Efficient FFT Computation in IFDMA Transceivers

TL;DR

This paper introduces a heuristic scheduling algorithm called MPS-FFT that significantly reduces FFT computation time in IFDMA transceivers with limited hardware resources, improving efficiency over conventional FFT methods.

Contribution

It proposes a practical heuristic algorithm for efficient FFT computation in resource-constrained IFDMA transceivers, filling a gap between theoretical design and hardware implementation.

Findings

MPS-FFT achieves near-optimal computation time with limited processors.

MPS-FFT reduces FFT computation time to less than 44.13% of conventional methods.

The approach is effective when the number of processors is a power of two.

Abstract

Interleaved Frequency Division Multiple Access (IFDMA) has the salient advantage of lower Peak-to-Average Power Ratio (PAPR) than its competitors like Orthogonal FDMA (OFDMA). A recent research effort put forth a new IFDMA transceiver design significantly less complex than conventional IFDMA transceivers. The new IFDMA transceiver design reduces the complexity by exploiting a certain correspondence between the IFDMA signal processing and the Cooley-Tukey IFFT/FFT algorithmic structure so that IFDMA streams can be inserted/extracted at different stages of an IFFT/FFT module according to the sizes of the streams. Although the prior work has laid down the theoretical foundation for the new IFDMA transceiver's structure, the practical realization of the transceiver on specific hardware with resource constraints has not been carefully investigated. This paper is an attempt to fill the gap. Specifically, this paper puts forth a heuristic algorithm called multi-priority scheduling (MPS) to schedule the execution of the butterfly computations in the IFDMA transceiver with the constraint of a limited number of hardware processors. The resulting FFT computation, referred to as MPS-FFT, has a much lower computation time than conventional FFT computation when applied to the IFDMA signal processing. Importantly, we derive a lower bound for the optimal IFDMA FFT computation time to benchmark MPS-FFT. Our experimental results indicate that when the number of hardware processors is a power of two: 1) MPS-FFT has near-optimal computation time; 2) MPS-FFT incurs less than 44.13\% of the computation time of the conventional pipelined FFT.