Review



application of specparam  (MathWorks Inc)


Bioz Verified Symbol MathWorks Inc is a verified supplier  
  • Logo
  • About
  • News
  • Press Release
  • Team
  • Advisors
  • Partners
  • Contact
  • Bioz Stars
  • Bioz vStars
    • 90
      Buy from Supplier

    Structured Review

    MathWorks Inc application of specparam
    Application Of Specparam, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/application of specparam/product/MathWorks Inc
    Average 90 stars, based on 1 article reviews
    application of specparam - by Bioz Stars, 2026-03
    90/100 stars

    Images



    Similar Products

    application of specparam  (MathWorks Inc)
    90
    MathWorks Inc application of specparam
    Application Of Specparam, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/application of specparam/product/MathWorks Inc
    Average 90 stars, based on 1 article reviews
    application of specparam - by Bioz Stars, 2026-03
    90/100 stars
    		  Buy from Supplier
    specparam algorithm  (MathWorks Inc)
    90
    MathWorks Inc specparam algorithm
    Specparam Algorithm, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/specparam algorithm/product/MathWorks Inc
    Average 90 stars, based on 1 article reviews
    specparam algorithm - by Bioz Stars, 2026-03
    90/100 stars
    		  Buy from Supplier
    specparam  (MathWorks Inc)
    90
    MathWorks Inc specparam
    Specparam, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/specparam/product/MathWorks Inc
    Average 90 stars, based on 1 article reviews
    specparam - by Bioz Stars, 2026-03
    90/100 stars
    		  Buy from Supplier
    spectral parameterization (specparam) toolbox  (MathWorks Inc)
    90
    MathWorks Inc spectral parameterization (specparam) toolbox
    Spectral Parameterization (Specparam) Toolbox, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/spectral parameterization (specparam) toolbox/product/MathWorks Inc
    Average 90 stars, based on 1 article reviews
    spectral parameterization (specparam) toolbox - by Bioz Stars, 2026-03
    90/100 stars
    		  Buy from Supplier
    specparam brainstorm matlab version  (MathWorks Inc)
    90
    MathWorks Inc specparam brainstorm matlab version
    Specparam Brainstorm Matlab Version, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/specparam brainstorm matlab version/product/MathWorks Inc
    Average 90 stars, based on 1 article reviews
    specparam brainstorm matlab version - by Bioz Stars, 2026-03
    90/100 stars
    		  Buy from Supplier
    specparam ( ;  (MathWorks Inc)
    90
    MathWorks Inc specparam ( ;
    ( a ) Overview of the Spectral Parameterization Resolved in Time (SPRiNT) approach: At each time bin along a neurophysiological time series (black trace) n overlapping time windows are Fourier-transformed to yield an estimate of spectral contents, which is subsequently parameterized using <t>specparam</t> . The procedure is replicated across time over sliding, overlapping windows to generate a parameterized spectrogram of neural activity. ( b ) Simulation challenge I: We simulated 10,000 time series composed of the same time-varying spectral (aperiodic and periodic) features, with different realizations of additive noise. ( c ) Simulation challenge II: We simulated another 10,000 time series, each composed of different time-varying spectral (aperiodic and periodic) ground-truth features with additive noise. All simulated time series were used to evaluate the respective performances of SPRiNT and the wavelet- specparam alternative.
    Specparam ( ;, supplied by MathWorks Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/specparam ( ;/product/MathWorks Inc
    Average 90 stars, based on 1 article reviews
    specparam ( ; - by Bioz Stars, 2026-03
    90/100 stars
    		  Buy from Supplier
    specparam  (RStudio)
    90
    RStudio specparam
    Brief overview of key settings for the <t> specparam </t> algorithm.
    Specparam, supplied by RStudio, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/specparam/product/RStudio
    Average 90 stars, based on 1 article reviews
    specparam - by Bioz Stars, 2026-03
    90/100 stars
    		  Buy from Supplier

    Image Search Results


    ( a ) Overview of the Spectral Parameterization Resolved in Time (SPRiNT) approach: At each time bin along a neurophysiological time series (black trace) n overlapping time windows are Fourier-transformed to yield an estimate of spectral contents, which is subsequently parameterized using specparam . The procedure is replicated across time over sliding, overlapping windows to generate a parameterized spectrogram of neural activity. ( b ) Simulation challenge I: We simulated 10,000 time series composed of the same time-varying spectral (aperiodic and periodic) features, with different realizations of additive noise. ( c ) Simulation challenge II: We simulated another 10,000 time series, each composed of different time-varying spectral (aperiodic and periodic) ground-truth features with additive noise. All simulated time series were used to evaluate the respective performances of SPRiNT and the wavelet- specparam alternative.

    Journal: eLife

    Article Title: Time-resolved parameterization of aperiodic and periodic brain activity

    doi: 10.7554/eLife.77348

    Figure Lengend Snippet: ( a ) Overview of the Spectral Parameterization Resolved in Time (SPRiNT) approach: At each time bin along a neurophysiological time series (black trace) n overlapping time windows are Fourier-transformed to yield an estimate of spectral contents, which is subsequently parameterized using specparam . The procedure is replicated across time over sliding, overlapping windows to generate a parameterized spectrogram of neural activity. ( b ) Simulation challenge I: We simulated 10,000 time series composed of the same time-varying spectral (aperiodic and periodic) features, with different realizations of additive noise. ( c ) Simulation challenge II: We simulated another 10,000 time series, each composed of different time-varying spectral (aperiodic and periodic) ground-truth features with additive noise. All simulated time series were used to evaluate the respective performances of SPRiNT and the wavelet- specparam alternative.

    Article Snippet: We also parameterized Morlet wavelet spectrograms of each simulated time series using specparam ( ; MATLAB version).

    Techniques: Transformation Assay, Activity Assay

    ( a ) Ground-truth spectrogram (left) and averaged modelled spectrograms produced by the wavelet- specparam approach (middle) and SPRiNT (right; n=10,000). ( b ) Aperiodic parameter estimates (lines: median; shaded regions: first and third quartiles, n=10,000) across time from wavelet- specparam (left) and SPRiNT (right; black: ground truth; blue: exponent; yellow: offset). ( c ) Absolute error (and detection performance) of alpha and beta-band rhythmic components for wavelet- specparam (left) and SPRiNT (right). Violin plots represent the sample distributions (n=10,000; blue: alpha peak; yellow: beta peak; white circle: median, grey box: first and third quartiles; whiskers: range).

    Journal: eLife

    Article Title: Time-resolved parameterization of aperiodic and periodic brain activity

    doi: 10.7554/eLife.77348

    Figure Lengend Snippet: ( a ) Ground-truth spectrogram (left) and averaged modelled spectrograms produced by the wavelet- specparam approach (middle) and SPRiNT (right; n=10,000). ( b ) Aperiodic parameter estimates (lines: median; shaded regions: first and third quartiles, n=10,000) across time from wavelet- specparam (left) and SPRiNT (right; black: ground truth; blue: exponent; yellow: offset). ( c ) Absolute error (and detection performance) of alpha and beta-band rhythmic components for wavelet- specparam (left) and SPRiNT (right). Violin plots represent the sample distributions (n=10,000; blue: alpha peak; yellow: beta peak; white circle: median, grey box: first and third quartiles; whiskers: range).

    Article Snippet: We also parameterized Morlet wavelet spectrograms of each simulated time series using specparam ( ; MATLAB version).

    Techniques: Produced

    ( a ) Results from the temporally smoothed wavelet -specparam approach for the alpha (top) and beta (bottom) rhythmic components for each estimated parameter (from left to right: centre frequency, spectral peak amplitude, and SD). Grey dashed line: ground truth; coloured line: median; shaded region: first and third quartiles. Bar plots in left panels: probability of detecting an oscillatory peak within respective frequency ranges at each time bin. ( b ) Same display for the results obtained with Spectral Parameterization Resolved in Time (SPRiNT). All with n=10,000 simulations.

    Journal: eLife

    Article Title: Time-resolved parameterization of aperiodic and periodic brain activity

    doi: 10.7554/eLife.77348

    Figure Lengend Snippet: ( a ) Results from the temporally smoothed wavelet -specparam approach for the alpha (top) and beta (bottom) rhythmic components for each estimated parameter (from left to right: centre frequency, spectral peak amplitude, and SD). Grey dashed line: ground truth; coloured line: median; shaded region: first and third quartiles. Bar plots in left panels: probability of detecting an oscillatory peak within respective frequency ranges at each time bin. ( b ) Same display for the results obtained with Spectral Parameterization Resolved in Time (SPRiNT). All with n=10,000 simulations.

    Article Snippet: We also parameterized Morlet wavelet spectrograms of each simulated time series using specparam ( ; MATLAB version).

    Techniques:

    ( a ) Aperiodic parameter estimates (lines: median; shaded regions: first and third quartiles, n=1000) across time from wavelet -specparam with full width at half maximum (FWHM) = 2 s (left) and wavelet- specparam with FWHM = 4 s (right; black dash: ground truth; blue: exponent; yellow: offset). ( b ) Absolute error (and detection performance) of alpha and beta-band rhythmic components for wavelet -specparam with FWHM = 2 s (left) and wavelet- specparam with FWHM = 4 s (right). Violin plots represent the sample distributions (n=1000; blue: alpha peak; yellow: beta peak; white circle: median, grey box: first and third quartiles; whiskers: range).

    Journal: eLife

    Article Title: Time-resolved parameterization of aperiodic and periodic brain activity

    doi: 10.7554/eLife.77348

    Figure Lengend Snippet: ( a ) Aperiodic parameter estimates (lines: median; shaded regions: first and third quartiles, n=1000) across time from wavelet -specparam with full width at half maximum (FWHM) = 2 s (left) and wavelet- specparam with FWHM = 4 s (right; black dash: ground truth; blue: exponent; yellow: offset). ( b ) Absolute error (and detection performance) of alpha and beta-band rhythmic components for wavelet -specparam with FWHM = 2 s (left) and wavelet- specparam with FWHM = 4 s (right). Violin plots represent the sample distributions (n=1000; blue: alpha peak; yellow: beta peak; white circle: median, grey box: first and third quartiles; whiskers: range).

    Article Snippet: We also parameterized Morlet wavelet spectrograms of each simulated time series using specparam ( ; MATLAB version).

    Techniques:

    ( a ) Aperiodic parameter estimates (lines: median; shaded regions: first and third quartiles, n=1000) across time from unsmoothed wavelet- specparam (left) and SPRiNT without outlier peak removal (right; black dash: ground truth; blue: exponent; yellow: offset). ( b ) Absolute error (and detection performance) of alpha and beta-band periodic components for unsmoothed wavelet- specparam (left) and SPRiNT without outlier peak removal (right). Violin plots represent the sample distributions (n=1000; blue: alpha peak; yellow: beta peak; white circle: median, grey box: first and third quartiles; whiskers: range).

    Journal: eLife

    Article Title: Time-resolved parameterization of aperiodic and periodic brain activity

    doi: 10.7554/eLife.77348

    Figure Lengend Snippet: ( a ) Aperiodic parameter estimates (lines: median; shaded regions: first and third quartiles, n=1000) across time from unsmoothed wavelet- specparam (left) and SPRiNT without outlier peak removal (right; black dash: ground truth; blue: exponent; yellow: offset). ( b ) Absolute error (and detection performance) of alpha and beta-band periodic components for unsmoothed wavelet- specparam (left) and SPRiNT without outlier peak removal (right). Violin plots represent the sample distributions (n=1000; blue: alpha peak; yellow: beta peak; white circle: median, grey box: first and third quartiles; whiskers: range).

    Article Snippet: We also parameterized Morlet wavelet spectrograms of each simulated time series using specparam ( ; MATLAB version).

    Techniques:

    ( a ) Mean periodogram and specparam models for eyes-closed (blue) and eyes-open (yellow) resting-state EEG activity (from electrode Oz; n=178). ( b ) Logistic regressions showed that specparam -derived eyes-closed alpha-peak amplitude was predictive of age group, but mean eyes-closed alpha-peak amplitude derived from SPRiNT was not. ( c ) Example of intrinsic dynamics in alpha activity during the eyes-closed period leading to divergent SPRiNT and specparam models (participant sub-016). In a subset of participants (<10%), we observed strong intermittence of the presence of an alpha peak. Since an alpha peak was not consistently present in the eyes-closed condition, and specparam -derived alpha-peak amplitude (0.77 a.u.; light blue) is lower than SPRiNT-derived mean alpha-peak amplitude (1.06 a.u.; dark blue), as the latter only includes time samples featuring a detected alpha peak. ( d ) Logistic regression showed that temporal variability in eyes-open alpha centre frequency predicts age group. Left: mean SPRiNT spectrogram (n=178) and sample distribution of eyes-open alpha centre frequency (participant sub-067). Right: variability (SD) in eyes-open alpha centre frequency separated by age group. Note: no alpha peaks were detected in the eyes-open period for one participant (boxplot line: median; boxplot limits: first and third quartiles; whiskers: range). Sample sizes: younger adults (age: 20–40 years): 121; older adults (age: 55–80 years): 56. Figure 4—source data 1. Spectral parameters and age group by participant.

    Journal: eLife

    Article Title: Time-resolved parameterization of aperiodic and periodic brain activity

    doi: 10.7554/eLife.77348

    Figure Lengend Snippet: ( a ) Mean periodogram and specparam models for eyes-closed (blue) and eyes-open (yellow) resting-state EEG activity (from electrode Oz; n=178). ( b ) Logistic regressions showed that specparam -derived eyes-closed alpha-peak amplitude was predictive of age group, but mean eyes-closed alpha-peak amplitude derived from SPRiNT was not. ( c ) Example of intrinsic dynamics in alpha activity during the eyes-closed period leading to divergent SPRiNT and specparam models (participant sub-016). In a subset of participants (<10%), we observed strong intermittence of the presence of an alpha peak. Since an alpha peak was not consistently present in the eyes-closed condition, and specparam -derived alpha-peak amplitude (0.77 a.u.; light blue) is lower than SPRiNT-derived mean alpha-peak amplitude (1.06 a.u.; dark blue), as the latter only includes time samples featuring a detected alpha peak. ( d ) Logistic regression showed that temporal variability in eyes-open alpha centre frequency predicts age group. Left: mean SPRiNT spectrogram (n=178) and sample distribution of eyes-open alpha centre frequency (participant sub-067). Right: variability (SD) in eyes-open alpha centre frequency separated by age group. Note: no alpha peaks were detected in the eyes-open period for one participant (boxplot line: median; boxplot limits: first and third quartiles; whiskers: range). Sample sizes: younger adults (age: 20–40 years): 121; older adults (age: 55–80 years): 56. Figure 4—source data 1. Spectral parameters and age group by participant.

    Article Snippet: We also parameterized Morlet wavelet spectrograms of each simulated time series using specparam ( ; MATLAB version).

    Techniques: Activity Assay, Derivative Assay

    Logistic regression model of specparam parameters for predicting condition (eyes-closed vs eyes-open).

    Journal: eLife

    Article Title: Time-resolved parameterization of aperiodic and periodic brain activity

    doi: 10.7554/eLife.77348

    Figure Lengend Snippet: Logistic regression model of specparam parameters for predicting condition (eyes-closed vs eyes-open).

    Article Snippet: We also parameterized Morlet wavelet spectrograms of each simulated time series using specparam ( ; MATLAB version).

    Techniques:

    Eyes-open logistic regression model parameters for predicting age group, specparam .

    Journal: eLife

    Article Title: Time-resolved parameterization of aperiodic and periodic brain activity

    doi: 10.7554/eLife.77348

    Figure Lengend Snippet: Eyes-open logistic regression model parameters for predicting age group, specparam .

    Article Snippet: We also parameterized Morlet wavelet spectrograms of each simulated time series using specparam ( ; MATLAB version).

    Techniques:

    Eyes-closed logistic regression model parameters for predicting age group, specparam .

    Journal: eLife

    Article Title: Time-resolved parameterization of aperiodic and periodic brain activity

    doi: 10.7554/eLife.77348

    Figure Lengend Snippet: Eyes-closed logistic regression model parameters for predicting age group, specparam .

    Article Snippet: We also parameterized Morlet wavelet spectrograms of each simulated time series using specparam ( ; MATLAB version).

    Techniques:

    Brief overview of key settings for the specparam algorithm.

    Journal: Developmental Cognitive Neuroscience

    Article Title: Spectral parameterization for studying neurodevelopment: How and why

    doi: 10.1016/j.dcn.2022.101073

    Figure Lengend Snippet: Brief overview of key settings for the specparam algorithm.

    Article Snippet: Abbreviated version of the 03-R_groupPSDs.Rmd script that parameterizes multiple power spectra using specparam in R Studio.

    Techniques:

    Abbreviated version of the 01-IndividualPSD.ipynb script for parameterizing individual power spectrum using specparam in Jupyter Notebook ( A ). See the GitHub repository for full annotated script. Results of the specparam fitting of EEG data from a single child, recorded during an eyes-closed resting state, is presented in B . CF = center frequency of identified peak. PW = power of identified peak above the aperiodic signal. BW = band width of identified peak.

    Journal: Developmental Cognitive Neuroscience

    Article Title: Spectral parameterization for studying neurodevelopment: How and why

    doi: 10.1016/j.dcn.2022.101073

    Figure Lengend Snippet: Abbreviated version of the 01-IndividualPSD.ipynb script for parameterizing individual power spectrum using specparam in Jupyter Notebook ( A ). See the GitHub repository for full annotated script. Results of the specparam fitting of EEG data from a single child, recorded during an eyes-closed resting state, is presented in B . CF = center frequency of identified peak. PW = power of identified peak above the aperiodic signal. BW = band width of identified peak.

    Article Snippet: Abbreviated version of the 03-R_groupPSDs.Rmd script that parameterizes multiple power spectra using specparam in R Studio.

    Techniques:

    Abbreviated version of the 03-R_groupPSDs.Rmd script that parameterizes multiple power spectra using specparam in R Studio. See the GitHub repository for full annotated script.

    Journal: Developmental Cognitive Neuroscience

    Article Title: Spectral parameterization for studying neurodevelopment: How and why

    doi: 10.1016/j.dcn.2022.101073

    Figure Lengend Snippet: Abbreviated version of the 03-R_groupPSDs.Rmd script that parameterizes multiple power spectra using specparam in R Studio. See the GitHub repository for full annotated script.

    Article Snippet: Abbreviated version of the 03-R_groupPSDs.Rmd script that parameterizes multiple power spectra using specparam in R Studio.

    Techniques:

    Histograms for variance explained (R^2) and mean absolute error (MAE) for the full sample, recorded during an eyes-open resting state ( A ). Mean error per frequency, as well as standard deviation in error per frequency (blue shading), are presented in B . In this condition, the 3 Hz bin had the highest mean error and largest standard deviation in error, suggesting possible misfit at the lower end of the examined frequency range. Further consideration about specparam settings may be needed. C and D depict two fit models that were flagged as potentially being overfit (MAE < 0.025) and underfit (MAE > 0.100), respectively. (For interpretation of the references to color in this figure legend, the reader is referred to the web version of this article.)

    Journal: Developmental Cognitive Neuroscience

    Article Title: Spectral parameterization for studying neurodevelopment: How and why

    doi: 10.1016/j.dcn.2022.101073

    Figure Lengend Snippet: Histograms for variance explained (R^2) and mean absolute error (MAE) for the full sample, recorded during an eyes-open resting state ( A ). Mean error per frequency, as well as standard deviation in error per frequency (blue shading), are presented in B . In this condition, the 3 Hz bin had the highest mean error and largest standard deviation in error, suggesting possible misfit at the lower end of the examined frequency range. Further consideration about specparam settings may be needed. C and D depict two fit models that were flagged as potentially being overfit (MAE < 0.025) and underfit (MAE > 0.100), respectively. (For interpretation of the references to color in this figure legend, the reader is referred to the web version of this article.)

    Article Snippet: Abbreviated version of the 03-R_groupPSDs.Rmd script that parameterizes multiple power spectra using specparam in R Studio.

    Techniques: Standard Deviation