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Incremental Redundancy Low-Density Parity-Check Codes for Hybrid FEC/ARQ SchemesHur, Woonhaing 23 January 2007 (has links)
The objective of this dissertation is to investigate incremental redundancy low-density parity-check (IR-LDPC) codes for hybrid forward error correction / automatic repeat request (HybridARQ) schemes. Powerful capacity-approaching IR-LDPC codes are one of the key functional elements in high-throughput HybridARQ schemes and provide a flexible rate-compatible structure, which is necessary for low-complexity HybridARQ schemes.
This dissertation first studies the design and performance evaluation of IR-LDPC codes, which have good error rate performance at short block lengths. The subset codes of the IR-LDPC codes are compared to conventional random punctured codes and multiple dedicated codes. As a system model for this work, an adaptive LDPC coded system is presented. This adaptive system can confront the nature of time-varying channels and approach the capacity of the system with the aid of LDPC codes. This system shows remarkable throughput improvement over a conventional punctured system and, for systems that use multiple dedicated codes, provides comparable performance with low-complexity at every target error rate.
This dissertation also focuses on IR-LDPC codes with a wider operating code range because the previous IR-LDPC codes exhibited performance limitation related to the maximum achievable code rate. For this reason, this research proposes a new way to increase the maximum code rate of the IR-LDPC codes, which provides throughput improvement at high throughput regions over conventional random punctured codes. Also presented is an adaptive code selection algorithm using threshold parameters. This algorithm reduces the number of the unnecessary traffic channels in HybridARQ schemes.
This dissertation also examines how to improve throughput performance in HybridARQ schemes with low-complexity by exploiting irregular repeat accumulate (IRA) codes. The proposed adaptive transmission method with adaptive puncturing patterns of IRA codes shows higher throughput performance in all of operating code ranges than does any other single mode in HybridARQ schemes.
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Root LDPC Codes for Non Ergodic Transmission Channels / Root LDPC Codes for Non Ergodic Transmission ChannelsBhutto, Tarique Inayat January 2011 (has links)
4 ABSTRACT Tremendous amount of research has been conducted in modern coding theory in the past few years and much of the work has been done in developing new coding techniques. Low density parity check (LDPC) codes are class of linear block error correcting codes which provide capacity performance on a large collection of data transmission and storage channels while Root LDPC codes in this thesis work are admitting implementable decoders with manageable complexity. Furthermore, work has been conducted to develop graphical methods to represent LDPC codes. This thesis implement one of the LDPC kind “Root LDPC code” using iterative method and calculate its threshold level for binary and non-binary Root LDPC code. This threshold value can serve as a starting point for further study on this topic. We use C++ as tool to simulate the code structure and parameters. The results show that non-binary Root LDPC code provides higher threshold value as compare to binary Root LDPC code. / postal address: Björnkullaringen 26, LGH 1029 14151 Huddinge Stockholm Sweden. Mobile: +46-720 490 967
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Joint JPEG2000/LDPC Code System Design for Image TelemetryJagiello, Kristin, Aydin, Mahmut Zafer, Ng, Wei-Ren 10 1900 (has links)
ITC/USA 2008 Conference Proceedings / The Forty-Fourth Annual International Telemetering Conference and Technical Exhibition / October 27-30, 2008 / Town and Country Resort & Convention Center, San Diego, California / This paper considers the joint selection of the source code rate and channel code rate in an image telemetry system. Specifically considered is the JPEG2000 image coder and an LDPC code family. The goal is to determine the optimum apportioning of bits between the source and channel codes for a given channel signal-to-noise ratio and total bit rate, R(total). Optimality is in the sense of maximum peak image SNR and the tradeoff is between the JPEG2000 bit rate R(source) and the LDPC code rate R(channel). For comparison, results are included for the industry standard rate-1/2, memory-6 convolutional code.
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Design and Decoding LDPC Codes With Low ComplexityZheng, Chao Unknown Date
No description available.
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Universality for Multi-terminal Problems via Spatial CouplingYedla, Arvind 2012 August 1900 (has links)
Consider the problem of designing capacity-achieving codes for multi-terminal communication scenarios. For point-to-point communication problems, one can optimize a single code to approach capacity, but for multi-terminal problems this translates to optimizing a single code to perform well over the entire region of channel parameters. A coding scheme is called universal if it allows reliable communication over the entire achievable region promised by information theory.
It was recently shown that terminated low-density parity-check convolutional codes (also known as spatially-coupled low-density parity-check ensembles) have belief-propagation thresholds that approach their maximum a-posteriori thresholds. This phenomenon, called "threshold saturation via spatial-coupling," was proven for binary erasure channels and then for binary memoryless symmetric channels. This approach provides us with a new paradigm for constructing capacity approaching codes. It was also conjectured that the principle of spatial coupling is very general and that the phenomenon of threshold saturation applies to a very broad class of graphical models.
In this work, we consider a noisy Slepian-Wolf problem (with erasure and binary symmetric channel correlation models) and the binary-input Gaussian multiple access channel, which deal with correlation between sources and interference at the receiver respectively. We derive an area theorem for the joint decoder and empirically show that threshold saturation occurs for these multi-user scenarios. We also show that the outer bound derived using the area theorem is tight for the erasure Slepian-Wolf problem and that this bound is universal for regular LDPC codes with large left degrees. As a result, we demonstrate near-universal performance for these problems using spatially-coupled coding systems.
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Αρχιτεκτονική και υλοποίηση κωδικοποιητών VLSI για κώδικες LDPCMahdi, Ahmed 20 April 2011 (has links)
Η διπλωματική εργασία επικεντρώνεται στη μελέτη της κωδικοποίησης για κώδικες LDPC. Στα πλαίσιά της, θα μελετηθούν τα προβλήματα και η πολυπλοκότητα κωδικοποίησης συναρτήσει του μήκους της κωδικής λέξης. Έμφαση θα δοθεί σε εφαρμογές με μεγάλο μήκος κωδικής λέξης όπως εκείνες που χρησιμοποιούνται σε νέες τηλεπικοινωνιακές εφαρμογές, όπως δορυφορικό Digital Video Broadcast (DVB) DVB-S2, IEEE 802.3an (10GBASE-T) και IEEE 802.16(WiMAX).
Σε τέτοιες εφαρμογές όπου η κωδική λέξη μπορεί να έχει μήκος αρκετά μεγαλύτερο των 1000 bits, η πολυπλοκότητα κωδικοποίησης είναι σημαντική. Αυτό συμβαίνει διότι απαιτούνται μεγάλες σε μέγεθος μνήμες για την αποθήκευση του Πίνακα Έλεγχου Ισοτιμίας (Parity-check Matrix H), πολύ μεγάλη χρονική επεξεργαστική πολυπλοκότητα O(n^2) αλλά και πολλά επεξεργαστικά στοιχεία τάξης Ο(n^2).
Ο σκοπός λοιπόν είναι να μελετηθούν οι αλγόριθμοι κωδικοποίησης και να μελετηθεί πώς μπορεί να αξιοποιηθεί η αραιότητα του Πίνακα Έλεγχου Ισοτιμίας έτσι ώστε να επιτευχθεί κατά το δυνατόν γραμμική πολυπλοκότητα O(n) κωδικοποίησης.
Στη συνέχεια, αφού αναπτυχθεί η κατάλληλη μέθοδος κωδικοποίησης, θα ακολουθήσει η μελέτη και ο σχεδιασμός μίας βέλτιστης VLSI αρχιτεκτονικής για την υλοποίηση σε υλικό του LDPC κωδικοποιητή, ώστε να ικανοποιεί και άλλα πρακτικά κριτήρια, με έμφαση στη μείωση της καθυστέρησης και της απαιτούμενης επιφάνειας. Θα αναπτυχθεί επίσης μια κατάλληλη αρχιτεκτονική για διάφορους βαθμούς παραλληλίας του κωδικοποιητή. / An LDPC code is a linear block code specified by a very sparse parity check matrix (PCM). LDPC codes are usually represented by a bi-partite graph in which a variable node corresponds to a ’coded bit’ or a PCM column, and a check node corresponds to a parity check equation or a PCM row. There is an edge between each pair of nodes if there is a ’one’ in the corresponding PCM entry. In a general analysis an (n, k) LDPC code has k information bits and n coded bits with code rate r = k/n.
An important issue in the implementation of LDPC-code based forward error correction systems is the encoding of LDPC codes. Generally, LDPC codes cannot have the simple encoding structures based on of shift registers as in the case of convolutional, turbo codes, or cyclic block codes. However, general LDPC codes do not fall in this category. Except QC-cyclic LDPC codes, most efficient LDPC codes, especially irregular LDPC codes are hard to encode with the idea of shift registers.
A straightforward way is to derive a systematic generator matrix from a PCM, and then to encode LDPC code systematically with the generator matrix. This can work for every LDPC code in theory, but practically it is a very bad idea because it has high complexity, as the generator matrix derived from parity-check matrix is not sparse contrasted to the PCM. Generator matrix can be very dense matrix. The objective is to utilize the sparseness to achieve LDPC encoding in linear time.
This Master’s thesis presents a flexible encoder architecture using QC-cyclic LDPC codes and efficient two-step encoding algorithm in order to achieve linear time encoding. The particular approach considers several VLSI design issues of LDPC encoder. In particular efficient approaches are presented for reducing memory requirements, for reducing hardware complexity, and increasing the speed and throughput of LDPC encoding. The proposed structure is also generic and scalable, supporting multiple configurations, in terms of bits per symbol and code rate. A generic scalable processing unit is also presented. It supports LDPC codes that define parity check matrix as a combination of identity matrix, shifted identity matrix and all-zero matrix (QC-cyclic LDPC codes). The particular LDPC encoder architecture is synthesized and experimental results are reported.
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LDPC-BASED ITERATIVE JOINT SOURCE/CHANNEL DECODING SCHEME FOR JPEG2000Pu, Lingling, Wu, Zhenyu, Bilgin, Ali, Marcellin, Michael W., Vasic, Bane 10 1900 (has links)
International Telemetering Conference Proceedings / October 18-21, 2004 / Town & Country Resort, San Diego, California / This paper presents a joint source-channel decoding scheme based on a JPEG2000 source coder and an LDPC channel coder. At the encoder, JPEG2000 is used to perform source coding with certain error resilience (ER) modes, and LDPC codes are used to perform channel coding. At the decoder, after one iteration of LDPC decoding, the output codestream is then decoded by JPEG2000. With the error resilience mode switches on, the source decoder detects the position of the first error within each codeblock of the JPEG2000 codestream. This information is fed back to the channel decoder, and incorporated into the calculation of likelihood values of variable nodes for the next iteration of LDPC decoding. Our results indicate that the proposed method has significant gains over conventional separate channel and source decoding.
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Decoding and Turbo Equalization for LDPC Codes Based on Nonlinear ProgrammingIltis, Ronald A. 10 1900 (has links)
ITC/USA 2010 Conference Proceedings / The Forty-Sixth Annual International Telemetering Conference and Technical Exhibition / October 25-28, 2010 / Town and Country Resort & Convention Center, San Diego, California / Decoding and Turbo Equalization (TEQ) algorithms based on the Sum-Product Algorithm (SPA) are well established for LDPC codes. However there is increasing interest in linear and nonlinear programming (NLP)-based decoders which may offer computational and performance advantages over the SPA. We present NLP decoders and Turbo equalizers based on an Augmented Lagrangian formulation of the decoding problem. The decoders update estimates of both the Lagrange multipliers and transmitted codeword while solving an approximate quadratic programming problem. Simulation results show that the NLP decoder performance is intermediate between the SPA and bit-flipping algorithms. The NLP may thus be attractive in some applications as it eliminates the tanh/atanh computations in the SPA.
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An Analysis on the Coverage Distance of LDPC-Coded Free-Space Optical LinksLuna, Ricardo, Tapse, Hrishikesh 10 1900 (has links)
ITC/USA 2008 Conference Proceedings / The Forty-Fourth Annual International Telemetering Conference and Technical Exhibition / October 27-30, 2008 / Town and Country Resort & Convention Center, San Diego, California / We design irregular Low-Density Parity-Check (LDPC) codes for free-space optical (FSO) channels for different transmitter-receiver link distances and analyze the error performance for different atmospheric conditions. The design considers atmospheric absorption, laser beam divergence, and random intensity fluctuations due to atmospheric turbulence. It is found that, for the same transmit power, a system using the designed codes works over much longer link distances than a system that employs regular LDPC codes. Our analysis is particularly useful for portable optical transceivers and mobile links.
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High-Performance Decoder Architectures For Low-Density Parity-Check CodesZhang, Kai 09 January 2012 (has links)
The Low-Density Parity-Check (LDPC) codes, which were invented by Gallager back in 1960s, have attracted considerable attentions recently. Compared with other error correction codes, LDPC codes are well suited for wireless, optical, and magnetic recording systems due to their near- Shannon-limit error-correcting capacity, high intrinsic parallelism and high-throughput potentials. With these remarkable characteristics, LDPC codes have been adopted in several recent communication standards such as 802.11n (Wi-Fi), 802.16e (WiMax), 802.15.3c (WPAN), DVB-S2 and CMMB. This dissertation is devoted to exploring efficient VLSI architectures for high-performance LDPC decoders and LDPC-like detectors in sparse inter-symbol interference (ISI) channels. The performance of an LDPC decoder is mainly evaluated by area efficiency, error-correcting capability, throughput and rate flexibility. With this work we investigate tradeoffs between the four performance aspects and develop several decoder architectures to improve one or several performance aspects while maintaining acceptable values for other aspects. Firstly, we present a high-throughput decoder design for the Quasi-Cyclic (QC) LDPC codes. Two new techniques are proposed for the first time, including parallel layered decoding architecture (PLDA) and critical path splitting. Parallel layered decoding architecture enables parallel processing for all layers by establishing dedicated message passing paths among them. The decoder avoids crossbar-based large interconnect network. Critical path splitting technique is based on articulate adjustment of the starting point of each layer to maximize the time intervals between adjacent layers, such that the critical path delay can be split into pipeline stages. Furthermore, min-sum and loosely coupled algorithms are employed for area efficiency. As a case study, a rate-1/2 2304-bit irregular LDPC decoder is implemented using ASIC design in 90 nm CMOS process. The decoder can achieve an input throughput of 1.1 Gbps, that is, 3 or 4 times improvement over state-of-art LDPC decoders, while maintaining a comparable chip size of 2.9 mm^2. Secondly, we present a high-throughput decoder architecture for rate-compatible (RC) LDPC codes which supports arbitrary code rates between the rate of mother code and 1. While the original PLDA is lack of rate flexibility, the problem is solved gracefully by incorporating the puncturing scheme. Simulation results show that our selected puncturing scheme only introduces the BER performance degradation of less than 0.2dB, compared with the dedicated codes for different rates specified in the IEEE 802.16e (WiMax) standard. Subsequently, PLDA is employed for high throughput decoder design. As a case study, a RC- LDPC decoder based on the rate-1/2 WiMax LDPC code is implemented in CMOS 90 nm process. The decoder can achieve an input throughput of 975 Mbps and supports any rate between 1/2 and 1. Thirdly, we develop a low-complexity VLSI architecture and implementation for LDPC decoder used in China Multimedia Mobile Broadcasting (CMMB) systems. An area-efficient layered decoding architecture based on min-sum algorithm is incorporated in the design. A novel split-memory architecture is developed to efficiently handle the weight-2 submatrices that are rarely seen in conventional LDPC decoders. In addition, the check-node processing unit is highly optimized to minimize complexity and computing latency while facilitating a reconfigurable decoding core. Finally, we propose an LDPC-decoder-like channel detector for sparse ISI channels using belief propagation (BP). The BP-based detection computationally depends on the number of nonzero interferers only and are thus more suited for sparse ISI channels which are characterized by long delay but a small fraction of nonzero interferers. Layered decoding algorithm, which is popular in LDPC decoding, is also adopted in this paper. Simulation results show that the layered decoding doubles the convergence speed of the iterative belief propagation process. Exploring the special structure of the connections between the check nodes and the variable nodes on the factor graph, we propose an effective detector architecture for generic sparse ISI channels to facilitate the practical application of the proposed detection algorithm. The proposed architecture is also reconfigurable in order to switch flexible connections on the factor graph in the time-varying ISI channels.
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