Difference between revisions of "ApCoCoA-1:CharP.IMBBasisF2"
(New page: <command> <title>CharP.IMBBasis</title> <short_description>Computing a Border Basis of a given ideal over <tt>F_2</tt>. </short_description> <syntax> CharP.IMBBasisF2(F:LIST):LIST ...) |
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+ | {{Version|1}} | ||
<command> | <command> | ||
<title>CharP.IMBBasis</title> | <title>CharP.IMBBasis</title> | ||
− | <short_description> | + | <short_description>Computes a Border Basis of a given ideal over <tt>F_2</tt>. </short_description> |
<syntax> | <syntax> | ||
CharP.IMBBasisF2(F:LIST):LIST | CharP.IMBBasisF2(F:LIST):LIST | ||
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<em>Please note:</em> The function(s) explained on this page is/are using the <em>ApCoCoAServer</em>. You will have to start the ApCoCoAServer in order to use it/them. | <em>Please note:</em> The function(s) explained on this page is/are using the <em>ApCoCoAServer</em>. You will have to start the ApCoCoAServer in order to use it/them. | ||
<par/> | <par/> | ||
− | Let <tt>f_1</tt>, ... , <tt>f_m</tt> is a set of polynomials which generate a zero-dimensional ideal. This function computes a Border Basis of the zero-dimensional radical ideal generated by <tt>f_1</tt>, ... , <tt>f_m</tt> and the field polynomials. Furthermore, it uses mutant strategy to compute a U-stable span. If you want to use the second version with the parameter NSol, you need to provide the exact number of <tt>F_2</tt> rational solutions. The first version is safe to use if you do not know the exact number of <tt>F_2</tt> rational solutions. | + | Let <tt>f_1</tt>, ... , <tt>f_m</tt> is a set of polynomials which generate a zero-dimensional ideal. This function computes a Border Basis of the zero-dimensional radical ideal generated by <tt>f_1</tt>, ... , <tt>f_m</tt> and the field polynomials. Furthermore, it uses improved mutant strategy to compute a U-stable span. If you want to use the second version with the parameter NSol, you need to provide the exact number of <tt>F_2</tt> rational solutions. The first version is safe to use if you do not know the exact number of <tt>F_2</tt> rational solutions. |
<itemize> | <itemize> | ||
<item>@param <em>F:</em> List of polynomials.</item> | <item>@param <em>F:</em> List of polynomials.</item> | ||
Line 26: | Line 27: | ||
-- Then we compute a Border Basis with | -- Then we compute a Border Basis with | ||
− | CharP. | + | CharP.IMBBasisF2(F); |
The size of Matrix is: | The size of Matrix is: | ||
Line 32: | Line 33: | ||
No. of Columns=11 | No. of Columns=11 | ||
The size of Matrix is: | The size of Matrix is: | ||
− | No. of Rows= | + | No. of Rows=4 |
No. of Columns=11 | No. of Columns=11 | ||
− | No. of | + | Total No. of Mutants are = 0 |
The size of Matrix is: | The size of Matrix is: | ||
− | No. of Rows= | + | No. of Rows=12 |
− | No. of Columns= | + | No. of Columns=15 |
− | No. of | + | Total No. of Mutants are = 2 |
+ | The No. of Mutants of Minimum degree (Mutants used) are = 1 | ||
+ | The size of Matrix is: | ||
+ | No. of Rows=14 | ||
+ | No. of Columns=15 | ||
+ | Total No. of Mutants are = 2 | ||
+ | The No. of Mutants of Minimum degree (Mutants used) are = 1 | ||
The size of Matrix is: | The size of Matrix is: | ||
No. of Rows=16 | No. of Rows=16 | ||
− | No. of Columns= | + | No. of Columns=15 |
− | No. of | + | Total No. of Mutants are = 2 |
+ | The No. of Mutants of Minimum degree (Mutants used) are = 1 | ||
+ | The size of Matrix is: | ||
+ | No. of Rows=17 | ||
+ | No. of Columns=15 | ||
+ | Total No. of Mutants are = 1 | ||
+ | The No. of Mutants of Minimum degree (Mutants used) are = 1 | ||
+ | The size of Matrix is: | ||
+ | No. of Rows=17 | ||
+ | No. of Columns=15 | ||
+ | Total No. of Mutants are = 2 | ||
+ | The No. of Mutants of Minimum degree (Mutants used) are = 2 | ||
The size of Matrix is: | The size of Matrix is: | ||
− | No. of Rows= | + | No. of Rows=18 |
No. of Columns=15 | No. of Columns=15 | ||
− | No. of | + | Total No. of Mutants are = 0 |
[x[4] + 1, x[3], x[2] + 1, x[1]] | [x[4] + 1, x[3], x[2] + 1, x[1]] | ||
− | |||
</example> | </example> | ||
Line 66: | Line 83: | ||
-- Solution is not unique i.e. [0, 1, 1, 1], [0, 0, 0, 0], and [1, 1, 1, 1] are solutions | -- Solution is not unique i.e. [0, 1, 1, 1], [0, 0, 0, 0], and [1, 1, 1, 1] are solutions | ||
-- Compute the solution with | -- Compute the solution with | ||
− | CharP. | + | CharP.IMBBasisF2(F,NSol); |
The size of Matrix is: | The size of Matrix is: | ||
No. of Rows=4 | No. of Rows=4 | ||
No. of Columns=9 | No. of Columns=9 | ||
+ | The size of Matrix is: | ||
+ | No. of Rows=7 | ||
+ | No. of Columns=14 | ||
+ | Total No. of Mutants are = 0 | ||
The size of Matrix is: | The size of Matrix is: | ||
No. of Rows=14 | No. of Rows=14 | ||
No. of Columns=14 | No. of Columns=14 | ||
The size of Matrix is: | The size of Matrix is: | ||
− | No. of Rows= | + | No. of Rows=11 |
− | No. of Columns= | + | No. of Columns=14 |
[x[3]x[4] + x[4], x[1]x[4] + x[1], x[1]x[3] + x[1], x[1]x[2] + x[1], x[2]x[3]x[4] + x[4], x[1]x[2]x[4] + x[1]] | [x[3]x[4] + x[4], x[1]x[4] + x[1], x[1]x[3] + x[1], x[1]x[2] + x[1], x[2]x[3]x[4] + x[4], x[1]x[2]x[4] + x[1]] | ||
Line 84: | Line 105: | ||
</description> | </description> | ||
<seealso> | <seealso> | ||
− | <see>CharP.MXLSolve</see> | + | <see>ApCoCoA-1:CharP.MXLSolve|CharP.MXLSolve</see> |
− | <see>Introduction to CoCoAServer</see> | + | <see>ApCoCoA-1:Introduction to CoCoAServer|Introduction to CoCoAServer</see> |
− | <see>Introduction to Groebner Basis in CoCoA</see> | + | <see>ApCoCoA-1:Introduction to Groebner Basis in CoCoA|Introduction to Groebner Basis in CoCoA</see> |
− | <see>CharP.IMNLASolve</see> | + | <see>ApCoCoA-1:CharP.IMNLASolve|CharP.IMNLASolve</see> |
− | <see>CharP. | + | <see>ApCoCoA-1:CharP.MBBasisF2|CharP.MBBasisF2</see> |
</seealso> | </seealso> | ||
Line 96: | Line 117: | ||
</types> | </types> | ||
− | <key>charP. | + | <key>charP.imbbasisf2</key> |
− | <key> | + | <key>imbbasisf2</key> |
<key>finite field</key> | <key>finite field</key> | ||
− | <wiki-category>Package_charP</wiki-category> | + | <wiki-category>ApCoCoA-1:Package_charP</wiki-category> |
</command> | </command> |
Latest revision as of 09:55, 7 October 2020
This article is about a function from ApCoCoA-1. |
CharP.IMBBasis
Computes a Border Basis of a given ideal over F_2.
Syntax
CharP.IMBBasisF2(F:LIST):LIST CharP.IMBBasisF2(F:LIST, NSol: INT):LIST
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.
Let f_1, ... , f_m is a set of polynomials which generate a zero-dimensional ideal. This function computes a Border Basis of the zero-dimensional radical ideal generated by f_1, ... , f_m and the field polynomials. Furthermore, it uses improved mutant strategy to compute a U-stable span. If you want to use the second version with the parameter NSol, you need to provide the exact number of F_2 rational solutions. The first version is safe to use if you do not know the exact number of F_2 rational solutions.
@param F: List of polynomials.
@param NSol: Number of F_2 rational solutions.
@return A Border Basis of the zero-dimensional radical ideal generated by the polynomials in F and the field polynomials.
Example
Use Z/(2)[x[1..4]]; F:=[ x[1]x[2] + x[2]x[3] + x[2]x[4] + x[3]x[4] + x[1] + x[3] + 1, x[1]x[2] + x[1]x[3] + x[1]x[4] + x[3]x[4] + x[2] + x[3] + 1, x[1]x[2] + x[1]x[3] + x[2]x[3] + x[3]x[4] + x[1] + x[4] + 1, x[1]x[3] + x[2]x[3] + x[1]x[4] + x[2]x[4] + 1 ]; -- Then we compute a Border Basis with CharP.IMBBasisF2(F); The size of Matrix is: No. of Rows=4 No. of Columns=11 The size of Matrix is: No. of Rows=4 No. of Columns=11 Total No. of Mutants are = 0 The size of Matrix is: No. of Rows=12 No. of Columns=15 Total No. of Mutants are = 2 The No. of Mutants of Minimum degree (Mutants used) are = 1 The size of Matrix is: No. of Rows=14 No. of Columns=15 Total No. of Mutants are = 2 The No. of Mutants of Minimum degree (Mutants used) are = 1 The size of Matrix is: No. of Rows=16 No. of Columns=15 Total No. of Mutants are = 2 The No. of Mutants of Minimum degree (Mutants used) are = 1 The size of Matrix is: No. of Rows=17 No. of Columns=15 Total No. of Mutants are = 1 The No. of Mutants of Minimum degree (Mutants used) are = 1 The size of Matrix is: No. of Rows=17 No. of Columns=15 Total No. of Mutants are = 2 The No. of Mutants of Minimum degree (Mutants used) are = 2 The size of Matrix is: No. of Rows=18 No. of Columns=15 Total No. of Mutants are = 0 [x[4] + 1, x[3], x[2] + 1, x[1]]
Example
Use Z/(2)[x[1..4]]; F:=[ x[2]x[3] + x[1]x[4] + x[2]x[4] + x[3]x[4] + x[1] + x[2] + x[3] + x[4], x[2]x[3] + x[2]x[4] + x[3]x[4] + x[2] + x[3] + x[4], x[1]x[2] + x[2]x[3] + x[2]x[4] + x[3]x[4] + x[1] + x[2], x[1]x[2] + x[2]x[3] + x[2]x[4] + x[3]x[4] + x[1] + x[2] ]; NSol:=3; -- Solution is not unique i.e. [0, 1, 1, 1], [0, 0, 0, 0], and [1, 1, 1, 1] are solutions -- Compute the solution with CharP.IMBBasisF2(F,NSol); The size of Matrix is: No. of Rows=4 No. of Columns=9 The size of Matrix is: No. of Rows=7 No. of Columns=14 Total No. of Mutants are = 0 The size of Matrix is: No. of Rows=14 No. of Columns=14 The size of Matrix is: No. of Rows=11 No. of Columns=14 [x[3]x[4] + x[4], x[1]x[4] + x[1], x[1]x[3] + x[1], x[1]x[2] + x[1], x[2]x[3]x[4] + x[4], x[1]x[2]x[4] + x[1]]
See also
Introduction to Groebner Basis in CoCoA