Difference between revisions of "ApCoCoA-1:Num.SubEXTABM"

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     <short_description>Computes a border basis of an almost vanishing sub-ideal for a set of points and an ideal using the <ref>Num.EXTABM</ref> algorithm.</short_description>
 
     <short_description>Computes a border basis of an almost vanishing sub-ideal for a set of points and an ideal using the <ref>Num.EXTABM</ref> algorithm.</short_description>
 
<syntax>
 
<syntax>
Num.SubABM(Points:MAT, Val:MAT, Epsilon:RAT, Basis:LIST):Object
+
Num.SubEXTABM(Points:MAT, Val:MAT, Epsilon:RAT, Basis:LIST):Object
Num.SubABM(Points:MAT, Val:MAT, Epsilon:RAT, Basis:LIST, Delta:RAT, NormalizeType:INT):Object
+
Num.SubEXTABM(Points:MAT, Val:MAT, Epsilon:RAT, Basis:LIST, Delta:RAT, NormalizeType:INT):Object
 
</syntax>
 
</syntax>
 
     <description>
 
     <description>
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       <type>ideal</type>
 
       <type>ideal</type>
 
     </types>
 
     </types>
     <key>SubABM</key>
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     <key>SubEXTABM</key>
     <key>num.SubABM</key>
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     <key>num.SubEXTABM</key>
     <key>numerical.subabm</key>
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     <key>numerical.subextabm</key>
 
     <wiki-category>Package_numerical</wiki-category>
 
     <wiki-category>Package_numerical</wiki-category>
 
   </command>
 
   </command>

Revision as of 11:39, 15 October 2009

Num.SubEXTABM

Computes a border basis of an almost vanishing sub-ideal for a set of points and an ideal using the Num.EXTABM algorithm.

Syntax

Num.SubEXTABM(Points:MAT, Val:MAT, Epsilon:RAT, Basis:LIST):Object
Num.SubEXTABM(Points:MAT, Val:MAT, Epsilon:RAT, Basis:LIST, Delta:RAT, NormalizeType:INT):Object

Description

Please note: The function(s) explained on this page is/are using the ApCoCoAServer. You will have to start the ApCoCoAServer in order to use it/them.

This command computes a border basis of an almost vanishing sub-ideal for a set of points and an ideal using the Num.EXTABM algorithm.

The current ring has to be a ring over the rational numbers with a standard-degree

compatible term-ordering. Each row in the matrix Points represents one point, so the number of columns must equal the

number of indeterminates in the current ring.

  • @param Points The points for which a border basis is computed.

  • @param Val The time series we want to approximate using Points.

  • @param Epsilon A positive rational number describing the maximal admissible least squares error for a polynomial. (Bigger values for Epsilon lead to bigger errors of the polynomials evaluated at the point set).

  • @param Basis A set of polynomials in the current ring. This basis defines the ideal in which we compute the basis of the approximate vanishing ideal.

  • @return A list of two results. First the border basis as a list of polynomials, second the vector space basis of P/I as a list of terms.


The following parameters are optional:

  • @param Delta A positive rational number which describes the computing precision. In different steps, it is crucial, if a value is 0 or not. The algorithm assumes every value in [-Delta, Delta] to be 0. The default value for Delta is 0.00000000001.

  • @param NormalizeType A integer of the set {1,2,3,4}. The default value is 2. This parameter describes, if and where required the input points are normalized. If NormalizeType equals 1, each coordinate of a point is divided by the maximal absolute value of all coordinates of this point. This ensures that all coordinates of the points are within [-1,1]. With NormalizeType=2 no normalization is done at all. NormalizeType=3 shifts each coordinate to [-1,1], i.e. the minimal coordinate of a point is mapped to -1 and the maximal coordinate to 1, which describes a unique affine mapping. The last option is NormalizeType=4. In this case, each point is normalized by its euclidean norm. Although NormalizeType=3 is in most cases a better choice, the default value is due to backward compatibility 1.


Example

Use P::=QQ[x,y,z];

Points := Mat([[1,2,3],[4,5,6],[7,11,12]]);
Val := Mat([[1],[0.1],[0.2]]);
R:=Num.SubEXTABM(Points,Val, 0.1, [x]);

Dec(-Eval(R[1],Points[1]),3);
Dec(-Eval(R[1],Points[2]),3);
Dec(-Eval(R[1],Points[3]),3);
-- CoCoAServer: computing Cpu Time = 0
-------------------------------
[<quotes>1.000</quotes>, <quotes>0.999</quotes>, <quotes>1.000</quotes>, <quotes>0.999</quotes>, <quotes>0.999</quotes>, <quotes>1.000</quotes>]
-------------------------------
[<quotes>0.099</quotes>, <quotes>0.100</quotes>, <quotes>0.100</quotes>, <quotes>0.099</quotes>, <quotes>0.099</quotes>, <quotes>0.100</quotes>]
-------------------------------
[<quotes>0.200</quotes>, <quotes>0.200</quotes>, <quotes>0.200</quotes>, <quotes>0.199</quotes>, <quotes>0.199</quotes>, <quotes>0.199</quotes>]
-------------------------------

See also

Introduction to CoCoAServer

Num.ABM