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Srinivasa Ramanuja


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Just now, AnotherTeluguBidda said:

Is there anyone in this db who could explain his findings to normal people like me.....or where to start to understand them?

There are many great people in history from einsten to stevejobs, from ramanujan to nobody at present generation from india. We dont have to appreciate and remember them everyday , we are in modern times appreciate calculators as we dont need to do math anymore 

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1 minute ago, AnotherTeluguBidda said:

Bro ramanujan is not shakunthala devi. His findings helped and helping many technologies and will continue to do so 

And what are those findings?

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10 minutes ago, AnotherTeluguBidda said:

Is there anyone in this db who could explain his findings to normal people like me.....or where to start to understand them?

Kacheri batch vachi cheppalamma

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Just now, tennisluvrredux said:
  • Ramanujan compiled around 3,900 results consisting of equations and identities. One of his most treasured findings was his infinite series for pi. This series forms the basis of many algorithms we use today. He gave several fascinating formulas to calculate the digits of pi in many unconventional ways.
  • He discovered a long list of new ideas to solve many challenging mathematical problems, which gave a significant impetus to the development of game theory. His contribution to game theory is purely based on intuition and natural talent and remains unrivalled to this day.
  • He elaborately described the mock theta function, which is a concept in the realm of modular form in mathematics. Considered an enigma till sometime back, it is now recognized as holomorphic parts of mass forms.
  • One of Ramanujan’s notebooks was discovered by George Andrews in 1976 in the library at Trinity College. Later the contents of this notebook were published as a book.
  • 1729 is known as the Ramanujan number. It is the sum of the cubes of two numbers 10 and 9. For instance, 1729 results from adding 1000 (the cube of 10) and 729 (the cube of 9). This is the smallest number that can be expressed in two different ways as it is the sum of these two cubes. Interestingly, 1729 is a natural number following 1728 and preceding 1730.
  • Ramanujan’s contributions stretch across mathematics fields, including complex analysis, number theory, infinite series, and continued fractions.

Ramanujan’s other notable contributions include hypergeometric series, the Riemann series, the elliptic integrals, the theory of divergent series, and the functional equations of the zeta function.

Say in layman language, so his findings helped to create game theory?

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Just now, DesiPokiri said:

Say in layman language, so his findings helped to create game theory?

It's written in very layman's language isn't it. Game theory is just one of the many items mentioned in that list. Is that the only thing you could understand? 

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7 minutes ago, tennisluvrredux said:

#1 HE WAS THE SECOND INDIAN TO BE ELECTED A FELLOW OF THE ROYAL SOCIETY

A self-taught genius, Ramanujan moved to England in March 1914 after his talent was recognized by British mathematician G. H. Hardy. In 1916, Ramanujan was awarded a Bachelor of Science by Research degree (later named Ph.D.) by Cambridge even though he was not an undergraduate. The Ph.D. was awarded in recognition of his work on ‘Highly composite numbers’. In 1918, Ramanujan became one of the youngest Fellows of the Royal Society and only the second Indian member. The same year he was elected a Fellow of Trinity College, Cambridge, the first Indian to be so honored. During his short lifespan of 32 years, Ramanujan independently compiled around 3,900 results. Apart from the below mentioned achievements his contributions include developing the relationship between partial sums and hyper-geometric series; independently discovering Bernoulli numbers and using these numbers to formulated the value of Euler’s constant up to 15 decimal places; discovering the Ramanujan prime number and the Landau–Ramanujan constant; and coming up with Ramanujan’s sum and the Ramanujan’s master theorem.

Srinivasa Ramanujan Srinivasa Ramanujan

 

#2 THE FASTEST ALGORITHMS FOR CALCULATION OF PI ARE BASED ON HIS SERIES

Finding an accurate approximation of π (pi) has been one of the most important challenges in the history of mathematics. In 1914, Srinivasa Ramanujan found a formula for computing pi that converges rapidly. His formula computes a further eight decimal places of π with each term in the series. It was in 1989, that Chudnovsky brothers computed π to over 1 billion decimal places on a supercomputer using a variation of Ramanujan’s infinite series of π. This was a world record for computing the most digits of pi. Moreover, the Ramanujan series is currently the basis for the fastest algorithms used to calculate π.

Ramanujan pi formula Ramanujan formula for estimating the value of Pi

 

#3 THE RAMANUJAN CONJECTURE PLAYED A KEY ROLE IN THE FAMOUS LANGLANDS PROGRAM

In 1916, Ramanujan published his paper titled “On certain arithmetical functions”. In the paper, Ramanujan investigated the properties of Fourier coefficients of modular forms. Though the theory of modular forms was not even developed then, he came up with three fundamental conjectures that served as a guiding force for its development. His first two conjectures helped develop the Hecke theory, which was formulated 20 years after his paper, in 1936, by German mathematician Erich Hecke. However, it was his last conjecture, known as the Ramanujan conjecture, that created a sensation in in 20th century mathematics. It played a pivotal role in the Langlands program, which began in 1970 through the proposal of American-Canadian mathematician Robert Langlands. The Langlands program aims to relate representation theory and algebraic number theory, two seemingly different fields of mathematics. It is widely viewed as the single biggest project in modern mathematical research. “On certain arithmetical functions” by Ramanujan thus effectively changed the course of 20th century mathematics.

Robert Langlands Robert Langlands – Founder of the Langlands program

 

#4 HE DEVELOPED THE INFLUENTIAL CIRCLE METHOD IN PARTITION NUMBER THEORY

A partition for a positive integer n is the number of ways the integer can be expressed as a sum of positive integers. For example p(4) = 5. That means 4 can be expressed as a sum of positive integers in 5 ways: 4, 3+1, 2+2, 2+1+1 and 1+1+1 +1. Ramanujan, along with G. H. Hardy, invented the circle method which gave the first approximations of the partition of numbers beyond 200. This method was largely responsible for major advances in the 20th century of notoriously difficult problems such as Waring’s conjecture and other additive questions. The circle method is now one of the central tools of analytic number theory. Moreover, circle method and its refinements constitute a large area of current mathematical research.

 

 

 

#5 HE DISCOVERED THE THREE RAMANUJAN’S CONGRUENCES

Related to the Partition Theory of Numbers, Ramanujan also came up with three remarkable congruences for the partition function p(n). They are p(5n+4) = 0(mod 5); p(7n+4) = 0(mod 7); p(11n+6) = 0(mod 11). For example, the first congruence means that if an integer is 4 more than a multiple of 5, then number of its partitions is a multiple of 5. The study of Ramanujan type congruence is a popular research topic of number theory. It was in 2011, that a conceptual explanation for Ramanujan’s congruences was finally discovered. Ramanujan’s work on partition theory has applications in a number of areas including particle physics (particularly quantum field theory) and probability.

Ramanujan's Congruences Ramanujan’s Congruences

 

#6 NUMBER 1729 IS NAMED HARDY–RAMANUJAN NUMBER

In a famous incident British mathematician G. H. Hardy while visiting Ramanujan had ridden in a taxi cab with the number 1729. He remarked to Ramanujan that the number “seemed to me rather a dull one, and that I hoped it was not an unfavourable omen”. “No,” Ramanajun replied, “it is a very interesting number; it is the smallest number expressible as the sum of two cubes in two different ways.” The two different ways are: 1729 = 13 + 123 = 93 + 103. 1729 is now known as the Hardy–Ramanujan number. Moreover, numbers that are the smallest number that can be expressed as the sum of two cubes in n distinct ways are now referred to as taxicab numbers due to the incident. The relevance of 1729 has recently come to light as it was part of a much larger theory that Ramanujan was developing. Theorems have been established in theory of elliptic curves that involve this fascinating number.

Godfrey Harold Hardy Godfrey Harold Hardy – Who collaborated with Ramanujan on several projects

 

#7 HE DID GROUNDBREAKING RESEARCH RELATED TO FERMAT’S LAST THEOREM

In 2013 famous Japanese American Mathematician Ken Ono, along with Sarah Trebat-Leder, found an equation by Ramanujan had clearly showed that he had been working on Fermat’s last theorem, one of the most notable and difficult to prove theorems in the history of mathematics. In 1637, French mathematician Pierre de Fermat had asserted that: if n is a whole number greater than 2, then there are no positive whole number triples x, y and z, such that xn + yn = zn. This means that there are no numbers which satisfy the equations: x3 + y3 = z3; x4 + y4 = z4; and so on. The equation of Ramanujan illustrates that he had found an infinite family of positive whole number triples x, y and z that very nearly, but not quite, satisfy Fermat’s equation for n=3. They are off only by plus or minus one. Among them is 1729, which misses the mark by 1 for x=9, y=10 and z=12. Moving forward, Ramanujan also considered the equations of the form: y2 = x3 + ax + b. If you plot the points (x,y) for this equation you get an elliptic curve. Elliptic curves played a key role when English mathematician Sir Andrew Wiles finally proved Fermat’s last theorem in 1994, a feat described as a “stunning advance” in maths.

Ramanujan Fermat's last theorem Ramanujan’s manuscript on Fermat’s last theorem with representations of 1729 as the sum of two cubes in the bottom right corner

 

#8 RAMANUJAN WAS THE FIRST TO DISCOVER K3 SURFACES IN 1910S

Ken Ono also found that Ramanujan went on to discover an object more complicated than elliptic curves. When it was re-discovered in 1958 by Andre Weil, it was named K3 surface. Thus it has come to light that Ramanujan was using 1729 and elliptic curves to develop formulas for a K3 surface. “Elliptic curves and K3 surfaces form an important next frontier in mathematics and Ramanujan gave remarkable examples illustrating some of their features that we didn’t know before.” Moreover, K3 surfaces play key roles today in string theory and quantum physics. Like, string theory suggests that the world consists of more than the three dimensions that we can see. These extra dimensions are rolled up tightly in tiny little spaces too small for us to perceive. These tiny spaces have a particular geometric structure. Calabi–Yau manifold is a class of geometric objects that have similar structure and one of the simplest classes of Calabi-Yau manifolds comes from K3 surfaces.

 

 

 

#9 HIS THETA FUNCTION LIES AT THE HEART OF STRING THEORY IN PHYSICS

In mathematics, theta functions are special functions of several complex variables. German Mathematician Carl Gustav Jacob Jacobi came up with several closely related theta functions known as Jacobi theta functions. Theta functions were studied extensively by Ramanujan. He came up with the Ramanujan theta function, which generalizes the form of Jacobi theta functions while also capturing their general properties. In particular, the Jacobi triple product takes on an elegant form when written in terms of the Ramanujan theta function. Ramanujan theta function has several important applications. It is used to determine the critical dimensions in Bosonic string theory, superstring theory and M-theory.

Ramanujan theta function Ramanujan theta function

 

#10 HIS MOCK MODULAR FORMS MAY UNLOCK THE SECRET OF BLACK HOLES

In a 1920 letter to Hardy, Ramanujan described several new functions that behaved differently from known theta functions, or modular forms, and yet closely mimicked them. These were the first ever examples of mock modular forms. More than 80 years later, in 2002, a description for these functions was provided by Sander Zwegers. Further, Ramanujan predicted that his mock modular forms corresponded to ordinary modular forms producing similar outputs for roots of 1. Ken Ono ultimately showed that a mock modular form could be computed just as Ramanujan predicted. It was found as the output of mock modular forms shoot off to enormous numbers, the corresponding ordinary modular form expand at a similar rate and thus their difference is a relatively small number. Expansion of mock modular forms is now used to compute the entropy, or level of disorder, of black holes. Thus even through black holes were virtually unknown during his time, Ramanujan was able to do maths which may unlock their secret.

Okay i cant read all of this baa, in simple words i ll say stevejobs, bill gates and edison are the greatest ppl in the past 100 years who invented bulb, windows and our way to communicate to internet and finally a smartphone by jobs which changed the entire world and connected everyone. So in layman words please 

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2 minutes ago, tennisluvrredux said:

It's written in very layman's language isn't it. Game theory is just one of the many items mentioned in that list. Is that the only thing you could understand? 

Baa i cant read thats why am asking in simple words 

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2 minutes ago, tennisluvrredux said:

:3D_Smiles:

Evaru baa electricity "invent" chesindi veelllallo? Einstein aah, Steve jobs aah leka Bill Gates aah. Please clarify and I can try to explain how mathematics works 

Adhe saari edison invented bulb ani maa meaning, end of the day thats my explaining way of things in simple words.

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3 minutes ago, tennisluvrredux said:

:3D_Smiles:

Evaru baa electricity "invent" chesindi veelllallo? Einstein aah, Steve jobs aah leka Bill Gates aah. Please clarify and I can try to explain how mathematics works 

Oh you donno who invented iphone? 

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