Hi Ryan, Yeah, this could be a little richer. For clarity, the "amplitude" Parameters will be the area of each peak. Well, it's the amplitude factor for the unit-normalized lineshape (Gaussian, Lorentzian, Voigt, etc), so it will be the area under that curve from -Inf to Inf. Those Infinities probably have small effects, here anyway ;). As you say, the centroid of multiple peaks is given, but not the total area under the sum of non-background peaks. That would not be too hard to add. But it might also fall into the category of "the sorts of calculations we should allow the user to do after a fit" without having to bake them all in. That is, if you open a Larch buffer after a pre-edge peak fit, you could get the most recent best-fit Parameters from lmfit with: pars = peakresult.result.params But also, you can get "uvars" as uvars = peakresult.result.uvars which is a dictionary of name:"ufloat" values for all Parameters (variables and "constrained values"). These "ufloat" values come from the `uncertainties` package and include uncertainties that know about the correlations between the Parameters. You can use these for simple calculations that will propagate the uncertainties (including correlations). As an example, if I do a pre-edge peak fit, with 2 Gaussian peaks (plus Line+Lorentzian for the background), I might get a good fit and a resulting report (from the larch buffer, do `print(peakresult.result.fit_report()`) that looks like this: [[Model]] (((Model(lorentzian, prefix='bpeak_') + Model(linear, prefix='bpoly_')) + Model(gaussian, prefix='gauss1_')) + Model(gaussian, prefix='gauss2_')) [[Fit Statistics]] # fitting method = leastsq # function evals = 355 # data points = 162 # variables = 11 chi-square = 4.5237e-04 reduced chi-square = 2.9958e-06 Akaike info crit = -2049.75462 Bayesian info crit = -2015.79106 R-squared = 0.99953048 [[Variables]] bpeak_amplitude: 1.82988250 +/- 0.04372160 (2.39%) (init = 2.462209) bpeak_center: 7118.44625 +/- 0.02812082 (0.00%) (init = 7120.091) bpeak_sigma: 1.36103880 +/- 0.01273292 (0.94%) (init = 2.121656) bpeak_fwhm: 2.72207761 +/- 0.02546583 (0.94%) == '2.0000000*bpeak_sigma' bpeak_height: 0.42795967 +/- 0.00701416 (1.64%) == '0.3183099*bpeak_amplitude/max(1e-15, bpeak_sigma)' bpoly_intercept: -6.37404087 +/- 0.65831626 (10.33%) (init = 2.467005) bpoly_slope: 8.9825e-04 +/- 9.2664e-05 (10.32%) (init = -0.000347) gauss1_amplitude: 0.10390560 +/- 0.00363058 (3.49%) (init = 0.14991) gauss1_center: 7111.52424 +/- 0.02714092 (0.00%) (init = 7112.452) gauss1_sigma: 0.75932812 +/- 0.02151410 (2.83%) (init = 1.315216) gauss1_fwhm: 1.78808103 +/- 0.05066183 (2.83%) == '2.3548200*gauss1_sigma' gauss1_height: 0.05459081 +/- 7.8147e-04 (1.43%) == '0.3989423*gass1_amplitude/max(1e-15, gauss1_sigma)' gauss2_amplitude: 0.03945700 +/- 0.00329914 (8.36%) (init = 0.116005) gauss2_center: 7113.18957 +/- 0.04258439 (0.00%) (init = 7113.403) gauss2_sigma: 0.57985874 +/- 0.03338641 (5.76%) (init = 0.556759) gauss2_fwhm: 1.36546297 +/- 0.07861898 (5.76%) == '2.3548200*gauss2_sigma' gauss2_height: 0.02714638 +/- 0.00110204 (4.06%) == '0.3989423*gauss2_amplitude/max(1e-15, gauss2_sigma)' fit_centroid: 7111.98258 +/- 0.01448240 (0.00%) == '(gauss1_amplitude*gauss1_center +gauss2_amplitude*gauss2_center )/(gauss1_amplitude+gauss2_amplitude)' [[Correlations]] (unreported correlations are < 0.100) C(bpoly_intercept, bpoly_slope) = -1.0000 C(bpeak_amplitude, bpeak_center) = +0.9722 C(gauss1_amplitude, gauss1_sigma) = +0.9186 .... C(gauss1_amplitude, gauss2_amplitude) = -0.7900 So there are 2 "gaussN_amplitude" Parameters for the area under each Gaussian, with a strong negative correlation. If you do

...

...

uvars = peakresult.result.uvars print(uvars['gauss1_amplitude'], uvars['gauss2_amplitude']) print(uvars['gauss1_amplitude'] + uvars['gauss2_amplitude'])

You'll get the area of the sum of the two Gaussians as 0.104+/-0.004 0.0395+/-0.0033 0.1434+/-0.0023 That is, one might expect the uncertainties in 'gauss1_amplitude' and 'gauss2_amplitude' should add in quadrature, but that would overestimate the uncertainty in the sum by almost ~2x because the parameters are highly (and negatively) correlated. The uncertainty in the reported peak heights and the centroid of the two peaks also takes the correlations into account. Such calculations are not too hard to do from the Larch buffer or Python script, but we might think about how that could be exposed more flexibly. I can be persuaded to just add a Parameter "peaks_area" = the sum of the amplitudes, which would then have this value and uncertainty. Any suggestions for what should be exposed here? Cheers, --Matt On Thu, Dec 14, 2023 at 10:47 AM Ryan Parmenter wrote:

Hello,

I successfully fitted Gaussian curves to my pre-edge peaks using Larix (XAS Viewer), yielding the centroid energy for indicating Fe oxidation state. The expected trends are observed, however, in reviewing articles, I noticed they report the area and integrated intensities of Gaussian curves, often automated with Peakfit software. Can Larix generate these values in its statistical report? If not, how can I calculate the area and integrated intensity using Larix's provided values, considering the absence of standard deviation?

Thanks,

Ryan

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