mookid's answer is fine. Or try this. Suppose you want to compute the derivative of \cos at a point a. Use the identity \cos(a+x)=\cos(a)\cos(x)-\sin(a)\sin(x) . Differentiate that with ...

This is a straightforward application of the product rule. If you've misplaced your notes, the product rule is: y' = f(x)*g(x)' + f(x)'*g(x) where y', f(x)', and g(x)' are the derivatives of y, f(x) ...

\displaystyle{I}={\tan{{x}}}-{\sec{{x}}}+{c} Explanation: We know that, \displaystyle{\left({\left({1}\right)}{{\sin}^{{2}}\theta}+{{\cos}^{{2}}\theta}={1}\right.} \displaystyle{\left({\left({2}\right)}\frac{{1}}{{\cos{\theta}}}={\sec{\theta}}{\quad\text{and}\quad}\frac{{\sin{\theta}}}{{\cos{\theta}}}={\tan{\theta}}\right.} ...

See below. Explanation: \displaystyle\int{\left(\frac{{1}}{{2}}+{\sin{{x}}}\right)}{\left.{d}{x}\right.} It is a known result that the derivative of \displaystyle{\sin{{x}}} is \displaystyle{\cos{{x}}} ...

It's too long to put in as a comment, so I'll post here instead. Based on the answer in the link, Newton did not use the method to find the derivative of \arcsin⁡ x. He uses the power series of \arcsin⁡ x ...

The essential problem is writing "\sin u, where u is measured in degrees". This doesn't really mean anything. If you want degrees, you need to write them explicitly: \sin u^\circ. If you want ...