Wheel theory

Template:Short description

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 ${\displaystyle \odot }$ of the real projective line together with an extra point ⊥ (bottom element) such that ${\displaystyle \mathrm{\perp }=0/0}$.Template:SfnTemplate:Sfn

A wheel can be regarded as the equivalent of a commutative ring (and semiring) where addition and multiplication are not a group but respectively a commutative monoid and a commutative monoid with involution.Template:Sfn

Definition

A wheel is an algebraic structure ${\displaystyle (W,0,1,+,\cdot ,/)}$, in which

• ${\displaystyle W}$ is a set,
• ${\displaystyle }0$ and ${\displaystyle 1}$ are elements of that set,
• ${\displaystyle +}$ and ${\displaystyle \cdot }$ are binary operations,
• ${\displaystyle /}$ is a unary operation,

and satisfying the following properties:

• ${\displaystyle +}$ and ${\displaystyle \cdot }$ are each commutative and associative, and have ${\displaystyle 0}$ and ${\displaystyle 1}$ as their respective identities.
• ${\displaystyle /}$ is an involution, for example ${\displaystyle //x=x}$
• ${\displaystyle /}$ is multiplicative, for example ${\displaystyle /(xy)=/x/y}$
• ${\displaystyle (x+y)z+0z=xz+yz}$
• ${\displaystyle (x+yz)/y=x/y+z+0y}$
• ${\displaystyle 0\cdot 0=0}$
• ${\displaystyle (x+0y)z=xz+0y}$
• ${\displaystyle /(x+0y)=/x+0y}$
• ${\displaystyle 0/0+x=0/0}$

Algebra of wheels

Wheels replace the usual division as a binary operation with multiplication, with a unary operation applied to one argument ${\displaystyle /x}$ similar (but not identical) to the multiplicative inverse ${\displaystyle x^{-1}}$, such that ${\displaystyle a/b}$ becomes shorthand for ${\displaystyle a\cdot /b=/b\cdot a}$, but neither ${\displaystyle a\cdot b^{-1}}$ nor ${\displaystyle b^{-1}\cdot a}$ in general, and modifies the rules of algebra such that

• ${\displaystyle 0x\ne 0}$ in the general case
• ${\displaystyle x/x\ne 1}$ in the general case, as ${\displaystyle /x}$ is not the same as the multiplicative inverse of ${\displaystyle x}$.

Other identities that may be derived are

• ${\displaystyle 0x+0y=0xy}$
• ${\displaystyle x/x=1+0x/x}$
• ${\displaystyle x-x=0x^2}$

where the negation ${\displaystyle -x}$ is defined by ${\displaystyle -x=ax}$ and ${\displaystyle x-y=x+(-y)}$ if there is an element ${\displaystyle a}$ such that ${\displaystyle 1+a=0}$ (thus in the general case ${\displaystyle x-x\ne 0}$).

However, for values of ${\displaystyle x}$ satisfying ${\displaystyle 0x=0}$ and ${\displaystyle 0/x=0}$, we get the usual

• ${\displaystyle x/x=1}$
• ${\displaystyle x-x=0}$

If negation can be defined as above then the subset ${\displaystyle \{x\mid 0x=0\}}$ is a commutative ring, and every commutative ring is such a subset of a wheel. If ${\displaystyle x}$ is an invertible element of the commutative ring then ${\displaystyle x^{-1}=/x}$. Thus, whenever ${\displaystyle x^{-1}}$ makes sense, it is equal to ${\displaystyle /x}$, but the latter is always defined, even when ${\displaystyle x=0}$.Template:Sfn

Examples

Wheel of fractions

Let ${\displaystyle A}$ be a commutative ring, and let ${\displaystyle S}$ be a multiplicative submonoid of ${\displaystyle A}$. Define the congruence relation ${\displaystyle {\sim }_S}$ on ${\displaystyle A\times A}$ via

${\displaystyle (x_1,x_2){\sim }_S(y_1,y_2)}$ means that there exist ${\displaystyle s_x,s_y\in S}$ such that ${\displaystyle (s_x{x}_1,s_x{x}_2)=(s_y{y}_1,s_y{y}_2)}$.

Define the wheel of fractions of ${\displaystyle A}$ with respect to ${\displaystyle S}$ as the quotient ${\displaystyle A\times A/{\sim }_S}$ (and denoting the equivalence class containing ${\displaystyle (x_1,x_2)}$ as ${\displaystyle [x_1,x_2]}$) with the operations

${\displaystyle 0=[0_A,1_A]}$ Template:In5(additive identity)

${\displaystyle 1=[1_A,1_A]}$ Template:In5(multiplicative identity)

${\displaystyle /[x_1,x_2]=[x_2,x_1]}$ Template:In5(reciprocal operation)

${\displaystyle [x_1,x_2]+[y_1,y_2]=[x_1{y}_2+x_2{y}_1,x_2{y}_2]}$ Template:In5(addition operation)

${\displaystyle [x_1,x_2]\cdot [y_1,y_2]=[x_1{y}_1,x_2{y}_2]}$ Template:In5(multiplication operation)

In general, this structure is not a ring unless it is trivial, as ${\displaystyle 0x\ne 0}$ in the usual sense – here with ${\displaystyle x=[0,0]}$ we get ${\displaystyle 0x=[0,0]}$, although that implies that ${\displaystyle {\sim }_S}$ is an improper relation on our wheel ${\displaystyle W}$.

This follows from the fact that ${\displaystyle [0,0]=[0,1]⟹0\in S}$, which is also not true in general.Template:Sfn

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 a bottom element noted ⊥, where ${\displaystyle 0/0=\mathrm{\perp }}$. The projective line is itself an extension of the original field by an element ${\displaystyle \mathrm{\infty }}$, where ${\displaystyle z/0=\mathrm{\infty }}$ for any element ${\displaystyle z\ne 0}$ in the field. However, ${\displaystyle 0/0}$ 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 ${\displaystyle 0/0}$ 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.

See also

• NaN

Citations

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References

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