1) Why do I have to pass
v even though
p is a constant which has already been declared?
Well, a MATLAB's inline function object has an
eval wrapper, so the only variables in its scope are those which were automatically captured from the expression or explicitly specified.
In other words, if you want
v to recognize
p, you have no other option but declaring it when creating the
inline object and passing it to
v explicitly. The same goes for
f as well!
2) How I can get an expression for v completely in terms of t as 3*[(50*t+2)*sin(50*t+2)] or in its simplified form?
Use anonymous functions, like Shai suggested. They are more powerful, more elegant and much faster. For instance:
v = @(t)(3*(50*t+2)*sin(50*t+2))
Note that if you use a name, which is already in use by a variable, as an argument, the anonymous function will treat it as an argument first. It does see other variables in the scope, so doing something like
g = @(x)(x + p) is also possible.
Here's another example, this time a function of a function:
x = 1:5;
f = @(x)(x .^ 3); %// Here x is a local variable, not as defined above
g = @(x)(x + 2); %// Here x is also a local variable
result = f(g(x));
or alternatively define yet another function that implements that:
h = @(x)f(g(x)); %// Same result as h = @(x)((x + 2) .^ 3)
result = h(x);
The output should be the same.
If you want to make an anonymous function out of the expression string, concatenate the '@(x)' (or the correct anonymous header, as you see fit) to the beginning and apply
eval, for example:
expr = '(x + 2) .^ 3';
f = eval(['@(x)', expr]) %// Same result as f = @(x)((x + 2) .^ 3)
Note that you can also do
char(f) to convert it back into a string, but you'll have to manually get rid of the
If you're looking for a different solution, you can explore the Symbolic Toolbox. For example, try:
f(x) = x + 2
g(x) = x ^ 3
or can also use
sym, like so:
f(x) = sym('x + 2');
g(x) = sym('x ^ 3');
subs to substitute values and evaluate the symbolic expression.