Knowing that $b,a \in C^{0}((0,L]) \cap C^{1}((0,L))$, are positive and $b(x) = \dfrac{1}{\sqrt{xa(x)}}$. Assume that $0 < \alpha < 1$ and $$ \int_{0}^{x}b(\tau)d\tau \sim \dfrac{2}{1-\alpha}\dfrac{\sqrt{x}}{\sqrt{a(x)}}, \ \ \text{when} \ \ x \to 0 $$ Then $$\dfrac{a(x)}{x^{2}}\int_{0}^{x}b(\tau)d\tau \sim \dfrac{2}{1-\alpha}\dfrac{\sqrt{a(x)}}{x^{3/2}}, \ \ \text{when} \ \ x \to 0.$$
I'm trying to understand the above implication which is a passage from the proof of Lemma 5.12 of Martinez & Vancostenoble - Carleman estimates for one-dimensional degenerate heat equations.
It seems to be simple, I'm trying to apply L'hopital's rule. Basically what the author of the article did was multiply $\dfrac{a(x)}{x^{2}}$ by the limit of $\displaystyle\int_{0}^{x}b(\tau)d\tau$. Why is this possible?
\dfracyour fractions, please also\displaystyleyour integrals: $\displaystyle\frac{a(x)}{x^2}\int_0^x b(\tau)\mathrm d\tau$\displaystyle\frac{a(x)}{x^2}\int_0^x b(\tau)\mathrm d\taulooks better than $\dfrac{a(x)}{x^2}\int_0^x b(\tau)d\tau$\dfrac{a(x)}{x^2}\int_0^x b(\tau)d\tau(though it's better not to\displaystyletitles at all). I have edited accordingly. $\endgroup$