1.5 Exercises on calculus: one variable
- Find the first derivatives of
- 2x4 + 3x1/2 + 7
- 4/x2
- (x + 3)/(x2 + x)
- xln x
- 8x3 + (3/2)x−1/2
- −8/x3
- (−x2 − 6x − 3)/(x2 + x)2
- ln x + 1
- Show that for any values of a and b for which ab > 0, the derivative of the function ax/(ax + b(1 − x)) with respect to x is positive. For a = 1 and b = 2, calculate f(1) and f(3). How are these two
results consistent? (Is the derivative really positive for all values of x?)
The derivative is ab/(ax + b(1 − x))2. For a = 1 and b = 2, the value of the function at x = 1 is 1 and its value at x = 3 is −3. The function is discontinuous at x = 2. At every point x ≠ 2 the derivative is positive, but at x = 2 it is not defined (the value of the function is very large and positive for values of x a bit smaller than 2 and is very large and negative for values of x a bit larger than 2).
- At what points is the function |x| differentiable?
The function is differentiable at all points except 0.
- Find the following indefinite integrals, remembering that the derivative of eax is aeax (an implication of the chain rule, studied in a later section).
- ∫x4dx
- ∫2e−2xdx
- ∫x(1 + x)1/2dx (use integration by parts)
- ∫(4x + 2)/(x2 + x)dx
- (1/5)x5 + c
- −e−2x + c
- x(2/3)(1 + x)3/2 − (4/15)(1 + x)5/2 + c = (2/15)(−2 + 3x)(1 + x)3/2 + c. (You can alternatively use the fact that ∫x(1 + x)1/2dx = ∫((1 + x)(1 + x)1/2 − (1 + x)1/2)dx = ∫(1 + x)3/2dx − ∫(1 + x)1/2dx to calculate the integral without using integration by parts.)
- 2ln |x2 + x| + c
- Find the following definite integrals.
- ∫3
13x1/2dx - ∫3
2(e2x + ex)dx - ∫∞
0e−rtdt where r > 0 is a constant
- 2(33/2−1)
- (1/2)e6 + e3 − (1/2)e4 − e2
- 1/r. (Note that because r > 0, e−rt converges to 0 as t increases without bound.)
- ∫3