Harnack integral

A generalization of the improper Riemann integral on the class of functions $ f $ whose set of unboundedness points $ E _ {f} $ has Jordan measure zero, and which are Riemann integrable on any segment not containing points of $ E _ {f} $. Let $ \Delta _ {i} $, $ i = 1 \dots n $, be a finite system of intervals containing $ E _ {f} $. The Harnack integral is then defined by the equation

$$ ( H) \int\limits _ { a } ^ { b } f ( x) dx = \ \lim\limits ( R) \int\limits _ {( a, b) \setminus \cup _ {i} \Delta _ {i} } f ( x) dx, $$

if the last limit for $ \mathop{\rm mes} ( \cup _ {i} \Delta _ {i} ) \rightarrow 0 $ exists. The integral was introduced by A. Harnack [1]. The condition that each interval $ \Delta _ {i} $ should have non-empty intersection with $ E _ {f} $ was added to the original definition at a later date. As a result, the Harnack integral usually becomes conditionally convergent. It partly overlaps the Lebesgue integral and is covered by the Perron integral and by the Denjoy integral. Nowadays, the Harnack integral is only of methodical and historical interest.

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