A=n×p, B=p×m, AB=n×m
A\vec v_1&A\vec v_2&\cdots&A\vec v_m
\end{bmatrix},\space B=\begin{bmatrix}
\vec v_1&\vec v_2&\cdots&\vec v_m
\end{bmatrix},\space A\vec v_i=v_{i_1}A_{j1}+v_{i_2}A_{j2}+\ldots + v_{i_m}A_{jm}$$
## $T:\mathbb{R}^m\rightarrow\mathbb{R}^n,\space A=n\times m$
* Not commuative $AB \ne BA$
* Associative $A(BC) = (AB)C$
* Has identity, $AI_p=I_nA=A$
* Distributive for matrix and scalar multiplication $A(B+C)=AB+AC \,\forall A\in\mathbb{M},\mathbb{R}$