Abstract
In this study, we propose a method named decomposition of the superposed constellation (DCSC) to design sparse code multiple access (SCMA) codebooks for the additive white Gaussian noise (AWGN) channel. We prove that the power of the user symbols (USs) is accurately determined by the power of the superposed constellation (SC). Thus, we select quadrature amplitude modulation (QAM) constellations as the SC and decompose the SC into several groups of USs with power diversity. The minimum Euclidean distance (MED) between superposed symbols (SS-MED) in the receiver is determined by the selected QAM and MED between the multi-dimensional codewords (CW-MED) is optimized by matching the symbols on different dimensions. We propose a simplified DCSC (S-DCSC) by modifying the factor graph and avoiding the transmission of USs with low power, which greatly reduces the complexity of the message passing algorithm (MPA). The simulations show that the SS-MEDs of DCSC and S-DCSC are larger than those in previous papers and the BER performance of the proposed codebooks is better than others.
Highlights
Compared with the 4G system, the spectrum efficiency of the 5G system in the future is increased by 5∼15 times [1]
By rotating the quadrature amplitude modulation (QAM) or pulse amplitude modulation (PAM) constellation employed by the colliding user on each resource, Ref. [11] optimized the superposed constellation (SC) to minimize the metric obtained from the upper bounded error probability in the additive white Gaussian noise (AWGN) channel
The Bit Error Rate (BER) performances of decomposition of the superposed constellation (DCSC) and simplified DCSC (S-DCSC) are estimated by comparing previous designs, such as MD-sparse code multiple access (SCMA) proposed in [8], golden angle modulation (GAM)-SCMA proposed in [9], and MUO-SCMA proposed in [11]
Summary
Compared with the 4G system, the spectrum efficiency of the 5G system in the future is increased by 5∼15 times [1]. A novel SCMA codebook design scheme to maximize the sum-rate was proposed in [5] by rotating the symbols on a 1-dimension complex constellation. By rotating the quadrature amplitude modulation (QAM) or pulse amplitude modulation (PAM) constellation employed by the colliding user on each resource, [11] optimized the SC to minimize the metric obtained from the upper bounded error probability in the additive white Gaussian noise (AWGN) channel. Since SCMA is a self interference system, these codebook design methods do not aim to reduce the interference between users Those schemes adopting the phase rotation are inefficient and the distribution of symbols in the SC is non-uniform which makes it difficult to distinguish some adjacent symbols. User is equivalent to user node (UN) and resource is equivalent to resource node (RN)
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