39 research outputs found
On Covert Communication With Noise Uncertainty
Prior studies on covert communication with noise
uncertainty adopted a worst-case approach from the warden’s
perspective. That is, the worst-case detection performance of the
warden is used to assess covertness, which is overly optimistic.
Instead of simply considering the worst limit, in this work,
we take the distribution of noise uncertainty into account to
evaluate the overall covertness in a statistical sense. Specifically,
we define new metrics for measuring the covertness, which are
then adopted to analyze the maximum achievable rate for a given
covertness requirement under both bounded and unbounded
noise uncertainty models.ARC Discovery Projects Grant DP15010390
Covert Communication in Fading Channels under Channel Uncertainty
A covert communication system under block fading channels is considered where
users experience uncertainty about their channel knowledge. The transmitter
seeks to hide the covert communication to a private user by exploiting a
legitimate public communication link while the warden tries to detect this
covert communication by using a radiometer. We derive the exact expression for
the radiometers optimal threshold which determines the performance limit of the
wardens detector. Furthermore for given transmission outage constraints the
achievable rates for legitimate and covert users are analyzed while maintaining
a specific level of covertness. Our numerical results illustrate how the
achievable performance is affected by the channel uncertainty and required
level of covertness.Comment: to appear in IEEE VTC2017-Sprin
Achieving Covert Wireless Communications Using a Full-Duplex Receiver
Covert communications hide the transmission of a message from a watchful
adversary while ensuring a certain decoding performance at the receiver. In
this work, a wireless communication system under fading channels is considered
where covertness is achieved by using a full-duplex (FD) receiver. More
precisely, the receiver of covert information generates artificial noise with a
varying power causing uncertainty at the adversary, Willie, regarding the
statistics of the received signals. Given that Willie's optimal detector is a
threshold test on the received power, we derive a closed-form expression for
the optimal detection performance of Willie averaged over the fading channel
realizations. Furthermore, we provide guidelines for the optimal choice of
artificial noise power range, and the optimal transmission probability of
covert information to maximize the detection errors at Willie. Our analysis
shows that the transmission of artificial noise, although causes
self-interference, provides the opportunity of achieving covertness but its
transmit power levels need to be managed carefully. We also demonstrate that
the prior transmission probability of 0.5 is not always the best choice for
achieving the maximum possible covertness, when the covert transmission
probability and artificial noise power can be jointly optimized.Comment: 13 pages, 11 figures, Accepted for publication in IEEE Transactions
on Wireless Communication
Covert Wireless Communication with a Poisson Field of Interferers
In this paper, we study covert communication in wireless networks consisting
of a transmitter, Alice, an intended receiver, Bob, a warden, Willie, and a
Poisson field of interferers. Bob and Willie are subject to uncertain shot
noise due to the ambient signals from interferers in the network. With the aid
of stochastic geometry, we analyze the throughput of the covert communication
between Alice and Bob subject to given requirements on the covertness against
Willie and the reliability of decoding at Bob. We consider non-fading and
fading channels. We analytically obtain interesting findings on the impacts of
the density and the transmit power of the concurrent interferers on the covert
throughput. That is, the density and the transmit power of the interferers have
no impact on the covert throughput as long as the network stays in the
interference-limited regime, for both the non-fading and the fading cases. When
the interference is sufficiently small and comparable with the receiver noise,
the covert throughput increases as the density or the transmit power of the
concurrent interferers increases