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Design of multidimensional signal constellations

Design of multidimensional signal constellations

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  • Author(s): J.-E. Porath 1  and  T. Aulin 2
    • View affiliations
    • Affiliations: 1: Department of Technology, University of Trollhättan/Uddevalla, Trollhättan, Sweden
      2: Telecommunication Theory, Department of Computer Engineering, Chalmers University of Technology, Göteborg, Sweden
  • Source: Volume 150, Issue 5, October 2003, p. 317 – 323
    DOI:  10.1049/ip-com:20030652 , Print ISSN 1350-2425, Online ISSN 1359-7019
© IEE
Published

An algorithmic technique intended for signal constellation design for an N-dimensional Euclidean signal space is presented. Such signals are used for reliable and efficient digital communications on an additive white Gaussian noise channel. The minimum Euclidean distance between signals and the constellation-constrained capacity are used as performance measures. The basic idea is to spread out the signal vectors using an iterative method modelling the behaviour of equally charged particles in free space. Initially, the vectors are randomly distributed. The vectors reach equilibrium after a few iterations. Numerical calculations for N=2, 3, 4 and 5 dimensions and M=N+1, N+2, …,20 signals show that the generated codes are nearly as good as previously known codes, and in some cases even better.

Inspec keywords: AWGN channels; multidimensional signal processing; digital communication; quadrature amplitude modulation; iterative methods; phase shift keying; modulation coding

Other keywords: iterative method; spherical codes; Euclidean signal space; minimum Euclidean distance; signal vectors; AWGN channel; nonspherical codes; M-PSK; additive white Gaussian noise channel; M-QAM; digital communications; multidimensional signal constellations

Subjects: Signal processing and detection; Modulation and coding methods; Interpolation and function approximation (numerical analysis)

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