------------------------------------------------------------------
     2.23607}}

o7 : List
 
i8 : floatApproxSols = msolveRealSolutions(I, RR_10)

o8 = {{1, -2.23584}, {1, 2.23584}, {1.72192e-40, -2.23584}, {1.2015e-45,
     ------------------------------------------------------------------------
     2.23584}}

o8 : List

Note in cases where solutions have multiplicity this is not reflected in the output. While the solver does not return multiplicities, it reliably outputs the verified isolating intervals for multiple solutions.

i9 : I = ideal {(x-1)*x^3, (y^2-5)^2}

             4    3   4      2
o9 = ideal (x  - x , y  - 10y  + 25)

o9 : Ideal of R
 
i10 : floatApproxSols = msolveRealSolutions(I, RRi)

o10 = {{[1,1], [-2.23607,-2.23607]}, {[1,1], [2.23607,2.23607]},
      -----------------------------------------------------------------------
      {[-1.23374e-38,1.26793e-38], [-2.23607,-2.23607]},
      -----------------------------------------------------------------------
      {[-8.07918e-45,1.04823e-44], [2.23607,2.23607]}}

o10 : List

Ways to use msolveRealSolutions:

  • msolveRealSolutions(Ideal)
  • msolveRealSolutions(Ideal,Ring)
  • msolveRealSolutions(Ideal,RingFamily)

For the programmer

The object msolveRealSolutions is a method function with options.

The source of this document is in Msolve.m2:636:0.