2,619 research outputs found
On Secrecy Metrics for Physical Layer Security over Quasi-Static Fading Channels
Theoretical studies on physical layer security often adopt the secrecy outage
probability as the performance metric for wireless communications over
quasi-static fading channels. The secrecy outage probability has two
limitations from a practical point of view: a) it does not give any insight
into the eavesdropper's decodability of confidential messages; b) it cannot
characterize the amount of information leakage to the eavesdropper when an
outage occurs. Motivated by the limitations of the secrecy outage probability,
we propose three new secrecy metrics for secure transmissions over quasi-static
fading channels. The first metric establishes a link between the concept of
secrecy outage and the decodability of messages at the eavesdropper. The second
metric provides an error-probability-based secrecy metric which is typically
used for the practical implementation of secure wireless systems. The third
metric characterizes how much or how fast the confidential information is
leaked to the eavesdropper. We show that the proposed secrecy metrics
collectively give a more comprehensive understanding of physical layer security
over fading channels and enable one to appropriately design secure
communication systems with different views on how secrecy is measured.ARC Discovery Projects Grant DP15010390
Near-Optimal Modulo-and-Forward Scheme for the Untrusted Relay Channel
This paper studies an untrusted relay channel, in which the destination sends
artificial noise simultaneously with the source sending a message to the relay,
in order to protect the source's confidential message. The traditional
amplify-and-forward (AF) scheme shows poor performance in this situation
because of the interference power dilemma: providing better security by using
stronger artificial noise will decrease the confidential message power from the
relay to the destination. To solve this problem, a modulo-and-forward (MF)
operation at the relay with nested lattice encoding at the source is proposed.
For this system with full channel state information at the transmitter (CSIT),
theoretical analysis shows that the proposed MF scheme approaches the secrecy
capacity within 1/2 bit for any channel realization, and hence achieves full
generalized security degrees of freedom (G-SDoF). In contrast, the AF scheme
can only achieve a small fraction of the G-SDoF. For this system without any
CSIT, the total outage event, defined as either connection outage or secrecy
outage, is introduced. Based on this total outage definition, analysis shows
that the proposed MF scheme achieves the full generalized secure diversity gain
(G-SDG) of order one. On the other hand, the AF scheme can only achieve a G-SDG
of 1/2 at most
On the Throughput Cost of Physical Layer Security in Decentralized Wireless Networks
This paper studies the throughput of large-scale decentralized wireless
networks with physical layer security constraints. In particular, we are
interested in the question of how much throughput needs to be sacrificed for
achieving a certain level of security. We consider random networks where the
legitimate nodes and the eavesdroppers are distributed according to independent
two-dimensional Poisson point processes. The transmission capacity framework is
used to characterize the area spectral efficiency of secure transmissions with
constraints on both the quality of service (QoS) and the level of security.
This framework illustrates the dependence of the network throughput on key
system parameters, such as the densities of legitimate nodes and eavesdroppers,
as well as the QoS and security constraints. One important finding is that the
throughput cost of achieving a moderate level of security is quite low, while
throughput must be significantly sacrificed to realize a highly secure network.
We also study the use of a secrecy guard zone, which is shown to give a
significant improvement on the throughput of networks with high security
requirements.Comment: Accepted for publication in IEEE Transactions on Wireless
Communication
On the Design of Artificial-Noise-Aided Secure Multi-Antenna Transmission in Slow Fading Channels
In this paper, we investigate the design of artificial-noise-aided secure
multi-antenna transmission in slow fading channels. The primary design concerns
include the transmit power allocation and the rate parameters of the wiretap
code. We consider two scenarios with different complexity levels: i) the design
parameters are chosen to be fixed for all transmissions, ii) they are
adaptively adjusted based on the instantaneous channel feedback from the
intended receiver. In both scenarios, we provide explicit design solutions for
achieving the maximal throughput subject to a secrecy constraint, given by a
maximum allowable secrecy outage probability. We then derive accurate
approximations for the maximal throughput in both scenarios in the high
signal-to-noise ratio region, and give new insights into the additional power
cost for achieving a higher security level, whilst maintaining a specified
target throughput. In the end, the throughput gain of adaptive transmission
over non-adaptive transmission is also quantified and analyzed.Comment: to appear in IEEE Transactions on Vehicular Technolog
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