608 research outputs found
LDPC decoder architecture for DVB-S2 and DVB-S2X standards
International audienceA particular type of conflict due to multiple-diagonal sub-matrices in the DVB-S2 parity-check matrices is known to complicate the implementation of the layered decoder architecture. The new matrices proposed in DVB-S2X no longer use such sub-matrices. For implementing a decoder compliant both with DVB-S2 and DVB-S2X, we propose an elegant solution which overcomes this conflicts relying on an efficient write disable of the memories, allowing a straightforward implementation of layered LDPC decoders. The complexity and latency are further reduced by eliminating one barrel shifter. Compared with the existing solutions, complexity is reduced without performance degradation. Keywords—Low-Density Parity-Check (LDPC) code, memory conflict, layered decoder, DVB-S2, DVB-S2X
LDPC Code Design for Noncoherent Physical Layer Network Coding
This work considers optimizing LDPC codes in the physical-layer network coded
two-way relay channel using noncoherent FSK modulation. The error-rate
performance of channel decoding at the relay node during the multiple-access
phase was improved through EXIT-based optimization of Tanner graph variable
node degree distributions. Codes drawn from the DVB-S2 and WiMAX standards were
used as a basis for design and performance comparison. The computational
complexity characteristics of the standard codes were preserved in the
optimized codes by maintaining the extended irregular repeat-accumulate (eIRA).
The relay receiver performance was optimized considering two modulation orders
M = {4, 8} using iterative decoding in which the decoder and demodulator refine
channel estimates by exchanging information. The code optimization procedure
yielded unique optimized codes for each case of modulation order and available
channel state information. Performance of the standard and optimized codes were
measured using Monte Carlo simulation in the flat Rayleigh fading channel, and
error rate improvements up to 1.2 dB are demonstrated depending on system
parameters.Comment: Six pages, submitted to 2015 IEEE International Conference on
Communication
Repeat-Accumulate Codes for Reconciliation in Continuous Variable Quantum Key Distribution
This paper investigates the design of low-complexity error correction codes
for the verification step in continuous variable quantum key distribution
(CVQKD) systems. We design new coding schemes based on quasi-cyclic
repeat-accumulate codes which demonstrate good performances for CVQKD
reconciliation
Investigation of punctured LDPC codes and time-diversity on free-space optical links
In this paper, we analyze the behavior of DVB-S2 un-punctured/punctured low-density parity-check (LDPC) coded on-off-keying (OOK) under atmospheric turbulence conditions by utilizing time diversity. A performance characterization between these schemes is evaluated, where punctured LDPC code provides a penalty of around 0.1 to 0.2 dB against unpunctured LDPC codes but still provides a coding gain of several dB against uncoded OOK. The combination of channel coding and a bit interleaver results in performance improvements in turbulence conditions. For example, such a system can achieve a coding gain of 16.7 dB in moderate turbulence conditions compared to uncoded OOK
A CRC usefulness assessment for adaptation layers in satellite systems
This paper assesses the real usefulness of CRCs in today's satellite network-to-link adaptation layers under the lights of enhanced error control and framing techniques, focusing on the DVB-S and DVB-S2 standards. Indeed, the outer block codes of their FEC schemes (Reed-Solomon and BCH, respectively) can provide very accurate error-detection information to the receiver in addition to their correction capabilities, at virtually no cost. This handy feature could be used to manage on a frame-by-frame basis what CRCs do locally, on the frames' contents, saving the bandwidth and processing load associated with them, and paving the way for enhanced transport of IP over DVB-S2. Mathematical and experimental results clearly show that if FEC has been properly congured for combined error correction and detection, having an uncorrected event after FEC decoding is likely to be an extremely improbable event. Under such conditions, it seems possible and attractive to optimize the way global error-control is done over satellite links by reducing the role of CRCs, or even by removing them from the overall encapsulation process
On Complexity, Energy- and Implementation-Efficiency of Channel Decoders
Future wireless communication systems require efficient and flexible baseband
receivers. Meaningful efficiency metrics are key for design space exploration
to quantify the algorithmic and the implementation complexity of a receiver.
Most of the current established efficiency metrics are based on counting
operations, thus neglecting important issues like data and storage complexity.
In this paper we introduce suitable energy and area efficiency metrics which
resolve the afore-mentioned disadvantages. These are decoded information bit
per energy and throughput per area unit. Efficiency metrics are assessed by
various implementations of turbo decoders, LDPC decoders and convolutional
decoders. New exploration methodologies are presented, which permit an
appropriate benchmarking of implementation efficiency, communications
performance, and flexibility trade-offs. These exploration methodologies are
based on efficiency trajectories rather than a single snapshot metric as done
in state-of-the-art approaches.Comment: Submitted to IEEE Transactions on Communication
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