An ultra-precise fast fourier transform – part 2

Manus Henry

doi:10.1016/j.measurement.2026.120779

An ultra-precise fast fourier transform – part 2

Manus Henry

Research Centre for Fluid and Complex Systems

University of Oxford

Research output: Contribution to journal › Article › peer-review

Abstract

An earlier paper [1] describes the application of Prism Signal Processing to the Fast Fourier Transform (FFT), which generates high precision estimates of the frequency, amplitude and phase of spectral peaks. The current paper describes improvements to the Prism FFT. These include: a simplified calculation; applicability to shorter FFT window lengths (e.g. 1024 samples); improved performance against the Cramer Rao Lower Bound (CRLB), typically delivering root mean square errors of 2.2σ for frequency and 1.5σ, for amplitude and phase, where σ is defined as the square root of the corresponding CRLB. The method also delivers significantly reduced spectral leakage. MATLAB code implementing the Prism FFT is provided as an appendix.

Original language	English
Article number	120779
Number of pages	29
Journal	Measurement
Volume	270
Early online date	12 Feb 2026
DOIs	https://doi.org/10.1016/j.measurement.2026.120779
Publication status	E-pub ahead of print - 12 Feb 2026

Bibliographical note

This is an open access article under the CC BY license.

Keywords

FFT
Prism signal processing
Spectral analysis
Spectral leakage
Romberg integration

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10.1016/j.measurement.2026.120779Licence: CC BY

1-s2.0-S0263224126004884-mainFinal published version, 36.9 MBLicence: CC BY

Cite this

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title = "An ultra-precise fast fourier transform – part 2",

abstract = "An earlier paper [1] describes the application of Prism Signal Processing to the Fast Fourier Transform (FFT), which generates high precision estimates of the frequency, amplitude and phase of spectral peaks. The current paper describes improvements to the Prism FFT. These include: a simplified calculation; applicability to shorter FFT window lengths (e.g. 1024 samples); improved performance against the Cramer Rao Lower Bound (CRLB), typically delivering root mean square errors of 2.2σ for frequency and 1.5σ, for amplitude and phase, where σ is defined as the square root of the corresponding CRLB. The method also delivers significantly reduced spectral leakage. MATLAB code implementing the Prism FFT is provided as an appendix.",

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KW - Spectral analysis

KW - Spectral leakage

KW - Romberg integration

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ER -

An ultra-precise fast fourier transform – part 2

Abstract

Bibliographical note

Keywords

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