Wheel theory
A wheel is a type of algebra, in the sense of universal algebra, where division is always defined. In particular, division by zero is meaningful. The real numbers can be extended to a wheel, as can any commutative ring.
The term wheel is inspired by the topological picture of the projective line together with an extra point .[1]
Definition
A wheel is an algebraic structure , in which
- is a set,
- and are elements of that set,
- and are binary operators,
- is a unary operator,
and satisfying the following:
- Addition and multiplication are commutative and associative, with and as their respective identities.
- (/ is an involution)
- (/ is multiplicative)
Algebra of wheels
Wheels replace the usual division as a binary operator with multiplication, with a unary operator applied to one argument similar (but not identical) to the multiplicative inverse , such that becomes shorthand for , and modifies the rules of algebra such that
- in the general case
- in the general case
- in the general case, as is not the same as the multiplicative inverse of .
If there is an element such that , then we may define negation by and .
Other identities that may be derived are
And, for with and , we get the usual
If negation can be defined as above then the subset is a commutative ring, and every commutative ring is such a subset of a wheel. If is an invertible element of the commutative ring, then . Thus, whenever makes sense, it is equal to , but the latter is always defined, even when .
Examples
Wheel of fractions
Let be a commutative ring, and let be a multiplicative submonoid of . Define the congruence relation on via
- means that there exist such that .
Define the wheel of fractions of with respect to as the quotient (and denoting the equivalence class containing as ) with the operations
- (additive identity)
- (multiplicative identity)
- (reciprocal operation)
- (addition operation)
- (multiplication operation)
Projective line and Riemann sphere
The special case of the above starting with a field produces a projective line extended to a wheel by adjoining an element , where . The projective line is itself an extension of the original field by an element , where for any element in the field. However, is still undefined on the projective line, but is defined in its extension to a wheel.
Starting with the real numbers, the corresponding projective "line" is geometrically a circle, and then the extra point gives the shape that is the source of the term "wheel". Or starting with the complex numbers instead, the corresponding projective "line" is a sphere (the Riemann sphere), and then the extra point gives a 3-dimensional version of a wheel.
Citations
References
- Setzer, Anton (1997), Wheels (PDF) (a draft)
- Carlström, Jesper (2004), "Wheels – On Division by Zero", Mathematical Structures in Computer Science, Cambridge University Press, 14 (1): 143–184, doi:10.1017/S0960129503004110 (also available online here).
- A, BergstraJ; V, TuckerJ (1 April 2007). "The rational numbers as an abstract data type". Journal of the ACM. 54 (2): 7. doi:10.1145/1219092.1219095. S2CID 207162259.
- Bergstra, Jan A.; Ponse, Alban (2015). "Division by Zero in Common Meadows". Software, Services, and Systems: Essays Dedicated to Martin Wirsing on the Occasion of His Retirement from the Chair of Programming and Software Engineering. Lecture Notes in Computer Science. Springer International Publishing. 8950: 46–61. doi:10.1007/978-3-319-15545-6_6. ISBN 978-3-319-15544-9. S2CID 34509835.