Performance analysis in multiuser downlink visible light communication MIMO system using SSK and optical orthogonal codes

This paper considers multiuser downlink transmission and detection in a multiple input-multiple output (MIMO) visible light communication (VLC) system. We combine two promising techniques: space-shift keying (SSK) and optical orthogonal codes (OOCs). Multiuser downlink transmission is realized by allowing each activated LED to transmit user-specific OOC simultaneously. An OOC despreader is implemented at the front end of each user terminal (UT) to extract the desired signal and mitigate multiuser interference (MUI). The second part of UT receiver aims to extract the index of the corresponding active LED based on maximum likelihood (ML) or zero-forcing (ZF) algorithm. The figure of merit we used to access the performance of the proposed downlink multiuser SSK system is the average symbol error rate (SER). Comprehensive Monte Carlo simulations have been undertaken for different system setup to evaluate SER at UT receiver. It is demonstrated that for a specified SER, the required SNR for ML-based detection algorithm is 3 dB less than the ZF detector in the MUI-free scenario. On the other hand, the ZF detector outperforms ML detector in the case with residual MUI and limited channel state information (CSI). Both algorithms are computationally attractive, hence can be put into practice in multiuser VLC MIMO system. This paper considers a space-shift keying (SSK)-based and optical orthogonal code (OOC)-aided multiuser downlink VLC-MIMO system. Multiuser downlink transmission is realized by allowing each activated LED to transmit user-specific optical orthogonal code (OOC). An OOC despreader is implemented in the front end of each user terminal (UT) to extract the desired signal to mitigate multiuser interference (MUI) and the index of the activated LED is identified by maximum likelihood (ML) or zero-forcing (ZF) algorithm. image