Quiz:Equivalence of integration problems

	Knowledge of an antiderivative for $x\mapsto f(x^{2})$ is equivalent to knowledge of an antiderivative for $F$ .
	Knowledge of an antiderivative for $x\mapsto xf(x^{2})$ is equivalent to knowledge of an antiderivative for $F$ .
	Knowledge of an antiderivative for $x\mapsto x^{2}f(x^{2})$ is equivalent to knowledge of an antiderivative for $F$ .
	Knowledge of an antiderivative for $x\mapsto x^{2}f(x)$ is equivalent to knowledge of an antiderivative for $F$ .
	Knowledge of an antiderivative for $x\mapsto xf(x)$ is equivalent to knowledge of an antiderivative for $F$ .

	$\int f({\sqrt {x}})\,dx$
	$\int xf(x)\,dx$
	$\int f(x^{2})\,dx$
	$\int F(x)\,dx$

3 Suppose we know the first three antiderivatives for $f$ , i.e., we have explicit expressions for an antiderivative of $f$ , an antiderivative of that antiderivative, and an antiderivative of the antiderivative of the antiderivative. What is the largest nonnegative integer $k$ for which this guarantees us an expression for an antiderivative of $x\mapsto x^{k}f(x)$ ?

4 Suppose we know the first three antiderivatives for $f$ , i.e., we have explicit expressions for an antiderivative of $f$ , an antiderivative of that antiderivative, and an antiderivative of the antiderivative of the antiderivative. What is the largest nonnegative integer $k$ for which this guarantees us an expression for an antiderivative of $x\mapsto f(x^{1/k})$ ? For simplicity, assume that we are only considering $x>0$ .

5 Suppose $f$ has a known antiderivative $F$ . Consider the problems of integrating $f(x^{2}),xf(x^{2}),x^{2}f(x^{2})$ . What can we say about the relation between these problems?

	All of these have antiderivatives expressible in terms of $F$ .
	$f(x^{2})$ has an antiderivative expressible in terms of $F$ . The integration problems for the other two functions are equivalent to each other.
	$xf(x^{2})$ has an antiderivative expressible in terms of $F$ . The integration problems for the other two functions are equivalent to each other.
	$x^{2}f(x^{2})$ has an antiderivative expressible in terms of $F$ . The integration problems for the other two functions are equivalent to each other.
	All the integration problems are equivalent to each other, but none has a guaranteed expression in terms of $f$ and $F$ .

6 Suppose $f$ is an elementarily expressible and infinitely differentiable function on the positive reals (so all derivatives of $f$ are also elementarily expressible). An antiderivative for $f''(x)/x$ is not equivalent up to elementary functions to which one of the following?

	An antiderivative for $x\mapsto f''(e^{x})$ , domain all of $\mathbb {R}$ .
	An antiderivative for $x\mapsto f'(e^{x}/x)$ , domain positive reals.
	An antiderivative for $x\mapsto f'''(x)(\ln x)$ , domain positive reals.
	An antiderivative for $x\mapsto f'(1/x)$ , domain positive reals.
	An antiderivative for $x\mapsto f(1/{\sqrt {x}})$ , domain positive reals.