Squaring the circle Information
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Squaring the circle is a problem proposed by ancient geometers. It is the challenge of constructing a square with the same area as a given circle by using only a finite number of steps with compass and straightedge. The difficulty of the problem raised the question of whether specified axioms of Euclidean geometry concerning the existence of lines and circles implied the existence of such a square.
In 1882, the task was proven to be impossible, as a consequence of the Lindemann–Weierstrass theorem, which proves that pi (π) is a transcendental, rather than an algebraic irrational number; that is, it is not the root of any polynomial with rational coefficients. It had been known for decades that the construction would be impossible if π were transcendental, but π was not proven to be transcendental until 1882. Approximate squaring to any given nonperfect accuracy, in contrast, is possible in a finite number of steps, since there are rational numbers arbitrarily close to π.
The expression "squaring the circle" is sometimes used as a metaphor for trying to do the impossible.^{ [1]} The term quadrature of the circle is sometimes used to mean the same thing as squaring the circle, but it may also refer to approximate or numerical methods for finding the area of a circle.
History
Methods to calculate the approximate area of a given circle, which can be thought of as a precursor problem to squaring the circle, were known already in many ancient cultures. These methods can be summarized by stating the approximation to that they produce. In around 2000 BCE, the Babylonian mathematicians used the approximation , and at approximately the same time the ancient Egyptian mathematicians used . Over 1000 years later, the Old Testament Books of Kings used the simpler approximation .^{ [2]} Ancient Indian mathematics, as recorded in the Shatapatha Brahmana and Shulba Sutras, used several different approximations to .^{ [3]} Archimedes proved a formula for the area of a circle according to which .^{ [2]} In Chinese mathematics, in the third century CE, Liu Hui found even more accurate approximations using a method similar to that of Archimedes, and in the fifth century Zu Chongzhi found .^{ [4]} See Approximations of π for more on this history.
The problem of constructing a square whose area is exactly that of a circle, rather than an approximation to it, comes from Greek mathematics. The first known Greek to be associated with the problem was Anaxagoras, who worked on it while in prison. Hippocrates of Chios squared certain lunes, in the hope that it would lead to a solution – see Lune of Hippocrates. Antiphon the Sophist believed that inscribing regular polygons within a circle and doubling the number of sides will eventually fill up the area of the circle, and since a polygon can be squared, it means the circle can be squared. Even then there were skeptics— Eudemus argued that magnitudes cannot be divided up without limit, so the area of the circle will never be used up.^{ [5]} The problem was even mentioned in Aristophanes's play The Birds.
It is believed that Oenopides was the first Greek who required a plane solution (that is, using only a compass and straightedge). James Gregory attempted a proof of its impossibility in Vera Circuli et Hyperbolae Quadratura (The True Squaring of the Circle and of the Hyperbola) in 1667.^{ [6]} Although his proof was faulty, it was the first paper to attempt to solve the problem using algebraic properties of π. It was not until 1882 that Ferdinand von Lindemann rigorously proved its impossibility.
The Victorianage mathematician, logician, and writer Charles Lutwidge Dodgson, better known by the pseudonym Lewis Carroll, also expressed interest in debunking illogical circlesquaring theories. In one of his diary entries for 1855, Dodgson listed books he hoped to write including one called "Plain Facts for CircleSquarers". In the introduction to "A New Theory of Parallels", Dodgson recounted an attempt to demonstrate logical errors to a couple of circlesquarers, stating:^{ [8]}
The first of these two misguided visionaries filled me with a great ambition to do a feat I have never heard of as accomplished by man, namely to convince a circle squarer of his error! The value my friend selected for Pi was 3.2: the enormous error tempted me with the idea that it could be easily demonstrated to BE an error. More than a score of letters were interchanged before I became sadly convinced that I had no chance.
A ridiculing of circlesquaring appears in Augustus de Morgan's A Budget of Paradoxes published posthumously by his widow in 1872. Having originally published the work as a series of articles in the Athenæum, he was revising it for publication at the time of his death. Circle squaring was very popular in the nineteenth century, but hardly anyone indulges in it today and it is believed that de Morgan's work helped bring this about.^{ [9]}
The two other classical problems of antiquity, famed for their impossibility, were doubling the cube and trisecting the angle. Like squaring the circle, these cannot be solved by compassandstraightedge methods. However, unlike squaring the circle, they can be solved by the slightly more powerful construction method of origami, as described at mathematics of paper folding.
Impossibility
The solution of the problem of squaring the circle by compass and straightedge requires the construction of the number √π. If √π is constructible, it follows from standard constructions that π would also be constructible. In 1837, Pierre Wantzel showed that lengths that could be constructed with compass and straightedge had to be solutions of certain polynomial equations with rational coefficients.^{ [10]}^{ [11]} Thus, constructible lengths must be algebraic numbers. If the problem of the quadrature of the circle could be solved using only compass and straightedge, then π would have to be an algebraic number. Johann Heinrich Lambert conjectured that π was not algebraic, that is, a transcendental number, in 1761.^{ [12]} He did this in the same paper in which he proved its irrationality, even before the general existence of transcendental numbers had been proven. It was not until 1882 that Ferdinand von Lindemann proved the transcendence of π and so showed the impossibility of this construction.^{ [13]}
The transcendence of π implies the impossibility of exactly "circling" the square, as well as of squaring the circle.
It is possible to construct a square with an area arbitrarily close to that of a given circle. If a rational number is used as an approximation of π, then squaring the circle becomes possible, depending on the values chosen. However, this is only an approximation and does not meet the constraints of the ancient rules for solving the problem. Several mathematicians have demonstrated workable procedures based on a variety of approximations.
Bending the rules by introducing a supplemental tool, allowing an infinite number of compassandstraightedge operations or by performing the operations in certain nonEuclidean geometries also makes squaring the circle possible in some sense. For example, the quadratrix of Hippias provides the means to square the circle and also to trisect an arbitrary angle, as does the Archimedean spiral.^{ [14]} Although the circle cannot be squared in Euclidean space, it sometimes can be in hyperbolic geometry under suitable interpretations of the terms.^{ [15]}^{ [16]} As there are no squares in the hyperbolic plane, their role needs to be taken by regular quadrilaterals, meaning quadrilaterals with all sides congruent and all angles congruent (but these angles are strictly smaller than right angles). There exist, in the hyperbolic plane, (countably) infinitely many pairs of constructible circles and constructible regular quadrilaterals of equal area, which, however, are constructed simultaneously. There is no method for starting with a regular quadrilateral and constructing the circle of equal area, and there is no method for starting with a circle and constructing a regular quadrilateral of equal area (even when the circle has small enough radius such that a regular quadrilateral of equal area exists).
Modern approximative constructions
Though squaring the circle with perfect accuracy is an impossible problem using only compass and straightedge, approximations to squaring the circle can be given by constructing lengths close to π. It takes only minimal knowledge of elementary geometry to convert any given rational approximation of π into a corresponding compassandstraightedge construction, but constructions made in this way tend to be very longwinded in comparison to the accuracy they achieve. After the exact problem was proven unsolvable, some mathematicians applied their ingenuity to finding elegant approximations to squaring the circle, defined roughly and informally as constructions that are particularly simple among other imaginable constructions that give similar precision.
Construction by Kochański
One of the early historical approximations is Kochański's approximation which diverges from π only in the 5th decimal place. It was very precise for the time of its discovery (1685).^{ [17]}
In the left diagram
Construction by Jacob de Gelder
In 1849 an elegant and simple construction by Jacob de Gelder (17651848) was published in Grünert's Archiv. That was 64 years earlier than the comparable construction by Ramanujan.^{ [18]} It is based on the approximation
This value is accurate to six decimal places and has been known in China since the 5th century as Zu Chongzhi's fraction, and in Europe since the 17th century.
Gelder did not construct the side of the square; it was enough for him to find the following value
 .
The illustration opposite – described below – shows the construction by Jacob de Gelder with continuation.
Draw two mutually perpendicular center lines of a circle with radius CD = 1 and determine the intersection points A and B. Lay the line segment CE = fixed and connect E to A. Determine on AE and from A the line segment AF = . Draw FG parallel to CD and connect E with G. Draw FH parallel to EG, then AH = Determine BJ = CB and subsequently JK = AH. Halve AK in L and use the Thales's theorem around L from A, which results in the intersection point M. The line segment BM is the square root of AK and thus the side length of the searched square with almost the same area.
Examples to illustrate the errors:
 In a circle of radius r = 100 km, the error of side length a ≈ 7.5 mm
 In the case of a circle with radius r = 1 m, the error of the area A ≈ 0.3 mm^{2}
Construction by Hobson
Among the modern approximate constructions was one by E. W. Hobson in 1913.^{ [18]} This was a fairly accurate construction which was based on constructing the approximate value of 3.14164079..., which is accurate to three decimal places (i.e. it differs from π by about 4.8×10^{−5}).
 "We find that GH = r . 1^{ .}77246 ..., and since = 1^{ .}77245 we see that GH is greater than the side of the square whose area is equal to that of the circle by less than two hundred thousandths of the radius."
Hobson does not mention the formula for the approximation of π in his construction. The above illustration shows Hobson's construction with continuation.
Constructions by Ramanujan
The Indian mathematician Srinivasa Ramanujan in 1913,^{ [19]}^{ [20]} Carl Olds in 1963, Martin Gardner in 1966, and Benjamin Bold in 1982 all gave geometric constructions for
which is accurate to six decimal places of π.
In 1914, Ramanujan gave a rulerandcompass construction which was equivalent to taking the approximate value for π to be
giving eight decimal places of π.^{ [21]} He describes his construction till line segment OS as follows.^{ [22]}
"Let AB (Fig.2) be a diameter of a circle whose centre is O. Bisect the arc ACB at C and trisect AO at T. Join BC and cut off from it CM and MN equal to AT. Join AM and AN and cut off from the latter AP equal to AM. Through P draw PQ parallel to MN and meeting AM at Q. Join OQ and through T draw TR, parallel to OQ and meeting AQ at R. Draw AS perpendicular to AO and equal to AR, and join OS. Then the mean proportional between OS and OB will be very nearly equal to a sixth of the circumference, the error being less than a twelfth of an inch when the diameter is 8000 miles long."
In this quadrature, Ramanujan did not construct the side length of the square, it was enough for him to show the line segment OS. In the following continuation of the construction, the line segment OS is used together with the line segment OB to represent the mean proportionals (red line segment OE).
Continuation of the construction up to the desired side length a of the square:
Extend AB beyond A and beat the circular arc b_{1} around O with radius OS, resulting in S′. Bisect the line segment BS′ in D and draw the semicircle b_{2} over D. Draw a straight line from O through C up to the semicircle b_{2}, it cuts b_{2} in E. The line segment OE is the mean proportional between OS′ and OB, also called geometric mean. Extend the line segment EO beyond O and transfer EO twice more, it results F and A_{1}, and thus the length of the line segment EA1 with the above described approximation value of π, the half circumference of the circle. Bisect the line segment EA_{1} in G and draw the semicircle b_{3} over G. Transfer the distance OB from A_{1} to the line segment EA_{1}, it results H. Create a vertical from H up to the semicircle b_{3} on EA_{1}, it results B_{1}. Connect A_{1} to B_{1}, thus the sought side a of the square A_{1}B_{1}C_{1}D_{1} is constructed, which has nearly the same area as the given circle.
Examples to illustrate the errors:
 In a circle of radius r = 10,000 km the error of side length a ≈ −2.8 mm
 In the case of a circle with the radius r = 10 m the error of the area A ≈ −0.1 mm^{2}
Construction using the golden ratio
 In 1991,
Robert Dixon gave a construction for where is the golden ratio.^{ [23]} Three decimal places are equal to those of π.
 If the radius and the side of the square then the expanded second formula shows the sequence of the steps for an alternative construction (see the following illustration). Four decimal places are equal to those of √π.
Squaring or quadrature as integration
Finding the area under a curve, known as integration in calculus, or quadrature in numerical analysis, was known as squaring before the invention of calculus. Since the techniques of calculus were unknown, it was generally presumed that a squaring should be done via geometric constructions, that is, by compass and straightedge. For example, Newton wrote to Oldenburg in 1676 "I believe M. Leibnitz will not dislike the Theorem towards the beginning of my letter pag. 4 for squaring Curve lines Geometrically" (emphasis added).^{ [24]} After Newton and Leibniz invented calculus, they still referred to this integration problem as squaring a curve.
Claims of circle squaring
Connection with the longitude problem
The mathematical proof that the quadrature of the circle is impossible using only compass and straightedge has not proved to be a hindrance to the many people who have invested years in this problem anyway. Having squared the circle is a famous crank assertion. (See also pseudomathematics.) In his old age, the English philosopher Thomas Hobbes convinced himself that he had succeeded in squaring the circle, a claim that was refuted by John Wallis as part of the Hobbes–Wallis controversy.^{ [25]}^{ [26]}
During the 18th and 19th century, the notion that the problem of squaring the circle was somehow related to the longitude problem seems to have become prevalent among wouldbe circle squarers. Using "cyclometer" for circlesquarer, Augustus de Morgan wrote in 1872:
Montucla says, speaking of France, that he finds three notions prevalent among cyclometers: 1. That there is a large reward offered for success; 2. That the longitude problem depends on that success; 3. That the solution is the great end and object of geometry. The same three notions are equally prevalent among the same class in England. No reward has ever been offered by the government of either country.^{ [27]}
Although from 1714 to 1828 the British government did indeed sponsor a £20,000 prize for finding a solution to the longitude problem, exactly why the connection was made to squaring the circle is not clear; especially since two nongeometric methods (the astronomical method of lunar distances and the mechanical chronometer) had been found by the late 1760s. The Board of Longitude received many proposals, including determining longitude by "squaring the circle", though the board did not take "any notice" of it.^{ [28]} De Morgan goes on to say that "[t]he longitude problem in no way depends upon perfect solution; existing approximations are sufficient to a point of accuracy far beyond what can be wanted." In his book, de Morgan also mentions receiving many threatening letters from wouldbe circle squarers, accusing him of trying to "cheat them out of their prize".
Other modern claims
Even after it had been proved impossible, in 1894, amateur mathematician Edwin J. Goodwin claimed that he had developed a method to square the circle. The technique he developed did not accurately square the circle, and provided an incorrect area of the circle which essentially redefined pi as equal to 3.2. Goodwin then proposed the Indiana Pi Bill in the Indiana state legislature allowing the state to use his method in education without paying royalties to him. The bill passed with no objections in the state house, but the bill was tabled and never voted on in the Senate, amid increasing ridicule from the press.^{ [29]}
The mathematical crank Carl Theodore Heisel also claimed to have squared the circle in his 1934 book, "Behold! : the grand problem no longer unsolved: the circle squared beyond refutation."^{ [30]} Paul Halmos referred to the book as a "classic crank book."^{ [31]}
In 1851, John Parker published a book Quadrature of the Circle in which he claimed to have squared the circle. His method actually produced an approximation of π accurate to six digits.^{ [32]}^{ [33]}^{ [34]}
In literature
The problem of squaring the circle has been mentioned by poets such as Dante and Alexander Pope, with varied metaphorical meanings. Its literary use dates back at least to 414 BC, when the play The Birds by Aristophanes was first performed. In it, the character Meton of Athens mentions squaring the circle, possibly to indicate the paradoxical nature of his utopian city.^{ [35]}
Dante's Paradise, canto XXXIII, lines 133–135, contain the verses:
As the geometer his mind applies
To square the circle, nor for all his wit
Finds the right formula, howe'er he tries
For Dante, squaring the circle represents a task beyond human comprehension, which he compares to his own inability to comprehend Paradise.^{ [36]}
By 1742, when Alexander Pope published the fourth book of his Dunciad, attempts at circlesquaring had come to be seen as "wild and fruitless":^{ [33]}
Mad Mathesis alone was unconfined,
Too mad for mere material chains to bind,
Now to pure space lifts her ecstatic stare,
Now, running round the circle, finds it square.
Similarly, the Gilbert and Sullivan comic opera Princess Ida features a song which satirically lists the impossible goals of the women's university run by the title character, such as finding perpetual motion. One of these goals is "And the circle – they will square it/Some fine day."^{ [37]}
The sestina, a poetic form first used in the 12th century by Arnaut Daniel, has been said to square the circle in its use of a square number of lines (six stanzas of six lines each) with a circular scheme of six repeated words. Spanos (1978) writes that this form invokes a symbolic meaning in which the circle stands for heaven and the square stands for the earth.^{ [38]} A similar metaphor was used in "Squaring the Circle", a 1908 short story by O. Henry, about a longrunning family feud. In the title of this story, the circle represents the natural world, while the square represents the city, the world of man.^{ [39]}
In later works circlesquarers such as Leopold Bloom in James Joyce's novel Ulysses and Lawyer Paravant in Thomas Mann's The Magic Mountain are seen as sadly deluded or as unworldly dreamers, unaware of its mathematical impossibility and making grandiose plans for a result they will never attain.^{ [40]}^{ [41]}
See also
 For a more modern related problem, see Tarski's circlesquaring problem.
 The squircle is a mathematical shape with properties between those of a square and those of a circle.
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^
Bloom, Harold (1987). Twentiethcentury American literature. Chelsea House Publishers. p. 1848.
ISBN
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Similarly, the story "Squaring the Circle" is permeated with the integrating image: nature is a circle, the city a square.
 ^ Pendrick, Gerard (1994). "Two notes on "Ulysses"". James Joyce Quarterly. 32 (1): 105–107. JSTOR 25473619.
 ^ Goggin, Joyce (1997). The Big Deal: Card Games in 20thCentury Fiction (PhD). University of Montréal. p. 196.
External links
 Media related to Squaring the circle at Wikimedia Commons
Wikisource has original text related to this article: 
 Squaring the circle at the MacTutor History of Mathematics archive
 Squaring the Circle at cuttheknot
 Circle Squaring at MathWorld, includes information on procedures based on various approximations of pi
 " Squaring the Circle" at " Convergence"
 The Quadrature of the Circle and Hippocrates' Lunes at Convergence
 How to Unroll a Circle Pi accurate to eight decimal places, using straightedge and compass.
 Squaring the Circle and Other Impossibilities, lecture by Robin Wilson, at Gresham College, 16 January 2008 (available for download as text, audio or video file).
 Archived at Ghostarchive and the Wayback Machine: Grime, James. "Squaring the Circle". Numberphile. Brady Haran.
 "2000 years unsolved: Why is doubling cubes and squaring circles impossible?" by Burkard Polster