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A New Decode-Rotate-and-Forward Strategy for Cooperative Relay Networks



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8.3A New Decode-Rotate-and-Forward Strategy for Cooperative Relay Networks

8.3.1System Description

We propose a new relaying strategy, called decode-rotate-and-forward for wireless relay networks. We consider a scenario where a source communicates with a destination with the help of a relay. The source and the relay are allowed to transmit simultaneously.

We consider a full-duplex relay, i.e., the relay is allowed to transmit and receive simultaneously.

We consider the wireless relay network depicted in Figure . The network consists of a source S which communicates statistically independent data to a single destination D cooperating through a relay R.

Except for the first transmission, the source and the relay transmit simultaneously. At source S, the information sequence us, of length k bits, is encoded by encoder Cs of rate Rs into codeword cs. Codeword cs is then modulated into xs and transmitted over a wireless channel. For simplicity, we first consider BPSK modulation.

Figure : Simultaneous transmission: the source and the relay transmit simultaneously; the relay forwards a coded version of the data source of the previous slot.


Due to the broadcast nature of the wireless channel the relay receives a noisy version of codewords cs, denoted by ys,r, from the source. During the same time slot, the relay transmits a new version xr of the source data received in the previous slot. The destination receives the signals from the source and the relay simultaneously and decodes the information of the source by jointly exploiting the received sequence yd from the source and the relay simultaneously. The transmission scheduling is illustrated Figure .
The relay receives a noisy version of codewords cs from the source, it decodes it, and generates an estimate of the information bits us. The estimated sequence ûs is then interleaved into ũs by an interleaver П, and re-encoded by another encoder Cr into codeword cr. Codeword cr is then modulated into xr using BPSK modulation rotated by an angle φ. Here, we consider a rotation angle φ=90°. The proposed distributed coding scheme is depicted in Figure .

Figure : Block diagram of the proposed decode-rotate-and-forward strategy: Encodings at the source and the relay. Equivalent distributed constellation between the source and the relay.


The modulation used in the proposed scheme can be seen as a distributed higher order modulation between the source and the relay (here, the resulting higher order modulation is a QPSK modulation) where the BPSK modulation at the source accounts for modulation on the I axis (Inphase axis) of the QPSK modulation and the BPSK modulation at the relay accounts for modulation on the Q axis (Quadrature axis). The equivalent distributed constellation is depicted in Figure .

At the destination D, a higher order demodulator is used to jointly demodulate the received sequence yd and generate the channels log-likelihood ratios (LLRs) LLR(xs) and LLR(xr). Here, since BPSK modulation is used at the source and the relay, a QPSK demodulator is considered. LLR(xs) and LLR(xr) are then passed to decoders C-1s and C-1r of the source code and the relay code, respectively. Decoding of the source information is performed in the classic way of a distributed turbo code [139], i.e., in an iterative fashion by exploiting the additional redundancy provided by the relay.

This work has recently been filed as a patent and is currently under review at the National Institute of Intellectual Properties (INPI France).

8.3.2Numerical Results

The performance of the proposed scheme is evaluated through simulations. For simplicity, the 4-state, rate-1/2, recursive convolutional encoder with generator polynomial (1,5/7)8 is used at the source and the relay. However, different constituent encoders at the sources and the relay can be considered. An S-random interleaver П and a maximum of ten decoding iterations are assumed.

For comparison purposes, we also consider the non-cooperation scenario where a source transmits to the destination without the help of the relay. For fair comparison, we consider that the source uses an encoder rate R=1/4 and QPSK modulation in order to be at the same spectral efficiency of our proposed scheme.
In Figure , we give BER results for the proposed decode-rotate-and-forward scheme over AWGN channels as a function of γsd and a block length k=128 bits. We also assume that drd=dsd and we assume that the source-to-relay link is reliable enough to guarantee a low error probability at the relay which is a necessary condition for the decode-and-forward strategy [141], and therefore for the new decode-rotate-and-forward strategy. In Figure , BPSK modulation is used at the source and a rotated BPSK of angle φ=90° is used at the relay. The resulting constellation is a QPSK constellation as described in Section 8.3.1.

The proposed distributed coding/modulation scheme shows a significant gain with respect to the non-cooperation scenario. For instance, a gain of almost 3 dB is observed at BER=10-3 compared to direct transmission. Moreover, it allows at efficiently exploiting the radio channel and achieves higher spectral efficiency compared to schemes time or frequency sharing transmission.




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