Secure Transmission With Antenna Selection in MIMO Nakagami- m Fading Channels

Secure Transmission With Antenna Selection in MIMO Nakagami- m Fading Channels

This paper considers transmit antenna selection (TAS) and receive generalized selection combining (GSC) for secure communication in the multiple-input-multiple-output wiretap channel, where confidential messages transmitted from an NA-antenna transmitter to an NB-antenna legitimate receiver are over...

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Bibliographic Details
Published in:IEEE transactions on wireless communications Vol. 13; no. 11; pp. 6054 - 6067
Main Authors: Lifeng Wang, Elkashlan, Maged, Jing Huang, Schober, Robert, Mallik, Ranjan K.
Format: Journal Article
Language:English
Published: New York IEEE 01-11-2014
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Antennas
Asymptotic properties
Channels
Codes
Fading
Niobium
Outages
Receivers
Receivers & amplifiers
Receiving antennas
Signal to noise ratio
Slopes
Transmitters
Transmitting antennas
Nakagami- m fading
physical layer security
Diversity combining
secrecy outage probability
average secrecy rate
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Summary:This paper considers transmit antenna selection (TAS) and receive generalized selection combining (GSC) for secure communication in the multiple-input-multiple-output wiretap channel, where confidential messages transmitted from an NA-antenna transmitter to an NB-antenna legitimate receiver are overheard by an NE-antenna eavesdropper. We assume that the main channel and the eavesdropper's channel undergo Nakagami-m fading with fading parameters mB and mE, respectively. In order to assess the secrecy performance, we present a new unifying framework for the average secrecy rate and the secrecy outage probability. We first derive expressions for the probability density function and the cumulative distribution function of the signal-to-noise ratio with TAS/GSC, from which we derive exact expressions for the average secrecy rate and the secrecy outage probability. We then derive compact expressions for the asymptotic average secrecy rate and the asymptotic secrecy outage probability for two distinct scenarios: 1) the legitimate receiver is located close to the transmitter, and 2) the legitimate receiver and the eavesdropper are located close to the transmitter. For these scenarios, we present new closed-form expressions for several key performance indicators: 1) the capacity slope and the power offset of the asymptotic average secrecy rate, and 2) the secrecy diversity order and the secrecy array gain of the asymptotic secrecy outage probability. For the first scenario, we confirm that the capacity slope is one and the secrecy diversity order is mBNBNA. For the second scenario, we confirm that the capacity slope and the secrecy diversity order collapse to zero.
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ISSN:1536-1276
1558-2248
DOI:10.1109/TWC.2014.2359877