An index coding (IC) problem consisting of a server and multiple receivers
with different side-information and demand sets can be equivalently represented
using a fitting matrix. A scalar linear index code to a given IC problem is a
matrix representing the transmitted linear combinations of the message symbols.
The length of an index code is then the number of transmissions (or
equivalently, the number of rows in the index code). An IC problem Iextβ is called an extension of another IC problem I if the
fitting matrix of I is a submatrix of the fitting matrix of Iextβ. We first present a straightforward m\textit{-order} extension
Iextβ of an IC problem I for which an index code is
obtained by concatenating m copies of an index code of I. The length
of the codes is the same for both I and Iextβ, and if the
index code for I has optimal length then so does the extended code for
Iextβ. More generally, an extended IC problem of I having
the same optimal length as I is said to be a \textit{rank-invariant}
extension of I. We then focus on 2-order rank-invariant extensions
of I, and present constructions of such extensions based on involutory
permutation matrices