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Euclidean semirings
Given a additively cancellative commutative semiring , a term is left cancellative if for all and , implies .
A term is right cancellative if for all and , implies .
An term is cancellative if it is both left cancellative and right cancellative.
The multiplicative submonoid of cancellative elements in is the subset of all cancellative elements in
A Euclidean semiring is a additively cancellative commutative semiring for which there exists a function from the multiplicative submonoid of cancellative elements in to the natural numbers, often called a degree function, a function called the division function, and a function called the remainder function, such that for all and , and either or .
Non-cancellative and non-invertible elements
Given a ring , an element is non-cancellative if: if there is an element with injection such that , then . An element is non-invertible if: if there is an element with injection such that , then .
On real numbers and square roots
There is a significant difference between square roots and -th roots. Square roots are the inverse operation of the diagonal for any binary operation , while -th roots are inverse operations of the -dimensional diagonals for -ary operations, which we typically do not formally talk about in typical practice for rings, etc…
Derivatives
Given an Archimedean ordered integral domain such that the dyadic rationals , a pointwise continuous function is pointwise differentiable if it comes with a functionpointwise differentiable called if the it comes with a function called the derivative and a function on the positive dyadic rationals called the modulus of differentiability such that for every positive dyadic rational , for every term such that , and for every term ,
Algebra
Given a commutative ring , there is a commutative ring where is a subring of , with a function called composition, a term called the composition identity, a function called the shift, and a function called the derivative such that
rules for composition:
- for all ,
- for all ,
- for all ,
- for all , , and ,
- for all , , and ,
- for all , , and ,
rules for shifts:
- for all and
rules for derivatives:
- for all ,
- for all and ,
- for all and ,
Symbolic representations of formal smooth functions on the entire domain.