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Friday, July 27, 2007

अबाउट me

about me:
i am piyushdadriwala,very creative,believe in GOD,WROTE WORLD FIRST MIRROR IMAGE BOOK "SHREEMADBHAGVADGITA"BY MY OWN HANDS ALL 18 CHAPTERS,700 VERSES IN TWO LANGUAGES HIDI AND ENGLISH,VERY FOND OF COLLECTION,MAKE CARTOONS AND CARRICTURES,AND LOT MORE.MY EMAILS : pkgdwala@rediffmail.compkgdwala@sify.compiyushdadriwala@gmail.compiyushdadriwala@humlog.comgpalgoo@yahoo.co.inpiyushdadriwala@india.compiyushdadriwala@zapak.compiyushdadriwala@myconnection2wealth.netLONGESTEMAILpkw@abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijk.compiyushdadriwala@breakthru.compiyushdadriwala@blogonfly.compiyushdadriwala@ICQ.mail.compiyushdadriwala.goyal@easy.lapkgdwala1967@indiatimes.comMY PAGESwww.blogme.comwww.piyushda.blogsource.comon blogexplosionwww.mirrorimagebhagvadgita.comwww.piyushdadriwala.whirrl.comwww.geocities.com/gpalgoo/piyushdadriwalawww.piyushdadriwala.onesite.comwww.piyushdadriwala.livejournal.comwww.piyushdadriwala.wordpress.comwww.piyushdadriwala.bravehost.comon technorati.comwww.piyushcreativeblog.comon winkwww.piyushcreative.comon science blogyou will read my creative blogs,reading in thousandswww.piyush.mindsay.comwww.bloglines.com/public/piyushdadriwalawww.DropShots.com/piyushdadriwalawww.piyushdadriwala.myblog.comwww.piyush.busythumbs.comwww.piyushdadriwala.sulekha.comwww.piyushcreation.blog.comwww.piyushcreation.eponym.com/blogsame as blogwirewww.piyushdadriwala.dotphoto.comhttp://piyushdadriwala.diinoweb.comwww.indiatalking.com/blog/piyushdadriwalawww.piyushcreation.bestbulletineboard.comwww.wohho.com/crazypiyushwww.protopage/piyushdadriwalawww.piyushdadriwala.bebo.comwww.myblobbo.com/piyushdadriwalawww.flickr.com/photos/piyushcreativewww.iblogit.com/piyushdadriwalawww.piyushdadriwalamaths.co.inyahoo groupsgroups.yahoo.com/group/truepeoplecreationgroups.yahoo.com/group/thewholeworldourfriendgroup on snapfishtruepeoplecreation.snapfish.comgroup on sulekhaweareallfriendsgoogle grouppiyushcreativeworldit is all about me,if you want to read me just put my name piyushdadriwala in search engine,you can......with lovehttp://www.agloco.com/r/BBDH2036now my new web site which is made by mewww.piyushdadriwala.4t.comwww.profileheaven.piyushdadriwala.com

पियुश्दाद्रिवाला,एस creation

piyushdadriwala,s creation
Piyush Dadriwala
Piyush, born on 10th Feb, 1967, Aquarian belongs to a middle class family in Dadri, Near Noida, elder son of Dr. Devender Kumar Goel and mother Ravikanta. I am diploma Mech Engg. passed in the year 1987, creative, believe in God too much, believe in Love & Friendship, cartoonist and fond of making tarricatures, hobby of collections.
I have a unique art (mirror Image writing in two languages Hindi & English) and have written world first Mirror Image Book "Shreemad Bhagwad Gita" all 18 chapters, 700 verses in Hindi & English, besides this I have written "Shree Durga Sapt Satti" in Sanskrit Language, Sunderkand, Arti Sangrah and "Shree Sai Sach Charitra" (all 51 chapters, 308 pages, more than 1 lakh words), which kept in Sai Mandir, Sonepat for forever for devotees.
I am very much fond of Mathematics, I have done a lot of work in Mathematics, like Points Design of Pyramid & got unique Equations, work on Pascal Triangle, A new triangle "A.P. Right Angled Triangle" in which introduced a new theorum, A very strange Table & Formula for two digits Square & Number Nine.
www.piyush-g.741.com­­­
www.piyushdadriwalam­aths.co.in
pkgdwala@rediffmail.­com
piyushdadriwala@gmai­l.com
creative piyushdadriwala
WHAT ALL GODS HAVE COMMON Edit
Mar 25, 2007, 5:29 pm
1 2 3 4 5 6 7 8 9
A B C D E F G H I
J K L M N O P Q R
S T U V W X Y Z

1. HINDU ( SHREE KRISHNA)
­ 1+8+9+5+5+2+9+9+1+8+­5+1=63=6+3=9
2. MUSLIM (MOHAMMED)
­ 4+6+8+1+4+4+5+4=36=3­+6=9
3. SHIK (GURU NANAK)
7+3+9+3+5+1+5+1+2=36­=3+6=9
4. PARSI (ZARA THUSTRA )
8+1+9+1+2+8+3+1+2+9+­1=45=4+5=9
5.BUDH (GAUTAM)
7+1+3+2+1+4=18=1+8=9­­
6.JAIN (MAHAVIR)
4+1+8+1+4+9+9=36=3+6­=9
7. ESAI (ESA MESSIAH)
5+1+1+4+5+1+1+9+1+8=­36=3+6=9
8. SAI NATH
1+1+9+5+1+2+8=27=2+7­=9
AT LAST BY CAHANCE WHEN I TRY TO CALCULATE MY NAME "PIYUSHDADARIWALA" AS PER THIS METHOD ,GOT NINE......BUT I AM NOT GOD.......BUTI BELIEVE,WITHOUT GOD ,I AM DOG
9. PIYUSHDADRIWALA
7+9+7+3+1+8+4+1+4+9+­9+5+1+3+1=72=7+2=9

I THINK YOU ALL ENJOY,I HAVE MORE,NEXT TIME
LOVE TO ALL
PIYUSHDADRIWALA
www.piyush-g.741.com­­­
www.piyushdadriwalam­aths.co.in

imagination
amazing number nine(piyush constant) Edit
Mar 25, 2007, 5:31 pm
AMAZING NUMBER NINE,(PIYUSH CONSTANT).
IT IS VERY INTERESTING ,IT IS MY OWN SEARCH,I LOVE MATHS,IN THE FUTURE VERY SOON MY OWN BOOK ON MATHS WILL PUBLISH MATHS--- A STUDY(IN HINDI),OR MAY BE IN THE FORM OF WEBSITE.
TAKE ANY NUMBER OF DIGITS,HERE I AM TAKING 25 AND 32,NOW
YOU CAN WRITE THEM IN FOUR WAYS LIKE THAT
25*32=800
25*23=575
52*23=1196
52*32=1664
NOW VERY AMAZING,SUBSTRACT BIGGER ONE TO ANY LOWER,ONE BY ONE
1664-1196=468=4+6+8=­18=1+8=9
1664-575=1089=1+0+8+­9=18=1+8=9
1164-800=864=8+6+4=1­8=1+8=9
1196-575=621=6+2+1=9­­
1196-800=396=3+6+9=1­8=1+8=9
800-575=225=2+2+5=9
ALWAYS NINE,FOR ANY DIGITS,NO BODY CAN COPY ALL RIGITS RESERVED TO PIYUSHDADRIWALA,IT IS JUST MY LOVEY BLOGGERS WHO HAVE INTEREST IN MATHS.LOVE TO ALL
PIYUSHDADRIWALA
www.piyush-g.741.com­­
www.piyushdadriwalam­aths.co.in
you can see all my creations

PIYUSH THOUGHTS
1.TO IMAGINE IS TO HAVE EVERYTHING.
2.A WISE THINKS BEFORE DOING,BUT A MAD.................­...........AFTER.
3.LOVE MAKES THE WAY TO GOD.
4.PRESENT IS PAST IN FUTURE.
5.GOD,BEFORE DYING YOU OURES,AFTER DYING WE YOURS.
6.TIME SAYS,TI-ght-ME, OTHERWISE GOING.
7.PAIN IS SURE IN GAIN.
8.WHO LOVES ALWAYS HATES.
9.WITHOUT GOD A MAN JUST REVERSE OF GOD.................­.......(DOG).
10.A MAN OF GOD BUT A MIND OF A MAN.
11.IN THIS WORLD THERE ARE LOT OF YESTERDAYS,NOT MANY TOMORROWS.
12.LUCK,A DUCK CAN SWIM,FLY AND WALK.
13.LUCK IS AS LOCK
YOU HAVE ITS KEY
CLICK LEFT,IT CLOSES.
CLICK RIGHT,IT OPENS. ­ (READ IT CAREFULLY,AND THINK)
14.MUCH TIME REQUIRED TO BE GOOD,TO BE BAD A LITTLE.
15.WE KNOW GOD,BUT GOD KNOWS US OR NOT WE DO NOT KNOW.
16.LOVE LAUGH AND LIVE LONG LIFE.
17.GOD IS ONE YOU ARE MANY.
18.LOVE IS "O" (+VE),DONATE IT.
19.LIFE IS MIRROR,YOUR WORKS ARE IMAGES.
20.LIFE IS HOUSEOF LOVE,CONFIDENCE,FAIT­H,SATISFACTION,DEVOT­ION,AMBITION,CHARACT­ER,HONESTY,SUCCESS AND POSITIVE ATTITUDE.
WITH LOT OF LOVE
PIYUSHDADRIWALA
www.piyush-g.741.com­­­
pkgdwala@rediffmail.­com
www.piyushdadriwalam­aths.co.in
email@emailaddress.com
love
world first mirror image book "shreemadbhagvadgita­" by piyushdadriwala

MIRROR IMAGED BHAGVADGITA
I AM PIYUSH DADRIWLA,MECH ENGG,VERY CREATIVE ,HOBBY OF COLLECTION,BELIEVE IN GOD,I WROTE GITA IN MIRROR IMAGED BY MY OWN HAND IN TWO LANGUAGES HINDI AND ENGLISH,ALL18 CHAPTERS ,700 VERSES,MEANS WILL READ IT IN FRONT OF MIRROR AND HOPE IT IS WORLD FIRST EVER HAND WRITTEN MIRROR IMAGED( ANY BOOK) "SHREEMADBHAGVADGITA­".HOBBY OF COLLECTION LIKE 10,000 MATCH BOXES,300 CIGARETTE PACKETS,1045 PENS,COINS AND CURRENCIES,AUTOGRAPH­S LIKE AMITABH,SACHIP,RITIQ­UE,LATA,ATAL,RAJIV GANDHI,INDRA GANDHI,ANIL KUMBLE,1983 WEST INDIES CRICKET TEAM,AUSTRALIAN CRICKET TEAM INDIAN WOMEN CRICKET TEAM AND OF MANY PESONALITIES,NEWSPAP­ER AND MAGAZINES COLLECTION,HOBBY OF MAKING CARTOONS AND CARICATURES.
WITH LOT OF LOVE
PIYUSHDADRIWALA
pkgdwala@rediffmail.­com
www.piyush-g.741.com­­­
www.piyushdadriwalam­aths.co.in

gpalgoo@yahoo.co.in
­

पीयूष constant

AMAZING NUMBER NINE,(PIYUSH CONSTANT).
IT IS VERY INTERESTING ,IT IS MY OWN SEARCH,I LOVE MATHS,IN THE FUTURE VERY SOON MY OWN BOOK ON MATHS WILL PUBLISH MATHS--- A STUDY(IN HINDI),OR MAY BE IN THE FORM OF WEBSITE.
TAKE ANY NUMBER OF DIGITS,HERE I AM TAKING 25 AND 32,NOW
YOU CAN WRITE THEM IN FOUR WAYS LIKE THAT
25*32=800
25*23=575
52*23=1196
52*32=1664
NOW VERY AMAZING,SUBSTRACT BIGGER ONE TO ANY LOWER,ONE BY ONE
1664-1196=468=4+6+8=­18=1+8=9
1664-575=1089=1+0+8+­9=18=1+8=9
1164-800=864=8+6+4=1­8=1+8=9
1196-575=621=6+2+1=9­­
1196-800=396=3+6+9=1­8=1+8=9
800-575=225=2+2+5=9
ALWAYS NINE,FOR ANY DIGITS,NO BODY CAN COPY ALL RIGITS RESERVED TO PIYUSHDADRIWALA,IT IS JUST MY LOVEY BLOGGERS WHO HAVE INTEREST IN MATHS.LOVE TO ALL
PIYUSHDADRIWALA
www.piyush-g.741.com­­
www.piyushdadriwalam­aths.co.in
व्व्व.पियुश्दाद्रिवाला.४त्.com

bhaskara

Bhaskara
Born: 1114 in Vijayapura, IndiaDied: 1185 in Ujjain, India
Bhaskara is also known as Bhaskara II or as Bhaskaracharya, this latter name meaning "Bhaskara the Teacher". Since he is known in India as Bhaskaracharya we will refer to him throughout this article by that name. Bhaskaracharya's father was a Brahman named Mahesvara. Mahesvara himself was famed as an astrologer. This happened frequently in Indian society with generations of a family being excellent mathematicians and often acting as teachers to other family members.
Bhaskaracharya became head of the astronomical observatory at Ujjain, the leading mathematical centre in India at that time. Outstanding mathematicians such as Varahamihira and Brahmagupta had worked there and built up a strong school of mathematical astronomy.
In many ways Bhaskaracharya represents the peak of mathematical knowledge in the 12th century. He reached an understanding of the number systems and solving equations which was not to be achieved in Europe for several centuries.
Six works by Bhaskaracharya are known but a seventh work, which is claimed to be by him, is thought by many historians to be a late forgery. The six works are: Lilavati (The Beautiful) which is on mathematics; Bijaganita (Seed Counting or Root Extraction) which is on algebra; the Siddhantasiromani which is in two parts, the first on mathematical astronomy with the second part on the sphere; the Vasanabhasya of Mitaksara which is Bhaskaracharya's own commentary on the Siddhantasiromani ; the Karanakutuhala (Calculation of Astronomical Wonders) or Brahmatulya which is a simplified version of the Siddhantasiromani ; and the Vivarana which is a commentary on the Shishyadhividdhidatantra of Lalla. It is the first three of these works which are the most interesting, certainly from the point of view of mathematics, and we will concentrate on the contents of these.
Given that he was building on the knowledge and understanding of Brahmagupta it is not surprising that Bhaskaracharya understood about zero and negative numbers. However his understanding went further even than that of Brahmagupta. To give some examples before we examine his work in a little more detail we note that he knew that x2 = 9 had two solutions. He also gave the formula

Bhaskaracharya studied Pell's equation px2 + 1 = y2 for p = 8, 11, 32, 61 and 67. When p = 61 he found the solutions x = 226153980, y = 1776319049. When p = 67 he found the solutions x = 5967, y = 48842. He studied many Diophantine problems.
Let us first examine the Lilavati. First it is worth repeating the story told by Fyzi who translated this work into Persian in 1587. We give the story as given by Joseph in [5]:-
Lilavati was the name of Bhaskaracharya's daughter. From casting her horoscope, he discovered that the auspicious time for her wedding would be a particular hour on a certain day. He placed a cup with a small hole at the bottom of the vessel filled with water, arranged so that the cup would sink at the beginning of the propitious hour. When everything was ready and the cup was placed in the vessel, Lilavati suddenly out of curiosity bent over the vessel and a pearl from her dress fell into the cup and blocked the hole in it. The lucky hour passed without the cup sinking. Bhaskaracharya believed that the way to console his dejected daughter, who now would never get married, was to write her a manual of mathematics!
This is a charming story but it is hard to see that there is any evidence for it being true. It is not even certain that Lilavati was Bhaskaracharya's daughter. There is also a theory that Lilavati was Bhaskaracharya's wife. The topics covered in the thirteen chapters of the book are: definitions; arithmetical terms; interest; arithmetical and geometrical progressions; plane geometry; solid geometry; the shadow of the gnomon; the kuttaka; combinations.
In dealing with numbers Bhaskaracharya, like Brahmagupta before him, handled efficiently arithmetic involving negative numbers. He is sound in addition, subtraction and multiplication involving zero but realised that there were problems with Brahmagupta's ideas of dividing by zero. Madhukar Mallayya in [14] argues that the zero used by Bhaskaracharya in his rule (a.0)/0 = a, given in Lilavati, is equivalent to the modern concept of a non-zero "infinitesimal". Although this claim is not without foundation, perhaps it is seeing ideas beyond what Bhaskaracharya intended.
Bhaskaracharya gave two methods of multiplication in his Lilavati. We follow Ifrah who explains these two methods due to Bhaskaracharya in [4]. To multiply 325 by 243 Bhaskaracharya writes the numbers thus:
243 243 243
3 2 5
-------------------
Now working with the rightmost of the three sums he computed 5 times 3 then 5 times 2 missing out the 5 times 4 which he did last and wrote beneath the others one place to the left. Note that this avoids making the "carry" in ones head.
243 243 243
3 2 5
-------------------
1015
20
-------------------
Now add the 1015 and 20 so positioned and write the answer under the second line below the sum next to the left.
243 243 243
3 2 5
-------------------
1015
20
-------------------
1215
Work out the middle sum as the right-hand one, again avoiding the "carry", and add them writing the answer below the 1215 but displaced one place to the left.
243 243 243
3 2 5
-------------------
4 6 1015
8 20
-------------------
1215
486
Finally work out the left most sum in the same way and again place the resulting addition one place to the left under the 486.
243 243 243
3 2 5
-------------------
6 9 4 6 1015
12 8 20
-------------------
1215
486
729
-------------------
Finally add the three numbers below the second line to obtain the answer 78975.
243 243 243
3 2 5
-------------------
6 9 4 6 1015
12 8 20
-------------------
1215
486
729
-------------------
78975
Despite avoiding the "carry" in the first stages, of course one is still faced with the "carry" in this final addition.
The second of Bhaskaracharya's methods proceeds as follows:
325
243
--------
Multiply the bottom number by the top number starting with the left-most digit and proceeding towards the right. Displace each row one place to start one place further right than the previous line. First step
325
243
--------
729
Second step
325
243
--------
729
486
Third step, then add
325
243
--------
729
486
1215
--------
78975
Bhaskaracharya, like many of the Indian mathematicians, considered squaring of numbers as special cases of multiplication which deserved special methods. He gave four such methods of squaring in Lilavati.
Here is an example of explanation of inverse proportion taken from Chapter 3 of the Lilavati. Bhaskaracharya writes:-
In the inverse method, the operation is reversed. That is the fruit to be multiplied by the augment and divided by the demand. When fruit increases or decreases, as the demand is augmented or diminished, the direct rule is used. Else the inverse.
Rule of three inverse: If the fruit diminish as the requisition increases, or augment as that decreases, they, who are skilled in accounts, consider the rule of three to be inverted. When there is a diminution of fruit, if there be increase of requisition, and increase of fruit if there be diminution of requisition, then the inverse rule of three is employed.
As well as the rule of three, Bhaskaracharya discusses examples to illustrate rules of compound proportions, such as the rule of five (Pancarasika), the rule of seven (Saptarasika), the rule of nine (Navarasika), etc. Bhaskaracharya's examples of using these rules are discussed in [15].
An example from Chapter 5 on arithmetical and geometrical progressions is the following:-
Example: On an expedition to seize his enemy's elephants, a king marched two yojanas the first day. Say, intelligent calculator, with what increasing rate of daily march did he proceed, since he reached his foe's city, a distance of eighty yojanas, in a week?
Bhaskaracharya shows that each day he must travel 22/7 yojanas further than the previous day to reach his foe's city in 7 days.
An example from Chapter 12 on the kuttaka method of solving indeterminate equations is the following:-
Example: Say quickly, mathematician, what is that multiplier, by which two hundred and twenty-one being multiplied, and sixty-five added to the product, the sum divided by a hundred and ninety-five becomes exhausted.
Bhaskaracharya is finding integer solution to 195x = 221y + 65. He obtains the solutions (x,y) = (6,5) or (23,20) or (40, 35) and so on.
In the final chapter on combinations Bhaskaracharya considers the following problem. Let an n-digit number be represented in the usual decimal form as
(*) d1d2... dn
where each digit satisfies 1 dj 9, j = 1, 2, ... , n. Then Bhaskaracharya's problem is to find the total number of numbers of the form (*) that satisfy
d1 + d2 + ... + dn = S.
In his conclusion to Lilavati Bhaskaracharya writes:-
Joy and happiness is indeed ever increasing in this world for those who have Lilavati clasped to their throats, decorated as the members are with neat reduction of fractions, multiplication and involution, pure and perfect as are the solutions, and tasteful as is the speech which is exemplified.
The Bijaganita is a work in twelve chapters. The topics are: positive and negative numbers; zero; the unknown; surds; the kuttaka; indeterminate quadratic equations; simple equations; quadratic equations; equations with more than one unknown; quadratic equations with more than one unknown; operations with products of several unknowns; and the author and his work.
Having explained how to do arithmetic with negative numbers, Bhaskaracharya gives problems to test the abilities of the reader on calculating with negative and affirmative quantities:-
Example: Tell quickly the result of the numbers three and four, negative or affirmative, taken together; that is, affirmative and negative, or both negative or both affirmative, as separate instances; if thou know the addition of affirmative and negative quantities.
Negative numbers are denoted by placing a dot above them:-
The characters, denoting the quantities known and unknown, should be first written to indicate them generally; and those, which become negative should be then marked with a dot over them.
Example: Subtracting two from three, affirmative from affirmative, and negative from negative, or the contrary, tell me quickly the result ...
In Bijaganita Bhaskaracharya attempted to improve on Brahmagupta's attempt to divide by zero (and his own description in Lilavati ) when he wrote:-
A quantity divided by zero becomes a fraction the denominator of which is zero. This fraction is termed an infinite quantity. In this quantity consisting of that which has zero for its divisor, there is no alteration, though many may be inserted or extracted; as no change takes place in the infinite and immutable God when worlds are created or destroyed, though numerous orders of beings are absorbed or put forth.
So Bhaskaracharya tried to solve the problem by writing n/0 = ∞. At first sight we might be tempted to believe that Bhaskaracharya has it correct, but of course he does not. If this were true then 0 times ∞ must be equal to every number n, so all numbers are equal. The Indian mathematicians could not bring themselves to the point of admitting that one could not divide by zero.
Equations leading to more than one solution are given by Bhaskaracharya:-
Example: Inside a forest, a number of apes equal to the square of one-eighth of the total apes in the pack are playing noisy games. The remaining twelve apes, who are of a more serious disposition, are on a nearby hill and irritated by the shrieks coming from the forest. What is the total number of apes in the pack?
The problem leads to a quadratic equation and Bhaskaracharya says that the two solutions, namely 16 and 48, are equally admissible.
The kuttaka method to solve indeterminate equations is applied to equations with three unknowns. The problem is to find integer solutions to an equation of the form ax + by + cz = d. An example he gives is:-
Example: The horses belonging to four men are 5, 3, 6 and 8. The camels belonging to the same men are 2, 7, 4 and 1. The mules belonging to them are 8, 2, 1 and 3 and the oxen are 7, 1, 2 and 1. all four men have equal fortunes. Tell me quickly the price of each horse, camel, mule and ox.
Of course such problems do not have a unique solution as Bhaskaracharya is fully aware. He finds one solution, which is the minimum, namely horses 85, camels 76, mules 31 and oxen 4.
Bhaskaracharya's conclusion to the Bijaganita is fascinating for the insight it gives us into the mind of this great mathematician:-
A morsel of tuition conveys knowledge to a comprehensive mind; and having reached it, expands of its own impulse, as oil poured upon water, as a secret entrusted to the vile, as alms bestowed upon the worthy, however little, so does knowledge infused into a wise mind spread by intrinsic force.
It is apparent to men of clear understanding, that the rule of three terms constitutes arithmetic and sagacity constitutes algebra. Accordingly I have said ... The rule of three terms is arithmetic; spotless understanding is algebra. What is there unknown to the intelligent? Therefore for the dull alone it is set forth.
The Siddhantasiromani is a mathematical astronomy text similar in layout to many other Indian astronomy texts of this and earlier periods. The twelve chapters of the first part cover topics such as: mean longitudes of the planets; true longitudes of the planets; the three problems of diurnal rotation; syzygies; lunar eclipses; solar eclipses; latitudes of the planets; risings and settings; the moon's crescent; conjunctions of the planets with each other; conjunctions of the planets with the fixed stars; and the patas of the sun and moon.
The second part contains thirteen chapters on the sphere. It covers topics such as: praise of study of the sphere; nature of the sphere; cosmography and geography; planetary mean motion; eccentric epicyclic model of the planets; the armillary sphere; spherical trigonometry; ellipse calculations; first visibilities of the planets; calculating the lunar crescent; astronomical instruments; the seasons; and problems of astronomical calculations.
There are interesting results on trigonometry in this work. In particular Bhaskaracharya seems more interested in trigonometry for its own sake than his predecessors who saw it only as a tool for calculation. Among the many interesting results given by Bhaskaracharya are:
sin(a + b) = sin a cos b + cos a sin b
and
sin(a - b) = sin a cos b - cos a sin b.
Bhaskaracharya rightly achieved an outstanding reputation for his remarkable contribution. In 1207 an educational institution was set up to study Bhaskaracharya's works. A medieval inscription in an Indian temple reads:-
Triumphant is the illustrious Bhaskaracharya whose feats are revered by both the wise and the learned. A poet endowed with fame and religious merit, he is like the crest on a peacock.

ई लोवे नुम्बेर निने,BECOZ

ई लोवे नुम्बेर निने बेकाउसे
१.ए=मक(२)
२.अल गोड्स हवे कोम्मों ----निने
३.पीयूष कोन्स्तंत
४.निने ---प्लानेट्स
५.निने --- गोद्देस
६.कोउन्तिंग व्हिच वी काउंट १ तो ९ तहत आईएस व्रोंग,आईटी आईएस इन मय ओपिनिओं ० तो ९।
थे फार्मूला ऑफ़ एइस्तें ए=मक(२),क आईएस स्पीड ऑफ़ लाइट तहत आईएस ३*१०(८),इफ यू मुल्त्प्ल्य नुम्बेर निने विथ अन्य नंबर्स ऑफ़ दिगिट्स यू विल अल्वाय्स गेट सुम ऑफ़ दिगिट्स निने,आईटी मांस थे व्होले वर्ल्ड आईएस देपेंद ओं निने,
इन फुतुरे वहत हप्पेनेद,इफ थे ग्लोबल वार्मिंग इन्क्रेअसे अस आईटी आईएस.....मांस ओर एक्षिस्तेन्के पेर्हप्स..........
पियुश्दाद्रिवाला

व्व्व.पियुश्दाद्रिवालामाथ्स.को.in

VIJAYANANDI

Vijayanandi
Born: about 940 in Benares (now Varanasi), IndiaDied: about 1010 in India
Vijayanandi (or Vijayanandin) was the son of Jayananda. He was born into the Brahman caste which meant he was from the highest ranking caste of Hindu priests. He was an Indian mathematician and astronomer whose most famous work was the Karanatilaka. We should note that there was another astronomer named Vijayanandi who was mentioned by Varahamihira in one of his works. Since Varahamihira wrote around 550 and the Karanatilaka was written around 966, there must be two astronomers both named "Vijayanandi".
The Karanatilaka has not survived in its original form but we know of the text through an Arabic translation by al-Biruni. It is a work in fourteen chapters covering the standard topics of Indian astronomy. It deals with the topics of: units of time measurement; mean and true longitudes of the sun and moon; the length of daylight; mean longitudes of the five planets; true longitudes of the five planets; the three problems of diurnal rotation; lunar eclipses, solar eclipses; the projection of eclipses; first visibility of the planets; conjunctions of the planets with each other and with fixed stars; the moon's crescent; and the patas of the moon and sun.
The Indians had a cosmology which was based on long periods of time with astronomical events occurring a certain whole number of times within the cycles. This system led to much work on integer solutions of equations and their application to astronomy. In particular there was, according to Aryabhata I, a basic period of 4320000 years called a mahayuga and it was assumed that the sun, the moon, their apsis and node, and the planets reached perfect conjunctions after this period. Hence it was assumed that the periods were rational multiples of each other.
All the planets and the node and apsis of the moon and sun had to have an integer number of revolutions in the mahayuga. Many Indian astronomers proposed different values for these integral numbers of revolutions. For the number of revolutions of the apsis and node of the moon per mahayuga, Aryabhata I proposed 488219 and 232226, respectively.
However Vijayanandi changed these numbers to 488211 and 232234. The reasons for giving the new numbers is unclear. Like other Indian astronomers, Vijayanandi made contributions to trigonometry and it appears that his calculation of the periods was computed by using tables of sines and versed sines. It is significant that accuracy was need in trigonometric tables to give accurate astronomical theories and this motivated many of the Indian mathematicians to produce more accurate methods of approximating entries in tables.

संकरा NARAYANA

Sankara Narayana
Born: about 840 in IndiaDied: about 900 in India
Sankara Narayana (or Shankaranarayana) was an Indian astronomer and mathematician. He was a disciple of the astronomer and mathematician Govindasvami. His most famous work was the Laghubhaskariyavivarana which was a commentary on the Laghubhaskariya of Bhaskara I which in turn is based on the work of Aryabhata I.
The Laghubhaskariyavivarana was written by Sankara Narayana in 869 AD for the author writes in the text that it is written in the Shaka year 791 which translates to a date AD by adding 78. It is a text which covers the standard mathematical methods of Aryabhata I such as the solution of the indeterminate equation by = ax c (a, b, c integers) in integers which is then applied to astronomical problems. The standard Indian method involves using the Euclidean algorithm. It is called kuttakara ("pulveriser") but the term eventually came to have a more general meaning like "algebra". The paper [2] examines this method. The reader who is wondering what the determination of "mati" means in the title of the paper [2] then it refers to the optional number in a guessed solution and it is a feature which differs from the original method as presented by Bhaskara I.
Perhaps the most unusual feature of the Laghubhaskariyavivarana is the use of katapayadi numeration as well as the place-value Sanskrit numerals which Sankara Narayana frequently uses. Sankara Narayana is the first author known to use katapayadi numeration with this name but he did not invent it for it appears to be identical to a system invented earlier which was called varnasamjna. The numeration system varnasamjna was almost certainly invented by the astronomer Haridatta, and it was explained by him in a text which many historians believe was written in 684 but this would contradict what Sankara Narayana himself writes. This point is discussed below. First we should explain ideas behind Sankara Narayana's katapayadi numeration.
The system is based on writing numbers using the letters of the Indian alphabet. Let us quote from [1]:-
... the numerical attribution of syllables corresponds to the following rule, according to the regular order of succession of the letters of the Indian alphabet: the first nine letters represent the numbers 1 to 9 while the tenth corresponds to zero; the following nine letters also receive the values 1 to 9 whilst the following letter has the value zero; the next five represent the first five units; and the last eight represent the numbers 1 to 8.
Under this system 1 to 5 are represented by four different letters. For example 1 is represented by the letters ka, ta, pa, ya which give the system its name (ka, ta, pa, ya becomes katapaya). Then 6, 7, 8 are represented by three letters and finally nine and zero are represented by two letters.
The system was a spoken one in the sense that consonants and vowels which are not vocalised have no numerical value. The system is a place-value system with zero but one may reasonably ask why such an apparently complicated numeral system might ever come to be invented. Well the answer must be that it lead to easily remembered mnemonics. In fact many different "words" could represent the same number and this was highly useful for works written in verse as the Indian texts tended to be.
Let us return to the interesting point about the date of Haridatta. Very unusually for an Indian text, Sankara Narayana expresses his thanks to those who have gone before him and developed the ideas about which he is writing. This in itself is not so unusual but the surprise here is that Sankara Narayana claims to give the list in chronological order. His list is
Aryabhata IVarahamihiraBhaskara IGovindasvamiHaridatta
[Note that we have written Bhaskara I where Sankara Narayana simply wrote Bhaskara. The more famous Bhaskara II lived nearly 300 years after Sankara Narayana.]
The chronological order in the list agrees with the dates we have for the first four of these mathematicians. However, putting Haridatta after Govindasvami would seem an unlikely mistake for Sankara Narayana to make if Haridatta really did write his text in 684 since Sankara Narayana was himself a disciple of Govindasvami. If the dating given by Sankara Narayana is correct then katapayadi numeration had been invented only a few years before he wrote his text.

MAHAVIRA

Mahavira
Born: about 800 in possibly Mysore, IndiaDied: about 870 in India
Mahavira (or Mahaviracharya meaning Mahavira the Teacher) was of the Jaina religion and was familiar with Jaina mathematics. He worked in Mysore in southern Indian where he was a member of a school of mathematics. If he was not born in Mysore then it is very likely that he was born close to this town in the same region of India. We have essentially no other biographical details although we can gain just a little of his personality from the acknowledgement he gives in the introduction to his only known work, see below. However Jain in [10] mentions six other works which he credits to Mahavira and he emphasises the need for further research into identifying the complete list of his works.
The only known book by Mahavira is Ganita Sara Samgraha, dated 850 AD, which was designed as an updating of Brahmagupta's book. Filliozat writes [6]:-
This book deals with the teaching of Brahmagupta but contains both simplifications and additional information. ... Although like all Indian versified texts, it is extremely condensed, this work, from a pedagogical point of view, has a significant advantage over earlier texts.
It consisted of nine chapters and included all mathematical knowledge of mid-ninth century India. It provides us with the bulk of knowledge which we have of Jaina mathematics and it can be seen as in some sense providing an account of the work of those who developed this mathematics. There were many Indian mathematicians before the time of Mahavira but, perhaps surprisingly, their work on mathematics is always contained in texts which discuss other topics such as astronomy. The Ganita Sara Samgraha by Mahavira is the earliest Indian text which we possess which is devoted entirely to mathematics.
In the introduction to the work Mahavira paid tribute to the mathematicians whose work formed the basis of his book. These mathematicians included Aryabhata I, Bhaskara I, and Brahmagupta. Mahavira writes:-
With the help of the accomplished holy sages, who are worthy to be worshipped by the lords of the world ... I glean from the great ocean of the knowledge of numbers a little of its essence, in the manner in which gems are picked from the sea, gold from the stony rock and the pearl from the oyster shell; and I give out according to the power of my intelligence, the Sara Samgraha, a small work on arithmetic, which is however not small in importance.
The nine chapters of the Ganita Sara Samgraha are:
1. Terminology2. Arithmetical operations3. Operations involving fractions4. Miscellaneous operations5. Operations involving the rule of three6. Mixed operations7. Operations relating to the calculations of areas8. Operations relating to excavations9. Operations relating to shadows
Throughout the work a place-value system with nine numerals is used or sometimes Sanskrit numeral symbols are used. Of interest in Chapter 1 regarding the development of a place-value number system is Mahavira's description of the number 12345654321 which he obtains after a calculation. He describes the number as:-
... beginning with one which then grows until it reaches six, then decreases in reverse order.
Notice that this wording makes sense to us using a place-value system but would not make sense in other systems. It is a clear indication that Mahavira is at home with the place-value number system.
Among topics Mahavira discussed in his treatise was operations with fractions including methods to decompose integers and fractions into unit fractions. For example
2/17 = 1/12 + 1/51 + 1/68.
He examined methods of squaring numbers which, although a special case of multiplying two numbers, can be computed using special methods. He also discussed integer solutions of first degree indeterminate equation by a method called kuttaka. The kuttaka (or the "pulveriser") method is based on the use of the Euclidean algorithm but the method of solution also resembles the continued fraction process of Euler given in 1764. The work kuttaka, which occurs in many of the treatises of Indian mathematicians of the classical period, has taken on the more general meaning of "algebra".
An example of a problem given in the Ganita Sara Samgraha which leads to indeterminate linear equations is the following:
Three merchants find a purse lying in the road. One merchant says "If I keep the purse, I shall have twice as much money as the two of you together". "Give me the purse and I shall have three times as much" said the second merchant. The third merchant said "I shall be much better off than either of you if I keep the purse, I shall have five times as much as the two of you together". How much money is in the purse? How much money does each merchant have?
If the first merchant has x, the second y, the third z and p is the amount in the purse then
p + x = 2(y + z), p + y = 3(x + z), p + z = 5(x + y).
There is no unique solution but the smallest solution in positive integers is p = 15, x = 1, y = 3, z = 5. Any solution in positive integers is a multiple of this solution as Mahavira claims.
Mahavira gave special rules for the use of permutations and combinations which was a topic of special interest in Jaina mathematics. He also described a process for calculating the volume of a sphere and one for calculating the cube root of a number. He looked at some geometrical results including right-angled triangles with rational sides, see for example [4].
Mahavira also attempts to solve certain mathematical problems which had not been studied by other Indian mathematicians. For example, he gave an approximate formula for the area and the perimeter of an ellipse. In [8] Hayashi writes:-
The formulas for a conch-like figure have so far been found only in the works of Mahavira and Narayana.
It is reasonable to ask what a "conch-like figure" is. It is two unequal semicircles (with diameters AB and BC) stuck together along their diameters. Although it might be reasonable to suppose that the perimeter might be obtained by considering the semicircles, Hayashi claims that the formulae obtained:-
... were most probably obtained not from the two semicircles AB and BC.

LALLA

Lalla
Born: about 720 in IndiaDied: about 790 in India
Lalla's father was Trivikrama Bhatta and Trivikrama's father, Lalla's paternal grandfather, was named Samba. Lalla was an Indian astronomer and mathematician who followed the tradition of Aryabhata I. Lalla's most famous work was entitled Shishyadhividdhidatantra. This major treatise was in two volumes. The first volume, On the computation of the positions of the planets, was in thirteen chapters and covered topics such as: mean longitudes of the planets; true longitudes of the planets; the three problems of diurnal rotation; lunar eclipses; solar eclipses; syzygies; risings and settings; the shadow of the moon; the moon's crescent; conjunctions of the planets with each other; conjunctions of the planets with the fixed stars; the patas of the moon and sun, and a final chapter in the first volume which forms a conclusion.
The second volume was On the sphere. In this volume Lalla examined topics such as: graphical representation; the celestial sphere; the principle of mean motion; the terrestrial sphere; motions and stations of the planets; geography; erroneous knowledge; instruments; and finally selected problems.
In Shishyadhividdhidatantra Lalla uses Sanskrit numerical symbols. Ifrah writes in [2]:-
... over the centuries, Sanskrit has lent itself admirably to the rules of prosody and versification. This explains why Indian astronomers [like Lalla] favoured the use of Sanskrit numerical symbols, based on a complex symbolism which was extraordinarily fertile and sophisticated, possessing as it did an almost limitless choice of synonyms.
Despite writing the most famous treatise giving the views of Aryabhata I, Lalla did not accept his theory given in the Aryabhatiya that the earth rotated. Lalla argues in his commentary, like many other Indian astronomers before him such as Varahamihira and Brahmagupta, that if the earth rotated then the speed would have to be such that one would have to ask how do the bees or birds flying in the sky come back to their nests? In fact Lalla misinterpreted some of Aryabhata I's statements about the rotating earth. One has to assume that the idea appeared so impossible to him that he just could not appreciate Aryabhata I's arguments. As Chatterjee writes in [3], Lalla in his commentary:-
... did not interpret the relevant verses in the way meant by Aryabhata I.
Astrology at this time was based on astronomical tables and often the horoscopes allow one to identify the tables used. Some Arabic horoscopes were based on astronomical tables calculated in India. The most frequently used tables were by Aryabhata I. Lalla improved on these tables and he produced a set of corrections for the Moon's longitude. One aspect of Aryabhata I's work which Lalla did follow was his value of π. Lalla uses π = 62832/20000, i.e. π = 3.1416 which is a value correct to the fourth decimal place.
Lalla also wrote a commentary on Khandakhadyaka, a work of Brahmagupta. Lalla's commentary has not survived but there is another work on astrology by Lalla which has survived, namely the Jyotisaratnakosa. This was a very popular work which was the main one on the subject in India for around 300 years.

GOVINDASVAMI

Govindasvami
Born: about 800 in IndiaDied: about 860 in India
Govindasvami (or Govindasvamin) was an Indian mathematical astronomer whose most famous treatise was a commentary on the Mahabhaskariya of Bhaskara I.
Bhaskara I wrote the Mahabhaskariya in about 600 A. D. It is an eight chapter work on Indian mathematical astronomy and includes topics which were fairly standard for such works at this time. It discussed topics such as the longitudes of the planets, conjunctions of the planets with each other and with bright stars, eclipses of the sun and the moon, risings and settings, and the lunar crescent.
Govindasvami wrote the Bhasya in about 830 which was a commentary on the Mahabhaskariya. In Govindasvami's commentary there appear many examples of using a place-value Sanskrit system of numerals. One of the most interesting aspects of the commentary, however, is Govindasvami's construction of a sine table.
Indian mathematicians and astronomers constructed sine table with great precision. They were used to calculate the positions of the planets as accurately as possible so had to be computed with high degrees of accuracy. Govindasvami considered the sexagesimal fractional parts of the twenty-four tabular sine differences from the Aryabhatiya. These lead to more correct sine values at intervals of 90 /24 = 3 45 '. In the commentary Govindasvami found certain other empirical rules relating to computations of sine differences in the argumental range of 60 to 90 degrees. Both of the references [1] and [2] are concerned with the sine tables in Govindasvami's work

अर्याभात II

Aryabhata II
Born: about 920 in IndiaDied: about 1000 in India
Essentially nothing is known of the life of Aryabhata II. Historians have argued about his date and have come up with many different theories. In [1] Pingree gives the date for his main publications as being between 950 and 1100. This is deduced from the usual arguments such as which authors Aryabhata II refers to and which refer to him. G R Kaye argued in 1910 that Aryabhata II lived before al-Biruni but Datta [2] in 1926 showed that these dates were too early.
The article [3] argues for a date of about 950 for Aryabhata II's main work, the Mahasiddhanta, but R Billiard has proposed a date for Aryabhata II in the sixteenth century. Most modern historians, however, consider the most likely dates for his main work as around 950 and we have given very approximate dates for his birth and death based on this hypothesis. See [7] for a fairly recent discussion of this topic.
The most famous work by Aryabhata II is the Mahasiddhanta which consists of eighteen chapters. The treatise is written in Sanskrit verse and the first twelve chapters form a treatise on mathematical astronomy covering the usual topics that Indian mathematicians worked on during this period. The topics included in these twelve chapters are: the longitudes of the planets, eclipses of the sun and moon, the projection of eclipses, the lunar crescent, the rising and setting of the planets, conjunctions of the planets with each other and with the stars.
The remaining six chapters of the Mahasiddhanta form a separate part entitled On the sphere. It discusses topics such as geometry, geography and algebra with applications to the longitudes of the planets.
In Mahasiddhanta Aryabhata II gives in about twenty verses detailed rules to solve the indeterminate equation: by = ax + c. The rules apply in a number of different cases such as when c is positive, when c is negative, when the number of the quotients of the mutual divisions is even, when this number of quotients is odd, etc. Details of Aryabhata II's method are given in [6].
Aryabhata II also gave a method to calculate the cube root of a number, but his method was not new, being based on that given many years earlier by Aryabhata I, see for example [5].
Aryabhata II constructed a sine table correct up to five decimal places when measured in decimal parts of the radius, see [4]। Indian mathematicians were very interested in giving accurate sine tables since they were used to calculate the planetary positions as accurately as possible.
PIYUSHDADRIWALA

अर्याभात II

Aryabhata II
Born: about 920 in IndiaDied: about 1000 in India
Essentially nothing is known of the life of Aryabhata II. Historians have argued about his date and have come up with many different theories. In [1] Pingree gives the date for his main publications as being between 950 and 1100. This is deduced from the usual arguments such as which authors Aryabhata II refers to and which refer to him. G R Kaye argued in 1910 that Aryabhata II lived before al-Biruni but Datta [2] in 1926 showed that these dates were too early.
The article [3] argues for a date of about 950 for Aryabhata II's main work, the Mahasiddhanta, but R Billiard has proposed a date for Aryabhata II in the sixteenth century. Most modern historians, however, consider the most likely dates for his main work as around 950 and we have given very approximate dates for his birth and death based on this hypothesis. See [7] for a fairly recent discussion of this topic.
The most famous work by Aryabhata II is the Mahasiddhanta which consists of eighteen chapters. The treatise is written in Sanskrit verse and the first twelve chapters form a treatise on mathematical astronomy covering the usual topics that Indian mathematicians worked on during this period. The topics included in these twelve chapters are: the longitudes of the planets, eclipses of the sun and moon, the projection of eclipses, the lunar crescent, the rising and setting of the planets, conjunctions of the planets with each other and with the stars.
The remaining six chapters of the Mahasiddhanta form a separate part entitled On the sphere. It discusses topics such as geometry, geography and algebra with applications to the longitudes of the planets.
In Mahasiddhanta Aryabhata II gives in about twenty verses detailed rules to solve the indeterminate equation: by = ax + c. The rules apply in a number of different cases such as when c is positive, when c is negative, when the number of the quotients of the mutual divisions is even, when this number of quotients is odd, etc. Details of Aryabhata II's method are given in [6].
Aryabhata II also gave a method to calculate the cube root of a number, but his method was not new, being based on that given many years earlier by Aryabhata I, see for example [5].
Aryabhata II constructed a sine table correct up to five decimal places when measured in decimal parts of the radius, see [4]। Indian mathematicians were very interested in giving accurate sine tables since they were used to calculate the planetary positions as accurately as possible.
PIYUSHDADRIWALA

भास्कर I

Bhaskara I
Born: about 600 in (possibly) Saurastra (modern Gujarat state), IndiaDied: about 680 in (possibly) Asmaka, India
We have very little information about Bhaskara I's life except what can be deduced from his writings. Shukla deduces from the fact that Bhaskara I often refers to the Asmakatantra instead of the Aryabhatiya that he must have been working in a school of mathematicians in Asmaka which was probably in the Nizamabad District of Andhra Pradesh. If this is correct, and it does seem quite likely, then the school in Asmaka would have been a collection of scholars who were followers of Aryabhata I and of course this fits in well with the fact that Bhaskara I himself was certainly a follower of Aryabhata I.
There are other references to places in India in Bhaskara's writings. For example he mentions Valabhi (today Vala), the capital of the Maitraka dynasty in the 7th century, and Sivarajapura, which were both in Saurastra which today is the Gujarat state of India on the west coast of the continent. Also mentioned are Bharuch (or Broach) in southern Gujarat and Thanesar in the eastern Punjab which was ruled by Harsa for 41 years from 606. Harsa was the preeminent ruler in north India through the first half of Bhaskara I's life. A reasonable guess would be that Bhaskara was born in Saurastra and later moved to Asmaka.
Bhaskara I was an author of two treatises and commentaries to the work of Aryabhata I. His works are the Mahabhaskariya, the Laghubhaskariya and the Aryabhatiyabhasya. The Mahabhaskariya is an eight chapter work on Indian mathematical astronomy and includes topics which were fairly standard for such works at this time. It discusses topics such as: the longitudes of the planets; conjunctions of the planets with each other and with bright stars; eclipses of the sun and the moon; risings and settings; and the lunar crescent.
Bhaskara I included in his treatise the Mahabhaskariya three verses which give an approximation to the trigonometric sine function by means of a rational fraction. These occur in Chapter 7 of the work. The formula which Bhaskara gives is amazingly accurate and use of the formula leads to a maximum error of less than one percent. The formula is
sin x = 16x (π - x)/[5π2 - 4x (π - x)]
and Bhaskara attributes the work as that of Aryabhata I. We have computed the values given by the formula and compared it with the correct value for sin x for x from 0 to π/2 in steps of π/20.
x = 0
formula = 0.00000
sin x = 0.00000
error = 0.00000
x = π/20
formula = 0.15800
sin x = 0.15643
error = 0.00157
x = π/10
formula = 0.31034
sin x = 0.30903
error = 0.00131
x = 3π/20
formula = 0.45434
sin x = 0.45399
error = 0.00035
x = π/5
formula = 0.58716
sin x = 0.58778
error = -0.00062
x = π/4
formula = 0.70588
sin x = 0.70710
error = -0.00122
x = π/10
formula = 0.80769
sin x = 0.80903
error = -0.00134
x = 7π/20
formula = 0.88998
sin x = 0.89103
error = -0.00105
x = 2π/5
formula = 0.95050
sin x = 0.95105
error = -0.00055
x = 9π/20
formula = 0.98753
sin x = 0.98769
error = -0.00016
x = π/2
formula = 1.00000
sin x = 1.00000
error = 0.00000In 629 Bhaskara I wrote a commentary, the Aryabhatiyabhasya, on the Aryabhatiya by Aryabhata I. The Aryabhatiya contains 33 verses dealing with mathematics, the remainder of the work being concerned with mathematical astronomy. The commentary by Bhaskara I is only on the 33 verses of mathematics. He considers problems of indeterminate equations of the first degree and trigonometric formulae. In the course of discussions of the Aryabhatiya, Bhaskara I expressed his idea on how one particular rectangle can be treated as a cyclic quadrilateral. He was the first to open discussion on quadrilaterals with all the four sides unequal and none of the opposite sides parallel.
One of the approximations used for π for many centuries was √10. Bhaskara I criticised this approximation. He regretted that an exact measure of the circumference of a circle in terms of diameter was not available and he clearly believed that π was not rational.
In [11], [12], [13] and [14] Shukla discusses some features of Bhaskara's mathematics such as: numbers and symbolism, the classification of mathematics, the names and solution methods of equations of the first degree, quadratic equations, cubic equations and equations with more than one unknown, symbolic algebra, unusual and special terms in Bhaskara's work, weights and measures, the Euclidean algorithm method of solving linear indeterminate equations, examples given by Bhaskara I illustrating Aryabhata I's rules, certain tables for solving an equation occurring in astronomy, and reference made by Bhaskara I to the works of earlier Indian mathematicians।
PIYUSHDADRIWALA