'Institute of Electrical and Electronics Engineers (IEEE)'
Abstract
In this paper, we investigate the sensing-aided
physical layer security (PLS) towards Integrated Sensing and
Communication (ISAC) systems. A well-known limitation of PLS
is the need to have information about potential eavesdroppers
(Eves). The sensing functionality of ISAC offers an enabling role
here, by estimating the directions of potential Eves to inform PLS.
In our approach, the ISAC base station (BS) firstly emits an omnidirectional waveform to search for potential Eves’ directions by
employing the combined Capon and approximate maximum likelihood (CAML) technique. Using the resulting information about
potential Eves, we formulate secrecy rate expressions, that are a
function of the Eves’ estimation accuracy. We then formulate a
weighted optimization problem to simultaneously maximize the
secrecy rate and minimize the CRB with the aid of the artificial
noise (AN), and minimize the CRB of targets’/Eves’ estimation.
By taking the possible estimation errors into account, we enforce
a beampattern constraint with a wide main beam covering all
possible directions of Eves. This implicates that security needs
to be enforced in all these directions. By improving estimation
accuracy, the sensing and security functionalities provide mutual
benefits, resulting in improvement of the mutual performances
with every iteration of the optimization, until convergence. Our
results avail of these mutual benefits and reveal the usefulness
of sensing as an enabler for practical PLS
