Publication: Predicting the DC bias and optimizing BER and PAPR in DCO-OFDM: An explainable machine learning approach
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Co-Authors
Kepezkaya, Talat
Dede, Reyhan
Başar, Ertuğrul
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Date
Language
eng
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No
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Abstract
This paper proposes an explainable machine-learning framework for adaptive DC-bias selection and optimization in DC-biased orthogonal frequency division multiplexing (DCO-OFDM) systems. A large-scale synthetic dataset comprising 20,000 OFDM instances is generated using a physics-consistent DCO-OFDM signal model by sweeping the bias scaling factor. Each instance is labeled with the minimum DC bias that satisfies a target reliability constraint, while the corresponding minimum required target signal-to-noise ratio (TSNR) and peak-to-average power ratio (PAPR) are also recorded. Using only compact signal statistics together with system parameters, a LightGBM regressor accurately predicts the optimal DC bias under a leak-safe evaluation protocol that includes train-only preprocessing, fixed holdout testing, and multi-seed validation. The model achieves R-2 = 0.9946 +/- 0.0004 on in-distribution data and retains meaningful generalization performance under out-of-distribution settings. To enhance transparency, SHAP and LIME analyses are employed to interpret feature contributions. In a subsequent optimization stage, multi-output regression models are investigated to jointly predict DC bias V-DC(dB) , PAPR, and TSNR. Among the evaluated models, the Gradient Boosting Regressor provides the best overall performance, achieving R-2 = 0.9614 for V-DC(dB) , 0.9287 for PAPR, and 0.9570 for TSNR. A Pareto-based Optuna optimization then identifies nondominated operating points that capture the trade-offs among V-DC(dB) , PAPR, and TSNR. Simulation results demonstrate consistent improvements in BER and PAPR over fixed-bias baselines, while preserving performance trends under deployment-relevant impairments, including LED front-end nonlinearity and static multipath optical channels.
Source
Publisher
IEEE
Subject
Telecommunications
Citation
Has Part
Source
IEEE Transactions on Cognitive Communications and Networking
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Edition
DOI
10.1109/TCCN.2026.3669130
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Creative Commons license
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