rloess Search Results


smooth function with span of 0.01 and method of rloess  (MathWorks Inc)
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robust loess fitting  (MathWorks Inc)
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Robust Loess Fitting, 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
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rloess function within matlab's curve fitting toolbox  (MathWorks Inc)
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Rloess, 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
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rloess function  (MathWorks Inc)
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Q 10 as a function of frequency for nine chinchillas, the probe frequency ranges from 1 to 12 kHz. The (blue) filled dots connected with dashed lines are the calculated mean values. The error bars indicate the standard errors of the mean; they are omitted for single measured data points. The red line is calculated with a <t>RLOESS</t> <t>function</t> <t>(MATLAB).</t>
Rloess Function, 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/rloess function/product/MathWorks Inc
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weighted linear least-squares robust regression method rloess  (MathWorks Inc)
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Q 10 as a function of frequency for nine chinchillas, the probe frequency ranges from 1 to 12 kHz. The (blue) filled dots connected with dashed lines are the calculated mean values. The error bars indicate the standard errors of the mean; they are omitted for single measured data points. The red line is calculated with a <t>RLOESS</t> <t>function</t> <t>(MATLAB).</t>
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rloess function within matlab s curve fitting toolbox  (MathWorks Inc)
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MathWorks Inc rloess function within matlab s curve fitting toolbox
Q 10 as a function of frequency for nine chinchillas, the probe frequency ranges from 1 to 12 kHz. The (blue) filled dots connected with dashed lines are the calculated mean values. The error bars indicate the standard errors of the mean; they are omitted for single measured data points. The red line is calculated with a <t>RLOESS</t> <t>function</t> <t>(MATLAB).</t>
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smooth.m rloess algorithm  (MathWorks Inc)
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MathWorks Inc smooth.m rloess algorithm
Q 10 as a function of frequency for nine chinchillas, the probe frequency ranges from 1 to 12 kHz. The (blue) filled dots connected with dashed lines are the calculated mean values. The error bars indicate the standard errors of the mean; they are omitted for single measured data points. The red line is calculated with a <t>RLOESS</t> <t>function</t> <t>(MATLAB).</t>
Smooth.M Rloess 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
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rloess curve fitting  (MathWorks Inc)
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MathWorks Inc rloess curve fitting
Anterior–posterior effect gradient. The figure shows an <t>rLOESS</t> curve fit (red) for mean t‐values at each integer MNI y‐coordinate. The distribution of mean t‐values after testing for longitudinal changes in MD suggests an increasing gradient from posterior to anterior segments. All WM‐skeleton t‐values were first extracted from the raw statistical t‐map output testing for MD increases over time across all participants. T‐values at each y‐coordinate were averaged and analyzed using rLOESS curve fitting <t>in</t> <t>Matlab.</t> A sagittal section of the MNI‐template T1‐brain is used as background and aligned so that the anatomy corresponds to the respective MNI y‐coordinates on the x‐axis of the diagram. Note that neither the y‐axis nor the x‐axis of the diagram starts at the conventional 0 levels.
Rloess Curve Fitting, 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
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Image Search Results


Q 10 as a function of frequency for nine chinchillas, the probe frequency ranges from 1 to 12 kHz. The (blue) filled dots connected with dashed lines are the calculated mean values. The error bars indicate the standard errors of the mean; they are omitted for single measured data points. The red line is calculated with a RLOESS function (MATLAB).

Journal: JARO: Journal of the Association for Research in Otolaryngology

Article Title: Auditory Nerve Frequency Tuning Measured with Forward-Masked Compound Action Potentials

doi: 10.1007/s10162-012-0346-z

Figure Lengend Snippet: Q 10 as a function of frequency for nine chinchillas, the probe frequency ranges from 1 to 12 kHz. The (blue) filled dots connected with dashed lines are the calculated mean values. The error bars indicate the standard errors of the mean; they are omitted for single measured data points. The red line is calculated with a RLOESS function (MATLAB).

Article Snippet: The red line is calculated with a RLOESS function (MATLAB).

Techniques:

Comparison between directly obtained Q factors (Fig. 8) and Q factors from an estimated ROEX filter function using a power spectrum model for masking. A Q 10 and B Q ERB. Q values for three cats are plotted against probe frequencies ranging from 0.5 to 14 kHz. The blue symbols indicate Q values from CAP; the red symbols are extracted from the fitted ROEX filter function. The lines are trend lines calculated with a RLOESS function available in MATLAB. The black line in A is the relationship between the sharpness of the two trend lines (ROEX-Q 10/direct-Q 10).

Journal: JARO: Journal of the Association for Research in Otolaryngology

Article Title: Auditory Nerve Frequency Tuning Measured with Forward-Masked Compound Action Potentials

doi: 10.1007/s10162-012-0346-z

Figure Lengend Snippet: Comparison between directly obtained Q factors (Fig. 8) and Q factors from an estimated ROEX filter function using a power spectrum model for masking. A Q 10 and B Q ERB. Q values for three cats are plotted against probe frequencies ranging from 0.5 to 14 kHz. The blue symbols indicate Q values from CAP; the red symbols are extracted from the fitted ROEX filter function. The lines are trend lines calculated with a RLOESS function available in MATLAB. The black line in A is the relationship between the sharpness of the two trend lines (ROEX-Q 10/direct-Q 10).

Article Snippet: The red line is calculated with a RLOESS function (MATLAB).

Techniques: Comparison

Dependence of Q factors on probe frequency in cats. A Q 10 values for four cats are plotted against probe frequencies ranging from 0.5 to 14 kHz. The blue-filled dots connected with dashed lines are the mean values. The error bars indicate the standard errors of the mean; they are omitted for single data points. The red line is a trend line calculated with a RLOESS function (MATLAB). B Same as A, but for Q ERB for three cats.

Journal: JARO: Journal of the Association for Research in Otolaryngology

Article Title: Auditory Nerve Frequency Tuning Measured with Forward-Masked Compound Action Potentials

doi: 10.1007/s10162-012-0346-z

Figure Lengend Snippet: Dependence of Q factors on probe frequency in cats. A Q 10 values for four cats are plotted against probe frequencies ranging from 0.5 to 14 kHz. The blue-filled dots connected with dashed lines are the mean values. The error bars indicate the standard errors of the mean; they are omitted for single data points. The red line is a trend line calculated with a RLOESS function (MATLAB). B Same as A, but for Q ERB for three cats.

Article Snippet: The red line is calculated with a RLOESS function (MATLAB).

Techniques:

Comparison between left/right single-sided and (symmetrical) double-sided noise masker MTCs. The measured probe frequencies are: A 5 kHz (L p = 35 dB), B 8 kHz (L p = 30 dB), C 4 kHz (L p = 50 dB), and D 8 kHz (L p = 40 dB). The trend lines are obtained with RLOESS and spline smoothing (MATLAB); the dashed blue line and blue circles denote the standard double-sided condition, the red line and left triangles denote the left single-sided masker condition, and the green line and right triangles denote the right single-sided masker condition. The masker reference levels are: A asym L = 31 dB, asym R = 32 dB, sym = 28 dB; B asym L = 26 dB, asym R = 28 dB, sym = 23 dB; C: asym L = 30 dB, asym R = 37 dB, sym = 30 dB; D asym L = 26 dB, asym R = 40 dB, sym = 31 dB.

Journal: JARO: Journal of the Association for Research in Otolaryngology

Article Title: Auditory Nerve Frequency Tuning Measured with Forward-Masked Compound Action Potentials

doi: 10.1007/s10162-012-0346-z

Figure Lengend Snippet: Comparison between left/right single-sided and (symmetrical) double-sided noise masker MTCs. The measured probe frequencies are: A 5 kHz (L p = 35 dB), B 8 kHz (L p = 30 dB), C 4 kHz (L p = 50 dB), and D 8 kHz (L p = 40 dB). The trend lines are obtained with RLOESS and spline smoothing (MATLAB); the dashed blue line and blue circles denote the standard double-sided condition, the red line and left triangles denote the left single-sided masker condition, and the green line and right triangles denote the right single-sided masker condition. The masker reference levels are: A asym L = 31 dB, asym R = 32 dB, sym = 28 dB; B asym L = 26 dB, asym R = 28 dB, sym = 23 dB; C: asym L = 30 dB, asym R = 37 dB, sym = 30 dB; D asym L = 26 dB, asym R = 40 dB, sym = 31 dB.

Article Snippet: The red line is calculated with a RLOESS function (MATLAB).

Techniques: Comparison

Anterior–posterior effect gradient. The figure shows an rLOESS curve fit (red) for mean t‐values at each integer MNI y‐coordinate. The distribution of mean t‐values after testing for longitudinal changes in MD suggests an increasing gradient from posterior to anterior segments. All WM‐skeleton t‐values were first extracted from the raw statistical t‐map output testing for MD increases over time across all participants. T‐values at each y‐coordinate were averaged and analyzed using rLOESS curve fitting in Matlab. A sagittal section of the MNI‐template T1‐brain is used as background and aligned so that the anatomy corresponds to the respective MNI y‐coordinates on the x‐axis of the diagram. Note that neither the y‐axis nor the x‐axis of the diagram starts at the conventional 0 levels.

Journal: Human Brain Mapping

Article Title: Memory training impacts short‐term changes in aging white matter: A Longitudinal Diffusion Tensor Imaging Study

doi: 10.1002/hbm.21370

Figure Lengend Snippet: Anterior–posterior effect gradient. The figure shows an rLOESS curve fit (red) for mean t‐values at each integer MNI y‐coordinate. The distribution of mean t‐values after testing for longitudinal changes in MD suggests an increasing gradient from posterior to anterior segments. All WM‐skeleton t‐values were first extracted from the raw statistical t‐map output testing for MD increases over time across all participants. T‐values at each y‐coordinate were averaged and analyzed using rLOESS curve fitting in Matlab. A sagittal section of the MNI‐template T1‐brain is used as background and aligned so that the anatomy corresponds to the respective MNI y‐coordinates on the x‐axis of the diagram. Note that neither the y‐axis nor the x‐axis of the diagram starts at the conventional 0 levels.

Article Snippet: T ‐values at each y ‐coordinate were averaged and analyzed using rLOESS curve fitting in Matlab.

Techniques: