None of these problems is testing your conceptual understanding of Lebesgue integration. All of these functions are continuous, so the Lebesgue integral exists if and only if either $\int_0^\infty f_+(x)\,dx$ or $\int_0^\infty f_-(x)\,dx$ is finite, where $f_+$ is the positive part of $f$ (i.e. $f_+(x) = \max(f(x),0)$), and $f_-$ is the negative part of $f$.
Really these questions are designed to help you practice your calculus skills, particularly the analysis of improper Riemann integrals. In each case, what you want to do is analyze the behavior of the function near $0$ and $\infty$.
For example, in the second problem, the function is bounded as $x\to 0$, and as $x\to\infty$ it's roughly $1/x^2$, so the improper integral converges. (This can be made rigorous using the Limit Comparison Test for improper integrals and L'Hospital's Rule.)
In the third problem, the function is strictly positive, and is roughly $1/x$ as $x\to\infty$, so the improper integral will diverge to $\infty$. Thus, the Lebesgue integral is infinite.
In general, remember that $\displaystyle\int_0^1 \!\!\frac{1}{x^p}\,dx$ converges if and only if $p<1$, and $\displaystyle\int_1^\infty \!\!\frac{1}{x^p}\,dx$ converges if and only if $p>1$. The techniques for checking convergence of improper integrals are the same as those for infinite series (Comparison Test, Limit Comparison Test, etc.)
I would suggest that you play with each of these problems using these sorts of techniques. If you get stuck on any of them, you could post that problem individually as a question.