SRINIVASA RAMANUJAN AIYANGAR
S.PONGOMATHI,
MATHEMATICS
Early
Life and Education:
Srinivasa Ramanujan
Aiyangar was an Indian Mathematician who was born in Erode, India in 1887 on
December 22. He was born into a family that was not very well to do. He went to
school at the nearby place, Kumbakonam. Ramanujan is very well known for his
efforts on continued fractions and series of hypergeometry. When Ramanujan was
thirteen, he could work out Loney’s Trigonometry exercises without any help. At
the of fourteen, he was able to acquire the theorems of cosine and sine given
by L. Euler. Synopsis of Elementary Results in Pure and Applied Mathematics by
George Shoobridge Carr was reached by him in 1903. The book helped him a lot
and opened new dimensions to him were opened which helped him introduce about
6,165 theorems for himself. As he had no proper and good books in his reach, he
had to figure out on his own the solutions for all the questions. It was in
this quest that he discovered many tremendous methods and new algebraic series.
In 1904, he received
a merit scholarship in a local college and became more indulgent into
mathematics. He lost his interest in all other subjects due to which he lost
his scholarship. Even after two attempts, he did not succeed to get a first
degree in the field of arts. In 1909, he got married and continued his clerical
work and, side by side, his investigations of mathematics. Finally in 1911, he
published some of his results.
It was in January 1913 that he
sent his work to a Cambridge Professor named G. H. Hardy but he did not
appreciate Ramanujan’s work much as he had not really done reached the standard
of the mathematicians of the west. But he was given a scholarship in May by the
University of Madras
Contributions and Achievements:
Ramanujan went
to Cambridge in 1914 and it helped him a lot but by that time his mind worked
on the patterns on which it had worked before and he seldom adopted new ways.
By then, it was more about intuition than argument. Hardy said Ramanujan could
have become an outstanding mathematician if his skills had been recognized
earlier. It was said about his talents of continued fractions and
hypergeometric series that, “he was unquestionably one of the great masters.”
It was due to his sharp memory, calculative mind, patience and insight that he
was a great formalist of his days. But it was due to his some methods of
working in the work analysis and theories of numbers that did not let him excel
that much.
He got elected as the fellow in
1918 at the Trinity College at Cambridge and the Royal Society. He departed
from this world on April 26, 1920.
Srinivasa Ramanujan
It is one of the
most romantic stories in the history of mathematics: in 1913, the English
mathematician G. H. Hardy received a strange letter from an unknown clerk in
Madras, India. The ten-page letter contained about 120 statements of theorems
on infinite series, improper integrals, continued fractions, and number theory
(Here is a .dvi file with a sample of these results).
Every prominent mathematician gets letters from cranks, and at first glance
Hardy no doubt put this letter in that class. But something about the formulas
made him take a second look, and show it to his collaborator J. E. Littlewood.
After a few hours, they concluded that the results "must be true because,
if they were not true, no one would have had the imagination to invent
them".
Thus was
Srinivasa Ramanujan (1887-1920) introduced to the mathematical world. Born in
South India, Ramanujan was a promising student, winning academic prizes in high
school. But at age 16 his life took a decisive turn after he obtained a book
titled A Synopsis of Elementary Results in Pure and Applied Mathematics.
The book was simply a compilation of thousands of mathematical results, most
set down with little or no indication of proof. It was in no sense a
mathematical classic; rather, it was written as an aid to coaching English
mathematics students facing the notoriously difficult Tripos examination, which
involved a great deal of wholesale memorization. But in Ramanujan it inspired a
burst of feverish mathematical activity, as he worked through the book's
results and beyond. Unfortunately, his total immersion in mathematics was disastrous
for Ramanujan's academic career: ignoring all his other subjects, he repeatedly
failed his college exams.
As a college
dropout from a poor family, Ramanujan's position was precarious. He lived off
the charity of friends, filling notebooks with mathematical discoveries and
seeking patrons to support his work. Finally he met with modest success when
the Indian mathematician Ramachandra Rao provided him with first a modest
subsidy, and later a clerkship at the Madras Port Trust. During this period Ramanujan
had his first paper published, a 17-page work on Bernoulli numbers that
appeared in 1911 in the Journal of the Indian Mathematical Society.
Still no one was quite sure if Ramanujan was a real genius or a crank. With the
encouragement of friends, he wrote to mathematicians in Cambridge seeking
validation of his work. Twice he wrote with no response; on the third try, he
found Hardy.
Hardy wrote
enthusiastically back to Ramanujan, and Hardy's stamp of approval improved
Ramanujan's status almost immediately. Ramanujan was named a research scholar
at the University of Madras, receiving double his clerk's salary and required
only to submit quarterly reports on his work. But Hardy was determined that
Ramanujan be brought to England. Ramanujan's mother resisted at
first--high-caste Indians shunned travel to foreign lands--but finally gave in,
ostensibly after a vision. In March 1914, Ramanujan boarded a steamer for
England.
Ramanujan's
arrival at Cambridge was the beginning of a very successful five-year collaboration
with Hardy. In some ways the two made an odd pair: Hardy was a great exponent
of rigor in analysis, while Ramanujan's results were (as Hardy put it)
"arrived at by a process of mingled argument, intuition, and induction, of
which he was entirely unable to give any coherent account". Hardy did his
best to fill in the gaps in Ramanujan's education without discouraging him. He
was amazed by Ramanujan's uncanny formal intuition in manipulating infinite
series, continued fractions, and the like: "I have never met his equal,
and can compare him only with Euler or Jacobi."
One remarkable
result of the Hardy-Ramanujan collaboration was a formula for the number p(n)
of partitions of a number n. A partition of a positive integer n
is just an expression for n as a sum of positive integers, regardless of
order. Thus p(4) = 5 because 4 can be written as 1+1+1+1, 1+1+2, 2+2, 1+3, or
4. The problem of finding p(n) was studied by Euler,
who found a formula for the generating function of p(n) (that is, for
the infinite series whose nth term is p(n)xn).
While this allows one to calculate p(n) recursively, it doesn't lead to
an explicit formula. Hardy and Ramanujan came up with such a formula (though
they only proved it works asymptotically; Rademacher proved it gives the exact
value of p(n)).
Ramanujan's
years in England were mathematically productive, and he gained the recognition
he hoped for. Cambridge granted him a Bachelor of Science degree "by
research" in 1916, and he was elected a Fellow of the Royal Society (the
first Indian to be so honored) in 1918. But the alien climate and culture took
a toll on his health. Ramanujan had always lived in a tropical climate and had
his mother (later his wife) to cook for him: now he faced the English winter,
and he had to do all his own cooking to adhere to his caste's strict dietary rules.
Wartime shortages only made things worse. In 1917 he was hospitalized, his
doctors fearing for his life. By late 1918 his health had improved; he returned
to India in 1919. But his health failed again, and he died the next year.
Besides his
published work, Ramanujan left behind several notebooks, which have been the
object of much study. The English mathematician G. N. Watson wrote a long
series of papers about them. More recently the American mathematician Bruce C.
Berndt has written a multi-volume study of the notebooks. In 1997 The
Ramanujan Journal was launched to publish work "in areas of
mathematics influenced by Ramanujan".
Achievements: Ramanujan independently discovered results of Gauss, Kummer and
others on hypergeometric series. Ramanujan's own work on partial sums and
products of hypergeometric series have led to major development in the topic.
His most famous work was on the number p(n) of partitions of an integer n into
summands.
Srinivasa Ramanujan was a mathematician par
excellence. He is widely believed to be the greatest mathematician of the 20th
Century. Srinivasa Ramanujan made significant contribution to the analytical
theory of numbers and worked on elliptic functions, continued fractions, and
infiniteseries.
Srinivasa Aiyangar Ramanujan was born on December 22,
1887 in Erode, Tamil Nadu. His father worked in Kumbakonam as a clerk in a
cloth merchant's shop. At the of five Ramanujan went to primary school in
Kumbakonam. In 1898 at age 10, he entered the Town High School in Kumbakonam.
At the age of eleven he was lent books on advanced trigonometry written by S.
L. Loney by two lodgers at his home who studied at the Government college. He
mastered them by the age of thirteen. Ramanujan was a bright student, winning
academic prizes in high school.
At age of 16 his life took a decisive turn after he
obtained a book titled" A Synopsis of Elementary Results in Pure and
Applied Mathematics". The book was simply a compilation of thousands of
mathematical results, most set down with little or no indication of proof. The
book generated Ramanujan's interest in mathematics and he worked through the
book's results and beyond. By 1904 Ramanujan had begun to undertake deep
research. He investigated the series (1/n) and calculated Euler's constant to
15 decimal places. He began to study the Bernoulli numbers, although this was
entirely his own independent discovery. He was given a scholarship to the
Government College in Kumbakonam which he entered in 1904. But he neglected his
subjects at the cost of mathematics and failed in college examination. He
dropped out of the college.
Ramanujan lived off the charity of friends, filling
notebooks with mathematical discoveries and seeking patrons to support his
work. In 1906 Ramanujan went to Madras where he entered Pachaiyappa's College.
His aim was to pass the First Arts examination which would allow him to be
admitted to the University of Madras. Continuing his mathematical work
Ramanujan studied continued fractions and divergent series in 1908. At this
stage he became seriously ill again and underwent an operation in April 1909
after which he took him some considerable time to recover.
On 14 July 1909 Ramanujan marry a ten year old girl S
Janaki Ammal. During this period Ramanujan had his first paper published, a 17-page
work on Bernoulli numbers that appeared in 1911 in the Journal of the Indian
Mathematical Society. In 191,1 Ramanujan approached the founder of the Indian
Mathematical Society for advice on a job. He got the job of clerk at the Madras
Port Trust with the help of Indian mathematician Ramachandra Rao.
The professor of civil engineering at the Madras
Engineering College C L T Griffith was interested in Ramanujan's abilities and,
having been educated at University College London, knew the professor of mathematics
there, namely M J M Hill. He wrote to Hill on 12 November 1912 sending some of
Ramanujan's work and a copy of his 1911 paper on Bernoulli numbers. Hill
replied in a fairly encouraging way but showed that he had failed to understand
Ramanujan's results on divergent series. In January 1913 Ramanujan wrote to G H
Hardy having seen a copy of his 1910 book Orders of infinity. Hardy, together
with Littlewood, studied the long list of unproved theorems which Ramanujan
enclosed with his letter. Hardy wrote back to Ramanujan a evinced interest in
his work.
University of Madras gave Ramanujan a scholarship in
May 1913 for two years and, in 1914, Hardy brought Ramanujan to Trinity
College, Cambridge, to begin an extraordinary collaboration. Right from the start
Ramanujan's collaboration with Hardy led to important results. In a joint paper
with Hardy, Ramanujan gave an asymptotic formula for p(n). It had the
remarkable property that it appeared to give the correct value of p(n), and
this was later proved by Rademacher.
Ramanujan had problems settling in London. He was an
orthodox Brahmin and right from the beginning he had problems with his diet.
The outbreak of World War I made obtaining special items of food harder and it
was not long before Ramanujan had health problems.
On 16 March 1916 Ramanujan graduated from Cambridge with a Bachelor of Science by Research. He had been allowed to enrol in June 1914 despite not having the proper qualifications. Ramanujan's dissertation was on Highly composite numbers and consisted of seven of his papers published in England.
On 16 March 1916 Ramanujan graduated from Cambridge with a Bachelor of Science by Research. He had been allowed to enrol in June 1914 despite not having the proper qualifications. Ramanujan's dissertation was on Highly composite numbers and consisted of seven of his papers published in England.
Ramanujan fell seriously ill in 1917 and his doctors
feared that he would die. He did improve a little by September but spent most
of his time in various nursing homes. On February 18, 1918 Ramanujan was
elected a fellow of the Cambridge Philosophical Society and later he was also
elected as a fellow of the Royal Society of London. By the end of November 1918
Ramanujan's health had greatly improved.
Ramanujan sailed to India on 27 February 1919 arriving
on 13 March. However his health was very poor and, despite medical treatment,
he died on April 26, 1920.
