Recall that any unit lower triangular matrix $L\in\mathbb{R}^{n\times n}$ can be written in factored form as \begin{equation} L = M_1 M_2\ldots M_{n-1} \end{equation} where $M_i = I + l_i e_i^{T}$ is an elementary unit lower triangular matrix (column form). Given a simple elementary unit lower triangular matrix (element form) that differs from the identity in one off-diagonal element in the strict lower triangular part, i.e. $$E_{ij} = I + \lambda_{ij}e_i e_j^{T}$$ where $i\neq j$.
i.) Write a column form elementary matrix $M_i$ in terms of element form elementary matrices. Does the order of the $E_{ji}$ matter in this product?
ii.) Show how it follows that the factorization of $L$ is easily expressed in terms of element form elementary matrices.
iii.) Show that the expression from part (ii) can be rearranged to form $L = R_2\ldots R_n$ where $R_i = I + e_i r_i^{T}$ is an elementary unit lower triangular matrix in row form.
i.) From the answer provided we let $\lambda_{ij}$ denote the $j$th entry of the vector $l_i$. We note that $$M_i = I + l_i e_{i}^{T} = \prod_{j=1}^{i-1}(I + \lambda_{ij}e_je_i^{T}) = \prod_{j=1}^{i-1}E_{ji}$$
ii.) So we have $$M_i = \prod_{j=1}^{i-1}E_{ji}$$ and $$L = M_1\ldots M_{n-1} = \prod_{j=1}^{i-1}E_{ji}$$ where do we go from here?
Let $\lambda_{ij}$ denote the $j$th entry of the vector $l_i$. We note that $$ (I + l_i e_i^T) = \prod_{j=1}^{i-1} (I + \lambda_{ij} e_je_i^T) $$ Note that these $E_{ji}$ commute with $[e_je_i^T][e_{j'}e_i^T] = 0$ so long as neither $j$ nor $j'$ is equal to $i$.