Flip-OFDM for Optical Wireless Communications

We consider two uniploar OFDM techniques for optical wireless communications: asymmetric clipped optical OFDM (ACO-OFDM) and Flip-OFDM. Both techniques can be used to compensate multipath distortion effects in optical wireless channels. However, ACO-OFDM has been widely studied in the literature, while the performance of Flip-OFDM has never been investigated. In this paper, we conduct the performance analysis of Flip-OFDM and propose additional modification to the original scheme in order to compare the performance of both techniques. Finally, it is shown by simulation that both techniques have the same performance but different hardware complexities. In particular, for slow fading channels, Flip-OFDM offers 50% saving in hardware complexity over ACO-OFDM at the receiver.Comment: published in IEEE Information Theory Workshop, Paraty Brazil, Sept 201

System design and performance analysis of asymmetrically and symmetrically clipped optical (ASCO)-OFDM for IM/DD optical wireless communications

As the quantity of mobile communication devices, such as cellphones, tablets, and laptops, dramatically increase, the demand for high speed wireless service has been growing. Optical wireless communications (OWCs), which offer unlimited transmission bandwidth, have received a lot of attention and been studied in recent decades. They can be an effective alternative to radio frequency communications (RFCs) for indoor high speed data transmission. Intensity modulation direct detection (IM/DD) is a simple way to realize the transmission of optical wireless signals in an indoor environment. Information data streams are modulated into the intensity of optical carriers and transmitted by light emitting diodes (LEDs). At the receiver, the instantaneous power of optical signals can be directly detected by photodiodes. Multipath distortion, especially in an indoor environment, caused by reflection from walls or furniture, severely affects the transmission quality of optical signals. Orthogonal frequency division multiplexing (OFDM) is a promising modulation technique and has been widely used to combat inter-symbol-interference (ISI) resulting from multipath propagation in RFCs. So far, the technique of OFDM has also been successfully applied into IM/DD optical wireless systems. In this dissertation, the author focuses on the system design and performance analysis of a novel power-efficient scheme based on OFDM for IM/DD OWCs. This dissertation is divided into four main sections. In the first part, a novel power-efficient scheme, called asymmetrically and symmetrically clipped optical (ASCO)-OFDM, for intensity modulation direct detection (IM/DD) optical wireless systems is proposed. The average bit rate versus (vs.) normalized bandwidth and the optical power per bit of this novel scheme are expressed by a closed form, respectively. The symbol error rate (SER) performance is investigated when optical signals are transmitted in a flat fading channel. Simulation results show that this proposed scheme can achieve better performances in terms of both power efficiency and symbol error rate (SER) when the optical power of transmitted signals is limited. In the second part, an improved receiving technique is applied into the conventional receiver of ASCO-OFDM to improve the SER performance. This technique can explore and reuse some useful information hidden in the received signals. The detection procedure is described in detail and the improved SER performances are presented for different constellation cases. In the third part, the information rates of ADO-OFDM and ASCO-OFDM are obtained for an additive white Gaussian noise (AWGN) channel with an average transmitted optical power constraint. In the last part, this novel power efficient scheme, ASCO-OFDM, is extended into two-dimensional (2D) IM/DD optical wireless systems. The theoretical analysis and simulation results show that this technique not only achieves high average bit rate, but reduces the Peak-to-average power ratio (PAPR) as well

Déploiement de réseaux optiques d'accès NGPON dans des métropoles de pays en développement : proposition de nouvelles techniques d'implémentation de l'OFDM

The rapid development of multimedia services and applications such as broadband Internet, 3G, LTE, has led customers to force operators to increase throughput of all network segments, including the access network. Solutions using optical fiber tend to gradually replace cable based-copper or coaxial communications to ensure larger transfer capacity. The optical fiber is a very attractive medium because its linear attenuation is very low and its bandwidth very high. However, the chromatic dispersion of the fiber associated with the chirp of the optical sources limit the rise in flowrate in future optical access networks (beyond rates of 10 Gb/s) NG-PON (Next Generation Passive Optical Network). In this context, modulation formats with higher spectral efficiency than NRZ-OOK could be selected. OFDM is a solution to increase the spectral efficiency, while ensuring a better performance and high robustness against frequency selective channel such as fiber optics. In this thesis, we proposed a new OFDM techniques implementation for NG-PON and evaluated their performance in an IM/DD channel. We showed by simulations system of a realistic optical channel, that New DCO, New INC-ACO and DC-ACO OFDM techniques are able to increase the limited transmission distances imposed by the NRZ-OOK modulation with the use of low-cost components. Thus, we showed that using the “Minimization and E-Tight (MET)”or the Levin-Campello algorithm, the New DCO and DC-ACO techniques permit to achieve data rates of 10 Gb/s with a split ratio of 1 × 64 over a distance of 70 km with New DCO and 55 km for DC-ACO. Then we conclude that the New AMOFDM approach is a good choice for the deployment of optical access networks in metropolitan cities of developing countries.L’évolution rapide des services et applications multimédias (Internet haut débit, 3G, LTE) a entrainé un besoin chez les clients qui contraint les opérateurs à augmenter le débit de tous les segments du réseau, y compris le réseau d’accès. Les solutions utilisant la fibre optique tendent à remplacer progressivement les liaisons câblées (cuivre ou coaxial) afin de garantir des capacités de transfert plus importantes. La fibre optique est un medium très attractif car son atténuation linéique est très faible et sa bande passante importante. Cependant la dispersion chromatique de la fibre associée au chirp des sources optiques limite la montée en débit dans les futurs réseaux d’accès optiques (débits au-delà de 10 Gb/s) NG-PON (Next Generation Passive Optical Network). Dans ce contexte, des formats de modulation à efficacité spectrale meilleure que le NRZ pourraient être retenus. L’OFDM est une solution pour accroître l’efficacité spectrale, tout en garantissant une meilleure performance et une grande robustesse face aux canaux sélectifs en fréquence comme la fibre optique. Dans ce travail de thèse, nous avons proposé de nouvelles techniques d’implémentation de l’OFDM pour le NG-PON et évalué leurs performances dans un canal IM/DD. Nous avons montré par des simulations système dans un canal optique réaliste, que les techniques New DCO, New INC-ACO et DC-ACO sont capables d’augmenter les limitations de distances de transmission imposées par la modulation NRZ-OOK (Non-Return to Zero On-Off Keying) avec l’utilisation de composants bas coût. Ainsi, nous avons montré qu’avec les méthodes «MET (Minimization E-Tight)» et Levin-Campello, les techniques New DCO et DC-ACO permettent de réaliser des débits de 10 Gb/s sur une distance de 70 km en New DCO et 55 km en DC-ACO avec un taux de partage de 1×64. Cela permet d’affirmer que l’approche New AMOFDM serait un bon candidat pour le déploiement de réseaux d’accès optiques dans les métropoles de pays en développement