Indiana pi bill

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Indiana Pi Bill
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Goodwin's model circle as described in section 2 of the bill. It has a diameter of 10 and a stated circumference of "32" (not 31.4159~); the chord of 90° has length stated as "7" (not 7.0710~).

The Indiana pi bill was bill #246 of the 1897 sitting of the

C. A. Waldo, a professor at Purdue University
, who happened to be present in the legislature on the day it went up for a vote.

The mathematical impossibility of squaring the circle using only straightedge and compass constructions, suspected since ancient times, had been rigorously proven 15 years previously, in 1882, by Ferdinand von Lindemann. Better approximations of π than those implied by the bill have been known since ancient times.

Legislative history

An 1897 political cartoon mocking the Indiana pi bill

In 1894, Indiana physician Edward J. Goodwin (ca. 1825 – 1902[2]), also called “Edwin Goodwin” by some sources,[3] believed that he had discovered a correct way of squaring the circle.[4] He proposed a bill to state representative Taylor I. Record, which Record introduced in the House under the long title "A Bill for an act introducing a new mathematical truth and offered as a contribution to education to be used only by the State of Indiana free of cost by paying any royalties whatever on the same, provided it is accepted and adopted by the official action of the Legislature of 1897".

The text of the bill consists of a series of mathematical claims (detailed below), followed by a recitation of Goodwin's previous accomplishments:

... his solutions of the

American Mathematical Monthly
... And be it remembered that these noted problems had been long since given up by scientific bodies as unsolvable mysteries and above man's ability to comprehend.

Goodwin's "solutions" were indeed published in the American Mathematical Monthly, though with a disclaimer of "published by request of the author".[5]

Upon its introduction in the Indiana House of Representatives, the bill's language and topic occasioned confusion among the membership; a member from Bloomington proposed that it be referred to the Finance Committee, but the Speaker accepted another member's recommendation to refer the bill to the Committee on Swamplands, where the bill could "find a deserved grave".[6] It was transferred to the Committee on Education, which reported favorably.[7] Following a motion to suspend the rules, the bill passed on February 6, 1897[8] without a dissenting vote.[7]

The news of the bill occasioned an alarmed response from Der Tägliche Telegraph, a

C. A. Waldo arrived in Indianapolis to secure the annual appropriation for the Indiana Academy of Science. An assemblyman handed him the bill, offering to introduce him to the genius who wrote it. He declined, saying that he already met as many crazy people as he cared to.[7][9]

When it reached the Indiana Senate, the bill was not treated as kindly, for Waldo had talked to the senators previously. The Committee on Temperance to which it had been assigned had reported it favorably, but the Senate on February 12, 1897, postponed the bill indefinitely. It had been nearly passed, but opinion changed when one senator observed that the General Assembly lacked the power to define mathematical truth.[10] Influencing some of the senators was a report that major newspapers, such as the Chicago Tribune, had begun to ridicule the situation.[8]

According to the Indianapolis News article of February 13, 1897, page 11, column 3:[11]

... the bill was brought up and made fun of. The Senators made bad puns about it, ridiculed it and laughed over it. The fun lasted half an hour. Senator Hubbell said that it was not meet for the Senate, which was costing the State $250 a day, to waste its time in such frivolity. He said that in reading the leading newspapers of Chicago and the East, he found that the Indiana State Legislature had laid itself open to ridicule by the action already taken on the bill. He thought consideration of such a proposition was not dignified or worthy of the Senate. He moved the indefinite postponement of the bill, and the motion carried.[7]

Mathematics

Approximation of π

Although the bill has become known as the "pi bill", its text does not mention the name "pi" at all. Goodwin appears to have thought of the ratio between the circumference and diameter of a circle as distinctly secondary to his main aim of squaring the circle. Towards the end of Section 2, the following passage appears:

Furthermore, it has revealed the ratio of the chord and arc of ninety degrees, which is as seven to eight, and also the ratio of the diagonal and one side of a square which is as ten to seven, disclosing the fourth important fact, that the ratio of the diameter and circumference is as five-fourths to four[.][12]

This comes close to an explicit claim that , and that .

This quotation is often read as three mutually incompatible assertions. However, they fit together well if the statement about is taken to be about the inscribed square (with the circle's diameter as diagonal) rather than the square on the radius (with the chord of 90° as diagonal). Together, they describe the circle shown in the figure, whose diameter is ten and circumference is 32; the chord of 90° is taken to be 7. Both values 7 and 32 are within a few percent of the true lengths for a diameter-10 circle (which does not justify Goodwin's presentation of them as exact). The circumference should be nearer to 31.4159, and the diagonal "7" should be the square root of 50 () or nearer to 7.071.

Area of the circle

Goodwin's main goal was not to measure lengths in the circle but to find a square with the same area as the circle. He knew that Archimedes' formula for the area of a circle, which calls for multiplying the diameter by one-fourth of the circumference, is not considered a solution to the ancient problem of squaring the circle.

This is because the problem is to construct the area using a

compass and straightedge
only. Archimedes did not give a method for constructing a straight line with the same length as the circumference. Goodwin was unaware of this central requirement; he believed that the problem with the Archimedean formula was that it gave wrong numerical results; a solution to the ancient problem should replace it with a "correct" formula. So, in the bill that he proposed, without argument, his method:

It has been found that a circular area is to the square on a line equal to the quadrant of the circumference, as the area of an equilateral rectangle is to the square on one side.[12]

This appears needlessly convoluted, as an "equilateral rectangle" is, by definition, a square. In simple terms, the assertion is that the area of a circle is the same as that of a square with the same perimeter. This claim results in other mathematical contradictions to which Goodwin attempts to respond. For example, right after the above quotation, the bill goes on to say:

The diameter employed as the linear unit according to the present rule in computing the circle's area is entirely wrong, as it represents the circle's area one and one-fifth times the area of a square whose perimeter is equal to the circumference of the circle.

In the model circle above, the Archimedean area (accepting Goodwin's values for the circumference and diameter) would be 80. In contrast, Goodwin's proposed rule leads to an area of 64. Now, 80 exceeds 64 by one-fifth of 80. Goodwin appears to confuse with , an approximation that works only for fractions much smaller than .

The area found by Goodwin's rule is   times the true area of the circle, which, in many accounts of the pi bill, is interpreted as a claim that . However, there is no internal evidence in the bill that Goodwin intended to make such a claim. On the contrary, he repeatedly denies that the area of the circle has anything to do with its diameter.

The relative area error of works out to about 21 percent, which is much more grave than the approximate lengths in the model circle of the previous section. It is unknown what made Goodwin believe that his rule could be correct. Generally, figures with identical perimeters do not have an identical area (see

isoperimetry
). The typical demonstration of this fact is to compare a long, thin shape with a small, enclosed area (the area approaching zero as the width decreases) to one with the same perimeter that is approximately as tall as it is wide (the area approaching the square of the width), obviously of a much greater area.

Notes

  1. ^ Wilkins, Alasdair (31 January 2012). "The Eccentric Crank Who Tried To Legislate The Value Of Pi". io9. Retrieved 23 May 2019.
  2. ^ Dudley 1992, p. 195, citing an obituary
  3. ^ "Did You Know?: Purdue and Indiana's Pi Bill - News - Purdue University". purdue.edu.
  4. ^ Goodwin, Edward J. (1894). "Quadrature of the Circle". Queries and Information. American Mathematical Monthly. 1 (7): 246–247.
    JSTOR 2971093
    .

    Reprinted in: Lennart Berggren, Jonathan Borwein, and Peter Borwein, Pi: A Source Book, 3rd ed. (New York, New York: Springer-Verlag, 2004), page 230.

    See also: Purdue Agricultural Economics.

    Edward J. Goodwin (1895) "(A) The trisection of an angle; (B) Duplication of the cube," American Mathematical Monthly, 2: 337.

  5. ^ "Clearing the Misunderstanding Re My April Fool's 'Joke'". math.rutgers.edu.
  6. ^ a b Hallerburg 1975, p. 385.
  7. ^ a b c d "Indiana Pi". Archived from the original on 2019-02-21.
  8. ^ a b Hallerburg 1975, p. 390.
  9. ^ Waldo, C. A. (1916). "What Might Have Been". Proceedings of the Indiana Academy of Science: 445–446. Retrieved 24 April 2017.
  10. ^ Hallerburg 1975, p. 391.
  11. ^ "THE MATHEMATICAL BILL. Fun-Making In the Senate Yester-day Afternoon--Other Action". Indianapolis News. 13 February 1897. Retrieved 24 April 2017.
  12. ^ a b "Text of the bill". Archived from the original on 2013-06-27.

References

External links