2016 8th IEEE International Conference on Communication Software and Networks (ICCSN) 2016
DOI: 10.1109/iccsn.2016.7586686
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Cross-layer power allocation scheme for wireless full duplex relaying system

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Cited by 1 publication
(3 citation statements)
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“…SI is minimized with the help of passive SIS approach while taking into consideration various buffer constraints (with respect to arrival rates) at relay, source, and destination node. FD-Relay Networks Rayleigh Fading Channel Not Defined Passive SIS Approaches [292] FD-Relay Networks Rayleigh Fading Channel Directional Antenna [59] FD-Relay Networks Rayleigh Fading Channel Single Antenna [61] FD-Cellular Networks Nakagami-m Fading Channel MIMO Antenna [113] FD-Cellular Networks Nakagami-m Fading Channel MIMO Antenna [33] FD-Relay Networks Nakagami-m Fading Channel Bidirectional Antenna [293] FD-Relay Networks Rayleigh Fading Channel Not Defined [34] FD-Relay Networks Rayleigh Fading Channel MIMO Antenna [294] FD-Relay Networks Rayleigh Fading Channel MIMO Antenna Hybrid SIS Approaches [32] FD-Relay Networks Rayleigh Fading Channel Two Antennas [295] FD-Cellular Networks Rayleigh Fading Channel Omni-directional Antenna…”
Section: A Passive Self-interference Suppression Approachmentioning
confidence: 99%
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“…SI is minimized with the help of passive SIS approach while taking into consideration various buffer constraints (with respect to arrival rates) at relay, source, and destination node. FD-Relay Networks Rayleigh Fading Channel Not Defined Passive SIS Approaches [292] FD-Relay Networks Rayleigh Fading Channel Directional Antenna [59] FD-Relay Networks Rayleigh Fading Channel Single Antenna [61] FD-Cellular Networks Nakagami-m Fading Channel MIMO Antenna [113] FD-Cellular Networks Nakagami-m Fading Channel MIMO Antenna [33] FD-Relay Networks Nakagami-m Fading Channel Bidirectional Antenna [293] FD-Relay Networks Rayleigh Fading Channel Not Defined [34] FD-Relay Networks Rayleigh Fading Channel MIMO Antenna [294] FD-Relay Networks Rayleigh Fading Channel MIMO Antenna Hybrid SIS Approaches [32] FD-Relay Networks Rayleigh Fading Channel Two Antennas [295] FD-Cellular Networks Rayleigh Fading Channel Omni-directional Antenna…”
Section: A Passive Self-interference Suppression Approachmentioning
confidence: 99%
“…SI is minimized with the help of passive SIS approach while taking into consideration various buffer constraints (with respect to arrival rates) at relay, source, and destination node. FD-Relay Networks Rayleigh Fading Channel Single Antenna [61] FD-Cellular Networks Nakagami-m Fading Channel MIMO Antenna [113] FD-Cellular Networks Nakagami-m Fading Channel MIMO Antenna [33] FD-Relay Networks Nakagami-m Fading Channel Bidirectional Antenna [293] FD-Relay Networks Rayleigh Fading Channel Not Defined [34] FD-Relay Networks Rayleigh Fading Channel MIMO Antenna [294] FD-Relay Networks Rayleigh Fading Channel MIMO Antenna Hybrid SIS Approaches [32] FD-Relay Networks Rayleigh Fading Channel Two Antennas [295] FD-Cellular Networks Rayleigh Fading Channel Omni-directional Antenna Performance of the proposed scheme has been tested with achievable EC and shows improvement as compared to other state-of-the-art schemes. Time-critical and delay-sensitive applications such as video transmission with FD communications is investigated in [59], while considering the EC model.…”
Section: A Passive Self-interference Suppression Approachmentioning
confidence: 99%
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