How to do curve fitting on data with inflection point?

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Hello
Dear experts,
I have a scatter plot of data of x and y and I need to fit a curve on them. However, it is obvious that there is no function that can fit the whole range of these data (blue line of the attached picture). So, I need to fit two curves (dashed red line): one is on the data that are less than the inflection point (yellow point), and one for data that are larger than the inflection point. The inflection point can visually be guessed as 0.25, but is there any way that I can calculate the inflection point from the original scatter plot?
Note that I know how to do the curve fitting, and my question is only regarding the inflection point.
Hope this is the appropriate forum to ask this question.
Thank you very much.
  1 Comment
Adam Danz
Adam Danz on 14 Jan 2021
Edited: Adam Danz on 14 Jan 2021
Why not fit the entire curve to a sigmoid and then extract values less than or greater than x=.25?
Alternatively, but inferior to the suggestion above, would be to separate the curves first and then fit each half to a sigmoid but I can't imagine it would be as good of a fit as fitting the full curve.

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Accepted Answer

Cris LaPierre
Cris LaPierre on 14 Jan 2021
Edited: Cris LaPierre on 14 Jan 2021
Why do you think there is no equation that can fit this data? This looks like a sigmoid E max model to me. A similar shape is obtained from the Hill equation, too.
Here's a simple example using the Hill equation and trying to match your curve.
mx = 0;
mn = 1;
ec50 = 0.25;
n=5;
x=0:.01:1;
y = mn + (mx-mn)*ec50^n./(ec50^n+x.^n);
plot(x,y)
grid on
  6 Comments
Cris LaPierre
Cris LaPierre on 14 Jan 2021
It is possible to numerically integrate it. I'll leave it to others to propose a closed-form solution.
Define your x values, calculate the corresponding y values, and use trapz to numercally integrate.
ec50 = 0.25;
n=5;
x=0:.01:1;
y = 1-ec50^n./(ec50^n+x.^n);
A = trapz(x,y)
A = 0.7330
Benjamin
Benjamin on 15 Jan 2021
Thanks Cris. I was able to numerically integrate the Hill function, then I fitted a curve on the integration results and by doing so, I was able to find a closed-form solution.
Your help is appreciated.

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