On Performance of Sparse Fast Fourier Transform Algorithms Using the Aliasing Filter

TL;DR

This paper analyzes the performance of sparse FFT algorithms that use aliasing filters, providing theoretical insights and experimental validation across various signal conditions and algorithm frameworks.

Contribution

It introduces a comprehensive theoretical analysis of six aliasing filter-based sFFT algorithms and validates the findings through extensive experiments.

Findings

Theoretical performance bounds for six sFFT algorithms are established.

Experimental results confirm the theoretical predictions across different signal parameters.

Algorithms demonstrate varying efficiency depending on sparsity and noise levels.

Abstract

Computing the Sparse Fast Fourier Transform(sFFT) of a K-sparse signal of size N has emerged as a critical topic for a long time. There are mainly two stages in the sFFT: frequency bucketization and spectrum reconstruction. Frequency bucketization is equivalent to hashing the frequency coefficients into B buckets through one of these filters: Dirichlet kernel filter, flat filter, aliasing filter, etc. The spectrum reconstruction is equivalent to identifying frequencies that are isolated in their buckets. More than forty different sFFT algorithms compute Discrete Fourier Transform(DFT) by their unique methods so far. In order to use them properly, the urgent topic of great concern is how to analyze and evaluate the performance of these algorithms in theory and practice. The paper mainly discusses the sFFT Algorithms using the aliasing filter. In the first part, the paper introduces the technique of three frameworks: the one-shot framework based on the compressed sensing(CS) solver, the peeling framework based on the bipartite graph and the iterative framework based on the binary tree search. Then, we get the conclusion of the performance of six corresponding algorithms: sFFT-DT1.0, sFFT-DT2.0, sFFT-DT3.0, FFAST, R-FFAST and DSFFT algorithm in theory. In the second part, we make two categories of experiments for computing the signals of different SNR, different N, different K by a standard testing platform and record the run time, percentage of the signal sampled and L0, L1, L2 error both in the exactly sparse case and general sparse case. The result of experiments satisfies the inferences obtained in theory.