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11-03-2016 10:38 AM
@Bob_Schor
Yes, no problem - I have attached an Excel file with sample data. At "point A" I will always have at least one period of data, but it will have the same period as that at "point B" and "point C", which is where I need it (so that bit isn't a problem). The problem is programatically finding the period at point A. In this example, it is clearly 15 minutes, but I will have so much data that I need to fit a sine function to the data programatically.
11-03-2016 10:51 AM
A sine function is a periodic function and your data is not. It can be described as a severly truncated sine function.
Do all data set look approximately similar? That would give you pretty strong boundaries on the wavelength (or frequency) or do you sometimes have several periods or even more truncation? Is the amplitude known to be 1 or can it vary? Is there a possible background slope or offset in the data?
In any case, fitting to a sine function given reasonable initial parameter estimates (amplitude, frequency, phase, offset) should work pretty well using nonlinear curve fit. Have you tried?
11-03-2016 01:41 PM
As usual, I completely agree with Altenbach, particularly as he agrees with my suggestion that you fit a sinusoid with offset, amplitude, phase, and frequency (requiring a non-linear fitting algorithm, tricky at times to code but very adept at producing answers quickly). For such algorithms, starting with good estimates of these parameters is very important. An excellent starting value for the offset is simply the mean of your data, while a reasonable estimate for amplitude is the max(abs(data - offset)) (where Offset is the constant you just calculated by taking the mean and Data refers to the array of data). You may already have a good estimate for frequency (in the present example, it was 1/15, 1 divided by the period, ignoring units of time).
Using the data for the A points and using only the first 15 points (and assuming the period is exactly 15 minutes, so I'm analyzing exactly one cycle, which makes the Fourier Series easy to do right on the Excel Worksheet), I get an offset of 0.1, an amplitude of 9.2, and a peak at 4.8 minutes. Note the key to this Quick Solution was the assumption and comments in parentheses.
Bob Schor
11-04-2016 04:30 AM
The non-linear curve fit does seem like the best solution here. I have attached a 1st draft of the program here (I can add robustness later). Thank you all for your help.
11-04-2016 07:34 AM
I got essentially the same answers for this data set using a Simplex method (instead of LevMar) and adding an Offset parameter (your model assumes the offset is 0 -- always better to use a model with fewer parameters, especially if you "know" the value). Congratulations on pulling this together -- now tackle those data!
Bob Schor
P.S. -- you might consider outputting a final "goodness of fit" number to detect if one of your fits goes "way off" (possibly because you have half a wave of data and it is absurdly noisy, for example).
11-04-2016 12:10 PM
@sharon1991 wrote:The non-linear curve fit does seem like the best solution here. I have attached a 1st draft of the program here (I can add robustness later). Thank you all for your help.
A few comments:
11-04-2016 01:51 PM