3.76-Gbps yellow-light visible light communication system over 1.2 m free space transmission utilizing a Si-substrate LED and a cascaded pre-equalizer network

Abstract: Recently, visible light communication (VLC) has emerged as a promising communication method in 6G. To achieve 6G high-speed transmission, wavelength division multiplexing (WDM) based VLC systems are a highly promising candidate. However, the “yellow and green gap” greatly limits the yellow light efficiency of InGaN-based LEDs and also restricts the transmission rate of yellow LEDs. In addition, pre-equalization and post-equalization also have an important impact on high-speed communication. In this paper, we p… Show more

“…Firstly, the lower resistance means lower heat dissipation given the same bias current. Secondly, the lower resistance in the V-pit sample suggests a higher optical signal in the modulation process 30 . The same conclusion could be drawn from Fig.…”

31.38 Gb/s GaN-based LED array visible light communication system enhanced with V-pit and sidewall quantum well structure

“…Firstly, the lower resistance means lower heat dissipation given the same bias current. Secondly, the lower resistance in the V-pit sample suggests a higher optical signal in the modulation process 30 . The same conclusion could be drawn from Fig.…”

31.38 Gb/s GaN-based LED array visible light communication system enhanced with V-pit and sidewall quantum well structure

Optimal Adaptive Waveform Design Utilizing an End-to-End Learning-Based Pre-Equalization Neural Network in an UVLC System

Key Technologies for High-Speed Si-Substrate LED Based Visible Light Communication