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6.451 Principles of Digital Communication II, Spring 2003

dc.contributor.authorForney, G. Daviden_US
dc.coverage.temporalSpring 2003en_US
dc.date.issued2003-06
dc.identifier6.451-Spring2003
dc.identifierlocal: 6.451
dc.identifierlocal: IMSCP-MD5-7b3d320cf570ec10712dab3722572ec0
dc.identifier.urihttp://hdl.handle.net/1721.1/36834
dc.description.abstractCoding for the AWGN channel; block and convolutional codes; lattice and trellis codes; capacity-approaching codes; equalization of linear Gaussian channels; linear, decision-feedback, and MLSD equalization; precoding; multicarrier modulation; and topics in wireless communication. Description from the course home page: This course is the second of a two-term sequence with 6.450. The focus is on coding techniques for approaching the Shannon limit of additive white Gaussian noise (AWGN) channels, their performance analysis, and design principles. After a review of 6.450 and the Shannon limit for AWGN channels, the course begins by discussing small signal constellations, performance analysis and coding gain, and hard-decision and soft-decision decoding. It continues with binary linear block codes, Reed-Muller codes, finite fields, Reed-Solomon and BCH codes, binary linear convolutional codes, and the Viterbi algorithm. More advanced topics include trellis representations of binary linear block codes and trellis-based decoding; codes on graphs; the sum-product and min-sum algorithms; the BCJR algorithm; turbo codes, LDPC codes and RA codes; and performance of LDPC codes with iterative decoding. Finally, the course addresses coding for the bandwidth-limited regime, including lattice codes, trellis-coded modulation, multilevel coding and shaping. If time permits, it covers equalization of linear Gaussian channels.en_US
dc.languageen-USen_US
dc.rights.uriUsage Restrictions: This site (c) Massachusetts Institute of Technology 2003. Content within individual courses is (c) by the individual authors unless otherwise noted. The Massachusetts Institute of Technology is providing this Work (as defined below) under the terms of this Creative Commons public license ("CCPL" or "license"). The Work is protected by copyright and/or other applicable law. Any use of the work other than as authorized under this license is prohibited. By exercising any of the rights to the Work provided here, You (as defined below) accept and agree to be bound by the terms of this license. The Licensor, the Massachusetts Institute of Technology, grants You the rights contained here in consideration of Your acceptance of such terms and conditions.en_US
dc.subjectcoding techniquesen_US
dc.subjectthe Shannon limit of additive white Gaussian noise channelsen_US
dc.subjectSmall signal constellationsen_US
dc.subjectperformance analysisen_US
dc.subjectcoding gainen_US
dc.subjectHard-decision and soft-decision decodingen_US
dc.subjectIntroduction to binary linear block codesen_US
dc.subjectReed-Muller codesen_US
dc.subjectfinite fieldsen_US
dc.subjectReed-Solomon and BCH codesen_US
dc.subjectbinary linear convolutional codesen_US
dc.subjectViterbi and BCJR algorithmsen_US
dc.subjectTrellis representations of binary linear block codesen_US
dc.subjecttrellis-based ML decodingen_US
dc.subjectCodes on graphsen_US
dc.subjectsum-producten_US
dc.subjectmax-producten_US
dc.subjectdecoding algorithmsen_US
dc.subjectTurbo codesen_US
dc.subjectLDPC codes and RA codesen_US
dc.subjectCoding for the bandwidth-limited regimeen_US
dc.subjectLattice codesen_US
dc.subjectTrellis-coded modulationen_US
dc.subjectMultilevel codingen_US
dc.subjectShapingen_US
dc.title6.451 Principles of Digital Communication II, Spring 2003en_US
dc.title.alternativePrinciples of Digital Communication IIen_US
dc.typeLearning Object
dc.contributor.departmentMassachusetts Institute of Technology. Department of Electrical Engineering and Computer Science


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