Signal Constellations with Enhanced Energy Efficiency for High-Speed Communication Systems

TL;DR

This paper introduces SCOPT, a new multidimensional signal constellation that improves energy efficiency and reliability in high-speed communication systems by increasing minimum Euclidean distance without extra power or coding.

Contribution

The paper presents SCOPT, a novel constellation design that enhances energy efficiency and enables reliable communication below Shannon limit without complex coding.

Findings

SCOPT outperforms classical Shannon-type constellations in energy efficiency.

SCOPT allows reliable communication below Shannon limit within the geometric framework.

Numerical analysis confirms SCOPT's shorter signal duration and improved performance.

Abstract

This paper proposes a new method for constructing multidimensional signal constellations (SC), referred to as SCOPT, for high-speed communication systems with enhanced energy efficiency (EE). In contrast to conventional approaches, the proposed method increases the minimum Euclidean distance (MED) between signals by increasing the normalized signal duration, without relying on coding or increasing transmit power. Analytical expressions for the demodulation error probability and the energy loss relative to the Shannon limit are derived. It is shown that, unlike classical Shannon-type constellations (SCSH), SCOPT enable reliable communication regimes in which the required signal-to-noise ratio may fall below the conventional Shannon limit within the adopted geometric framework. The proposed constellations retain a simple structure compatible with standard modulation schemes such as QAM and APSK,making them suitable for practical implementation in modern communication systems. Numerical analysis demonstrates that SCOPT significantly outperform SCSH in terms of energy efficiency while requiring substantially shorter signal duration.