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D.4.16 modules_lib
- Library:
- modules.lib
- Purpose:
- Modules
- Authors:
- J. Boehm, boehm@mathematik.uni-kl.de
D. Wienholz wienholz@mathematik.uni-kl.de
C. Koenen koenen@rhrk.uni-kl.de
M. Mayer mayer@mathematik.uni-kl.de - Overview:
- This library is used for the computation of graded free resolutions with an own graduation of
the monomials. For these Resolution is a new class of modules needed. These modules, can be
computed via the image, kernel, cokernel of a matrix or the subquotient of two matrices.
The used matrices also have a free module as source and target, with graded generators if the
matrix is homogeneous. A matrix of this new form is created by a normal matrix, source, target and
the graduatin, if the matrix is homogeneous, are done automatically. With this matrices it is then
possible to compute the new class of modules.
This library also offers the opppurtunity to create R-module-homomorphisms betweens two modules. For these homorphisms the kernel can be computed an will be returned as a module of the new class.This is experimental work in progress!!!
- Types:
- Matrix the class of matrices with source and target in form of free modules
FreeModule free modules representet with the ring and degree
Resolution class of graded resolutions
Module modules represented by either the image, coker, kernelof a matrix or the subquotient of two matrices Vector element of a Module
Ideal same as ideal, but with it's own basering saved, used to compute resolutions Homomorphism class of R-module-homomormphisms
Procedures:
D.4.16.1 id return a nxn identity Matrix D.4.16.2 zero return a nxm zero Matrix D.4.16.3 freeModule creating a graded free module D.4.16.4 makeMatrix creating a Matrix with graded target and source if the matrix is homogeneous. If # is set to 1, makeMatrix ignores the grading of source & target. D.4.16.5 makeIdeal creates an Ideal from an given ideal, is used to compute a resolution of the ideal D.4.16.6 Target return target of the Matrix D.4.16.7 Source return source of the Matrix D.4.16.8 printMatrix print a Matrix D.4.16.9 printFreeModule print a FreeModule D.4.16.10 printResolution print a Resolution D.4.16.11 printModule print a Module D.4.16.12 printHom print a Homomorphism D.4.16.13 mRes return a minimized graded Resolution D.4.16.14 sRes return a graded Resolution computet with Schreyer's method D.4.16.15 Res return a graded Resolution D.4.16.16 Betti return the Betti-Matrix of the Resolution D.4.16.17 printBetti prints the Betti-matrix of the Resolution D.4.16.18 SetDeg sets an own graduatuation for the monomials D.4.16.19 Deg same as deg, but can be used with an own graduation D.4.16.20 Degree return list with degrees of the module D.4.16.21 Degrees return list with degrees of the module D.4.16.22 subquotient return a Module, the subquotient of the two Matrices D.4.16.23 coker return a Module, the cokernel of the Matrix D.4.16.24 image return a Module, the image of the Matrix D.4.16.25 Ker return a Module, the kernel of the Matrix D.4.16.26 compareModules return 0 or 1, compares the two Modules up to isomorphism D.4.16.27 addModules return a Module, sum of the two Modules D.4.16.28 homomorphism creates a R-Modul-Homomorphism D.4.16.29 target return a Module, target of the Homomorphism D.4.16.30 source return a Module, source of the Homomorphism D.4.16.31 compareMatrix return 0 or 1, compares two Matrices D.4.16.32 freeModule2Module converts a FreeModule into a Module D.4.16.33 makeVector creates Vector in the given Module D.4.16.34 netVector prints Vector D.4.16.35 netMatrix prints Matrix D.4.16.36 presentation converts M as a Subquotient to the Coker of a matrix C D.4.16.37 tensorMatrix computes tensorproduct of two Matrices D.4.16.38 tensorModule computes tensorproduct of two Modules D.4.16.39 tensorModFreemod computes tensorproduct of Module and FreeModule D.4.16.40 tensorFreemodMod computes tensorproduct of FreeModule and Module D.4.16.41 tensorFreeModule computes tensorproduct ot two FreeModules D.4.16.42 tensorProduct computes tensorproduct D.4.16.43 pruneModule simplifies the presentation of a Module D.4.16.44 hom computes Hom(M,N) D.4.16.45 kerHom computes the kernel of a Homomorphism D.4.16.46 interpret interprets the Vector in some Module or abstract space D.4.16.47 interpretInv interprets a Vector or Homomorphism into the given Module D.4.16.48 reduceIntChain reduces a chain of interpretations to minimal size or # steps D.4.16.49 interpretElem interpret a Vector with # steps or until can't interpret further D.4.16.50 interpretList interpret a list of Vectors as far as possible D.4.16.51 compareVectors compares two Vectors with regard to the relations of their Module D.4.16.52 simplePrune simplify module