How to define a function consisting of multiple parts (i.e different f:n at different times) in Matlab using a single equation?

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Example
f(x)
= x^2 for 0<x<1;
= x^3 for 1<x<2;
= ......and so on.
Please help me with this.

Accepted Answer

Sally Al Khamees
Sally Al Khamees on 23 Dec 2016
Edited: Sally Al Khamees on 21 Feb 2017
If you have R2016b and the Symbolic Math Toolbox installed, you can just use the piecewise function:
Here is an example:
syms y(x);
y(x) = piecewise(1<x <2, x^3, 2 <= x <= 3, x^2, 1)
fplot(y)
%You can evaluate it at one point. Example when x = 2
y(2)
%You can evaluate a vector. Example
v = linspace(1,4,4)
y(v)

More Answers (2)

Walter Roberson
Walter Roberson on 22 Apr 2013
You can define it symbolically using MuPAD's "piecewise" construct.
In some cases you can define it numerically using logical constructs such as
(x > 1 & x < 2) .* x.^3 + (x > 0 & x < 1) .* x^2
This will not work properly for locations that generate NaN or infinity when evaluated for any part. For example, if f(x) = 1 for x = 0, and f(x) = 1/x for other x, then you cannot use
(x == 0) .* 1 + (x ~= 0) .* 1./x
because the second part will generate NaN when evaluated for x(K) = 0, and the NaN multiplied by the 0 of (x(K) ~= 0) will still be NaN instead of vanishing to 0 as it does for finite values. Similarily, 0 * inf is NaN rather than 0.

John BG
John BG on 23 Dec 2016
y=[1:0.001:2].^3
  4 Comments
Stephen23
Stephen23 on 22 Feb 2017
@John BG: how could this be used in a function of x (as the question requests), e.g.:
fun = @(x) ???
Note that both Sally Al Khamees' and Walter Roberson's answers provide this.
Walter Roberson
Walter Roberson on 22 Feb 2017
Consider, for example, if the task is to find the point at which the function equals 3.5,
x0 = 2 * rand(); %range is 0 to 2
fzero(@(x) f(x) - 3.5, x0)
Using a fixed dx is not going to be able to handle this task -- not unless dx = eps(realmin), so that you are testing all 2^62 representable numbers between 0 and 2.
You could, of course, write code that assumes that the input is a scalar:
function y = f(x)
y = 0;
if x > 0 & x < 1
y = x.^2;
elseif x > 1 & x < 2
y = x.^3;
end
end
and you could loop that code for non-scalar x.
You can use logical indexing:
function y = f(x);
y = zeros(size(x));
mask = x > 0 & x < 1;
y(mask) = x(mask).^2;
mask = x > 1 & x < 2;
y(mask) = x(mask).^3;
end
You can define it with an anonymous function,
f = @(x) (x > 1 & x < 2) .* x.^3 + (x > 0 & x < 1) .* x^2;
You can look at the pattern and predict
f = @(x) (x ~= ceil(x)) .* x.^(1 + ceil(x));
And all of those versions are functions that could be used as functions over arbitrary domains such as for fzero() purposes.
But using a fixed dx is not an approach that can be used for this kind of common application.

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