Wave analysis tools

Shahin Jafarzadeh; David Jess; Marco Stangalini; Samuel Grant; J. Higham; Martin Pessah; Peter Keys; Sergey Belov; Daniele Calchetti; Timothy Duckenfield; Viktor Fedun; Bernhard Fleck; Ricardo Gafeira; Stuart Jefferies; Elena Khomenko; R.J. Morton; Aimee Norton; Paul Rajaguru; L. A. C. A. Schiavo; Rahul Sharma; Suzana Silva; Sami K. Solanki; Oskar Steiner; Gary Verth; G.  Vigeesh; Nitin Yadav

doi:10.1038/s43586-025-00392-0

Wave analysis tools

Shahin Jafarzadeh^*, David Jess, Marco Stangalini, Samuel Grant, J. Higham, Martin Pessah, Peter Keys, Sergey Belov, Daniele Calchetti, Timothy Duckenfield, Viktor Fedun, Bernhard Fleck, Ricardo Gafeira, Stuart Jefferies, Elena Khomenko, R.J. Morton, Aimee Norton, Paul Rajaguru, L. A. C. A. Schiavo, Rahul SharmaSuzana Silva, Sami K. Solanki, Oskar Steiner, Gary Verth, G. Vigeesh, Nitin Yadav

^*Corresponding author for this work

Research output: Contribution to journal › Review article › peer-review

Abstract

This Primer provides an overview of a fundamental set of analysis methods for studying waves, vibrations, and related oscillatory phenomena - including instabilities, turbulence, and shocks - across diverse scientific fields. These phenomena are ubiquitous, from astrophysics to complex systems in terrestrial environments, and understanding them requires careful selection of techniques. Misapplication of analysis tools can introduce misleading results. In this Primer the fundamental principles of various wave analysis methods are first reviewed, along with adaptations to address complexities such as non-linear, non-stationary, and transient signal behaviour. These techniques are applied to identical synthetic datasets to provide a quantitative comparison of their strengths and limitations. Details are provided to help select the most appropriate analysis tools based on specific data characteristics and scientific goals, promoting reliable interpretations and ensuring reproducibility. Additionally, the Primer highlights best ethical practices for data deposition and the importance of open-code sharing. Finally, the broad applications of these techniques are explored in various research fields, current challenges in wave analysis are discussed and an outlook on future directions is provided, with an emphasis on potential transformative discoveries that could be made by optimising and developing cutting-edge analysis methods.

Original language	English
Article number	21
Journal	Nature Reviews Methods Primers
Volume	5
DOIs	https://doi.org/10.1038/s43586-025-00392-0
Publication status	Published - 03 Apr 2025

Keywords

Wave analysis
oscillatory phenomena

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Jafarzadeh, S., Jess, D., Stangalini, M., Grant, S., Higham, J., Pessah, M., Keys, P., Belov, S., Calchetti, D., Duckenfield, T., Fedun, V., Fleck, B., Gafeira, R., Jefferies, S., Khomenko, E., Morton, R. J., Norton, A., Rajaguru, P., Schiavo, L. A. C. A., ... Yadav, N. (2025). Wave analysis tools. Nature Reviews Methods Primers, 5, Article 21. https://doi.org/10.1038/s43586-025-00392-0

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title = "Wave analysis tools",

abstract = "This Primer provides an overview of a fundamental set of analysis methods for studying waves, vibrations, and related oscillatory phenomena - including instabilities, turbulence, and shocks - across diverse scientific fields. These phenomena are ubiquitous, from astrophysics to complex systems in terrestrial environments, and understanding them requires careful selection of techniques. Misapplication of analysis tools can introduce misleading results. In this Primer the fundamental principles of various wave analysis methods are first reviewed, along with adaptations to address complexities such as non-linear, non-stationary, and transient signal behaviour. These techniques are applied to identical synthetic datasets to provide a quantitative comparison of their strengths and limitations. Details are provided to help select the most appropriate analysis tools based on specific data characteristics and scientific goals, promoting reliable interpretations and ensuring reproducibility. Additionally, the Primer highlights best ethical practices for data deposition and the importance of open-code sharing. Finally, the broad applications of these techniques are explored in various research fields, current challenges in wave analysis are discussed and an outlook on future directions is provided, with an emphasis on potential transformative discoveries that could be made by optimising and developing cutting-edge analysis methods.",

keywords = "Wave analysis, oscillatory phenomena",

author = "Shahin Jafarzadeh and David Jess and Marco Stangalini and Samuel Grant and J. Higham and Martin Pessah and Peter Keys and Sergey Belov and Daniele Calchetti and Timothy Duckenfield and Viktor Fedun and Bernhard Fleck and Ricardo Gafeira and Stuart Jefferies and Elena Khomenko and R.J. Morton and Aimee Norton and Paul Rajaguru and Schiavo, {L. A. C. A.} and Rahul Sharma and Suzana Silva and Solanki, {Sami K.} and Oskar Steiner and Gary Verth and G. Vigeesh and Nitin Yadav",

year = "2025",

month = apr,

day = "3",

doi = "10.1038/s43586-025-00392-0",

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Jafarzadeh, S , Jess, D, Stangalini, M, Grant, S, Higham, J, Pessah, M, Keys, P, Belov, S, Calchetti, D, Duckenfield, T, Fedun, V, Fleck, B, Gafeira, R, Jefferies, S, Khomenko, E, Morton, RJ, Norton, A, Rajaguru, P, Schiavo, LACA, Sharma, R, Silva, S, Solanki, SK, Steiner, O, Verth, G, Vigeesh, G & Yadav, N 2025, 'Wave analysis tools', Nature Reviews Methods Primers, vol. 5, 21. https://doi.org/10.1038/s43586-025-00392-0

TY - JOUR

T1 - Wave analysis tools

AU - Jafarzadeh, Shahin

AU - Jess, David

AU - Stangalini, Marco

AU - Grant, Samuel

AU - Higham, J.

AU - Pessah, Martin

AU - Keys, Peter

AU - Belov, Sergey

AU - Calchetti, Daniele

AU - Duckenfield, Timothy

AU - Fedun, Viktor

AU - Fleck, Bernhard

AU - Gafeira, Ricardo

AU - Jefferies, Stuart

AU - Khomenko, Elena

AU - Morton, R.J.

AU - Norton, Aimee

AU - Rajaguru, Paul

AU - Schiavo, L. A. C. A.

AU - Sharma, Rahul

AU - Silva, Suzana

AU - Solanki, Sami K.

AU - Steiner, Oskar

AU - Verth, Gary

AU - Vigeesh, G.

AU - Yadav, Nitin

PY - 2025/4/3

Y1 - 2025/4/3

N2 - This Primer provides an overview of a fundamental set of analysis methods for studying waves, vibrations, and related oscillatory phenomena - including instabilities, turbulence, and shocks - across diverse scientific fields. These phenomena are ubiquitous, from astrophysics to complex systems in terrestrial environments, and understanding them requires careful selection of techniques. Misapplication of analysis tools can introduce misleading results. In this Primer the fundamental principles of various wave analysis methods are first reviewed, along with adaptations to address complexities such as non-linear, non-stationary, and transient signal behaviour. These techniques are applied to identical synthetic datasets to provide a quantitative comparison of their strengths and limitations. Details are provided to help select the most appropriate analysis tools based on specific data characteristics and scientific goals, promoting reliable interpretations and ensuring reproducibility. Additionally, the Primer highlights best ethical practices for data deposition and the importance of open-code sharing. Finally, the broad applications of these techniques are explored in various research fields, current challenges in wave analysis are discussed and an outlook on future directions is provided, with an emphasis on potential transformative discoveries that could be made by optimising and developing cutting-edge analysis methods.

AB - This Primer provides an overview of a fundamental set of analysis methods for studying waves, vibrations, and related oscillatory phenomena - including instabilities, turbulence, and shocks - across diverse scientific fields. These phenomena are ubiquitous, from astrophysics to complex systems in terrestrial environments, and understanding them requires careful selection of techniques. Misapplication of analysis tools can introduce misleading results. In this Primer the fundamental principles of various wave analysis methods are first reviewed, along with adaptations to address complexities such as non-linear, non-stationary, and transient signal behaviour. These techniques are applied to identical synthetic datasets to provide a quantitative comparison of their strengths and limitations. Details are provided to help select the most appropriate analysis tools based on specific data characteristics and scientific goals, promoting reliable interpretations and ensuring reproducibility. Additionally, the Primer highlights best ethical practices for data deposition and the importance of open-code sharing. Finally, the broad applications of these techniques are explored in various research fields, current challenges in wave analysis are discussed and an outlook on future directions is provided, with an emphasis on potential transformative discoveries that could be made by optimising and developing cutting-edge analysis methods.

KW - Wave analysis

KW - oscillatory phenomena

UR - http://WaLSA.tools/nrmp

U2 - 10.1038/s43586-025-00392-0

DO - 10.1038/s43586-025-00392-0

M3 - Review article

SN - 2662-8449

VL - 5

JO - Nature Reviews Methods Primers

JF - Nature Reviews Methods Primers

M1 - 21

ER -

Wave analysis tools

Abstract

Keywords

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