What is the derivative of $f(t) = sin^2 (e^(sin^2t))$ ?

Question

5076 views around the world

You can reuse this answer
Creative Commons License

Answer 1 · 2017-01-24T21:52:54

$f'(t)=sin(2e^(sin^2t))e^(sin^2t)(sin(2t))$

We will peel off functions one by one using the chain rule. The overriding function is the squared function.

The chain rule states that the derivative of $g(t)^2=2g(t)^1*g'(t)$ .

So, where $g(t)=sin(e^(sin^2t))$ :

$f'(t)=2sin(e^(sin^2t))*d/dtsin(e^(sin^2t))$

For the leftover derivative, the overriding function is the sine function. Where $sin(h(t))$ , the derivative is $cos(h(t))*h'(t)$ .

Where $h(t)=e^(sin^2t)$ , this becomes:

$f'(t)=2sin(e^(sin^2t))*cos(e^(sin^2t))*d/dte^(sin^2t)$

Now the overriding function is the power of $e$ . For a function $e^(j(t))$ , the derivative through the chain rule is $e^(j(t))*j'(t)$ .

Here, $j(t)=sin^2t$ , so:

$f'(t)=2sin(e^(sin^2t))cos(e^(sin^2t))*e^(sin^2t)*d/dtsin^2t$

We again have a squared function. Following the method before:

$f'(t)=2sin(e^(sin^2t))cos(e^(sin^2t))e^(sin^2t)*2sint*d/dtsint$

$f'(t)=2sin(e^(sin^2t))cos(e^(sin^2t))e^(sin^2t)(2sintcost)$

Using $2sinthetacostheta=sin2theta$ this can be rewritten as:

$f'(t)=sin(2e^(sin^2t))e^(sin^2t)(sin(2t))$

What is the derivative of f(t) = sin^2 (e^(sin^2t))f(t) = sin^2 (e^(sin^2t))?