Hadamard Coded Modulation for Visible Light Communications

TL;DR

This paper introduces Hadamard coded modulation (HCM) for visible light communication systems, offering improved performance at high illumination levels by reducing peak-to-average power ratio and enhancing signal robustness.

Contribution

The paper proposes HCM using FWHT as an alternative to OFDM, and introduces DCR-HCM for dimmer lighting, improving power efficiency and reducing nonlinear distortion in VLC systems.

Findings

HCM outperforms OFDM at high illumination levels due to lower PAPR.

DCR-HCM enables lower peak amplitudes for dimmer lighting environments.

Interleaving enhances resistance to inter-symbol interference in dispersive VLC links.

Abstract

Visible light communication (VLC) systems using the indoor lighting system to also provide downlink communications require high average optical powers in order to satisfy the illumination needs. This can cause high amplitude signals common in higher-order modulation schemes to be clipped by the peak power constraint of the light emitting diode (LED) and lead to high signal distortion. In this paper we introduce Hadamard coded modulation (HCM) to achieve low error probabilities in LED-based VLC systems needing high average optical powers. This technique uses a fast Walsh-Hadamard transform (FWHT) to modulate the data as an alternative modulation technique to orthogonal frequency division multiplexing (OFDM). HCM achieves a better performance for high illumination levels because of its small peak to average power ratio (PAPR). The power efficiency of HCM can be improved by reducing the DC part of the transmitted signals without losing any information. The resulting so-called DC-reduced HCM (DCR-HCM) is well suited to environments requiring dimmer lighting as it transmits signals with lower peak amplitudes compared to HCM, which are thus subject to less nonlinear distortion. Interleaving can be applied to HCM to make the resulting signals more resistant against inter-symbol interference (ISI) in dispersive VLC links.