bilinear map

Let $R$ be a ring, and let $M$, $N$ and $P$ be modules over $R$.A function $f:M\times N\to P$is said to be a bilinear mapif for each $b\in M$ the function $h:N\to P$defined by $h(y)=f(b,y)$ for all $y\in N$ is linear (http://planetmath.org/LinearTransformation)(that is, an $R$-module homomorphism),and for each $c\in N$ the function $g:M\to P$defined by $g(x)=f(x,c)$ for all $x\in M$ is linear.Sometimes we may say that the function is $R$-bilinear,.

A common case is a bilinear map $V\times V\to V$,where $V$ is a vector space over a field $K$;the vector space with this operation then forms an algebra over $K$.

If $R$ is a commutative ring, then every $R$-bilinear map $M\times N\to P$corresponds in a natural way to a linear map $M\otimes N\to P$,where $M\otimes N$ is the tensor product of $M$ and $N$ (over $R$).