Fwd: Jaina mathematics

[Guest guest]

hinducivilization , " S.Kalyanaraman " <kalyan97 wrote:

 

Jaina mathematics

 

---

-----------

 

It is a little hard to define Jaina mathematics. Jainism is a

religion and philosophy which was founded in India around the 6th

century BC. To a certain extent it began to replace the Vedic

religions which, with their sacrificial procedures, had given rise

to the mathematics of building altars. The mathematics of the Vedic

religions is described in the article Indian Sulbasutras.

 

Now we could use the term Jaina mathematics to describe mathematics

done by those following Jainism and indeed this would then refer to

a part of mathematics done on the Indian subcontinent from the

founding of Jainism up to modern times. Indeed this is fair and some

of the articles in the references refer to fairly modern

mathematics. For example in [16] Jha looks at the contributions of

Jainas from the 5th century BC up to the 18th century AD.

 

This article will concentrate on the period after the founding of

Jainism up to around the time of Aryabhata in around 500 AD. The

reason for taking this time interval is that until recently this was

thought to be a time when there was little mathematical activity in

India. Aryabhata's work was seen as the beginning of a new classical

period for Indian mathematics and indeed this is fair. Yet Aryabhata

did not work in mathematical isolation and as well as being seen as

the person who brought in a new era of mathematical investigation in

India, more recent research has shown that there is a case for

seeing him also as representing the end-product of a mathematical

period of which relatively little is known. This is the period we

shall refer to as the period of Jaina mathematics.

 

There were mathematical texts from this period yet they have

received little attention from historians until recent times. Texts,

such as the Surya Prajnapti which is thought to be around the 4th

century BC and the Jambudvipa Prajnapti from around the same period,

have recently received attention through the study of later

commentaries. The Bhagabati Sutra dates from around 300 BC and

contains interesting information on combinations. From about the

second century BC is the Sthananga Sutra which is particularly

interesting in that it lists the topics which made up the

mathematics studied at the time. In fact this list of topics sets

the scene for the areas of study for a long time to come in the

Indian subcontinent. The topics are listed in [2] as:-

 

.... the theory of numbers, arithmetical operations, geometry,

operations with fractions, simple equations, cubic equations,

quartic equations, and permutations and combinations.

 

The ideas of the mathematical infinite in Jaina mathematics is very

interesting indeed and they evolve largely due to the Jaina's

cosmological ideas. In Jaina cosmology time is thought of as eternal

and without form. The world is infinite, it was never created and

has always existed. Space pervades everything and is without form.

All the objects of the universe exist in space which is divided into

the space of the universe and the space of the non-universe. There

is a central region of the universe in which all living beings,

including men, animals, gods and devils, live. Above this central

region is the upper world which is itself divided into two parts.

Below the central region is the lower world which is divided into

seven tiers. This led to the work described in [3] on a mathematical

topic in the Jaina work, Tiloyapannatti by Yativrsabha. A circle is

divided by parallel lines into regions of prescribed widths. The

lengths of the boundary chords and the areas of the regions are

given, based on stated rules.

 

This cosmology has strongly influenced Jaina mathematics in many

ways and has been a motivating factor in the development of

mathematical ideas of the infinite which were not considered again

until the time of Cantor. The Jaina cosmology contained a time

period of 2588 years. Note that 2588 is a very large number!

 

2588 = 1013 065324 433836 171511 818326 096474 890383 898005 918563

696288 002277 756507 034036 354527 929615 978746 851512 277392

062160 962106 733983 191180 520452 956027 069051 297354 415786

421338 721071 661056.

 

So what are the Jaina ideas of the infinite. There was a fascination

with large numbers in Indian thought over a long period and this

again almost required them to consider infinitely large measures.

The first point worth making is that they had different infinite

measures which they did not define in a rigorous mathematical

fashion, but nevertheless are quite sophisticated. The paper [6]

describes the way that the first unenumerable number was constructed

using effectively a recursive construction.

 

The Jaina construction begins with a cylindrical container of very

large radius rq (taken to be the radius of the earth) and having a

fixed height h. The number nq = f(rq) is the number of very tiny

white mustard seeds that can be placed in this container. Next, r1 =

g(rq) is defined by a complicated recursive subprocedure, and then

as before a new larger number n1 = f(r1) is defined. The text the

Anuyoga Dwara Sutra then states:-

 

Still the highest enumerable number has not been attained.

 

The whole procedure is repeated, yielding a truly huge number which

is called jaghanya- parita- asamkhyata meaning " unenumerable of low

enhanced order " . Continuing the process yields the smallest

unenumerable number.

 

Jaina mathematics recognised five different types of infinity [2]:-

 

.... infinite in one direction, infinite in two directions, infinite

in area, infinite everywhere and perpetually infinite.

 

The Anuyoga Dwara Sutra contains other remarkable numerical

speculations by the Jainas. For example several times in the work

the number of human beings that ever existed is given as 296.

 

By the second century AD the Jaina had produced a theory of sets. In

Satkhandagama various sets are operated upon by logarithmic

functions to base two, by squaring and extracting square roots, and

by raising to finite or infinite powers. The operations are repeated

to produce new sets.

 

Permutations and combinations are used in the Sthananga Sutra. In

the Bhagabati Sutra rules are given for the number of permutations

of 1 selected from n, 2 from n, and 3 from n. Similarly rules are

given for the number of combinations of 1 from n, 2 from n, and 3

from n. Numbers are calculated in the cases where n = 2, 3 and 4.

The author then says that one can compute the numbers in the same

way for larger n. He writes:-

 

In this way, 5, 6, 7, ..., 10, etc. or an enumerable, unenumerable

or infinite number of may be specified. Taking one at a time, two at

a time, ... ten at a time, as the number of combinations are formed

they must all be worked out.

 

Interestingly here too there is the suggestion that the arithmetic

can be extended to various infinite numbers. In other works the

relation of the number of combinations to the coefficients occurring

in the binomial expansion was noted. In a commentary on this third

century work in the tenth century, Pascal's triangle appears in

order to give the coefficients of the binomial expansion.

 

Another concept which the Jainas seem to have gone at least some way

towards understanding was that of the logarithm. They had begun to

understand the laws of indices. For example the Anuyoga Dwara Sutra

states:-

 

The first square root multiplied by the second square root is the

cube of the second square root.

 

The second square root was the fourth root of a number. This

therefore is the formula

 

(ãa).(ããa) = (ããa)3.

 

Again the Anuyoga Dwara Sutra states:-

 

.... the second square root multiplied by the third square root is

the cube of the third square root.

 

The third square root was the eighth root of a number. This

therefore is the formula

 

(ããa).(ãããa) = (ãããa)3.

 

Some historians studying these works believe that they see evidence

for the Jainas having developed logarithms to base 2.

 

The value of ƒÎ in Jaina mathematics has been a topic of a number of

research papers, see for example [4], [5], [7], and [17]. As with

much research into Indian mathematics there is interest in whether

the Indians took their ideas from the Greeks. The approximation ƒÎ =

ã10 seems one which was frequently used by the Jainas.

 

Finally let us comment on the Jaina's astronomy. This was not very

advanced. It was not until the works of Aryabhata that the Greek

ideas of epicycles entered Indian astronomy. Before the Jaina period

the ideas of eclipses were based on a demon called Rahu which

devoured or captured the Moon or the Sun causing their eclipse. The

Jaina school assumed the existence of two demons Rahu, the Dhruva

Rahu which causes the phases of the Moon and the Parva Rahu which

has irregular celestial motion in all directions and causes an

eclipse by covering the Moon or Sun or their light. The author of

[23] points out that, according to the Jaina school, the greatest

possible number of eclipses in a year is four.

 

Despite this some of the astronomical measurements were fairly good.

The data in the Surya Prajnapti implies a synodic lunar month equal

to 29 plus 16/31 days; the correct value being nearly 29.5305888.

There has been considerable interest in examining the data presented

in these Jaina texts to see if the data originated from other

sources. For example in the Surya Prajnapti data exists which

implies a ratio of 3:2 for the maximum to the minimum length of

daylight. Now this is not true for India but is true for Babylonia

which makes some historians believe that the data in the Surya

Prajnapti is not of Indian origin but is Babylonian. However, in

[22] Sharma and Lishk present an alternative hypothesis which would

allow the data to be of Indian origin. One has to say that their

suggestion that 3:2 might be the ratio of the amounts of water to be

poured into the water-clock on the longest and shortest days seems

less than totally convincing.

 

 

Article by: J J O'Connor and E F Robertson

 

Books

 

L C Jain, The Tao of Jaina sciences (Delhi, 1992).

G G Joseph, The crest of the peacock (London, 1991).

Articles:

 

 

R C Gupta, Chords and areas of Jambudvipa regions in Jaina

cosmography, Ganita Bharati 9 (1-4) (1987), no. 1-4, 51-53.

R C Gupta, Madhavacandra's and other octagonal derivations of the

Jaina value ƒÎ = ã10, Indian J. Hist. Sci. 21 (2) (1986), 131-139.

R C Gupta, On some rules from Jaina mathematics, Ganita Bharati 11

(1-4) (1989), 18-26.

R C Gupta, The first unenumerable number in Jaina mathematics,

Ganita Bharati 14 (1-4) (1992), 11-24.

R C Gupta, Circumference of the Jambudvipa in Jaina cosmography,

Indian J. History Sci. 10 (1) (1975), 38-46.

R C Gupta, Errata: " Chords and areas of Jambudvipa regions in Jaina

cosmography " , Ganita Bharati 10 (1-4) (1988), 124.

A Jain, Some unknown Jaina mathematical works (Hindi), Ganita

Bharati 4 (1-2) (1982), 61-71.

L C Jain, On certain mathematical topics of the Dhavala texts (the

Jaina School of Mathematics), Indian J. History Sci. 11 (2) (1976),

85-111.

L C Jain, System theory in Jaina school of mathematics, Indian J.

Hist. Sci. 14 (1) (1979), 31-65.

L C Jain and Km Meena Jain, System theory in Jaina school of

mathematics. II, Indian J. Hist. Sci. 24 (3) (1989), 163-180.

L C Jain and Km Prabha Jain, Certain special features on the ancient

Jaina calendar, Indian J. Hist. Sci. 30 (2-4) (1995), 103-131.

L C Jain and Km Prabha Jain, Constant-set (dhruva-rasi) technique in

Jaina school of astronomy, Indian J. Hist. Sci. 28 (4) (1993), 303-

308.

L C Jain and R K Trivedi, Todaramala of Jaipur (a Jaina philosopher-

mathematician), Indian J. Hist. Sci. 22 (4) (1987), 359-371.

P Jha, Contributions of the Jainas to astronomy and mathematics,

Math. Ed. (Siwan) 18 (3) (1984), 98-107.

S K Jha and M Jha, A study of the value of ƒÎ known to ancient Hindu

& Jaina mathematicians, J. Bihar Math. Soc. 13 (1990), 38-44.

S S Lishk and S D Sharma, Role of pre-Aryabhata Jaina school of

astronomy in the development of Siddhantic astronomy, in Proceedings

of the Symposium on the 1500th Birth Anniversary of Aryabhata I, New

Delhi, 1976, Indian J. Hist. Sci. 12 (2) (1977), 106-113.

S S Lishk and S D Sharma, Season determination through the science

of sciatherics in Jaina School of Astronomy, Indian J. Hist. Sci. 12

(1) (1977), 33-44.

S S Lishk and S D Sharma, Zodiacal circumference as graduated in

Jaina astronomy, Indian J. Hist. Sci. 14 (1) (1979), 1-15.

I Schneider, The contributions of the sceptic philosophers Arcesilas

and Carneades to the development of an inductive logic compared with

the Jaina-logic, in Proceedings of the Symposium on the 1500th Birth

Anniversary of Aryabhata I, New Delhi, 1976, Indian J. Hist. Sci. 12

(2) (1977), 173-180.

S D Sharma, and S S Lishk, Length of the day in Jaina astronomy,

Centaurus 22 (3) (1978/79), 165-176.

J C Sikdar, Eclipses of the Sun and Moon according to Jaina

astronomy, in Proceedings of the Symposium on the 1500th Birth

Anniversary of Aryabhata I, New Delhi, 1976, Indian J. Hist. Sci. 12

(2) (1977), 127-136.

 

 

http://www-history.mcs.st-

andrews.ac.uk/PrintHT/Jaina_mathematics.html

 

Index of Ancient Indian mathematics

 

---

-----------

 

 

Articles on Indian Mathematics

An overview of Indian mathematics

 

Indian numerals

 

The Indian Sulbasutras

 

Jaina mathematics

 

The Bakhshali manuscript

 

A history of Zero

 

 

History of Pi

 

Chronology of Pi

 

Indian Mathematics: Redressing the balance (Ian G Pearce)

Ancient Indian mathematicians in our archive in chronological order

800 BC Baudhayana

600 Bhaskara I

1060 Brahmadeva

 

750 BC Manava

720 Lalla

1114 Bhaskara II

 

600 BC Apastamba

800 Govindasvami

1340 Mahendra Suri

 

520 BC Panini

800 Mahavira

1340 Narayana

 

200 BC Katyayana

830 Prthudakasvami

1350 Madhava

 

120 AD Yavanesvara

840 Sankara

1370 Paramesvara

 

476 Aryabhata I

870 Sridhara

1444 Nilakantha

 

500 Yativrsabha

920 Aryabhata II

1500 Jyesthadeva

 

505 Varahamihira

940 Vijayanandi

1616 Kamalakara

 

598 Brahmagupta

1019 Sripati

1690 Jagannatha

 

 

http://www-history.mcs.st-andrews.ac.uk/Indexes/Indians.html

 

--- End forwarded message ---