A Computationally Efficient Schnorr-Euchner Enumeration for Solving Integer Least-Squares Problem in Wireless Communications

A Computationally Efficient Schnorr-Euchner Enumeration for Solving Integer Least-Squares Problem in Wireless Communications

The integer least-squares (ILS) problem frequently arises in wireless communication systems. Sphere decoding (SD) is a systematic search scheme for solving ILS problem. The enumeration of candidates is a key part of SD for selecting a lattice point, which will be searched by the algorithm. Herein, t...

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Veröffentlicht in:IEICE Transactions on Fundamentals of Electronics, Communications and Computer Sciences Communications and Computer Sciences, 2017/01/01, Vol.E100.A(1), pp.327-331
Hauptverfasser: AHN, Junil, CHANG, Jaewon, LEE, Chiho
Format: Artikel
Sprache:eng
Schlagworte:
Algorithms
Computational efficiency
Electronics
Enumeration
finite lattice
integer least-squares problem
Integers
Lattices
Least squares method
Mathematical analysis
Schnorr-Euchner enumeration
sphere decoding
Wireless communication systems
Wireless communications
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Zusammenfassung:The integer least-squares (ILS) problem frequently arises in wireless communication systems. Sphere decoding (SD) is a systematic search scheme for solving ILS problem. The enumeration of candidates is a key part of SD for selecting a lattice point, which will be searched by the algorithm. Herein, the authors present a computationally efficient Schnorr-Euchner enumeration (SEE) algorithm to solve the constrained ILS problems, where the solution is limited into the finite integer lattice. To trace only valid lattice points within the underlying finite lattice, the authors devise an adaptive computation of the enumeration step and counting the valid points enumerated. In contrast to previous SEE methods based on a zig-zag manner, the proposed method completely avoids enumerating invalid points outside the finite lattice, and it further reduces real arithmetic and logical operations.
ISSN:0916-8508
1745-1337
DOI:10.1587/transfun.E100.A.327