PAPR reduction of space-time and space-frequency coded OFDM systems using active constellation extension

TL;DR

This paper extends Active Constellation Extension (ACE) techniques to space-time and space-frequency coded OFDM systems, effectively reducing PAPR across all antennas while maintaining spatial encoding, with two proposed methods for SFBC.

Contribution

The paper introduces novel ACE-based PAPR reduction methods tailored for spatially encoded OFDM systems, including modifications for SFBC to improve performance with multiple antennas.

Findings

Both algorithms converge effectively.

The second method outperforms the first as the number of antennas increases.

PAPR is reduced simultaneously at all antennas without disrupting spatial encoding.

Abstract

Active Constellation Extension (ACE) is one of techniques introduced for Peak to Average Power Ratio (PAPR) reduction for OFDM systems. In this technique, the constellation points are extended such that the PAPR is minimized but the minimum distance of the constellation points does not decrease. In this paper, an iterative ACE method is extended to spatially encoded OFDM systems. The proposed methods are such that the PAPR is reduced simultaneously at all antennas, while the spatial encoding relationships still hold. It will be shown that the original ACE method can be employed before Space Time Block Coding (STBC). But in case of Space Frequency Block Coding (SFBC), two modified techniques have been proposed. In the first method, the OFDM frame is separated by several subframes and the ACE method is applied to these subframes independently to reduce their corresponding PAPRs. Then the low PAPR subframes are recombined based on SFBC relationships to yield the transmitted signals from different antennas. In the second method, for each iteration, the ACE is applied to the antenna with the maximum PAPR, and the signals of the other antennas are generated from that of this antenna. Simulation results show that both algorithms converge, but the second method outperforms the first one when the number of antennas is increased.