A parallel convolutional coder including embedded puncturing with application to consumer devices

As consumers demand more functionality) from their electronic devices and manufacturers supply the demand then electrical power and clock requirements tend to increase, however reassessing system architecture can fortunately lead to suitable counter reductions. To maintain low clock rates and therefore reduce electrical power, this paper presents a parallel convolutional coder for the transmit side in many wireless consumer devices. The coder accepts a parallel data input and directly computes punctured convolutional codes without the need for a separate puncturing operation while the coded bits are available at the output of the coder in a parallel fashion. Also as the computation is in parallel then the coder can be clocked at 7 times slower than the conventional shift-register based convolutional coder (using DVB 7/8 rate). The presented coder is directly relevant to the design of modern low-power consumer device

An overview on the standard of digital video broadcasting – terrestrial.

Digital Video Broadcasting (DVB) es un consorcio formado por industriales de los medios de comunicación, que está integrado por radiodifusores, fabricantes, operadores de redes, desarrolladores de software y organismos reguladores. El consorcio fue creado con el fin de definir las normas técnicas para estandarizar todos los aspectos relacionados con la prestación de servicios de televisión digital. El estándar DVB ha sido adoptado en Europa, Oriente Medio, Suráfrica y Australasia. Adicionalmente, el estándar DVB fue seleccionado en Colombia y Panamá como el sistema de transmisión de televisión digital terrestre (DVB-T/T2). El estándar DVB es un conjunto de especificaciones que permiten la integración de información multimedia para proveer servicios de información, educación, negocios y entretenimiento. La implementación de DVB requiere de acuerdos entre los radiodifusores, operadores de redes y fabricantes en la definición de los parámetros de operación, además de tener en cuenta las normativas gubernamentales. Este artículo presenta un resumen de los principales elementos definidos en el estándar DVB-T/T2, basado en los documentos guía elaborados por el consorcio DVB, e incluye algunas de las acciones tomadas durante el proceso de implementación de DVB-T/T2 en Colombia

Reconfigurable architectures for the next generation of mobile device telecommunications systems

Mobile devices have become a dominant tool in our daily lives. Business and personal usage has escalated tremendously since the emergence of smartphones and tablets. The combination of powerful processing in mobile devices, such as smartphones and the Internet, have established a new era for communications systems. This has put further pressure on the performance and efficiency of telecommunications systems in delivering the aspirations of users. Mobile device users no longer want devices that merely perform phone calls and messaging. Rather, they look for further interactive applications such as video streaming, navigation and real time social interaction. Such applications require a new set of hardware and standards. The WiFi (IEEE 802.11) standard has been at the forefront of reliable and high-speed internet access telecommunications. This is due to its high signal quality (quality of service) and speed (throughput). However, its limited availability and short range highlights the need for further protocols, in particular when far away from access points or base stations. This led to the emergence of 3G followed by 4G and the upcoming 5G standard that, if fully realised, will provide another dimension in “anywhere, anytime internet connectivity.” On the other hand, the WiMAX (IEEE 802.16) standard promises to exceed the WiFi signal coverage range. The coverage range could be extended to kilometres at least with a better or similar WiFi signal level. This thesis considers a dynamically reconfigurable architecture that is capable of processing various modules within telecommunications systems. Forward error correction, coder and navigation modules are deployed in a unified low power communication platform. These modules have been selected since they are among those with the highest demand in terms of processing power, strict processing time or throughput. The modules are mainly realised within WiFi and WiMAX systems in addition to global positioning systems (GPS). The idea behind the selection of these modules is to investigate the possibility of designing an architecture capable of processing various systems and dynamically reconfiguring between them. The GPS system is a power-hungry application and, at the same time, it is not needed all of the time. Hence, one key idea presented in this thesis is to effectively exploit the dynamic reconfiguration capability so as to reconfigure the architecture (GPS) when it is not needed in order to process another needed application or function such as WiFi or WiMAX. This will allow lower energy consumption and the optimum usage of the hardware available on the device. This work investigates the major current coarse-grain reconfigurable architectures. A novel multi-rate convolution encoder is then designed and realised as a reconfigurable fabric. This demonstrates the ability to adapt the algorithms involved to meet various requirements. A throughput of between 200 and 800 Mbps has been achieved for the rates 1/2 to 7/8, which is a great achievement for the proposed novel architecture. A reconfigurable interleaver is designed as a standalone fabric and on a dynamically reconfigurable processor. High throughputs exceeding 90 Mbps are achieved for the various supported block sizes. The Reed Solomon coder is the next challenging system to be designed into a dynamically reconfigurable processor. A novel Galois Field multiplier is designed and integrated into the developed Reed Solomon reconfigurable processor. As a result of this work, throughputs of 200Mbps and 93Mbps respectively for RS encoding and decoding are achieved. A GPS correlation module is also investigated in this work. This is the main part of the GPS receiver responsible for continuously tracking GPS satellites and extracting messages from them. The challenging aspect of this part is its real-time nature and the associated critical time constraints. This work resulted in a novel dynamically reconfigurable multi-channel GPS correlator with up to 72 simultaneous channels. This work is a contribution towards a global unified processing platform that is capable of processing communication-related operations efficiently and dynamically with minimum energy consumption

Optimisation de la transmission de phonie et vidéophonie sur les réseaux à larges bandes PMR

Cet exposé analyse les perspectives large bande des réseaux PMR, à travers l'évaluation du candidat LTE, et la proposition d'une possible évolution du codage canal, la solution brevetée des codes turbo à protection non uniforme. Une première étude dans le chapitre 2 se concentre sur l'analyse multi-couche et l'identification des problèmes clé des communications de voix et de vidéo sur un réseau LTE professionnel. Les capacités voix et vidéo sont estimées pour les liens montant et descendant de la transmission LTE, et l'efficacité spectrale de la voix en lien descendant est comparée à celle de PMR et GSM. Ce chapitre souligne certains points clé de l'évolution de LTE. S'ils étaient pas résolus par la suite, LTE se verrait perdre de sa crédibilité en tant que candidat à l'évolution de la PMR. Une telle caractéristique clé des réseaux PMR est le codage canal à protection non uniforme, qui pourrait être adapté au système LTE pour une évolution aux contraintes de la sécurité publique. Le chapitre 3 introduit cette proposition d'évolution, qui a été brevetée: les turbo codes à protection non uniforme intégrée. Nous proposons une nouvelle approche pour le codage canal à protection non uniforme à travers les codes turbo progressives hiérarchiques. Les configurations parallèles et séries sont analysées. Les mécanismes de protection non uniformes sont intégrés dans la structure de l'encodeur même à travers l'insertion progressif et hiérarchique de nouvelles données de l'utilisateur. Le turbo décodage est modifié pour exploiter de façon optimale l'insertion progressive de données dans le processus d'encodage et estimer hiérarchiquement ces données. Les propriétés des structures parallèles et séries sont analysées à l'aide d'une analogie aux codes pilotes, ainsi qu'en regardant de plus près leurs caractéristiques de poids de codage. Le taux de transmission virtuel et les représentations des graphs factor fournissent une meilleure compréhension de ces propriétés. Les gains de codage sont évalués à l'aide de simulations numériques, en supposant des canaux de transmission radio statiques et dynamiques, et en utilisant des codes de référence. Enfin, dans le chapitre 4, l'idée breveté du code turbo parallal progressif et hiérarchique (PPHTC) est évaluée sur la plateforme LTE. Une description détaillée de l'architecture des bearers de LTE est donnée, et ses conséquences sont discutées. Le nouveau codage canal est inséré et évalué sur cette plateforme, et ses performances sont comparées avec des schémas de transmission typique à LTE. L'analyse de la qualité de la voix aide à conclure sur l'efficacité de la solution proposée dans un système de transmission réel. Pourtant, même si cette dernière donne les meilleurs résultats, d'avantage d'optimisations devraient être envisagées pour obtenir des gains améliorés et mieux exploiter le potentiel du codage proposé. L'exposé se conclut dans le chapitre 5 et une courte discussion présente les futures perspectives de rechercheThis dissertation analyzes the PMR broadband perspectives, through the evaluation of the preferred candidate, LTE, and the proposal of a possible channel coding evolution, the patented solution of unequal error protection embedded turbo codes. A first study in chapter 2 focuses on the multi-layer analysis and the identification of key issues for professional-like LTE for voice and video communications. The voice and video capacities are estimated for both downlink and uplink LTE transmissions, and the downlink LTE voice system efficiency is compared with that of the PMR and Global System for Mobile Communications (GSM). This chapter helps highlighting some of the key points. If not resolved, the latter could lead to the LTE downfall as a candidate for the PMR evolution. One such key characteristic of PMR systems is the unequal error protection channel coding technique, which might be adapted to the LTE technology for its evolution to public safety requirements. Chapter 3 further introduces the proposed evolution patented ideas: the unequal error protection embedded turbo codes. We propose a new approach for the unequal error protection channel coding through the progressive hierarchical turbo codes. Both parallel and serial turbo configurations are closely studied. The unequal error protection mechanisms are embedded in the encoder s structure itself through the progressive and hierarchical insertion of new data. The turbo decoding is modified as to optimally exploit the progressive insertion of information in the encoding process and hierarchically estimate the corresponding data. Both parallel and serial configurations properties are analyzed using an analogy with a pilot code behavior, as well as a zoom on the weight error functions coefficients. The virtual code rate and factor graph interpretations also provide a better insight on the code properties. The code possible gains are highlighted through computer simulations in both static and dynamic transmission environments, by using carefully chosen benchmarks. Finally, in chapter 4, the patented idea of parallel progressive hierarchical turbo codes (PPHTC) is evaluated over the LTE platform. A detailed description is given of the voice transmission bearer architecture over LTE, and its consequences are discussed. The new channel code is inserted and evaluated over this platform and its performances compared with the existent LTE transmission schemes. The voice quality results help concluding on the efficiency of the proposed solution in a real transmission scenario. However, even though the newly presented solution gives the best results, further system optimizations should be envisaged for obtaining better gains and exploit the parallel progressive hierarchical turbo codes potential. The dissertation concludes in chapter 5 and a short discussion is given on future research perspectivesEVRY-INT (912282302) / SudocSudocFranceF

Implementation of WiMAX physical layer baseband processing blocks in FPGA

This project thesis elaborates on designing a baseband processing blocks for Worldwide Interoperability for Microwave Access (WiMAX) physical layer using an FPGA. WiMAX provides broadband wireless access and uses OFDM as the essential modulation technique. The channel performance is badly affected due to synchronization mismatches between the transmitter and receiver ends so the transmitted signal received is not reliable as the OFDM deals with high data rate. This thesis includes the theory and concepts behind OFDM, WiMAX IEEE 802.16d standard and other blocks algorithms, its architectures used for designing as well as a presentation of how they are implemented. Here Altera’s FPGA has been used for targeting to the EP4SGX70HF35C2 device of the Stratix IV family. WiMAX use sophisticated digital signal processing techniques, which typically require a large number of mathematical computations. Here Stratix IV devices are ideally suited for these kinds of complex tasks because the DSP blocks have a combination of dedicated elements that perform multiplication, addition, subtraction, accumulation, summation, and dynamic shift operations. The WiMAX physical layer baseband processing architecture consists of various major modules which were simulated block wise in order to check its giving the correct output as required. The coding style used here is VHDL. The sub-blocks have been synthesized using Altera Quartus II v11. 0 and simulated using ModelSim Altera Edition 6.6d

Advanced Coding And Modulation For Ultra-wideband And Impulsive Noises

The ever-growing demand for higher quality and faster multimedia content delivery over short distances in home environments drives the quest for higher data rates in wireless personal area networks (WPANs). One of the candidate IEEE 802.15.3a WPAN proposals support data rates up to 480 Mbps by using punctured convolutional codes with quadrature phase shift keying (QPSK) modulation for a multi-band orthogonal frequency-division multiplexing (MB-OFDM) system over ultra wideband (UWB) channels. In the first part of this dissertation, we combine more powerful near-Shannon-limit turbo codes with bandwidth efficient trellis coded modulation, i.e., turbo trellis coded modulation (TTCM), to further improve the data rates up to 1.2 Gbps. A modified iterative decoder for this TTCM coded MB-OFDM system is proposed and its bit error rate performance under various impulsive noises over both Gaussian and UWB channel is extensively investigated, especially in mismatched scenarios. A robust decoder which is immune to noise mismatch is provided based on comparison of impulsive noises in time domain and frequency domain. The accurate estimation of the dynamic noise model could be very difficult or impossible at the receiver, thus a significant performance degradation may occur due to noise mismatch. In the second part of this dissertation, we prove that the minimax decoder in \cite, which instead of minimizing the average bit error probability aims at minimizing the worst bit error probability, is optimal and robust to certain noise model with unknown prior probabilities in two and higher dimensions. Besides turbo codes, another kind of error correcting codes which approach the Shannon capacity is low-density parity-check (LDPC) codes. In the last part of this dissertation, we extend the density evolution method for sum-product decoding using mismatched noises. We will prove that as long as the true noise type and the estimated noise type used in the decoder are both binary-input memoryless output symmetric channels, the output from mismatched log-likelihood ratio (LLR) computation is also symmetric. We will show the Shannon capacity can be evaluated for mismatched LLR computation and it can be reduced if the mismatched LLR computation is not an one-to-one mapping function. We will derive the Shannon capacity, threshold and stable condition of LDPC codes for mismatched BIAWGN and BIL noise types. The results show that the noise variance estimation errors will not affect the Shannon capacity and stable condition, but the errors do reduce the threshold. The mismatch in noise type will only reduce Shannon capacity when LLR computation is based on BIL

Communications for smart grid substation monitoring using WIMAX protocol

The SMARTGRID is a general term for a series of infrastructural changes applied to the electric transmission and distribution systems. By using the latest communication and computing technology, additional options such as Condition Monitoring can now be implemented to further improve and optimise complex electricity supply grid operation. Lifecycle optimisation of high voltage assets and other system components in the utility provide a case in point. Today Utility experts agree that application of scheduled maintenance is not the effective use of resources. To reduce maintenance expenses and unnecessary outages and repairs of equipment due to scheduled maintenance, utilities are adopting condition based approaches. Real time online monitoring of substation parameters can be achieved by retrofitting the existing substation with SMARTGRID technology. The IEC 61850 is a common protocol meant for Substation Automation Systems, designed for the purpose of establishing interoperability, one that all manufacturers of all different assets must comply with. This thesis advocates the estimation of bandwidth required for monitoring a substation after retrofitting the existing substation with smart communication technologies. This includes establishing a latest wireless communication infrastructure from the substation to the control centre and evaluating the performance modelling and simulating the physical layer of communication technologies such as WIMAX (IEEE802.16) and MICROWAVE point to point using MATLAB SIMULINK and RADIO mobile online simulation software. Also, link budget of the satellite communication for the same application is calculated. Satellite communication in this case is considered as a redundant or back up technology to ensure that the communication between entities is continuous. On performing the simulation on different environments the results prove that the selected protocols are best suited for condition monitoring. The measured Latency could be the best approximated value which complies with the current objective. However the white noise that exists in the substation has significant hazard with respect to the security of the wireless network. To compensate this constraint whole substation is hard wired by means of plastic fibre optics and the data sent to the base station located near the substation

Design and Analysis of Forward Error Control Coding and Signaling for Guaranteeing QoS in Wireless Broadcast Systems

Broadcasting systems are networks where the transmission is received by several terminals. Generally broadcast receivers are passive devices in the network, meaning that they do not interact with the transmitter. Providing a certain Quality of Service (QoS) for the receivers in heterogeneous reception environment with no feedback is not an easy task. Forward error control coding can be used for protection against transmission errors to enhance the QoS for broadcast services. For good performance in terrestrial wireless networks, diversity should be utilized. The diversity is utilized by application of interleaving together with the forward error correction codes. In this dissertation the design and analysis of forward error control and control signalling for providing QoS in wireless broadcasting systems are studied. Control signaling is used in broadcasting networks to give the receiver necessary information on how to connect to the network itself and how to receive the services that are being transmitted. Usually control signalling is considered to be transmitted through a dedicated path in the systems. Therefore, the relationship of the signaling and service data paths should be considered early in the design phase. Modeling and simulations are used in the case studies of this dissertation to study this relationship. This dissertation begins with a survey on the broadcasting environment and mechanisms for providing QoS therein. Then case studies present analysis and design of such mechanisms in real systems. The mechanisms for providing QoS considering signaling and service data paths and their relationship at the DVB-H link layer are analyzed as the first case study. In particular the performance of different service data decoding mechanisms and optimal signaling transmission parameter selection are presented. The second case study investigates the design of signaling and service data paths for the more modern DVB-T2 physical layer. Furthermore, by comparing the performances of the signaling and service data paths by simulations, configuration guidelines for the DVB-T2 physical layer signaling are given. The presented guidelines can prove useful when configuring DVB-T2 transmission networks. Finally, recommendations for the design of data and signalling paths are given based on findings from the case studies. The requirements for the signaling design should be derived from the requirements for the main services. Generally, these requirements for signaling should be more demanding as the signaling is the enabler for service reception.Siirretty Doriast