Abstract
We consider specular and diffuse reflection models for indoor visible light communications using a mobile receiver with angular diversity detectors in multiple input multiple output (MIMO) channels. We aim to improve the MIMO throughput compared to vertically oriented detectors by exploiting multipath reflections from different surfaces in the room. We then evaluate data throughput across multiple locations in the small room by using repetition coding, spatial multiplexing, and spatial modulation approaches. In spatial modulation, we also propose a novel approach called adaptive spatial modulation. This makes use of channel matrix rank information to decide which TX/RX setup to be used, and is developed to cope with rank deficient channels. In a scenario, where the receiver is moving, channel gains are weak in some locations due to the lack of line of sight (LOS) propagation between transmitters and receivers. This effect is mitigated by employing adaptive modulation and coding together with per antenna rate control. We then compare the throughput for LOS only channels against LOS with specular or diffuse reflection conditions, for both vertical and angular oriented receivers. The results show that exploiting specular and diffuse reflections provide significant improvements in link performance.
Highlights
W ITH the development of wireless communications applications, there is a rapid rise in data demand, while the available radio frequency (RF) spectrum cannot meet this growth and becomes the limiting factor for achieving higher transmission rates [1]
We provide performance statistics for multiple input multiple output (MIMO) methods operating over many room locations using adaptive modulation and coding (AMC), adaptive spatial modulation (ASM), and per antenna rate control (PARC) [18]
The system is located within a room of size 4 × 4 × 3 m and we assume the transmitters are placed at a height of 2.50 m and oriented downwards perpendicular to the floor of the room
Summary
W ITH the development of wireless communications applications, there is a rapid rise in data demand, while the available radio frequency (RF) spectrum cannot meet this growth and becomes the limiting factor for achieving higher transmission rates [1]. The spectrum ranging from 10μm (infra-red) to 10nm (ultraviolet) including visible light offers nearly limitless bandwidth which may be utilized for communications such as wireless local area networks (WLAN). The light emitting diode transmitter modulates data and transforms the electrical signal to an optical signal while the photo-diode receiver converts the incoming optical signal into an electrical current for data processing. With the development of solidstate lighting, white light emitting diodes (LEDs) will replace existing conventional light bulbs so communications and illumination can take place simultaneously, saving power [2]. Visible light communications is cheap because of the low cost and reliability of light sources and receivers
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