Construction of block codes |
The stabilizer of the first element f1=(1,...,1)Îan is Sa \ 1 wr Sn. So there are an coset representatives of Sa wr Sn/ Sa \ 1 wr Sn given by (y, id ), where y is a function from n to { id ,(1,2),(1,3),...,(1,a)} . Having computed the pointwise stabilizers of the first ai elements for 0£i<n (i.e. the set of all elements in Sa wr Sn which stabilize each element in {f1,...,fai} ) we can compute the pointwise stabilizers of {f1,...,fl } for l Î{ai+1,...,ai+1} with the following method. The set {ai+1,...,ai+1} can be partitioned into sets {(j-1)ai+1,...,jai} for j=2,...,a. For l Î{(j-1)ai+1,...,jai} the l -th element fl in an is of the form
fl =(1,...,1,j,...)starting with n-i-1 entries of 1 followed by j in the (n-i)-th position and an arbitrary sequence of length i. Depending on j we have: If j=2, then the pointwise stabilizer of {f1,...,fl } can be expressed as a direct product
(Sa \ 1 wr Sn-(i+1))´Sa \ 2´á id ñi.So there are (n-i)(a-1) coset representatives of
(Sa \ 1 wr Sn-i)/ ((Sa \ 1 wr Sn-(i+1))´Sa \ 2´á id ñi),given by (y,p), where pÎ{ id ,(n-i,1),...,(n-i,n-i-1)} , y(k)= id for k¹n-i and y(n-i)Î{ id ,(2,3),(2,4),...,(2,a)} .
For 3£j£a the pointwise stabilizer of {f1,...,fl } is given by
(Sa \ 1 wr Sn-(i+1))´Sa \ j´á id ñi,and the a-j+1 coset representatives of
((Sa \ 1 wr Sn-(i+1))´Sa \ j-1´á id ñi)/ ((Sa \ 1 wr Sn-(i+1))´Sa \ j´á id ñi)are given in the form (y, id ), where y(n-i)Î{ id ,(j,j+1),...,(j,a)} and y(k)= id for k¹n-i.
Because of the fact that the lexicographically smallest element of an orbit is chosen to be the canonic representative of it, the minimal distance of a code can be read from the canonic representative in a very comfortable way. It is the Hamming distance between the first and the second word in the code (with respect to the numbering of the elements of an given above. As a matter of fact the first code word is always f1, and the second code word is of the form (1,...,1,2,...,2) with at least one occurrence of 2. So the minimal distance is the number of 2's in the second code word of the canonic representative. This fact is very useful for recursively constructing all [n,m] block codes of given minimal distance.
In addition to this let me point out that in the case a=2 the S2 wr Sn classes of functions f:{0,1} n -> {0,1} correspond to classes of boolean functions or switching circuits. See for instance [21] or [8].
Harrison and High [9] counted classes of Post-functions under various group actions. These functions are functions f:{1,...,a} n -> {1,...,a} . Even in the case when Sa wr Sn is acting on the domain of these functions, the number of representatives is growing rather fast. Using the homomorphism principle and the method of surjective resolution [12] it is possible to compute a transversal of Post functions, from a transversal of Sa wr Sn-orbits on the set of all functions f:{1,...,a} n -> {1,...,a-1} . Iterating this process we can start constructing the classes of Post functions from a transversal of block codes.
Construction of block codes |