Minimal algebra

Minimal algebra is an important concept in tame congruence theory, a theory that has been developed by Ralph McKenzie and David Hobby.^[1]

Definition[edit]

A minimal algebra is a finite algebra with more than one element, in which every non-constant unary polynomial is a permutation on its domain.

Classification[edit]

A polynomial of an algebra is a composition of its basic operations, $0$ -ary operations and the projections. Two algebras are called polynomially equivalent if they have the same universe and precisely the same polynomial operations. A minimal algebra $\mathbb {M}$ falls into one of the following types (P. P. Pálfy) ^[1]^[2]

$\mathbb {M}$ is of type ${\bf {1}}$ , or unary type, iff ${\rm {Pol}}~\mathbb {M} ={\rm {Pol}}\langle M,G\rangle$ , where $M$ denotes the universe of $\mathbb {M}$ , ${\rm {Pol~\mathbb {A} }}$ denotes the set of all polynomials of an algebra $\mathbb {A}$ and $G$ is a subgroup of the symmetric group over $M$ .

$\mathbb {M}$ is of type ${\bf {2}}$ , or affine type, iff $\mathbb {M}$ is polynomially equivalent to a vector space.

$\mathbb {M}$ is of type ${\bf {3}}$ , or Boolean type, iff $\mathbb {M}$ is polynomially equivalent to a two-element Boolean algebra.

$\mathbb {M}$ is of type ${\bf {4}}$ , or lattice type, iff $\mathbb {M}$ is polynomially equivalent to a two-element lattice.

$\mathbb {M}$ is of type ${\bf {5}}$ , or semilattice type, iff $\mathbb {M}$ is polynomially equivalent to a two-element semilattice.

References[edit]

^ ^a ^b Hobby, David; McKenzie, Ralph (1988). The structure of finite algebras. Providence, RI: American Mathematical Society. p. xii+203 pp. ISBN 0-8218-5073-3.
^ Pálfy, P. P. (1984). "Unary polynomials in algebras. I". Algebra Universalis. 18 (3): 262–273. doi:10.1007/BF01203365. S2CID 15991530.

[HobbyMcKenzie-1] Hobby, David; McKenzie, Ralph (1988). The structure of finite algebras. Providence, RI: American Mathematical Society. p. xii+203 pp. ISBN 0-8218-5073-3.

[unarypolynomial-2] Pálfy, P. P. (1984). "Unary polynomials in algebras. I". Algebra Universalis. 18 (3): 262–273. doi:10.1007/BF01203365. S2CID 15991530.

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