Definition:Bilinear Mapping

Definition
Let $\left({R, +_R, \times_R}\right)$ be a commutative ring.

Let $\left({A_1, +_1, \circ_1}\right)_R, \left({A_2, +_2, \circ_2}\right)_R, \left({A_3, +_3, \circ_3}\right)_R$ be $R$-modules.

Let $\oplus: A_1 \times A_2 \to A_3$ be a binary operator with the property that: $\forall \left({g_1, g_2}\right) \in G_1 \times G_2$:
 * $g_1 \mapsto g_1 \oplus g_2$ is a linear transformation from $G_1$ to $G_3$
 * $g_2 \mapsto g_1 \oplus g_2$ is a linear transformation from $G_2$ to $G_3$

Then $\oplus$ is a bilinear mapping.

That is, $\forall a, b \in R, \forall x, y, z \in A$:


 * $\left({a \circ_1 x}\right) +_1 \left({b \circ_1 y}\right) \oplus z = \left({a \circ_3 \left({x \oplus z}\right)}\right) +_3 \left({b \circ_3 \left({y \oplus z}\right)}\right)$
 * $z \oplus \left({a \circ_2 x}\right) +_2 \left({b \circ_2 y}\right) = \left({a \circ_3 \left({z \oplus x}\right)}\right) +_3 \left({b \circ_3 \left({z \oplus y}\right)}\right)$

If $\left({A, +, \circ}\right)_R = A_1 = A_2 = A_3$, the notation simplifies considerably:


 * $\left({a \circ x}\right) + \left({b \circ y}\right) \oplus z = \left({a \circ \left({x \oplus z}\right)}\right) + \left({b \circ \left({y \oplus z}\right)}\right)$
 * $z \oplus \left({a \circ x}\right) + \left({b \circ y}\right) = \left({a \circ \left({z \oplus x}\right)}\right) + \left({b \circ \left({z \oplus y}\right)}\right)$