. Here = and = 3x^2 . Now we plug x = 1 into the
derivative. Note that where x = 1, t = (1)^3 = 1. We get = = −8 and = 3(1)^2 = 3. Thus, = (−8)(3) = −24.18. +
Here the solution will be much simpler if we first substitute x = into the expression for y.We get y = . Now we find the derivative using the Product Rule, which saysthat if f(x) = uv, then f′(x) = u + v . Here y = , so u = t^3 −6t and v = 5t + . Using the Product Rule, we get = + .
19. 2
We find the derivative using the Chain Rule, which says that if y = y(v) and v = v(x), then . Here and = 2x. Now, we plug x = 1 into the
derivative. Note that, where x = 1, u = 0. We get = 1 and = 2, so = (1)(2) = 2.
20.
We find the derivative using the Chain Rule, which says that if y = y(v) and v = v(x), then , although, in this case, we have u(y), y(x), and x(v), so we will find by . Here = 3y^2 , = , and = 2v. Next,
= . Now because x = v^2 and y = , we get =(2v) = .