Generalized Multi-Carrier Waveforms in Two-Way Relay Systems

Autoren: M. Woltering, S. Schedler, D. Wübben, A. Dekorsy, V. Kühn
Kurzfassung:

In this chapter, two-way relaying networks using Physical-Layer Network Coding (PLNC) are considered with practical constraints. In a Multiple Access (MA) phase, two users transmit messages simultaneously on the same physical resources. The relay constructs a relay message based on the superimposed receive signal of both users. This message is broadcasted to the users which are able to extract the desired data from the other user. However, as the relay is not able to resolve shifts in time and frequency for the individual channels, the transmission scheme needs to be adjusted, if perfect synchronization cannot be ensured. This chapter deals with the proper selection of waveforms for multi-carrier systems in the Two-
Way-Relay Channel (TWRC) using PLNC. We address Generalized Frequency Division Multiplexing (GFDM) compared to Orthogonal Frequency Division Multiplexing (OFDM) under practical constraints like Carrier Frequency Offsets (CFOs) and Timing Offsets (TOs) within double dispersive channels. For OFDM rectangular transmit filters are used, which have a broad spectrum shape and are sensitive to shifts, especially in frequency domain. GFDM applies Gaussian waveforms that are inherently less susceptible to synchronization offsets than theirs rectangular counterparts, but additional interference is introduced even in a perfectly synchronized and flat fading channel. Thus, interferences caused by the channel or by the non-
orthogonal Gaussian impulse shape are treated by an equalizer at the relay. The simulation results show that the Gaussian waveform outperforms the conventional OFDM system if the nodes are not perfectly synchronized.

Dokumenttyp: Buchkapitel
in Buch: Communications in Interference-Limited Networks
Veröffentlichung: Springer, Berlin, Deutschland, Februar 2016
Dateien: BibTEX
Zuletzt aktualisiert am 16.12.2015 von D. Wübben
AIT ieee GOC tzi ith Fachbereich 1
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