Functional-theoretic algebra

Any vector space can be made into a unital associative algebra, called functional-theoretic algebra, by defining products in terms of two linear functionals. In general, it is a non-commutative algebra. It becomes commutative when the two functionals are the same.

Definition[edit]

Let A_F be a vector space over a field F, and let L₁ and L₂ be two linear functionals on A_F with the property L₁(e) = L₂(e) = 1_F for some e in A_F. We define multiplication of two elements x, y in A_F by

${\displaystyle x\cdot y=L_{1}(x)y+L_{2}(y)x-L_{1}(x)L_{2}(y)e.}$

It can be verified that the above multiplication is associative and that e is the identity of this multiplication.

So, A_F forms an associative algebra with unit e and is called a functional theoretic algebra(FTA).

Suppose the two linear functionals L₁ and L₂ are the same, say L. Then A_F becomes a commutative algebra with multiplication defined by

${\displaystyle x\cdot y=L(x)y+L(y)x-L(x)L(y)e.}$

Example[edit]

X is a nonempty set and F a field. F^X is the set of functions from X to F.

If f, g are in F^X, x in X and α in F, then define

${\displaystyle (f+g)(x)=f(x)+g(x)\,}$

and

${\displaystyle (\alpha f)(x)=\alpha f(x).\,}$

With addition and scalar multiplication defined as this, F^X is a vector space over F.

Now, fix two elements a, b in X and define a function e from X to F by e(x) = 1_F for all x in X.

Define L₁ and L₂ from F^X to F by L₁(f) = f(a) and L₂(f) = f(b).

Then L₁ and L₂ are two linear functionals on F^X such that L₁(e)= L₂(e)= 1_F For f, g in F^X define

${\displaystyle f\cdot g=L_{1}(f)g+L_{2}(g)f-L_{1}(f)L_{2}(g)e=f(a)g+g(b)f-f(a)g(b)e.}$

Then F^X becomes a non-commutative function algebra with the function e as the identity of multiplication.

Note that

${\displaystyle (f\cdot g)(a)=f(a)g(a){\mbox{ and }}(f\cdot g)(b)=f(b)g(b).}$

FTA of Curves in the Complex Plane[edit]

Let C denote the field of Complex numbers. A continuous function γ from the closed interval [0, 1] of real numbers to the field C is called a curve. The complex numbers γ(0) and γ(1) are, respectively, the initial and terminal points of the curve. If they coincide, the curve is called a loop. The set V[0, 1] of all the curves is a vector space over C.

We can make this vector space of curves into an algebra by defining multiplication as above. Choosing ${\displaystyle e(t)=1,\forall \in [0,1]}$ we have for α,β in C[0, 1],

${\displaystyle {\alpha }\cdot {\beta }={\alpha }(0){\beta }+{\beta }(1){\alpha }-{\alpha }(0){\beta }(1)e}$

Then, V[0, 1] is a non-commutative algebra with e as the unity.

We illustrate this with an example.

Example of f-Product of Curves[edit]

Let us take (1) the line segment joining the points (1, 0) and (0, 1) and (2) the unit circle with center at the origin. As curves in V[0, 1], their equations can be obtained as

${\displaystyle f(t)=1-t+it{\mbox{ and }}g(t)=\cos(2\pi t)+i\sin(2\pi t)}$

Since ${\displaystyle g(0)=g(1)=1}$ the circle g is a loop. The line segment f starts from :${\displaystyle f(0)=1}$ and ends at ${\displaystyle f(1)=i}$

Now, we get two f-products ${\displaystyle f\cdot g{\mbox{ and }}g\cdot f}$ given by

${\displaystyle (f\cdot g)(t)=[-t+\cos(2\pi t)]+i[t+\sin(2\pi t)]}$

and

${\displaystyle (g\cdot f)(t)=[1-t-\sin(2\pi t)]+i[t-1+\cos(2\pi t)]}$

See the Figure.

Observe that ${\displaystyle f\cdot g\neq g\cdot f}$ showing that multiplication is non-commutative. Also both the products starts from ${\displaystyle f(0)g(0)=1{\mbox{ and ends at }}f(1)g(1)=i.}$

See also[edit]

• N-curve

References[edit]