 Method of exhaustion

This article is about the method of finding the area of a shape using limits. For the method of proof, see Proof by exhaustion.
The method of exhaustion (methodus exhaustionibus, or méthode des anciens) is a method of finding the area of a shape by inscribing inside it a sequence of polygons whose areas converge to the area of the containing shape. If the sequence is correctly constructed, the difference in area between the nth polygon and the containing shape will become arbitrarily small as n becomes large. As this difference becomes arbitrarily small, the possible values for the area of the shape are systematically "exhausted" by the lower bound areas successively established by the sequence members. The idea originated with Antiphon, although it is not entirely clear how well he understood it.^{[1]} The theory was made rigorous by Eudoxus. The first use of the term was in 1647 by Grégoire de SaintVincent in Opus geometricum quadraturae circuli et sectionum .
The method of exhaustion typically required a form of proof by contradiction, known as reductio ad absurdum. This amounts to finding an area of a region by first comparing it to the area of a second region (which can be “exhausted” so that its area becomes arbitrarily close to the true area). The proof involves assuming that the true area is greater than the second area, and then proving that assertion false, and then assuming that it is less than the second area, and proving that assertion false, too.
The method of exhaustion is seen as a precursor to the methods of calculus. The development of analytical geometry and rigorous integral calculus in the 17th19th centuries (in particular a rigorous definition of limit) subsumed the method of exhaustion so that it is no longer explicitly used to solve problems. An important early intermediate step was Cavalieri's principle, also termed the "method of indivisibles", which was a bridge between the method of exhaustion and fullfledged integral calculus.
Contents
Use by Euclid
Euclid used the method of exhaustion to prove the following six propositions in the book 12 of Elements.
 Proposition 2
 The area of a circle is proportional to the square of its diameter.
 Proposition 5
 The volume of a tetrahedron of the same height is proportional to the triangular area of the base each other.
 Proposition 10
 The volume of a cone is a third of the volume of the corresponding cylinder which has the same base and height.
 Proposition 11
 The volume of a cone (or cylinder) of the same height is proportional to the area of the base.
 Proposition 12
 The volume of a cone (or cylinder) that is the similar to another is proportional to the cube of the ratio of the diameters of the bases.
 Proposition 18
 The volume of a sphere is proportional to the cube of its diameter.
Use by Archimedes
Part of a series of articles on the mathematical constant π Uses Area of disk · Circumference
Use in other formulaeProperties Irrationality · Transcendence
Less than 22/7Value Approximations · Memorization People Archimedes · Liu Hui · Zu Chongzhi
Madhava of Sangamagrama
William Jones · John Machin
John Wrench · Ludolph van CeulenHistory Chronology · Book In culture Legislation · Holiday Related topics Squaring the circle · Basel problem
Tau (τ) · Other topics related to πArchimedes used the method of exhaustion as a way to compute the area inside a circle by filling the circle with a polygon of a greater area and greater number of sides. The quotient formed by the area of this polygon divided by the square of the circle radius can be made arbitrarily close to π as the number of polygon sides becomes large, proving that the area inside the circle of radius r is πr^{2}, π being defined as the ratio of the circumference to the diameter. Incidentally, he also provided the celebrated bounds 3+10/71 < π < 3 + 1/7 comparing the perimeters of the circle with the perimeters of the inscribed and circumscribed 96sided regular polygons.
Other results he obtained with the method of exhaustion included^{[2]}
 The area bounded by the intersection of a line and a parabola is 4/3 that of the triangle having the same base and height;
 The area of an ellipse is proportional to a rectangle having sides equal to its major and minor axes;
 The volume of a sphere is 4 times that of a cone having a base and height of the same radius;
 The volume of a cylinder having a height equal to its diameter is 3/2 that of a sphere having the same diameter;
 The area bounded by one spiral rotation and a line is 1/3 that of the circle having a radius equal to the line segment length;
 Use of the method of exhaustion also led to the successful evaluation of a geometric series (for the first time).
See also
Notes and references
 ^ The MacTutor History of Mathematics archive
 ^ Smith, David E (1958). History of Mathematics. New York: Dover Publications. ISBN 0486204308.
Categories: Volume
 Euclidean geometry
 Integral calculus
 History of mathematics
Wikimedia Foundation. 2010.