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.
Let A<sub>F</sub> be a vector space over a field F, and let L<sub>1</sub> and L<sub>2</sub> be two linear functionals on A<sub>F</sub> with the property L<sub>1</sub>(e) = L<sub>2</sub>(e) = 1<sub>F</sub> for some e in A<sub>F</sub>. We define multiplication of two elements x, y in A<sub>F</sub> by
It can be verified that the above multiplication is associative and that e is the identity of this multiplication.
So, A<sub>F</sub> forms an associative algebra with unit e and is called a functional theoretic algebra(FTA).
Suppose the two linear functionals L<sub>1</sub> and L<sub>2</sub> are the same, say L. Then A<sub>F</sub> becomes a commutative algebra with multiplication defined by
X is a nonempty set and F a field. F<sup>X</sup> is the set of functions from X to F.
If f, g are in F<sup>X</sup>, x in X and ñ in F, then define
and
With addition and scalar multiplication defined as this, F<sup>X</sup> 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<sub>F</sub> for all x in X.
Define L<sub>1</sub> and L<sub>2</sub> from F<sup>X</sup> to F by L<sub>1</sub>(f) = f(a) and L<sub>2</sub>(f) = f(b).
Then L<sub>1</sub> and L<sub>2</sub> are two linear functionals on F<sup>X</sup> such that L<sub>1</sub>(e)= L<sub>2</sub>(e)= 1<sub>F</sub> For f, g in F<sup>X</sup> define
Then F<sup>X</sup> becomes a non-commutative function algebra with the function e as the identity of multiplication.
Note that
Let C denote the field of Complex numbers. A continuous function ó from the closed interval [0, 1] of real numbers to the field C is called a curve. The complex numbers ó(0) and ó(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 we have for ñ,ò in C[0, 1],
Then, V[0, 1] is a non-commutative algebra with e as the unity.
We illustrate this with an example.
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
Since the circle g is a loop. The line segment f starts from : and ends at
Now, we get two f-products given by
and
See the Figure.
Observe that showing that multiplication is non-commutative. Also both the products starts from