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Many algebraic structures of mathematics and Axiom have a multiplication operation * that satisfies the associativity law associativity law for all , and . The octonions are a well known exception. There are many other interesting non-associative structures, such as the class of Lie algebra Lie algebras.Two Axiom implementations of Lie algebras are LieSquareMatrix and FreeNilpotentLie. Lie algebras can be used, for example, to analyse Lie symmetry algebras of symmetry partial differential differential equation:partial equations. partial differential equation In this section we show a different application of non-associative algebras, non-associative algebra the modelling of genetic laws. algebra:non-associative
The Axiom library contains several constructors for creating non-associative structures, ranging from the categories Monad, NonAssociativeRng, and FramedNonAssociativeAlgebra, to the domains AlgebraGivenByStructuralConstants and GenericNonAssociativeAlgebra. Furthermore, the package AlgebraPackage provides operations for analysing the structure of such algebras. The interested reader can learn more about these aspects of the Axiom library from the paper ``Computations in Algebras of Finite Rank,'' by Johannes Grabmeier and Robert Wisbauer, Technical Report, IBM Heidelberg Scientific Center, 1992.
Mendel's genetic laws are often written in a form like
The implementation of general algebras in Axiom allows us to Mendel's genetic laws use this as the definition for multiplication in an algebra. genetics Hence, it is possible to study questions of genetic inheritance using Axiom. To demonstrate this more precisely, we discuss one example from a monograph of A. Wörz-Busekros, where you can also find a general setting of this theory. Wörz-Busekros, A., Algebras in Genetics, Springer Lectures Notes in Biomathematics 36, Berlin e.a. (1980). In particular, see example 1.3.
We assume that there is an infinitely large random mating population. Random mating of two gametes and gives zygotes zygote , which produce new gametes. gamete In classical Mendelian segregation we have . In general, we have
The segregation rates are the structural constants of an -dimensional algebra. This is provided in Axiom by the constructor AlgebraGivenByStructuralConstants (abbreviation ALGSC).
Consider two coupled autosomal loci with alleles , , , and , building four different gametes and { and }. The zygotes produce gametes and with classical Mendelian segregation. Zygote undergoes transition to and vice versa with probability .
Define a list of four four-by-four matrices giving the segregation rates. We use the value for .
Choose the appropriate symbols for the basis of gametes,
Define the algebra.
What are the probabilities for zygote to produce the different gametes?
Elements in this algebra whose coefficients sum to one play a distinguished role. They represent a population with the distribution of gametes reflected by the coefficients with respect to the basis of gametes.
Random mating of different populations and is described by their product .
This product is commutative only if the gametes are not sex-dependent, as in our example.
In general, it is not associative.
Random mating within a population is described by . The next generation is .
Use decimal numbers to compare the distributions more easily.
To compute directly the gametic distribution in the fifth generation, we use plenaryPower.
We now ask two questions: Does this distribution converge to an equilibrium state? What are the distributions that are stable?
This is an invariant of the algebra and it is used to answer the first question. The new indeterminates describe a symbolic distribution.
Because the coefficient has absolute value less than 1, all distributions do converge, by a theorem of this theory.
The second question is answered by searching for idempotents in the algebra.
Solve these equations and look at the first solution.
Further analysis using the package PolynomialIdeals shows that there is a two-dimensional variety of equilibrium states and all other solutions are contained in it.
Choose one equilibrium state by setting two indeterminates to concrete values.
Verify the result.