A Note on Antenna Selection in Gaussian MIMO Channels: Capacity Guarantees and Bounds
Abstract
We consider the problem of selecting
k
t
×
k
r
antennas from a Gaussian MIMO channel with
n
t
×
n
r
antennas, where
k
t
≤
n
t
and
k
r
≤
n
r
. We prove the following two results that hold universally, in the sense that they do not depend on the channel coefficients: (i) The capacity of the best
k
t
×
k
r
subchannel is always lower bounded by a fraction
k
t
k
r
n
t
n
r
of the full capacity (with
n
t
×
n
r
antennas). This bound is tight as the channel coefficients diminish in magnitude. (ii) There always exists a selection of
k
t
×
k
r
antennas (including the best) that achieves a fraction greater than
min(
k
t
,
k
r
)
min(
n
t
,
n
r
)
of the full capacity within an additive constant that is independent of the coefficients in the channel matrix. The key mathematical idea that allows us to derive these universal bounds is to directly relate the determinants of principle sub-matrices of a Hermitian matrix to the determinant of the entire matrix.