Your search keyword '"Wesel, Richard D."' showing total 5 results

1. Achievable Rates for Low-Complexity Posterior Matching Over the Binary Symmetric Channel

Author

Antonini, Amaael, Gimelshein, Rita, and Wesel, Richard D.

Abstract

Horstein, Burnashev, Shayevitz and Feder, Naghshvar et al. and others have studied sequential transmission of a k-bit message over the binary symmetric channel (BSC) with full, noiseless feedback using posterior matching. Yang et al. provide an improved lower bound on the achievable rate using martingale analysis that relies on the small-enough difference (SED) partitioning introduced by Naghshvar et al. SED requires a relatively complex encoder and decoder. To reduce complexity, this paper replaces SED with relaxed constraints that admit the small enough absolute difference (SEAD) partitioning rule. The main analytical results show that achievable-rate bounds higher than those found by Yang et al. (2021) are possible even under the new constraints, which are less restrictive than SED. The new analysis does not use martingale theory for the confirmation phase and applies a surrogate channel technique to tighten the results. An initial systematic transmission further increases the achievable rate bound. The simplified encoder associated with SEAD has a complexity below order $O(K^{2})$ and allows simulations for message sizes of at least 1000 bits. For example, simulations achieve 99% of of the channel’s 0.50-bit capacity with an average block size of 200 bits for a target codeword error rate of $10^{-3}$ .

Published

2024

2. LDPC Decoding With Degree-Specific Neural Message Weights and RCQ Decoding

Author

Wang, Linfang, Terrill, Caleb, Divsalar, Dariush, and Wesel, Richard D.

Abstract

Recently, neural networks have improved MinSum message-passing decoders for low-density parity-check (LDPC) codes by multiplying or adding weights to the messages, where the weights are determined by a neural network. The neural network complexity to determine distinct weights for each edge is high, often limiting the application to relatively short LDPC codes. Furthermore, storing separate weights for every edge and every iteration can be a burden for hardware implementations. To reduce neural network complexity and storage requirements, this paper proposes a family of weight-sharing schemes that use the same weight for edges that have the same check node degree and/or variable node degree. Our simulation results show that node-degree-based weight-sharing can deliver the same performance requiring distinct weights for each node. This paper also combines these degree-specific neural weights with a reconstruction-computation-quantization (RCQ) decoder to produce a weighted RCQ (W-RCQ) decoder. The W-RCQ decoder with node-degree-based weight sharing has a reduced hardware requirement compared with the original RCQ decoder. As an additional contribution, this paper identifies and resolves a gradient explosion issue that can arise when training neural LDPC decoders.

Published

2024

3. CRC-Aided High-Rate Convolutional Codes With Short Blocklengths for List Decoding

Author

Sui, Wenhui, Towell, Brendan, Asmani, Ava, Yang, Hengjie, Grissett, Holden, and Wesel, Richard D.

Abstract

Recently, rate- $1/n$ zero-terminated (ZT) and tail-biting (TB) convolutional codes (CCs) with cyclic redundancy check (CRC)-aided list decoding have been shown to closely approach the random-coding union (RCU) bound for short blocklengths. This paper designs CRC polynomials for rate- $(n-1)/n$ ZT and TB CCs with short blocklengths. This paper considers both standard rate- $(n-1)/n$ CC polynomials and rate- $(n-1)/n$ designs resulting from puncturing a rate- $1/2$ code. The CRC polynomials are chosen to maximize the minimum distance $d_{\min }$ and minimize the number of nearest neighbors $A_{d_{\min }}$ . For the standard rate- $(n-1)/n$ codes, utilization of the dual trellis proposed by Yamada et al. lowers the complexity of CRC-aided serial list Viterbi decoding (SLVD). CRC-aided SLVD of the TBCCs closely approaches the RCU bound at a blocklength of 128. This paper compares the FER performance (gap to the RCU bound) and complexity of the CRC-aided standard and punctured ZTCCs and TBCCs. This paper also explores the complexity-performance trade-off for three TBCC decoders: a single-trellis approach, a multi-trellis approach, and a modified single-trellis approach with pre-processing using the wrap around Viterbi algorithm.

Published

2024

4. Probabilistic Shaping for Trellis-Coded Modulation With CRC-Aided List Decoding

Author

Wang, Linfang, Song, Dan, Areces, Felipe, Wiegart, Thomas, and Wesel, Richard D.

Abstract

This paper applies probabilistic amplitude shaping (PAS) to cyclic redundancy check (CRC)-aided tail-biting trellis-coded modulation (TCM). CRC-TCM-PAS produces practical codes for short block lengths on the additive white Gaussian noise (AWGN) channel. In the transmitter, equally likely message bits are encoded by a distribution matcher (DM) generating amplitude symbols with a desired distribution. A CRC is appended to the sequence of amplitude symbols, and this sequence is then encoded and modulated by TCM to produce real-valued channel input signals. This paper proves that the sign values produced by the TCM are asymptotically equally likely to be positive or negative. The CRC-TCM-PAS scheme can thus generate channel input symbols with a symmetric capacity-approaching probability mass function. The paper provides an analytical upper bound on the frame error rate of the CRC-TCM-PAS system over the AWGN channel. This FER upper bound is the objective function used for jointly optimizing the CRC and convolutional code. Additionally, this paper proposes a multi-composition DM, which is a collection of multiple constant-composition DMs. The optimized CRC-TCM-PAS systems achieve frame error rates below the random coding union (RCU) bound in AWGN and outperform the short-blocklength PAS systems with various other forward error correction codes studied in Coşkun et al. (2019).

Published

2023

5. CONVOLUTIONAL CODES.

Author

Wesel, Richard D.

Subjects

CIPHER & telegraph codes, TRELLIS-coded modulation, DECODERS (Electronics), DECODERS & decoding, TELECOMMUNICATION, DATA transmission systems

Abstract

This article introduces trellis diagrams, describes the fundamental add-compare-select computation, compares hard and soft decoding, and describes the suboptimal finite traceback version of Viterbi decoding. It states that convolutional codes represent one technique within the general class of channel codes. Channel codes--also called error-correction codes--permit reliable communication of an information sequence over a channel that adds noise, introduces bit errors, or otherwise distorts the transmitted signal.

Published

2003