Multi-User Visible Light Communications with Probabilistic Constellation Shaping and Precoding

This paper proposes a joint design of probabilistic constellation shaping (PCS) and precoding to enhance the sumrate performance of multi-user visible light communications (VLC) broadcast channels subject to signal amplitude constraint. In the proposed design, the transmission probabilities of bipol...

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Bibliographic Details
Published inIEEE transactions on communications p. 1
Main Authors Nguyen, Thang K., Pham, Thanh V., Le, Hoang D., Nguyen, Chuyen T., Pham, Anh T.
Format Journal Article
LanguageEnglish
Published IEEE 2025
Subjects
Light emitting diodes
Optical transmitters
Optimization
Precoding
probabilistic constellation shaping
Probabilistic logic
sum-rate maximization
Symbols
Uncertainty
Vectors
Visible light communication
Visible light communications
Wireless communication
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ISSN0090-6778
1558-0857
DOI10.1109/TCOMM.2025.3543208

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Summary:This paper proposes a joint design of probabilistic constellation shaping (PCS) and precoding to enhance the sumrate performance of multi-user visible light communications (VLC) broadcast channels subject to signal amplitude constraint. In the proposed design, the transmission probabilities of bipolar M -pulse amplitude modulation ( M -PAM) symbols for each user and the transmit precoding matrix are jointly optimized to improve the sum-rate performance. The joint design problem is shown to be a complex multivariate non-convex problem due to the non-convexity of the objective function. To tackle the original non-convex optimization problem, the firefly algorithm (FA), a nature-inspired heuristic optimization approach, is employed to solve a local optima. The FA-based approach, however, suffers from high computational complexity. Thus, using zero-forcing (ZF) precoding, we propose a low-complexity design, which is solved using an alternating optimization approach. Additionally, considering the channel uncertainty, a robust design based on the concept of end-to-end learning with autoencoder (AE) is also presented. Simulation results reveal that the proposed joint design with PCS significantly improves the sum-rate performance compared to the conventional design with uniform signaling. For instance, the joint design achieves 17.5% and 19.2% higher sum-rate for 8-PAM and 16-PAM, respectively, at 60 dB peak amplitude-to-noise ratio. Some insights into the optimal symbol distributions of the two joint design approaches are also provided. Furthermore, our results show the advantage of the proposed robust design over the non-robust one under uncertain channel conditions.
ISSN:0090-6778
1558-0857
DOI:10.1109/TCOMM.2025.3543208