Lebesgue integral $\int_{(0, \infty)} \frac{\sin x}{x} dm$ doesn't exist but improper Riemann integral exists

real-analysis measure-theory

Show that the Lebesgue integral $\int_{(0, \infty)} \frac{\sin x}{x} dm$ doesn't exist but the improper Riemann integral $\int_{0}^\infty \frac{\sin x}{x} dx = \lim_{t\to\infty} \int_{0}^t \frac{\sin x}{x} dx$ does exist and is finite.


The Lebesgue integration does not exist. Why? consider $$\int \frac{(\sin x)^+}{x} \text{ v.s. }\int \frac{(\sin x)^-}{x}$$ What the value of those two integration? are they finite? infinite? if both infinite, then what is the definition of lebesgure integration say?

why they are infinite? Hint: $$ \int \frac{(\sin x)^+}{x} \geq\sum_{k=1}^\infty \int_{2k\pi+6/\pi}^{2k\pi+\pi/3} \frac{(\sin x)^+}{x}=?$$

why riemann is finite? can you get an idea from above prove?

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