The constant pi, denoted  , is a real
number defined as the ratio of a circle's
circumference  to its diameter  ,
 |
(1)
|
It is also sometimes called Archimedes' constant or Ludolph's constant.
It is equal to
 |
(2)
|
(Sloane's A000796). Pi's digits have many interesting
properties, although not very much is known about their analytic properties. Spigot (Rabinowitz and Wagon 1995; Arndt and Haenel 2001; Borwein
and Bailey 2003, pp. 140-141) and digit-extraction algorithms (the BBP formula) are known for  .
Pi's continued fraction is given by [3, 7, 15, 1, 292, 1, 1, 1, ...] (Sloane's A001203). Its Engel
expansion is 1, 1, 1, 8, 8, 17, 19, 300, 1991, 2492, ... (Sloane's A006784).
 is known to be irrational
(Lambert 1761; Legendre 1794; Hermite 1873; Nagell 1951; Niven 1956; Struik 1969;
Königsberger 1990; Schröder 1993; Stevens 1999; Borwein and Bailey 2003,
pp. 139-140). In 1794, Legendre also proved that  is irrational (Wells 1986, p. 76).  is also transcendental (Lindemann 1882). An immediate consequence of
Lindemann's proof of the transcendence of  also proved that
the geometric problem
of antiquity known as circle
squaring is impossible. A simplified, but still difficult, version of Lindemann's
proof is given by Klein (1955).
It is also known that  is not a Liouville number (Mahler 1953), but it is not known if  is normal to any base (Stoneham 1970). The following table
summarizes progress in computing upper bounds on the irrationality measure for  . It is likely
that the exponent can be reduced to  , where
 is an infinitesimally small number (Borwein et al.
1989).
| upper bound | reference | | 20 | Mahler (1953), Le Lionnais
(1983, p. 50) | | 14.65 | Chudnovsky
and Chudnovsky (1984) | | 8.0161 | Hata (1992) |
It is not known if  ,  , or  are irrational. However, it is known that they cannot satisfy any
polynomial equation of degree  with integer coefficients of average size  (Bailey 1988, Borwein et al. 1989).
J. H. Conway has shown that there is a sequence of fewer than 40 fractions  ,  , ... with the
property that if you start with  and repeatedly multiply by the first
of the  that gives an integer result until a power of 2 (say,  ) occurs, then
 is the  th decimal digit of  .
 crops up in all sorts of unexpected places in mathematics
besides circles and spheres. For example, it occurs in the normalization of the
normal distribution, in
the distribution of primes, in
the construction of numbers which are very close to integers (the Ramanujan
constant), and in the probability that a pin dropped on a set of parallel lines intersects
a line (Buffon's needle problem).
Pi also appears as the average ratio of the actual length and the direct distance
between source and mouth in a meandering river (Stølum 1996, Singh 1997).
A brief history of notation for pi is given by Castellanos (1988).  is sometimes known as Ludolph's constant after Ludolph van Ceulen (1539-1610), a
Dutch  calculator. The symbol  was first used
by Welsh mathematician William Jones in 1706, and subsequently adopted by Euler.
In Measurement of a Circle, Archimedes (ca. 225 BC) obtained the first rigorous
approximation by inscribing and circumscribing  -gons
on a circle using the Archimedes algorithm. Using  (a 96-gon),
Archimedes obtained
 |
(3)
|
(Wells 1986, p. 49; Shanks 1993, p. 140; Borwein et al. 2004, pp. 1-3).
The Bible contains two references (I Kings 7:23 and Chronicles 4:2) which give a value of 3 for  (Wells 1986, p. 48). It should
be mentioned, however, that both instances refer to a value obtained from physical
measurements and, as such, are probably well within the bounds of experimental uncertainty.
I Kings 7:23 states, "Also he made a molten sea of ten cubits from brim to brim,
round in compass, and five cubits in height thereof; and a line thirty cubits did
compass it round about." This implies  .
The Babylonians gave an estimate of  as  , while
the Egyptians gave  in the Rhind papyrus
and 22/7 elsewhere. The Chinese geometers, however, did best of all, rigorously deriving
 to 6 decimal places.
 appeared in Alfred Hitchcock's insipid and poorly acted 1966
film Torn Curtain, including in one particularly strange but memorable scene
where Paul Newman (Professor Michael Armstrong) draws a  symbol in the
dirt with his foot at the door of a farmhouse. In this film, the symbol  is the pass-sign
of an underground East German network that smuggles fugitives to the West.
The 1998 film Pi is a dark, strange, and hyperkinetic movie about a mathematician
who is slowly going insane searching for a pattern to the Stock Market. Both a Hasidic
cabalistic sect and a Wall Street firm learn of his investigation and attempt to
seduce him. Unfortunately, the film has essentially nothing to do with real mathematics.
314159, the first six digits of  , is the combination to Ellie's office
safe in the novel Contact by Carl Sagan.
On Sept. 15, 2005, Google offered exactly 14159265 shares of Class A stock, which is the same as the first eight digits or  after the decimal
point (Markoff 2005).
The formula for the volume of a cylinder leads to the mathematical joke: "What is the volume of a pizza of thickness
 and radius  ?" Answer: pi z z a. This result
is sometimes known as the second pizza
theorem.
The 2005 album Aerial features a song called "Pi" in which the
first digits of  are interspersed with lyrics:
"Sweet and gentle and sensitive man With an obsessive nature and deep fascination For numbers And a complete infatuation with the calculation Of PI.;
Oh he love, he love, he love He does love his numbers And they run, they run, they run him In a great big circle In a circle of infinity.;
3.1415926535 897932 3846 264 338 3279;
Oh he does, he does, he does He does love his numbers And they run, they run, they run him In a great big circle In a circle of infinity But he must, he must, he must Put a number to it;
50288419 716939937510 582319749 44 5923078 16406286208 821 4808651 32;
Oh he love, he love, he love He does love his numbers And they run, they run, they run him In a great big circle In a circle of infinity;
82306647 0938446095 505 8223...."
There are many, many formulas for pi,
from the simple to the very complicated.
Ramanujan (1913-14) and Olds (1963) give geometric constructions for 355/113. Gardner (1966, pp. 92-93) gives a geometric construction for  .
Dixon (1991) gives constructions for 
and ![sqrt(4+[3-tan(30 degrees)]^2)=3.141533...](/images/equations/Pi/Inline49.gif) . Constructions
for approximations of  are approximations to circle squaring (which is itself impossible).
http://functions.wolfram.com/Constants/Pi/
Almkvist, G. and Berndt, B. "Gauss, Landen, Ramanujan, and Arithmetic-Geometric Mean, Ellipses,  , and the Ladies Diary." Amer.
Math. Monthly 95, 585-608, 1988.
Almkvist, G. "Many Correct Digits of  , Revisited."
Amer. Math. Monthly 104, 351-353, 1997.
Arndt, J. "Cryptic Pi Related Formulas." http://www.jjj.de/hfloat/pise.dvi.
Arndt, J. and Haenel, C. Pi: Algorithmen, Computer, Arithmetik. Berlin: Springer-Verlag,
1998.
Arndt, J. and Haenel, C. Pi--Unleashed, 2nd ed. Berlin: Springer-Verlag, 2001.
Assmus, E. F. "Pi." Amer. Math. Monthly 92, 213-214,
1985.
Bailey, D. H. "Numerical Results on the Transcendence of Constants Involving  ,  , and Euler's Constant." Math.
Comput. 50, 275-281, 1988a.
Bailey, D. H. "The Computation of  to  Decimal
Digit using Borwein's' Quartically Convergent Algorithm." Math. Comput. 50,
283-296, 1988b.
Bailey, D. H.; Borwein, P. B.; and Plouffe, S. "On the Rapid Computation of Various Polylogarithmic Constants." Math. Comput. 66, 903-913,
1997.
Ball, W. W. R. and Coxeter, H. S. M. Mathematical Recreations and Essays, 13th ed. New York:
Dover, p. 55 and 274, 1987.
 Beck, G. and Trott, M. "Calculating Pi from Antiquity to
Modern Times." http://library.wolfram.com/infocenter/Demos/107/.
Beckmann, P. A History of Pi, 3rd ed. New York: Dorset Press, 1989.
Beeler, M. et al. Item 140 in Beeler, M.; Gosper, R. W.; and Schroeppel, R. HAKMEM. Cambridge, MA: MIT Artificial Intelligence Laboratory, Memo AIM-239,
p. 69, Feb. 1972. http://www.inwap.com/pdp10/hbaker/hakmem/pi.html#item140.
Berggren, L.; Borwein, J.; and Borwein, P. Pi: A Source Book. New York: Springer-Verlag, 1997.
Bellard, F. "Fabrice Bellard's Pi Page." http://www-stud.enst.fr/~bellard/pi/.
Berndt, B. C. Ramanujan's Notebooks, Part IV. New York: Springer-Verlag,
1994.
Blatner, D. The Joy of Pi. New York: Walker, 1997.
Blatner, D. "The Joy of Pi." http://www.joyofpi.com/.
Borwein, J. M. "Ramanujan Type Series." http://www.cecm.sfu.ca/organics/papers/borwein/paper/html/local/omlink9/html/node1.html.
Borwein, J. and Bailey, D. Mathematics by Experiment: Plausible Reasoning in the 21st Century.
Wellesley, MA: A K Peters, 2003.
Borwein, J.; Bailey, D.; and Girgensohn, R. Experimentation in Mathematics: Computational Paths to Discovery.
Wellesley, MA: A K Peters, 2004.
Borwein, J. M. and Borwein, P. B. Pi & the AGM: A Study in Analytic Number Theory and Computational
Complexity. New York: Wiley, 1987a.
Borwein, J. M. and Borwein, P. B. "Ramanujan's Rational and Algebraic Series for  ." Indian J. Math. 51, 147-160,
1987b.
Borwein, J. M. and Borwein, P. B. "More Ramanujan-Type Series for  ." In Ramanujan Revisited: Proceedings of the Centenary Conference, University
of Illinois at Urbana-Champaign, June 1-5, 1987 (Ed. G. E. Andrews,
B. C. Berndt, and R. A. Rankin). New York: Academic Press, pp. 359-374,
1988.
Borwein, J. M. and Borwein, P. B. "Class Number Three Ramanujan Type Series for  ." J. Comput. Appl. Math. 46,
281-290, 1993.
Borwein, J. M.; Borwein, P. B.; and Bailey, D. H. "Ramanujan, Modular Equations, and Approximations to Pi, or How to Compute One Billion Digits
of Pi." Amer. Math. Monthly 96, 201-219, 1989.
Borwein, P. B. "Pi and Other Constants." http://www.cecm.sfu.ca/~pborwein/PISTUFF/Apistuff.html.
Calvet, C. "First Communication. A) Secrets of Pi: Strange Things in a Mathematical
Train." http://www.terravista.pt/guincho/1219/1a_index_uk.html.
Castellanos, D. "The Ubiquitous Pi. Part I." Math. Mag. 61,
67-98, 1988a.
Castellanos, D. "The Ubiquitous Pi. Part II." Math. Mag. 61,
148-163, 1988b.
Chan, J. "As Easy as Pi." Math Horizons, pp. 18-19, Winter
1993.
Choong, K. Y.; Daykin, D. E.; and Rathbone, C. R. "Rational Approximations to  ." Math. Comput. 25, 387-392, 1971.
Chudnovsky, D. V. and Chudnovsky, G. V. Padé and Rational Approximations to Systems of Functions and Their Arithmetic Applications. Berlin: Springer-Verlag,
1984.
Chudnovsky, D. V. and Chudnovsky, G. V. "Approximations and Complex Multiplication According to Ramanujan." In Ramanujan Revisited: Proceedings of the Centenary Conference, University
of Illinois at Urbana-Champaign, June 1-5, 1987 (Ed. G. E. Andrews,
B. C. Berndt, and R. A. Rankin). Boston, MA: Academic Press,
pp. 375-472, 1987.
Conway, J. H. and Guy, R. K. "The Number  ." In The
Book of Numbers. New York: Springer-Verlag, pp. 237-239, 1996.
David, Y. "On a Sequence Generated by a Sieving Process." Riveon Lematematika 11,
26-31, 1957.
Dixon, R. "The Story of Pi ( )." §4.3 in Mathographics. New York: Dover, pp. 44-49 and 98-101,
1991.
Dunham, W. "A Gem from Isaac Newton." Ch. 7 in Journey through Genius: The Great Theorems of Mathematics.
New York: Wiley, pp. 106-112 and 155-183, 1990.
Exploratorium. " Page." http://www.exploratorium.edu/learning_studio/pi/.
Finch, S. R. "Archimedes' Constant." §1.4 in Mathematical Constants. Cambridge, England: Cambridge University
Press, pp. 17-28, 2003.
Flajolet, P. and Vardi, I. "Zeta Function Expansions of Classical Constants." Unpublished manuscript. 1996. http://algo.inria.fr/flajolet/Publications/landau.ps.
Gardner, M. "Memorizing Numbers." Ch. 11 in The Scientific American Book of Mathematical Puzzles and Diversions.
New York: Simon and Schuster, p. 103, 1959.
Gardner, M. "The Transcendental Number Pi." Ch. 8 in Martin Gardner's New Mathematical Diversions from Scientific American.
New York: Simon and Schuster, pp. 91-102, 1966.
Gosper, R. W. Table of Simple Continued Fraction for  and the Derived
Decimal Approximation. Stanford, CA: Artificial Intelligence Laboratory, Stanford
University, Oct. 1975. Reviewed in Math. Comput. 31, 1044, 1977.
Gourdon, X. and Sebah, P. "The Constant  ." http://numbers.computation.free.fr/Constants/Pi/pi.html.
Hardy, G. H. A Course of Pure Mathematics, 10th ed. Cambridge, England:
Cambridge University Press, 1952.
Hata, M. "Improvement in the Irrationality Measures of  and  ." Proc.
Japan. Acad. Ser. A Math. Sci. 68, 283-286, 1992.
Havermann, H. " Terms of the Continued Fraction
Expansion of Pi." http://odo.ca/~haha/j/seq/cfpi/.
Hermite, C. "Sur quelques approximations algébriques." J. reine angew. Math. 76, 342-344, 1873. Reprinted in Oeuvres complètes,
Tome III. Paris: Hermann, pp. 146-149, 1912.
Hobson, E. W. Squaring the Circle. New York: Chelsea, 1988.
Klein, F. Famous Problems. New York: Chelsea, 1955.
Knopp, K. §32, 136, and 138 in Theory and Application of Infinite Series. New York: Dover,
p. 238, 1990.
Königsberger, K. Analysis 1. Berlin: Springer-Verlag, 1990.
Laczkovich, M. "On Lambert's Proof of the Irrationality of  ." Amer.
Math. Monthly 104, 439-443, 1997.
Lambert, J. H. "Mémoire sur quelques propriétés remarquables des quantités transcendantes circulaires et logarithmiques." Mémoires
de l'Academie des sciences de Berlin 17, 265-322, 1761.
Le Lionnais, F. Les nombres remarquables. Paris: Hermann, pp. 22 and
50, 1983.
Legendre, A. M. Eléments de géométrie. Paris, France:
Didot, 1794.
Lindemann, F. "Über die Zahl  ." Math.
Ann. 20, 213-225, 1882.
Lopez, A. "Indiana Bill Sets the Value of  to 3." http://db.uwaterloo.ca/~alopez-o/math-faq/node45.html.
MacTutor Archive. "Pi Through the Ages." http://www-groups.dcs.st-and.ac.uk/~history/HistTopics/Pi_through_the_ages.html.
Mahler, K. "On the Approximation of  ." Nederl.
Akad. Wetensch. Proc. Ser. A. 56/Indagationes Math. 15,
30-42, 1953.
Markoff, J. "14,159,265 New Slices of Rich Technology." The New York
Times. Aug. 19, 2005.
MathPages. "Rounding Up to Pi." http://www.mathpages.com/home/kmath001.htm.
Nagell, T. "Irrationality of the numbers  and  ." §13
in Introduction to Number Theory. New York: Wiley, pp. 38-40,
1951.
Niven, I. "A Simple Proof that  is Irrational."
Bull. Amer. Math. Soc. 53, 509, 1947.
Niven, I. M. Irrational Numbers. New York: Wiley, 1956.
Ogilvy, C. S. "Pi and Pi-Makers." Ch. 10 in Excursions in Mathematics. New York: Dover, pp. 108-120,
1994.
Olds, C. D. Continued Fractions. New York: Random House, pp. 59-60,
1963.
Pappas, T. "Probability and  ." The Joy of Mathematics. San Carlos, CA: Wide World Publ./Tetra,
pp. 18-19, 1989.
Peterson, I. Islands of Truth: A Mathematical Mystery Cruise. New York:
W. H. Freeman, pp. 178-186, 1990.
Pickover, C. A. Keys to Infinity. New York: Wiley, p. 62, 1995.
Plouffe, S. "Table of Current Records for the Computation of Constants."
http://pi.lacim.uqam.ca/eng/records_en.html.
 Plouffe, S. "1 Billion
Digits of Pi." http://pi.lacim.uqam.ca/eng/
Plouffe, S. "A Few Approximations of Pi." http://pi.lacim.uqam.ca/eng/approximations_en.html.
Plouffe, S. "PiHex: A Distributed Effort to Calculate Pi." http://www.cecm.sfu.ca/projects/pihex/.
Plouffe, S. "The  Page." http://www.cecm.sfu.ca/pi/.
Plouffe, S. "Table of Computation of Pi from 2000 BC to Now." http://oldweb.cecm.sfu.ca/projects/ISC/Pihistory.html.
Preston, R. "Mountains of Pi." New Yorker 68, 36-67, Mar.
2, 1992. http://www.lacim.uqam.ca/~plouffe/Chudnovsky.html.
Project Mathematics. "The Story of Pi." Videotape. http://www.projectmathematics.com/storypi.htm.
Rabinowitz, S. and Wagon, S. "A Spigot Algorithm for the Digits of  ." Amer.
Math. Monthly 102, 195-203, 1995.
Ramanujan, S. "Modular Equations and Approximations to  ." Quart.
J. Pure. Appl. Math. 45, 350-372, 1913-1914.
Rivera, C. "Problems & Puzzles: Puzzle 050-The Best Approximation to Pi
with Primes." http://www.primepuzzles.net/puzzles/puzz_050.htm.
Rudio, F. "Archimedes, Huygens, Lambert, Legendre." In Vier Abhandlungen
über die Kreismessung. Leipzig, Germany, 1892.
Sagan, C. Contact. Pocket Books, 1997.
Schröder, E. M. "Zur Irrationalität von  und  ." Mitt.
Math. Ges. Hamburg 13, 249, 1993.
Shanks, D. "Dihedral Quartic Approximations and Series for  ." J. Number.
Th. 14, 397-423, 1982.
Shanks, D. Solved and Unsolved Problems in Number Theory, 4th ed.
New York: Chelsea, 1993.
Singh, S. Fermat's Enigma: The Epic Quest to Solve the World's Greatest Mathematical
Problem. New York: Walker, pp. 17-18, 1997.
Sloane, N. J. A. Sequences A000796/M2218, A001203/M2646, A001901, A002485/M3097, A002486/M4456, A006784, A007509/M2061, A025547, A032510, A032523 A033089, A033090, A036903, and A046126 in in "The On-Line Encyclopedia of Integer Sequences."
Smith, D. E. "The History and Transcendence of  ." Ch. 9
in Monographs on Topics of Modern Mathematics Relevant to the Elementary
Field (Ed. J. W. A. Young). New York: Dover, pp. 388-416,
1955.
Stevens, J. "Zur Irrationalität von  ." Mitt.
Math. Ges. Hamburg 18, 151-158, 1999.
Stølum, H.-H. "River Meandering as a Self-Organization Process."
Science 271, 1710-1713, 1996.
Stoneham, R. "A General Arithmetic Construction of Transcendental Non-Liouville Normal Numbers from Rational Functions." Acta Arith. 16, 239-253,
1970.
Stoschek, E. "Modul 33: Algames with Numbers" http://marvin.sn.schule.de/~inftreff/modul33/task33.htm.
Struik, D. A Source Book in Mathematics, 1200-1800. Cambridge, MA:
Harvard University Press, 1969.
Vardi, I. Computational Recreations in Mathematica. Reading,
MA: Addison-Wesley, p. 159, 1991.
Viète, F. Uriorum de rebus mathematicis responsorum, liber VIII, 1593.
Wagon, S. "Is  Normal?" Math. Intel. 7,
65-67, 1985.
Wells, D. The Penguin Dictionary of Curious and Interesting Numbers.
Middlesex, England: Penguin Books, pp. 48-55 and 76, 1986.
Whitcomb, C. "Notes on Pi ( )." http://witcombe.sbc.edu/earthmysteries/EMPi.html.
Woon, S. C. "Problem 1441." Math. Mag. 68, 72-73, 1995.
|
Contact the MathWorld Team
