coincident-root-loci: Equivariant CSM classes of coincident root loci

[ bsd3, library, math ] [ Propose Tags ] [ Report a vulnerability ]

This library contians a set of function to compute, among others, the GL(2)-equivariant Chern-Schwartz-MacPherson classes of coincident root loci, which are subvarieties of the space of unordered n-tuples of points in the complex projective line. To such an n-tuples we can associate a partition of n given by the multiplicities of the distinct points; this stratifies the set of all n-tuples, and we call these strata "coincident root loci". This package is supplementary software for a forthcoming paper.


[Skip to Readme]

Downloads

Maintainer's Corner

Package maintainers

For package maintainers and hackage trustees

Candidates

  • No Candidates
Versions [RSS] 0.2, 0.3
Dependencies array (>=0.5), base (>=4 && <5), combinat (>=0.2.10.0), containers (>=0.5), polynomial-algebra (>=0.1), random, transformers [details]
Tested with ghc ==8.6.5
License BSD-3-Clause
Copyright (c) 2015-2021 Balazs Komuves
Author Balazs Komuves
Maintainer bkomuves (plus) hackage (at) gmail (dot) com
Category Math
Home page https://hub.darcs.net/bkomuves/coincident-root-loci
Source repo head: darcs get https://hub.darcs.net/bkomuves/coincident-root-loci
Uploaded by BalazsKomuves at 2021-07-26T16:22:19Z
Distributions
Reverse Dependencies 1 direct, 0 indirect [details]
Downloads 1089 total (1 in the last 30 days)
Rating 2.0 (votes: 1) [estimated by Bayesian average]
Your Rating
  • λ
  • λ
  • λ
Status Docs available [build log]
Last success reported on 2021-07-28 [all 1 reports]

Readme for coincident-root-loci-0.3

[back to package description]

Characteristic classes of coincident root loci

Coincident root loci (or discriminant strata) are subsets of the space of homogeneous polynomials in two variables defined by root multiplicities: A nonzero degree n polynomial has n roots in the complex projective line P^1, but some of these can coincide, which gives us a partition of n. Hence for each partition lambda we get a set of polynomials (those with root multiplicities given by lambda), which together stratify the space of these polynomials, which (modulo multiplying by scalars) is P^n. These are quasi-projective varieties, invariant under the action of GL(2); their closures are highly singular projective varieties, making them a good example for studying invariants of singular varieties.

This package contains a number of different algorithms to compute invariants and characteristic classes of these varieties:

  • degree
  • Euler characteristic
  • the fundamental class in equivariant cohomology
  • Chern-Schwartz-MacPherson (CSM) class, Segre-SM class
  • equivariant CSM class
  • Hirzebruch Chi-y genus
  • Todd class, motivic Hirzebruch class
  • motivic Chern class
  • equivariant motivic Chern class

Some of the algorithms are implemented in Mathematica instead of (or in addition to) Haskell.

Another (better organized) Mathematica implementation is available at https://github.com/bkomuves/mathematica-packages.

Example usage

For example if you want to know what is the equivariant CSM class of the (open) loci corresponding to the partition [2,2,1,1], you can use the following piece of code:

{-# LANGUAGE TypeApplications #-}

import Math.Combinat.Partitions
import Math.RootLoci.Algebra.SymmPoly ( AB )
import Math.Algebra.Polynomial.Pretty ( pretty )
import Math.RootLoci.CSM.Equivariant.Umbral

csm ps = umbralOpenCSM @AB (mkPartition ps)

main = do
  putStrLn $ pretty $ csm [2,2,1,1]