10 research outputs found
The Weight Distributions of Cyclic Codes and Elliptic Curves
Cyclic codes with two zeros and their dual codes as a practically and
theoretically interesting class of linear codes, have been studied for many
years. However, the weight distributions of cyclic codes are difficult to
determine. From elliptic curves, this paper determines the weight distributions
of dual codes of cyclic codes with two zeros for a few more cases
The weight distributions of a class of cyclic codes III
Recently, the weight distributions of the duals of the cyclic codes with two
zeros have been obtained for several cases. In this paper we solve one more
special case. The problem of finding the weight distribution is transformed
into a problem of evaluating certain character sums over finite fields, which
in turn can be solved by using the Jacobi sums directly
The Intersection of Two Fermat Hypersurfaces in P^3 via Computation of Quotient Curves
We study the intersection of two particular Fermat hypersurfaces in
over a finite field. Using the Kani-Rosen decomposition we study
arithmetic properties of this curve in terms of its quotients. Explicit
computation of the quotients is done using a Gr\"obner basis algorithm. We also
study the -rank, zeta function, and number of rational points, of the modulo
reduction of the curve. We show that the Jacobian of the genus 2 quotient
is -split
The Weight Distributions of a Class of Cyclic Codes with Three Nonzeros over F3
Cyclic codes have efficient encoding and decoding algorithms. The decoding
error probability and the undetected error probability are usually bounded by
or given from the weight distributions of the codes. Most researches are about
the determination of the weight distributions of cyclic codes with few
nonzeros, by using quadratic form and exponential sum but limited to low
moments. In this paper, we focus on the application of higher moments of the
exponential sum to determine the weight distributions of a class of ternary
cyclic codes with three nonzeros, combining with not only quadratic form but
also MacWilliams' identities. Another application of this paper is to emphasize
the computer algebra system Magma for the investigation of the higher moments.
In the end, the result is verified by one example using Matlab.Comment: 10 pages, 3 table
์๋ก์ด ์์ค ์ฑ๋์ ์ํ ์๊ธฐ๋ํ ๊ตฐ ๋ณตํธ๊ธฐ ๋ฐ ๋ถ๋ถ ์ ์ ๋ณต๊ตฌ ๋ถํธ ๋ฐ ์ผ๋ฐํ๋ ๊ทผ ํ๋กํ ๊ทธ๋ํ LDPC ๋ถํธ์ ์ค๊ณ
ํ์๋
ผ๋ฌธ (๋ฐ์ฌ)-- ์์ธ๋ํ๊ต ๋ํ์ : ๊ณต๊ณผ๋ํ ์ ๊ธฐยท์ปดํจํฐ๊ณตํ๋ถ, 2019. 2. ๋
ธ์ข
์ .In this dissertation, three main contributions are given asi) new two-stage automorphism group decoders (AGD) for cyclic codes in the erasure channel, ii) new constructions of binary and ternary locally repairable codes (LRCs) using cyclic codes and existing LRCs, and iii) new constructions of high-rate generalized root protograph (GRP) low-density parity-check (LDPC) codes for a nonergodic block interference and partially regular (PR) LDPC codes for follower noise jamming (FNJ), are considered.
First, I propose a new two-stage AGD (TS-AGD) for cyclic codes in the erasure channel.
Recently, error correcting codes in the erasure channel have drawn great attention for various applications such as distributed storage systems and wireless sensor networks, but many of their decoding algorithms are not practical because they have higher decoding complexity and longer delay. Thus, the AGD for cyclic codes in the erasure channel was introduced, which has good erasure decoding performance with low decoding complexity. In this research, I propose new TS-AGDs for cyclic codes in the erasure channel by modifying the parity check matrix and introducing the preprocessing stage to the AGD scheme. The proposed TS-AGD is analyzed for the perfect codes, BCH codes, and maximum distance separable (MDS) codes. Through numerical analysis, it is shown that the proposed decoding algorithm has good erasure decoding performance with lower decoding complexity than the conventional AGD. For some cyclic codes, it is shown that the proposed TS-AGD achieves the perfect decoding in the erasure channel, that is, the same decoding performance as the maximum likelihood (ML) decoder. For MDS codes, TS-AGDs with the expanded parity check matrix and the submatrix inversion are also proposed and analyzed.
Second, I propose new constructions of binary and ternary LRCs using cyclic codes and existing two LRCs for distributed storage system. For a primitive work, new constructions of binary and ternary LRCs using cyclic codes and their concatenation are proposed. Some of proposed binary LRCs with Hamming weights 4, 5, and 6 are optimal in terms of the upper bounds. In addition, the similar method of the binary case is applied to construct the ternary LRCs with good parameters.
Also, new constructions of binary LRCs with large Hamming distance and disjoint repair groups are proposed. The proposed binary linear LRCs constructed by using existing binary LRCs are optimal or near-optimal in terms of the bound with disjoint repair group.
Last, I propose new constructions of high-rate GRP LDPC codes for a nonergodic block interference and anti-jamming PR LDPC codes for follower jamming.
The proposed high-rate GRP LDPC codes are based on nonergodic two-state binary symmetric channel with block interference and Nakagami- block fading. In these channel environments, GRP LDPC codes have good performance approaching to the theoretical limit in the channel with one block interference, where their performance is shown by the channel threshold or the channel outage probability. In the proposed design, I find base matrices using the protograph extrinsic information transfer (PEXIT) algorithm.
Also, the proposed new constructions of anti-jamming partially regular LDPC codes is based on follower jamming on the frequency-hopped spread spectrum (FHSS). For a channel environment, I suppose follower jamming with random dwell time and Rayleigh block fading environment with M-ary frequnecy shift keying (MFSK) modulation. For a coding perspective, an anti-jamming LDPC codes against follower jamming are introduced. In order to optimize the jamming environment, the partially regular structure and corresponding density evolution schemes are used. A series of simulations show that the proposed codes outperforms the 802.16e standard in the presence of follower noise jamming.์ด ๋
ผ๋ฌธ์์๋, i) ์์ค ์ฑ๋์์ ์ํ ๋ถํธ์ ์๋ก์ด ์ด๋จ ์๊ธฐ๋ํ ๊ตฐ ๋ณตํธ๊ธฐ , ii) ๋ถ์ฐ ์ ์ฅ ์์คํ
์ ์ํ ์ํ ๋ถํธ ๋ฐ ๊ธฐ์กด์ ๋ถ๋ถ ์ ์ ๋ณต๊ตฌ ๋ถํธ(LRC)๋ฅผ ์ด์ฉํ ์ด์ง ํน์ ์ผ์ง ๋ถ๋ถ ์ ์ ๋ณต๊ตฌ ๋ถํธ ์ค๊ณ๋ฒ, ๋ฐ iii) ๋ธ๋ก ๊ฐ์ญ ํ๊ฒฝ์ ์ํ ๊ณ ๋ถํจ์จ์ ์ผ๋ฐํ๋ ๊ทผ ํ๋กํ ๊ทธ๋ํ(generalized root protograph, GRP) LDPC ๋ถํธ ๋ฐ ์ถ์ ์ฌ๋ฐ ํ๊ฒฝ์ ์ํ ํญ์ฌ๋ฐ ๋ถ๋ถ ๊ท ์ผ (anti-jamming paritally regular, AJ-PR) LDPC ๋ถํธ๊ฐ ์ฐ๊ตฌ๋์๋ค.
์ฒซ๋ฒ์งธ๋ก, ์์ค ์ฑ๋์์ ์ํ ๋ถํธ์ ์๋ก์ด ์ด๋จ ์๊ธฐ๋ํ ๊ตฐ ๋ณตํธ๊ธฐ๋ฅผ ์ ์ํ์๋ค. ์ต๊ทผ ๋ถ์ฐ ์ ์ฅ ์์คํ
ํน์ ๋ฌด์ ์ผ์ ๋คํธ์ํฌ ๋ฑ์ ์์ฉ์ผ๋ก ์ธํด ์์ค ์ฑ๋์์์ ์ค๋ฅ ์ ์ ๋ถํธ ๊ธฐ๋ฒ์ด ์ฃผ๋ชฉ๋ฐ๊ณ ์๋ค. ๊ทธ๋ฌ๋ ๋ง์ ๋ณตํธ๊ธฐ ์๊ณ ๋ฆฌ์ฆ์ ๋์ ๋ณตํธ ๋ณต์ก๋ ๋ฐ ๊ธด ์ง์ฐ์ผ๋ก ์ธํด ์ค์ฉ์ ์ด์ง ๋ชปํ๋ค. ๋ฐ๋ผ์ ๋ฎ์ ๋ณตํธ ๋ณต์ก๋ ๋ฐ ๋์ ์ฑ๋ฅ์ ๋ณด์ผ ์ ์๋ ์ํ ๋ถํธ์์ ์ด๋จ ์๊ธฐ ๋ํ ๊ตฐ ๋ณตํธ๊ธฐ๊ฐ ์ ์๋์๋ค. ๋ณธ ์ฐ๊ตฌ์์๋ ํจ๋ฆฌํฐ ๊ฒ์ฌ ํ๋ ฌ์ ๋ณํํ๊ณ , ์ ์ฒ๋ฆฌ ๊ณผ์ ์ ๋์
ํ ์๋ก์ด ์ด๋จ ์๊ธฐ๋ํ ๊ตฐ ๋ณตํธ๊ธฐ๋ฅผ ์ ์ํ๋ค. ์ ์ํ ๋ณตํธ๊ธฐ๋ perfect ๋ถํธ, BCH ๋ถํธ ๋ฐ ์ต๋ ๊ฑฐ๋ฆฌ ๋ถ๋ฆฌ (maximum distance separable, MDS) ๋ถํธ์ ๋ํด์ ๋ถ์๋์๋ค. ์์น ๋ถ์์ ํตํด, ์ ์๋ ๋ณตํธ ์๊ณ ๋ฆฌ์ฆ์ ๊ธฐ์กด์ ์๊ธฐ ๋ํ ๊ตฐ ๋ณตํธ๊ธฐ๋ณด๋ค ๋ฎ์ ๋ณต์ก๋๋ฅผ ๋ณด์ด๋ฉฐ, ๋ช๋ช์ ์ํ ๋ถํธ ๋ฐ ์์ค ์ฑ๋์์ ์ต๋ ์ฐ๋ (maximal likelihood, ML)๊ณผ ๊ฐ์ ์์ค์ ์ฑ๋ฅ์์ ๋ณด์ธ๋ค. MDS ๋ถํธ์ ๊ฒฝ์ฐ, ํ์ฅ๋ ํจ๋ฆฌํฐ๊ฒ์ฌ ํ๋ ฌ ๋ฐ ์์ ํฌ๊ธฐ์ ํ๋ ฌ์ ์ญ์ฐ์ฐ์ ํ์ฉํ์์ ๊ฒฝ์ฐ์ ์ฑ๋ฅ์ ๋ถ์ํ๋ค.
๋ ๋ฒ์งธ๋ก, ๋ถ์ฐ ์ ์ฅ ์์คํ
์ ์ํ ์ํ ๋ถํธ ๋ฐ ๊ธฐ์กด์ ๋ถ๋ถ ์ ์ ๋ณต๊ตฌ ๋ถํธ (LRC)๋ฅผ ์ด์ฉํ ์ด์ง ํน์ ์ผ์ง ๋ถ๋ถ ์ ์ ๋ณต๊ตฌ ๋ถํธ ์ค๊ณ๋ฒ์ ์ ์ํ์๋ค. ์ด๊ธฐ ์ฐ๊ตฌ๋ก์, ์ํ ๋ถํธ ๋ฐ ์ฐ์ ์ ํ์ฉํ ์ด์ง ๋ฐ ์ผ์ง LRC ์ค๊ณ ๊ธฐ๋ฒ์ด ์ฐ๊ตฌ๋์๋ค. ์ต์ ํด๋ฐ ๊ฑฐ๋ฆฌ๊ฐ 4,5, ํน์ 6์ธ ์ ์๋ ์ด์ง LRC ์ค ์ผ๋ถ๋ ์ํ๊ณผ ๋น๊ตํด ๋ณด์์ ๋ ์ต์ ์ค๊ณ์์ ์ฆ๋ช
ํ์๋ค. ๋ํ, ๋น์ทํ ๋ฐฉ๋ฒ์ ์ ์ฉํ์ฌ ์ข์ ํ๋ผ๋ฏธํฐ์ ์ผ์ง LRC๋ฅผ ์ค๊ณํ ์ ์์๋ค. ๊ทธ ์ธ์ ๊ธฐ์กด์ LRC๋ฅผ ํ์ฉํ์ฌ ํฐ ํด๋ฐ ๊ฑฐ๋ฆฌ์ ์๋ก์ด LRC๋ฅผ ์ค๊ณํ๋ ๋ฐฉ๋ฒ์ ์ ์ํ์๋ค. ์ ์๋ LRC๋ ๋ถ๋ฆฌ๋ ๋ณต๊ตฌ ๊ตฐ ์กฐ๊ฑด์์ ์ต์ ์ด๊ฑฐ๋ ์ต์ ์ ๊ฐ๊น์ด ๊ฐ์ ๋ณด์๋ค.
๋ง์ง๋ง์ผ๋ก, GRP LDPC ๋ถํธ๋ Nakagami- ๋ธ๋ก ํ์ด๋ฉ ๋ฐ ๋ธ๋ก ๊ฐ์ญ์ด ์๋ ๋ ์ํ์ ์ด์ง ๋์นญ ์ฑ๋์ ๊ธฐ๋ฐ์ผ๋ก ํ๋ค. ์ด๋ฌํ ์ฑ๋ ํ๊ฒฝ์์ GRP LDPC ๋ถํธ๋ ํ๋์ ๋ธ๋ก ๊ฐ์ญ์ด ๋ฐ์ํ์ ๊ฒฝ์ฐ, ์ด๋ก ์ ์ฑ๋ฅ์ ๊ฐ๊น์ด ์ข์ ์ฑ๋ฅ์ ๋ณด์ฌ์ค๋ค. ์ด๋ฌํ ์ด๋ก ๊ฐ์ ์ฑ๋ ๋ฌธํฑ๊ฐ์ด๋ ์ฑ๋ outage ํ๋ฅ ์ ํตํด ๊ฒ์ฆํ ์ ์๋ค. ์ ์๋ ์ค๊ณ์์๋, ๋ณํ๋ PEXIT ์๊ณ ๋ฆฌ์ฆ์ ํ์ฉํ์ฌ ๊ธฐ์ด ํ๋ ฌ์ ์ค๊ณํ๋ค. ๋ํ AJ-PR LDPC ๋ถํธ๋ ์ฃผํ์ ๋์ฝ ํ๊ฒฝ์์ ๋ฐ์ํ๋ ์ถ์ ์ฌ๋ฐ์ด ์๋ ํ๊ฒฝ์ ๊ธฐ๋ฐ์ผ๋ก ํ๋ค. ์ฑ๋ ํ๊ฒฝ์ผ๋ก MFSK ๋ณ๋ณต์กฐ ๋ฐฉ์์ ๋ ์ผ๋ฆฌ ๋ธ๋ก ํ์ด๋ฉ ๋ฐ ๋ฌด์์ํ ์ง์ ์๊ฐ์ด ์๋ ์ฌ๋ฐ ํ๊ฒฝ์ ๊ฐ์ ํ๋ค. ์ด๋ฌํ ์ฌ๋ฐ ํ๊ฒฝ์ผ๋ก ์ต์ ํํ๊ธฐ ์ํด, ๋ถ๋ถ ๊ท ์ผ ๊ตฌ์กฐ ๋ฐ ํด๋น๋๋ ๋ฐ๋ ์งํ (density evolution, DE) ๊ธฐ๋ฒ์ด ํ์ฉ๋๋ค. ์ฌ๋ฌ ์๋ฎฌ๋ ์ด์
๊ฒฐ๊ณผ๋ ์ถ์ ์ฌ๋ฐ์ด ์กด์ฌํ๋ ํ๊ฒฝ์์ ์ ์๋ ๋ถํธ๊ฐ 802.16e์ ์ฌ์ฉ๋์๋ LDPC ๋ถํธ๋ณด๋ค ์ฑ๋ฅ์ด ์ฐ์ํจ์ ๋ณด์ฌ์ค๋ค.Contents
Abstract
Contents
List of Tables
List of Figures
1 INTRODUCTION
1.1 Background
1.2 Overview of Dissertation
1.3 Notations
2 Preliminaries
2.1 IED and AGD for Erasure Channel
2.1.1 Iterative Erasure Decoder
2.1.1 Automorphism Group Decoder
2.2. Binary Locally Repairable Codes for Distributed Storage System
2.2.1 Bounds and Optimalities of Binary LRCs
2.2.2 Existing Optimal Constructions of Binary LRCs
2.3 Channels with Block Interference and Jamming
2.3.1 Channels with Block Interference
2.3.2 Channels with Jamming with MFSK and FHSS Environment.
3 New Two-Stage Automorphism Group Decoders for Cyclic Codes in the Erasure Channel
3.1 Some Definitions
3.2 Modification of Parity Check Matrix and Two-Stage AGD
3.2.1 Modification of the Parity Check Matrix
3.2.2 A New Two-Stage AGD
3.2.3 Analysis of Modification Criteria for the Parity Check Matrix
3.2.4 Analysis of Decoding Complexity of TS-AGD
3.2.5 Numerical Analysis for Some Cyclic Codes
3.3 Construction of Parity Check Matrix and TS-AGD for Cyclic MDS Codes
3.3.1 Modification of Parity Check Matrix for Cyclic MDS Codes .
3.3.2 Proposed TS-AGD for Cyclic MDS Codes
3.3.3 Perfect Decoding by TS-AGD with Expanded Parity Check Matrix for Cyclic MDS Codes
3.3.4 TS-AGD with Submatrix Inversion for Cyclic MDS Codes . .
4 New Constructions of Binary and Ternary LRCs Using Cyclic Codes and Existing LRCs
4.1 Constructions of Binary LRCs Using Cyclic Codes
4.2 Constructions of Linear Ternary LRCs Using Cyclic Codes
4.3 Constructions of Binary LRCs with Disjoint Repair Groups Using Existing LRCs
4.4 New Constructions of Binary Linear LRCs with d โฅ 8 Using Existing LRCs
5 New Constructions of Generalized RP LDPC Codes for Block Interference and Partially Regular LDPC Codes for Follower Jamming
5.1 Generalized RP LDPC Codes for a Nonergodic BI
5.1.1 Minimum Blockwise Hamming Weight
5.1.2 Construction of GRP LDPC Codes
5.2 Asymptotic and Numerical Analyses of GRP LDPC Codes
5.2.1 Asymptotic Analysis of LDPC Codes
5.2.2 Numerical Analysis of Finite-Length LDPC Codes
5.3 Follower Noise Jamming with Fixed Scan Speed
5.4 Anti-Jamming Partially Regular LDPC Codes for Follower Noise Jamming
5.4.1 Simplified Channel Model and Corresponding Density Evolution
5.4.2 Construction of AJ-PR-LDPC Codes Based on DE
5.5 Numerical Analysis of AJ-PR LDPC Codes
6 Conclusion
Abstract (In Korean)Docto