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Kerala school of astronomy and mathematics - Wikipedia, the free encyclopedia

Kerala school of astronomy and mathematics

From Wikipedia, the free encyclopedia

The Kerala school of astronomy and mathematics was a school of mathematics and astronomy founded by Madhava of Sangamagrama in Kerala, South India, which included among its members: Parameshvara, Neelakanta Somayaji, Jyeshtadeva, Achyuta Pisharati, Melpathur Narayana Bhattathiri and Achyuta Panikkar. The school flourished between the 14th and 16th centuries and the original discoveries of the school seems to have ended with Narayana Bhattathiri (1559-1632). In attempting to solve astronomical problems, the Kerala school independently created a number of important mathematics concepts. Their most important results—series expansion for trigonometric functions—were described in Sanskrit verse in a book by Neelakanta called Tantrasangraha, and again in a commentary on this work, called Tantrasangraha-vakhya, of unknown authorship. The theorems were stated without proof, but proofs for the series for sine, cosine, and inverse tangent were provided a century later in the work Yuktibhasa (c.1500-c.1610), written in Malayalam, by Jyesthadeva, and also in a commentary on Tantrasangraha.[1]

Their discovery of these three important series expansions of calculus—several centuries before calculus was developed in Europe by Leibniz and Newton—was a landmark achievement in mathematics. However, the Kerala School cannot be said to have invented calculus,[2] because, while they were able to develop Taylor series expansions for the important trigonometric functions, they developed neither a comprehensive theory of differentiation or integration, nor the fundamental theorem of calculus.[3]

Contents

[edit] Contributions

[edit] Infinite Series and Calculus

The Kerala school has made a number of contributions to the fields of infinite series and calculus. These include the following (infinite) geometric series:

\frac{1}{1-x} = 1 + x + x^2 + x^3 + \dots for | x | < 1[4]

This formula, however, was already known in the work of the 10th century Iraqi mathematician Alhazen (the Latinized form of the name Ibn al-Haytham) (965-1039).[5]

The Kerala school made intuitive use of mathematical induction, though the inductive hypothesis was not yet formulated or employed in proofs.[1] They used this to discover a semi-rigorous proof of the result:

1^p+ 2^p + \cdots + n^p \approx \frac{n^{p+1}}{p+1} for large n. This result was also known to Alhazen.[1]

They applied ideas from (what was to become) differential and integral calculus to obtain (Taylor-Maclaurin) infinite series for sinx, cosx, and arctanx.[2] The Tantrasangraha-vakhya gives the series in verse, which when translated to mathematical notation, can be written as:[1]

r\arctan(\frac{y}{x}) = \frac{1}{1}\cdot\frac{ry}{x} -\frac{1}{3}\cdot\frac{ry^3}{x^3} + \frac{1}{5}\cdot\frac{ry^5}{x^t} - \cdots , where y/x \leq 1.
r\sin \frac{x}{r} = x - x\cdot\frac{x^2}{(2^2+2)r^2} + x\cdot \frac{x^2}{(2^2+2)r^2}\cdot\frac{x^2}{(4^2+4)r^2} - \cdot
r - \cos x = r\cdot \frac{x^2}{(2^2-2)r^2} - r\cdot \frac{x^2}{(2^2-2)r^2}\cdot \frac{x^2}{(4^2-4)r^2} + \cdots , where, for r = 1, the series reduce to the standard power series for these trigonometric functions, for example:
\sin x = x - \frac{x^3}{3!} + \frac{x^5}{5!} - \frac{x^7}{7!} + \cdots and
\cos x = 1 - \frac{x^2}{2!} + \frac{x^4}{4!} - \frac{x^6}{6!} + \cdots (The Kerala school themselves did not use the "factorial" symbolism.)

The Kerala school made use of the rectification (computation of length) of the arc of a circle to give a proof of these results. (The later method of Leibniz, using quadrature (i.e. computation of area under the arc of the circle), was not yet developed.)[1] They also made use of the series expansion of arctanx to obtain an infinite series expression (later known as Gregory series) for π:[1]

\frac{\pi}{4} = 1 - \frac{1}{3} + \frac{1}{5} - \frac{1}{7} + \ldots

Their rational approximation of the error for the finite sum of their series are of particular interest. For example, the error, fi(n + 1), (for n odd, and i = 1, 2, 3) for the series:

\frac{\pi}{4} \approx 1 - \frac{1}{3}+ \frac{1}{5} - \cdots (-1)^{(n-1)/2}\frac{1}{n} + (-1)^{(n+1)/2}f_i(n+1)
where f_1(n) = \frac{1}{2n}, \ f_2(n) = \frac{n/2}{n^2+1}, \ f_3(n) = \frac{(n/2)^2+1}{(n^2+5)n/2}.

They manipulated the error term to derive a faster converging series for π:[1]

\frac{\pi}{4} = \frac{3}{4} + \frac{1}{3^3-3} - \frac{1}{5^3-5} + \frac{1}{7^3-7} - \cdots

They used the improved series to derive a rational expression,[1] 104348 / 33215 for π correct up to nine decimal places, i.e. 3.141592653. They made use of an intuitive notion of a limit to compute these results.[1] The Kerala school mathematicians also gave a semi-rigorous method of differentiation of some trigonometric functions,[3] though the notion of a function, or of exponential or logarithmic functions, was not yet formulated.

The works of the Kerala school were first written up for the Western world by Englishman C. M. Whish in 1835, though there exists some other works, namely Kala Sankalita by J.Warren in 1825[6] which briefly mentions the discovery of infinite series by Kerala astronomers . According to Whish, the Kerala mathematicians had "laid the foundation for a complete system of fluxions" and these works abounded "with fluxional forms and series to be found in no work of foreign countries."[7] However, Whish's results were almost completely neglected, until over a century later, when the discoveries of the Kerala school were investigated again by C. Rajagopal and his associates. Their work includes commentaries on the proofs of the arctan series in Yuktibhasa given in two papers,[8][9] a commentary on the Yuktibhasa's proof of the sine and cosine series[10] and two papers that provide the Sanskrit verses of the Tantrasangrahavakhya for the series for arctan, sin, and cosine (with English translation and commentary).[11][12]

[edit] Geometry, Arithmetic, and Algebra

In the fields of geometry, arithmetic, and algebra, the Kerala school discovered a formula for the ecliptic,[citation needed] Lhuilier's formula for the circumradius of a cyclic quadrilateral by Parameshvara,[13][14] decimal floating point numbers,[15] the secant method and iterative methods for solution of non-linear equations by Parameshvara,[13][16] and the Newton-Gauss interpolation formula by Govindaswami.[citation needed]

[edit] Astronomy

In astronomy, Madhava discovered a procedure to determine the positions of the Moon every 36 minutes, and methods to estimate the motions of the planets.[17] Late Kerala school astronomers gave a formulation for the equation of the center of the planets,[17][18] and a heliocentric model of the solar system.[17]

[edit] Linguistics

In linguistics, the ayurvedic and poetic traditions of Kerala were founded by this school, and the famous poem, Narayaneeyam, was composed by Narayana Bhattathiri.[citation needed]

[edit] Prominent mathematicians

[edit] Madhavan of Sangamagrama

Madhava of Sangamagrama (c. 1340-1425) was the founder of the Kerala School. Although it is possible that he wrote Karana Paddhati a work written sometime between 1375 and 1475, all we really know of his work comes from works of later scholars.

Little is known about Madhava, who lived at Irinjalakuda,Thrissur district between the years 1340 and 1425.the famous Bharatha temple is Koodalmaanikyam is at Irinjalakuda.'Koodal'in Sanskrit means Sangamam. Nilkantha attributes the series for sine to Madhava. It is not known if Madhava discovered the other series as well, or whether they were discovered later by others in the Kerala school.

Madhava's discoveries include the Taylor series for the sine,[3] cosine, tangent and arctangen functions,[19] the second-order Taylor series approximations of the sine and cosine functions and the third-order Taylor series approximation of the sine function, the power series of π (usually attributed to Leibniz),[20] the solution of transcendental equations by iteration,[citation needed] and the approximation of transcendental numbers by continued fractions.[20] Madhava correctly computed the value of π to 9 decimal places[1] and 13 decimal places,[20] and produced sine and cosine tables to 9 decimal places of accuracy.[21] He also extended some results found in earlier works, including those of Bhaskara.[20]

[edit] Narayanan Pandit

Narayana Pandit (1340-1400), one among the notable Kerala mathematicians, had written two works, an arithmetical treatise called Ganita Kaumudi and an algebraic treatise called Bijganita Vatamsa. Narayanan is also thought to be the author of an elaborate commentary of Bhaskara II's Lilavathi, titled Karmapradipika (or Karma-Paddhati).[22]

Although the Karmapradipika contains little original work, it contains seven different methods for squaring numbers, a contribution that is wholly original to the author, as well as contributions to algebra and magic squares.[22]

Narayanan's other major works contain a variety of mathematical developments, including a rule to calculate approximate values of square roots, investigations into the second order indeterminate equation nq2 + 1 = p2 (Pell's equation), solutions of indeterminate higher-order equations, mathematical operations with zero, several geometrical rules, and a discussion of magic squares and similar figures.[22] Evidence also exists that Narayana made minor contributions to the ideas of differential calculus found in Bhaskara II's work. Narayana has also made contributions to the topic of cyclic quadrilaterals.[14]

[edit] Parameshvaran

Parameshvara (1370-1460), the founder of the Drigganita system of Astronomy, was a prolific author of several important works. He belonged to the Alathur village situated on the bank of Bharathappuzha.He is stated to have made direct astronomical observations for fifty-five years before writing his famous work, Drigganita. He also wrote commentaries on the works of Bhaskara I, Aryabhata and Bhaskara II. His Lilavathi Bhasya, a commentary on Bhaskara II's Lilavathi, contains one of his most important discoveries: an early version of the mean value theorem.[13] This is considered one of the most important results in differential calculus and one of the most important theorems in mathematical analysis, and was later essential in proving the fundamental theorem of calculus.

The Siddhanta-Deepika by Paramesvara is a commentary on the commentary of Govindsvamin on Bhaskara I's Maha-bhaskareeya. This work contains some of his eclipse observations, including one made at Navakshethra in 1422 and two made at Gokarna in 1425 and 1430. It also presents a mean value type formula for inverse interpolation of the sine function, a one-point iterative technique for calculating the sine of a given angle, and a more efficient approximation that works using a two-point iterative algorithm, which is essentially the same as the modern secant method.[13]

Parameshvaran was also the first mathematician to give the radius of a circle with an inscribed cyclic quadrilateral, an expression that is normally attributed to L'Huilier (1782).[13]

[edit] Nilakanthan Somayaji

Nilakantha (1444-1544) was a disciple of Govinda, son of Parameshvara. He was a brahmin from Trkkantiyur in Ponnani taluk. His younger brother Sankara was also a scholar in astronomy. Nilakantha's most notable work Tantra Samgraha (which 'spawned' a later anonymous commentary Tantrasangraha-vyakhya and a further commentary by the name Yukthideepika, written in 1501) he elaborates and extends the contributions of Madhava.[23]

Nilakantha was also the author of Aryabhatiya-bhashya, a commentary of the Aryabhatiya. Of great significance in Nilakantha's work includes the presence of inductive mathematical proofs, a derivation and proof of the Madhava-Gregory series of the arctangent trigonometric function, improvements and proofs of other infinite series expansions by Madhava, an improved series expansion of π that converges more rapidly, and the relationship between the power series of π and arctangent.[23] He also gave sophisticated explanations of the irrationality of π, the correct formulation for the equation of the center of the planets, and a heliocentric model of the solar system.[17]

[edit] Chitrabhanu

Citrabhanu (c. 1530) was a 16th century mathematician from Kerala who gave integer solutions to 21 types of systems of two simultaneous Diophantine equations in two unknowns. These types are all the possible pairs of equations of the following seven forms:[24]

\ x + y = a, x - y = b, xy = c, x^2 + y^2 = d, x^2 - y^2 = e, x^3 + y^3 = f, x^3 - y^3 = g.

For each case, Chitrabhanu gave an explanation and justification of his rule as well as an example. Some of his explanations are algebraic, while others are geometric.[24]

[edit] Jyesthadevan

Jyesthadeva (c. 1500-1600) was another member of the Kerala School. His key work was the Yuktibhasa (written in Malayalam, a regional language of the Indian state of Kerala), the world's first Calculus text. It contained most of the developments of earlier Kerala School mathematicians, particularly from Madhava. Similar to the work of Nilakantha, it is unique in the history of Indian mathematics, in that it contains proofs of theorems, derivations of rules and series, a derivation and proof of the Madhava-Gregory series of the arctangent function, proofs of most mathematical theorems and infinite series earlier discovered by Madhava and other mathematicians of the Kerala School. It also contains a proof of the series expansion of the arctangent function (equivalent to Gregory's proof), and the sine and cosine functions.[23]

He also studied various topics found in many previous Indian works, including integer solutions of systems of first degree equations solved using kuttaka method, and rules of finding the sines and the cosines of the sum and difference of two angles.[23] Jyesthadevan also gave the earliest statement of Wallis' theorem, and geometrical derivations of infinite series.

[edit] Sankaran Varma

There remains a final Kerala work worthy of a brief mention, Sadratnamala an astronomical treatise written by Sankara Varma (1800-1838) that serves as a summary of most of the results of the Kerala School. What is of most interest is that it was composed in the early 19th century and the author stands out as the last notable name in Keralan mathematics. A remarkable contribution was his compution of π correct to 17 decimal places.[20]

[edit] Possibility of transmission of Kerala School results to Europe

Some scholars have recently suggested that knowledge of these results might have been transmitted to Europe through the trade route from Kerala by traders and Jesuit missionaries.[25] Kerala was in continuous contact with China and Arabia, and Europe. The existence of circumstantial evidence[26] such as communication routes and a suitable chronology certainly make such a transmission a possibility. However, there is no direct evidence by way of relevant manuscripts that such a transmission took place.[25] According to David Bressoud, "there is no evidence that the Indian work of series was known beyond India, or even outside of Kerala, until the nineteenth century."[2][27]

Both Arab and Indian scholars made discoveries before the 17th century that are now considered a part of calculus.[3] However, they were not able to, as Newton and Leibniz were, to "combine many differing ideas under the two unifying themes of the derivative and the integral, show the connection between the two, and turn calculus into the great problem-solving tool we have today."[3] The intellectual careers of both Newton and Leibniz are well-documented and there is no indication of their work not being their own;[3] however, it is not known with certainty whether the immediate predecessors of Newton and Leibniz, "including, in particular, Fermat and Roberval, learned of some of the ideas of the Islamic and Indian mathematicians through sources of which we are not now aware."[3] This is an active area of current research, especially in the manuscript collections of Spain and Maghreb, research that is now being pursued, among other places, at the Centre national de la recherche scientifique in Paris.[3]

[edit] Notes

  1. ^ a b c d e f g h i j Roy, Ranjan. 1990. "Discovery of the Series Formula for π by Leibniz, Gregory, and Nilakantha." Mathematics Magazine (Mathematical Association of America) 63(5):291-306.
  2. ^ a b c Bressoud, David. 2002. "Was Calculus Invented in India?" The College Mathematics Journal (Mathematical Association of America). 33(1):2-13.
  3. ^ a b c d e f g h Katz, V. J. 1995. "Ideas of Calculus in Islam and India." Mathematics Magazine (Mathematical Association of America), 68(3):163-174.
  4. ^ Singh, A. N. Singh. 1936. "On the Use of Series in Hindu Mathematics." Osiris 1:606-628.
  5. ^ Edwards, C. H., Jr. 1979. The Historical Development of the Calculus. New York: Springer-Verlag.
  6. ^ Current Science
  7. ^ Charles Whish (1835). Transactions of the Royal Asiatic Society of Great Britain and Ireland. 
  8. ^ Rajagopal, C. and M. S. Rangachari. 1949. "A Neglected Chapter of Hindu Mathematics." Scripta Mathematica. 15:201-209.
  9. ^ Rajagopal, C. and M. S. Rangachari. 1951. "On the Hindu proof of Gregory's series." Ibid. 17:65-74.
  10. ^ Rajagopal, C. and A. Venkataraman. 1949. "The sine and cosine power series in Hindu mathematics." Journal of the Royal Asiatic Society of Bengal (Science). 15:1-13.
  11. ^ Rajagopal, C. and M. S. Rangachari. 1977. "On an untapped source of medieval Keralese mathematics." Archive for the History of Exact Sciences. 18:89-102.
  12. ^ Rajagopal, C. and M. S. Rangachari. 1986. "On Medieval Kerala Mathematics." Archive for the History of Exact Sciences. 35:91-99.
  13. ^ a b c d e J. J. O'Connor and E. F. Robertson (2000). Paramesvara, MacTutor History of Mathematics archive.
  14. ^ a b Ian G. Pearce (2002). Mathematicians of Kerala. MacTutor History of Mathematics archive. University of St Andrews.
  15. ^ D. F. Almeida, G. G. Joseph (2004). "Eurocentrism in the History of Mathematics: The Case of the Kerala School", Race and Class.
  16. ^ K. Plofker (1996). "An Example of the Secant Method of Iterative Approximation in a Fifteenth-Century Sanskrit Text", Historia Mathematica 23 (3), p. 246-256.
  17. ^ a b c d S. Kak (2002). History of Indian Science, p. 6. Louisiana State University.
  18. ^ Joseph (2000), p. 298-300.
  19. ^ O'Connor, John J. & Robertson, Edmund F., “Kerala school of astronomy and mathematics”, MacTutor History of Mathematics archive  St Andrews University, 2000.
  20. ^ a b c d e Ian G. Pearce (2002). Madhava of Sangamagramma. MacTutor History of Mathematics archive. University of St Andrews.
  21. ^ Joseph (2000), p. 293.
  22. ^ a b c J. J. O'Connor and E. F. Robertson (2000). Narayana, MacTutor History of Mathematics archive.
  23. ^ a b c d J. J. O'Connor and E. F. Robertson (2000). Nilakantha, MacTutor History of Mathematics archive.
  24. ^ a b J. J. O'Connor and E. F. Robertson (2000). An overview of Indian mathematics, MacTutor History of Mathematics archive.
  25. ^ a b Almeida, D. F., J. K. John, and A. Zadorozhnyy. 2001. "Keralese Mathematics: Its Possible Transmission to Europe and the Consequential Educational Implications." Journal of Natural Geometry, 20:77-104.
  26. ^ C. K. Raju (2001). "Computers, Mathematics Education, and the Alternative Epistemology of the Calculus in the Yuktibhasa", Philosophy East and West 51 (3), p. 325-362.
  27. ^ Gold, D. and D. Pingree. 1991. "A hitherto unknown Sanskrit work concerning Madhava's derivation of the power series for sine and cosine." Historia Scientiarum. 42:49-65.

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