Yeşilkaya, AnılPurwita, Ardimas AndiPanayırcı, ErdalPoor, H. VincentHaas, Harald2021-07-242021-07-2420202978-172818298-8https://hdl.handle.net/20.500.12469/4091The limited bandwidth of optical wireless communication (OWC) front-end devices motivates the use of multipleinput- multiple-output (MIMO) techniques to enhance data rates. It is known that very high multiplexing gains can be achieved by spatial multiplexing (SMX) at the cost of prohibitive detection complexity. Alternatively, in spatial modulation (SM), a single light emitting diode (LED) is activated per time instance where information is carried by both the signal and the LED index. Since only one LED is active, both the transmitter (TX) and receiver (RX) complexity reduce significantly while retaining the information transmission in the spatial domain. However, this simplified TX utilization approach leads SM to suffer from significant spectral efficiency losses compared to SMX. In this paper, we propose a technique that benefits from the advantages of both systems. Accordingly, the proposed flexible LED index modulation (FLIM) technique harnesses the inactive state of the LEDs as a transmit symbol. Therefore, the number of active LEDs changes in each transmission, unlike conventional techniques. Moreover, the system complexity is reduced by employing a linear minimum mean squared error (MMSE) equalizer and an angle perturbed receiver. Numerical results show that FLIM outperforms the reference systems by at least 6 dB in the low and medium/high spectral efficiency regions.eninfo:eu-repo/semantics/openAccessminimum mean square equalizer (MMSE)multiple-input-multiple-output (MIMO)Optical wireless communications (OWC)spatial modulation (SM)Book PartWOS:00066897050215210.1109/GLOBECOM42002.2020.93225282-s2.0-85100401491N/AN/A