Spatial Modulation – A Low Complexity Modulation Technique for Visible Light Communications

In visible light communication (VLC), the fundamental limitation on the achievable data rate/spectral efficiency is imposed by the optical source, particularly the phosphor-converted white light emitting diode (LED). These low-cost white LEDs favoured in solid-state lighting have very limited modulation bandwidth of less than 5 MHz, typically. This imposes a severe limitation on the attainable data rate. This is recognised in the literature and has led to the emergence of techniques such as multiple-input-multiple-output (MIMO) VLC systems as a means of addressing this challenge. The MIMO approach takes advantage of the multi-LED/multi-receiver structure to improve performance. In this chapter, we shall be discussing spatial modulation (SM) as a novel low-complexity MIMO technique for the VLC system. The SM technique exploits the spatial location of the individual LED as an additional degree of freedom in data modulation. Moreover, the chapter includes the comparison analysis of the SM technique with other traditional methods of modulation such as on-off keying (OOK) and pulse position modulation (PPM)

Space Shift Keying Modulation in Non-Orthogonal Multiple Access Hybrid Visible Light Communication Systems (Invited Paper)

Visible light communication (VLC) is considered a breakthrough wireless communication technology that has been proven capable of achieving very high data rates. This is a key advantage in indoor communication scenarios, since the vast majority of wireless traffic is witnessed in indoor communications. In every wireless system, the trade-off between achievable throughput, transmit signal power and corresponding error rate performance is largely dependent upon the considered modulation format. This is also the case in VLC systems, which are typically characterized by stringent performance requirements. Motivated by this, in the present contribution we introduce the space shift keying (SSK) modulation scheme in the context of non-orthogonal-multiple-access (NOMA) communications, which have been shown to be a performance enhancer of indoor based VLC systems. Based on this, all network users in the considered set up receive the same superimposed signal of all NOMA users, which is transmitted from the activated transmitters corresponding to the multiplexed SSK users information. Based on this and assuming a unique maximum likelihood detection, we quantity the system performance in terms of the corresponding bit error rate (BER) performance at each receiver. This analysis leads to the development of useful insights of theoretical and practical interest, which are expected to be useful in the effective design, implementation and deployment of SSK in NOMA based VLC systems.acceptedVersionPeer reviewe

A review of gallium nitride LEDs for multi-gigabit-per-second visible light data communications

The field of visible light communications (VLC) has gained significant interest over the last decade, in both fibre and free-space embodiments. In fibre systems, the availability of low cost plastic optical fibre (POF) that is compatible with visible data communications has been a key enabler. In free-space applications, the availability of hundreds of THz of the unregulated spectrum makes VLC attractive for wireless communications. This paper provides an overview of the recent developments in VLC systems based on gallium nitride (GaN) light-emitting diodes (LEDs), covering aspects from sources to systems. The state-of-the-art technology enabling bandwidth of GaN LEDs in the range of >400 MHz is explored. Furthermore, advances in key technologies, including advanced modulation, equalisation, and multiplexing that have enabled free-space VLC data rates beyond 10 Gb/s are also outlined

Sparsity Signal Detection for Indoor GSSK-VLC System

In this paper, the signal detection problem in indoor visible light communication (VLC) system aided by generalized space shift keying (GSSK) is modeled as a sparse signal reconstruction problem, which has lower computational complexity by exploiting the sparse reconstruction algorithms in compressed sensing (CS). In order to satisfy the measurement matrix property to perform sparse signal reconstruction, a preprocessing approach of measurement matrix is proposed based on singular value decomposition (SVD), which theoretically guarantees the feasibility of utilizing CS based sparse signal detection method in indoor GSSK-VLC system. Then, by adopting classical orthogonal matching pursuit (OMP) algorithm and compressed sampling matching pursuit (CoSaMP) algorithm, the GSSK signals are efficiently detected in the considered indoor GSSK-VLC system. Furthermore, a more efficient detection algorithm combined with OMP and maximum likelihood (ML) is also presented especially for SSK scenario. Finally, the effectiveness of the proposed sparsity aided detection algorithms in indoor GSSK-VLC system are verified by computer simulations. The results show that the proposed algorithms can achieve better bit error rate (BER) and lower computation complexity than ML based detection method. Specifically, a signal-to-noise ratio (SNR) gain as high as 12 dB is observed in the SSK scenario and about 5 dB in case of a GSSK scenario upon employing our proposed detection methods

Practical implementation of multiple-input multiple-output visible light communication systems

Wireless data transmission occurs everywhere and the global data traffic is growing rapidly. Current radio frequency (RF) spectrum resource is becoming saturated and our current RF based wireless communication system will not meet the demands for data traffic in the future. Research efforts have been put into increasing the spectral efficiency of existing RF networks. Techniques such as multiple-input multiple-output (MIMO), have been well studied. However, it is still insufficient for the rapid growth of the wireless data traffic. The visible light (VL) spectrum is over 1000 times wider than the size of the entire 300 GHz RF spectrum, therefore, it is a viable alternative resource. The spread of light emitting diode (LED) lighting infrastructures provides a good opportunity for visible light communication (VLC). VLC turns the LEDs into high speed wireless data transmitter while retaining their illumination function. VLC has drawn much attention in recent years. MIMO techniques have also been studied in VLC. However, there have only been a few studies that compared practical MIMO VLC systems with theoretical studies. In this thesis, several practical implementations of the MIMO VLC system have been presented. First, a generalised space shift keying (GSSK) system, which is a simple form of spatial modulation (SM), has been presented. The performance of the field programmable gate array (FPGA) based real-time system has been studied against different transmitter (Tx) and receiver (Rx) numbers. The performance against mobility has also been evaluated. Up to 16 transmitters have been used and the result shows high spectral efficiency is achievable with the low complexity implementation of GSSK. Second, an investigation of an ultra-high speed wavelength division multiplexing (WDM) VLC system using inexpensive, low-complexity front-end components has been developed. We have used ordinary off-the-shelf red, green, blue and yellow (RGBY) LEDs in surface-mount technology (SMT). The result shows that a data rate of over 15 Gbits/s can be achieved by using proper optimising procedures on the inexpensive commercially available components. This study has confirmed the potential of high achievable capacities of VLC systems. Third, the first MIMO VLC system using organic photovoltaics (OPVs) has been implemented featuring simultaneous data communication and energy harvesting. Record data rates of 102 Mbits/s for a single pixel and 146 Mbits/s for a 2-by-2 MIMO set-up have been presented. The first system model for MIMO OPV VLC system has been proposed. The model has been validated with experimental results. The scalability of the system has also been discussed

Study of MIMO techniques for optical wireless communications

With its huge spectral resource, optical wireless communication (OWC) has emerged as a promising complementary technology to the radio frequency (RF) communication systems. OWC provides data communications for a variety of user applications and it can be deployed using simple, low-cost, low-power and energy-efficient component. In order to enhance capacity, reliability and/or coverage of OWC, multiple-input-multiple-output (MIMO) systems are employed to exploit additional degrees of freedom, such as the location and angular orientation of optical sources and detectors. However, the implementation of MIMO systems is faced with challenges such as the strong correlation and multipath propagation in indoor OWC channels, system synchronisation, as well as inter-channel interference (ICI) due to multiple parallel data transmission. This dissertation investigates MIMO OWC systems which utilises transmission techniques with reduced complexity. A detailed study and performance evaluation of the techniques in terms of capacity, spectral efficiency and error rates is conducted through theoretical analysis, simulation and experiments. The system performance is investigated under different constraints imposed by impairments such as interference, synchronization and channel correlation. Optical spatial modulation (OSM) is studied as a low complexity technique using multiple light sources to enhance system capacity. A generalised framework for implementing OSM with energy efficient pulse position modulation scheme is devised. This framework supports other variants of OSM, and it can be adapted to satisfy varying system requirement such as spectral and energy efficiencies. The performance of the OWC system is investigated in indoor line-of-sight (LOS) propagation. The error performance of the system is analysed theoretically and matched by simulation results. Also, the system performance is evaluated with experiments to demonstrate feasibility. Furthermore, the performance of OSM MIMO techniques in the realistic indoor scenario is considered by taking into account the multiple reflections of the transmitted signal from room surfaces. This is motivated by the recent drive towards high-speed Gigabits per second (Gbps) data communication, where the inter-symbol interference (ISI) caused by the multipath propagation may pose a major bottleneck. A model of the multipath-induced ISI is presented to account for signal spreading and then applied to formulate the error performance analysis. The impact of multipath-induced power penalty and delay spread on system performance is demonstrated using their spatial distributions across the coverage area. Additionally, the impact of timing synchronization problems on the error performance of different variants of the OSM MIMO techniques is investigated. While most works related to SM have assumed a perfect synchronization among the multiple transmitter and receiver elements, such assumption pose a challenge in practical deployment. Hence, the need to examine the impact of synchronisation error that can result from clock jitters and variations in propagation delay. Synchronisation error analyses of OSM schemes are presented, and the tolerance of each scheme to timing synchronization errors is demonstrated. To further enhance system capacity, this thesis also explores spatial multiplexing MIMO technique with orthogonal frequency division multiplexing (OFDM). The central objective is to propose and apply techniques to address the correlation of the indoor optical wireless channel and the frequency selectivity due to the limited bandwidth of LEDs. To address these two effects, a joint coding of paired information symbols was applied in a technique termed pairwise coding (PWC). This technique is based on rotated symbol constellation and it offers significant performance improvement. The error performance of the proposed system is evaluated through simulation and experimental demonstration. PWC proved to be effective over varying degrees of bandwidth limitation and under different channel conditions

Physical layer security for multi-user MIMO visible light communication systems with generalized space shift keying

We consider the physical layer security (PLS) of multi-user (MU) multiple-input-multiple-output visible light communication (VLC) systems with an eavesdropper (Eve) and propose a novel spatial constellation design technique based on generalized space shift keying (MU-GSSK-SCD). The received signals of the legitimate users are optimized jointly, such that their bit error ratios (BERs) are minimized and Eve's BER is significantly degraded. The emission power of randomly selected light-emitting diodes is adjusted, by exploiting users' channel state information at the transmitter. Our strategy ensures that legitimate users receive confidential messages fully in an undistorted fashion, while any meaningful leakage to Eve is strongly prohibited, without any artificial noise addition. Every user can decode only its information, hence inter-user security is also guaranteed. The PLS improvements are presented in terms of both BERs and achievable secrecy rates in practical VLC scenarios. For various user configurations, it is shown that MU-GSSK-SCD increases the BER at Eve to the 0.5 level, while providing minimized BERs to the legitimate users. The achievable secrecy rate region is derived for MU-GSSK-SCD and it is shown that full secrecy can be achieved at 0 dB signal-to-noise ratio (SNR) level with a user separation as small as 90 cm

Améliorations des transmissions VLC (Visible Light Communication) sous contrainte d'éclairage : études théoriques et expérimentations

Abstract : Indoor visible light communication (VLC) networks based on light-emitting diodes (LEDs) currently enjoy growing interest thanks in part to their robustness against interference, wide license-free available bandwidth, low cost, good energy efficiency and compatibility with existing lighting infrastructure. In this thesis, we investigate spectral-efficient modulation techniques for the physical layer of VLC to increase throughput while considering the quality of illumination as well as implementation costs. Numerical and experimental studies are performed employing pulse amplitude modulation (PAM) and carrierless amplitude and phase (CAP) modulation under illumination constraints and for high modulation orders. Furthermore, the impact of LED nonlinearity is investigated and a postdistortion technique is evaluated to compensate these nonlinear effects. Within this framework, transmission rates in the order of a few hundred Mb/s are achieved using a test bench made of low-cost components. In addition, an imaging multiple input multiple-output (MIMO) system is developed and the impact on performance of imaging lens misalignment is theoretically and numerically assessed. Finally, a polynomial matrix decomposition technique based on the classical LU factorization method is studied and applied for the first time to MIMO VLC systems in large space indoor environments.Les réseaux de communication en lumière visible (VLC) s’appuyant sur l’utilisation de diodes électroluminescentes (LED) bénéficient actuellement d’un intérêt grandissant, en partie grâce à leur robustesse face aux interférences électromagnétiques, leur large bande disponible non-régulée, leur faible coût, leur bonne efficacité énergétique, ainsi que leur compatibilité avec les infrastructures d’éclairage déjà existantes. Dans cette thèse, nous étudions des techniques de modulation à haute efficacité spectrale pour la couche physique des VLC pour augmenter les débits tout en considérant la qualité de l’éclairage ainsi que les coûts d’implémentation. Des études numériques et expérimentales sont réalisées sur la modulation d’impulsion d’amplitude (PAM) et sur la modulation d’amplitude et de phase sans porteuse (CAP) sous des contraintes d’éclairage et pour des grands ordres de modulation. De plus, l’impact des non-linéarités de la LED est étudié et une technique de post-distorsion est évaluée pour corriger ces effets non-linéaires. Dans ce cadre, des débits de plusieurs centaines de Mb/s sont atteints en utilisant un banc de test réalisé à partir de composants à bas coûts. Par ailleurs, un système multi-entrées multi-sorties (MIMO) imageant est également développé et l’impact du désaxage de l’imageur sur les performances est étudié. Finalement, une technique de décomposition polynomiale basée sur la méthode de factorisation classique LU est étudiée et appliquée aux systèmes MIMO VLC dans des grands espaces intérieurs

Indoor Visible Light Communication:A Tutorial and Survey

Abstract With the advancement of solid-state devices for lighting, illumination is on the verge of being completely restructured. This revolution comes with numerous advantages and viable opportunities that can transform the world of wireless communications for the better. Solid-state LEDs are rapidly replacing the contemporary incandescent and fluorescent lamps. In addition to their high energy efficiency, LEDs are desirable for their low heat generation, long lifespan, and their capability to switch on and off at an extremely high rate. The ability of switching between different levels of luminous intensity at such a rate has enabled the inception of a new communication technology referred to as visible light communication (VLC). With this technology, the LED lamps are additionally being used for data transmission. This paper provides a tutorial and a survey of VLC in terms of the design, development, and evaluation techniques as well as current challenges and their envisioned solutions. The focus of this paper is mainly directed towards an indoor setup. An overview of VLC, theory of illumination, system receivers, system architecture, and ongoing developments are provided. We further provide some baseline simulation results to give a technical background on the performance of VLC systems. Moreover, we provide the potential of incorporating VLC techniques in the current and upcoming technologies such as fifth-generation (5G), beyond fifth-generation (B5G) wireless communication trends including sixth-generation (6G), and intelligent reflective surfaces (IRSs) among others

Evaluation of spectrally efficient indoor optical wireless transmission techniques

Optical wireless communications (OWC) has the potential to become a remedy for the shortage of the radio frequency (RF) spectrum. Especially in indoor environments, OWC could enable wireless home networking systems which offload data traffic from existing RF systems. In OWC, data is transmitted by modulating the intensity of light sources, typically incoherent light emitting diodes (LEDs). Thus, OWC systems employ intensity modulation (IM) and direct detection (DD) of the optical carrier. Since off-the-shelf LEDs have a limited modulation capability, the transmission bandwidth of practical OWC systems is restricted. Consequently, the available bandwidth has to be used efficiently. In this thesis, spectrally efficient optical wireless transmission techniques are evaluated. Firstly, multiple transmitter-receiver techniques are investigated. These multiple-input-multiple-output (MIMO) techniques provide high spectral efficiency, and therefore high data rates. Specifically, the MIMO techniques repetition coding (RC), spatial multiplexing (SMP) and spatial modulation (SM) are analysed for indoor OWC. The performance of these techniques is evaluated analytically and by means of computer simulations. It is shown that inducing power imbalance between the multiple optical transmitters can substantially improve the performance of optical MIMO techniques as the power imbalance improves the differentiability of the multiple channels. In addition, it is found that link blockage and the utilisation of transmitters having different optical wavelengths enhance channel differentiability as well. These methods enable the utilisation of optical MIMO techniques under conditions which typically disallow the application of MIMO schemes due to little differences between the multiple links. Secondly, a novel optical wireless transmitter concept is developed. This concept uses discrete power level stepping to generate intensity modulated optical signals, such as orthogonal frequency division multiplexing (OFDM) waveforms. The transmitter consists of several on-off-switchable LED groups which are individually controlled to emit scaled optical intensities. As a result, the digital-to-analogue conversion of the signals to be sent is done in the optical domain. This method enables the implementation of low-complex and power-efficient optical transmitter front-ends – the major shortcoming of conventional optical OFDM transmitters. Thirdly, a novel approach for wireless data transmission within an aircraft cabin is presented. The data is transferred by 2-dimensional visual code sequences. These sequences are displayed on the in-flight entertainment (IFE) screen and are captured by the built-in camera of a user device which acts as receiver. Transmission experiments within an aircraft cabin mock-up demonstrate the functionality of the implemented system under realistic conditions, such as ambient illumination and geometric configuration. Altogether, this thesis has analysed the potential of spectrally efficient optical wireless transmission techniques. It is shown that OWC systems can greatly benefit from these techniques