<P/>
The &Sophus; package was originally designed to aid the author to
classify some small-dimensional nilpotent Lie algebras over small fields. The
classification follows the ideas that were used to classify small
<Math>p</Math>-groups by O'Brien . The theory developed
by O'Brien could easily be adopted to Lie algebras, and the details of
this new theory can be found in <Cite Key="Sch"/>. Here we only summarise
the main ideas, so that the user can understand the procedures
implemented in this package.
In this section <Math>L</Math> denotes a finitely generated, and hence
finite-dimensional, nilpotent Lie algebra.
Suppose that <Math>L</Math> has
nilpotency class <Math>c</Math>, and hence the
lower central series is as follows:
<Display>
L= \gamma_1(L)>\gamma_2(L)=L'>\gamma_3(L)>\cdots >\gamma_c(L)>\gamma_{c+1}(L)=0.
</Display>
We say that a basis <Math>\mathcal B=\{b_1,\ldots,b_n\}</Math> for <Math>L</Math> is <Emph>compatible with the
lower central series</Emph> if there are indices
<Math>1=i_1&tlt;i_2&tlt;\cdots&tlt;i_{c}&tlt;n</Math> such that
<Math>\{b_{i_k},\ldots,b_n\}</Math> is
a basis of <Math>\gamma_k(L)</Math> for <Math>k\in\{1,\ldots,c\}</Math>. We compute the
structure constants table with respect to this basis, that is, we
compute coefficients <Math>\alpha_{i,j}^k</Math> for <Math>1\leq i&tlt;j&tlt;k\leq n</Math> such that
<Display>
[b_i,b_j]=\sum_{k=j+1}^n\alpha_{i,j}^k b_k.
</Display>
Suppose that <Math>b_i\in\gamma_j(L)\setminus\gamma_{j+1}(L)</Math>. Then we say that
the number <Math>j</Math> is the <Emph>weight</Emph> of the basis element
<Math>b_i</Math>.
<P/>
Note that in the nilpotent Lie
algebra <Math>L</Math> minimal
generating sets have the same size, namely the dimension of <Math>L/L'. If
<Math>\dim L/L'=d then we call a -generator algebra.
We call a basis <Math>\mathcal B</Math> a <Emph>nilpotent basis</Emph>
if the following
hold.
<List>
<Item> The basis <Math>\mathcal B</Math>
is compatible with the lower central
series.
</Item>
<Item>For each <Math>b_i\in \mathcal B</Math> with weight <Math>w\geq
2</Math>
there are
<Math>b_{j_1},\ b_{j_2}\in\mathcal B</Math> with weight 1 and <Math>w-1</Math>, respectively such
that <Math>b_i=[b_{j_1},b_{j_2}]</Math>. The product <Math>[b_{j_1},b_{j_2}]</Math> is
called the definition of <Math>b_i</Math>.</Item>
</List>
<P/>
A Lie
algebra <Math>K</Math> is said to be a <Emph>central extension</Emph> of <Math>L</Math> if <Math>L\cong
K/I</Math> for some ideal <Math>I</Math> such that <Math>I\leq Z(K)\cap K'.
Suppose that <Math>c</Math> denotes the nilpotency
class of <Math>L</Math>. Then a Lie algebra <Math>K</Math>
is an <Emph>immediate descendant</Emph> of <Math>L</Math> if <Math>K</Math> has class <Math>c+1</Math> and <Math>K/\gamma_{c+1}(K)\cong L</Math>. As in this case <Math>\gamma_{c+1}(K)\leq Z(K)\cap K', it follows
that an immediate descendant <Math>K</Math> is a central extension of <Math>L</Math>. If <Math>s=\dim \gamma_{c+1}(K)</Math> then <Math>K</Math> is said to be a <Emph>step-<Math>s</Math></Emph> immediate descendant of <Math>L</Math>.
<P/>Let <Math>L</Math> be a
<Math>d</Math>-generator nilpotent Lie algebra with class <Math>c</Math>, and let <Math>F</Math> be a free Lie algebra of rank
<Math>d</Math>. Choose an ideal <Math>I</Math> of <Math>F</Math> such that <Math>L\cong F/I</Math>. Then the Lie
algebra <Math>L^*=F/[I,F]</Math> is called the <Emph>Lie cover</Emph> of <Math>L</Math>.
The <Emph>Lie multiplicator</Emph> in <Math>L^*</Math> is
the subspace <Math>I/[I,F]</Math> and the <Emph>Lie nucleus</Emph> is <Math>\gamma_c(L^*)</Math>. It clear from the definition that <Math>L^*/M\cong L</Math>. It is verified in <Cite Key="Sch"/> that, up to
isomorphism, the Lie cover,
the Lie multiplicator and the Lie nucleus are determined by the
isomorphism type of <Math>L</Math>.
Further, each
central extension of the nilpotent Lie algebra
<Math>L</Math> is a quotient of the Lie cover <Math>L^*</Math>. Thus
it is possible to obtain all such descendants by first computing the
Lie cover; this procedure is explained in <Cite Key="Sch"/>.
Similar ideas can be used to compute the automorphism group of a
nilpotent Lie algebra, and to verify isomorphism between two nilpotent
Lie algebras; see <Cite Key="Sch"/> for details.
<P/>The main functions in &Sophus; are thus able to compute
<List>
<Item> a nilpotent basis for a nilpotent Lie algebra;</Item>
<Item> the cover of a nilpotent Lie algebra;</Item>
<Item> the immediate descendants of a nilpotent Lie algebra;</Item>
<Item> the full automorphism group of a nilpotent Lie algebra.</Item>
</List>
There is also a function in the package to check if two nilpotent Lie
algebras are isomorphic. After repeated applications of the immediate
descendants algorithm, it is, in theory, possible to list all
nilpotent Lie algebras of a given dimension over a prime
field <Math>\mathbb F_p</Math>. Of course, this computation requires
relatively large computational resources, and quickly becomes
unfeasible as the dimension or the characteristic <Math>p</Math> grows.
<P/>
The &Sophus; package was written for the GAP~4 computer algebra
system. In many procedures it is very important that we can compute
the stabiliser of a subspace under some matrix group action. This is
carried out using the procedures implemented in the <A>autpgrp</A> package <Cite Key="autpgrp"/>.
Hence this package is required to run &Sophus;.
<P/>
The current version of &Sophus; deals with
general nilpotent Lie algebras over finite
prime fields. If you are to compute with Lie algebras
obtained from group algebras via the bracket operation,
then another GAP package LAGUNA <Cite Key="Laguna"/>
may also offer some very efficient methods.
</Chapter>
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