Minimal algebra

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. In simpler terms, it’s an algebraic structure where unary operations (those involving a single input) behave like permutations (bijective mappings). These algebras provide intriguing connections between mathematical concepts and are classified into different types, including affine, Boolean, lattice, and semilattice types.

A polynomial of an algebra is a composition of its basic operations, ${\displaystyle 0}$ -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 ${\displaystyle \mathbb {M} }$  falls into one of the following types (P. P. Pálfy) ^[1][2]

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

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

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

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

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