Mahāvīra (mathematician)

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Mahāvīra
Born India
Occupation Mathematician

Mahāvīra (or Mahaviracharya, "Mahavira the Teacher") was a 9th-century Jain mathematician from Mysore, India.[1][2][3] He was the author of Gaṇitasārasan̄graha (or Ganita Sara Samgraha, c. 850), which revised the Brāhmasphuṭasiddhānta.[1] He was patronised by the Rashtrakuta king Amoghavarsha.[4] He separated astrology from mathematics. It is the earliest Indian text entirely devoted to mathematics.[5] He expounded on the same subjects on which Aryabhata and Brahmagupta contended, but he expressed them more clearly. His work is a highly syncopated approach to algebra and the emphasis in much of his text is on developing the techniques necessary to solve algebraic problems.[6] He is highly respected among Indian mathematicians, because of his establishment of terminology for concepts such as equilateral, and isosceles triangle; rhombus; circle and semicircle.[7] Mahāvīra's eminence spread in all South India and his books proved inspirational to other mathematicians in Southern India.[8] It was translated into Telugu language by Pavuluri Mallana as Saar Sangraha Ganitam.[9]

He discovered algebraic identities like a3=a(a+b)(a-b) +b2(a-b) + b3.[3] He also found out the formula for nCr as [n(n-1)(n-2)...(n-r+1)]/r(r-1)(r-2)...2*1.[10] He devised formula which approximated area and perimeters of ellipses and found methods to calculate the square of a number and cube roots of a number.[11] He asserted that the square root of a negative number did not exist.[12]

Rules for decomposing fractions

Mahāvīra's Gaṇita-sāra-saṅgraha gave systematic rules for expressing a fraction as the sum of unit fractions.[13] This follows the use of unit fractions in Indian mathematics in the Vedic period, and the Śulba Sūtras' giving an approximation of √2 equivalent to 1 + \tfrac13 + \tfrac1{3\cdot4} - \tfrac1{3\cdot4\cdot34}.[13]

In the Gaṇita-sāra-saṅgraha (GSS), the second section of the chapter on arithmetic is named kalā-savarṇa-vyavahāra (lit. "the operation of the reduction of fractions"). In this, the bhāgajāti section (verses 55–98) gives rules for the following:[13]

  • To express 1 as the sum of n unit fractions (GSS kalāsavarṇa 75, examples in 76):[13]

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rūpāṃśakarāśīnāṃ rūpādyās triguṇitā harāḥ kramaśaḥ /
dvidvitryaṃśābhyastāv ādimacaramau phale rūpe //

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When the result is one, the denominators of the quantities having one as numerators are [the numbers] beginning with one and multiplied by three, in order. The first and the last are multiplied by two and two-thirds [respectively].

 1 = \frac1{1 \cdot 2} + \frac1{3} + \frac1{3^2} + \dots + \frac1{3^{n-2}} + \frac1{\frac23 \cdot 3^{n-1}}
  • To express 1 as the sum of an odd number of unit fractions (GSS kalāsavarṇa 77):[13]
1 = \frac1{2\cdot 3 \cdot 1/2} + \frac1{3 \cdot 4 \cdot 1/2} + \dots + \frac1{(2n-1) \cdot 2n \cdot 1/2} + \frac1{2n \cdot 1/2}
  • To express a unit fraction 1/q as the sum of n other fractions with given numerators a_1, a_2, \dots, a_n (GSS kalāsavarṇa 78, examples in 79):
\frac1q = \frac{a_1}{q(q+a_1)} + \frac{a_2}{(q+a_1)(q+a_1+a_2)} + \dots + \frac{a_{n-1}}{q+a_1+\dots+a_{n-2})(q+a_1+\dots+a_{n-1})} + \frac{a_n}{a_n(q+a_1+\dots+a_{n-1})}
  • To express any fraction p/q as a sum of unit fractions (GSS kalāsavarṇa 80, examples in 81):[13]
Choose an integer i such that \tfrac{q+i}{p} is an integer r, then write
 \frac{p}{q} = \frac{1}{r} + \frac{i}{r \cdot q}
and repeat the process for the second term, recursively. (Note that if i is always chosen to be the smallest such integer, this is identical to the greedy algorithm for Egyptian fractions.)
  • To express a unit fraction as the sum of two other unit fractions (GSS kalāsavarṇa 85, example in 86):[13]
\frac1{n} = \frac1{p\cdot n} + \frac1{\frac{p\cdot n}{n-1}} where p is to be chosen such that \frac{p\cdot n}{n-1} is an integer (for which p must be a multiple of n-1).
\frac1{a\cdot b} = \frac1{a(a+b)} + \frac1{b(a+b)}
  • To express a fraction p/q as the sum of two other fractions with given numerators a and b (GSS kalāsavarṇa 87, example in 88):[13]
\frac{p}{q} = \frac{a}{\frac{ai+b}{p}\cdot\frac{q}{i}} + \frac{b}{\frac{ai+b}{p} \cdot \frac{q}{i} \cdot{i}} where i is to be chosen such that p divides ai + b

Some further rules were given in the Gaṇita-kaumudi of Nārāyaṇa in the 14th century.[13]

Notes

  1. 1.0 1.1 Pingree 1970.
  2. O'Connor & Robertson 2000.
  3. 3.0 3.1 Tabak 2009, p. 42.
  4. Puttaswamy 2012, p. 231.
  5. The Math Book: From Pythagoras to the 57th Dimension, 250 Milestones in the ... by Clifford A. Pickover: page 88
  6. Algebra: Sets, Symbols, and the Language of Thought by John Tabak: p.43
  7. Geometry in Ancient and Medieval India by T. A. Sarasvati Amma: page 122
  8. Hayashi 2013.
  9. Census of the Exact Sciences in Sanskrit by David Pingree: page 388
  10. Tabak 2009, p. 43.
  11. Krebs 2004, p. 132.
  12. Selin 2008, p. 1268.
  13. 13.0 13.1 13.2 13.3 13.4 13.5 13.6 13.7 13.8 Kusuba 2004, pp. 497–516

See also

List of Indian mathematicians

References

  • Bibhutibhusan Datta and Avadhesh Narayan Singh (1962). History of Hindu mathematics: a source book.
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