# MATLAB: Interpolating to find the x value of the intersection between a line and a curve

Here is the graph I currently have :

The Dotted Blue line represented the y value that corresponds to the x value I am looking for. I am trying to find the x values of the line's intersections with the blue curve(Upper).Since the interesections do not fall on a point that has already been defined, we need to interpolate a point that falls onto the Upper plot.

Here is the information I have:

LineValue - The y value of the intersection and the value of the dotted line( y = LineValue) Frequency - an array containing the x value coordinates seen on this plot. The interpolated values of Frequency that corresponds to LineValue are what we are looking for Upper/Lower - arrays containing the y value info for this graph

Have a great Thursday!

-Alex

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Example solution using FZERO:

``````%# data resembling your curve
x = linspace(-100,100,100);
f = @(x) 1-2.*exp(-0.5*x.^2./20)./(2*pi) + randn(size(x))*0.002;
VALUE = 0.8;

%# solve f(x)=VALUE
z1 = fzero(@(x)f(x)-VALUE, -10);  %# find solution near x=-10
z2 = fzero(@(x)f(x)-VALUE, 10);   %# find solution near x=+10

%# plot
plot(x,f(x),'b.-'), hold on
plot(z1, VALUE, 'go', z2, VALUE, 'go')
line(xlim(), [VALUE VALUE], 'Color',[0.4 0.4 0.4], 'LineStyle',':')
hold off
``````

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This solution is an improvement on Amro's answer. Instead of using `fzero` you can simply calculate the intersection of the line by looking for transition in the first-difference of the series created by a logical comparison to `LineValue`. So, using Amro's sample data:

```>> x = linspace(-100,100,100);
>> y =  1-2.*exp(-0.5*x.^2./20)./(2*pi) + randn(size(x))*0.002;
>> LineValue = 0.8;
```

Find the starting indices of those segments of consecutive points that exceed `LineValue`:

```>> idx = find(diff(y >= LineValue))

idx =

48    52
```

You can then calculate the x positions of the intersection points using weighted averages (i.e. linear interpolation):

```>> x2 = x(idx) + (LineValue - y(idx)) .* (x(idx+1) - x(idx)) ./ (y(idx+1) - y(idx))

x2 =

-4.24568579887939          4.28720287203057
```

Plot these up to verify the results:

```>> figure;
>> plot(x, y, 'b.-', x2, LineValue, 'go', [x(1) x(end)], LineValue*[1 1], 'k:');
```

The advantages of this approach are:

• The determination of the intersection points is vectorized so will work regardless of the number of intersection points.
• Determining the intersection points arithmetically is presumably faster than using `fzero`.
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