Monday, March 28, 2011

Georg Simon Ohm

Georg Simon Ohm
Well i need to change name of the blog to famous mathematician and engineers. As mathematician have done some unmatched and highly popular contributions towards engineering. Here is the most famous one.

Georg Simon Ohm came from a Protestant family. His father, Johann Wolfgang Ohm, was a locksmith while his mother, Maria Elizabeth Beck, was the daughter of a tailor. Although his parents had not been formally educated, Ohm's father was a rather remarkable man who had educated himself to a high level and was able to give his sons an excellent education through his own teachings. Had Ohm's brothers and sisters all survived he would have been one of a large family but, as was common in those times, several of the children died in their childhood. Of the seven children born to Johann and Maria Ohm only three survived, Georg Simon, his brother Martin who went on to become a well-known mathematician, and his sister Elizabeth Barbara.

When they were children, Georg Simon and Martin were taught by their father who brought them to a high standard in mathematics, physics, chemistry and philosophy. This was in stark contrast to their school education. Georg Simon entered Erlangen Gymnasium at the age of eleven but there he received little in the way of scientific training. In fact this formal part of his schooling was uninspired stressing learning by rote and interpreting texts. This contrasted strongly with the inspired instruction that both Georg Simon and Martin received from their father who brought them to a level in mathematics which led the professor at the University of Erlangen, Karl Christian von Langsdorf, to compare them to the Bernoulli family. It is worth stressing again the remarkable achievement of Johann Wolfgang Ohm, an entirely self-taught man, to have been able to give his sons such a fine mathematical and scientific education.

In 1805 Ohm entered the University of Erlangen but he became rather carried away with student life. Rather than concentrate on his studies he spent much time dancing, ice skating and playing billiards. Ohm's father, angry that his son was wasting the educational opportunity that he himself had never been fortunate enough to experience, demanded that Ohm leave the university after three semesters. Ohm went (or more accurately, was sent) to Switzerland where, in September 1806, he took up a post as a mathematics teacher in a school in Gottstadt bei Nydau.

Karl Christian von Langsdorf left the University of Erlangen in early 1809 to take up a post in the University of Heidelberg and Ohm would have liked to have gone with him to Heidelberg to restart his mathematical studies. Langsdorf, however, advised Ohm to continue with his studies of mathematics on his own, advising Ohm to read the works of Euler, Laplace and Lacroix. Rather reluctantly Ohm took his advice but he left his teaching post in Gottstadt bei Nydau in March 1809 to become a private tutor in Neuchâtel. For two years he carried out his duties as a tutor while he followed Langsdorf's advice and continued his private study of mathematics. Then in April 1811 he returned to the University of Erlangen.

His private studies had stood him in good stead for he received a doctorate from Erlangen on 25 October 1811 and immediately joined the staff as a mathematics lecturer. After three semesters Ohm gave up his university post. He could not see how he could attain a better status at Erlangen as prospects there were poor while he essentially lived in poverty in the lecturing post. The Bavarian government offered him a post as a teacher of mathematics and physics at a poor quality school in Bamberg and he took up the post there in January 1813.

This was not the successful career envisaged by Ohm and he decided that he would have to show that he was worth much more than a teacher in a poor school. He worked on writing an elementary book on the teaching of geometry while remaining desperately unhappy in his job. After Ohm had endured the school for three years it was closed down in February 1816. The Bavarian government then sent him to an overcrowded school in Bamberg to help out with the mathematics teaching.

On 11 September 1817 Ohm received an offer of the post of teacher of mathematics and physics at the Jesuit Gymnasium of Cologne. This was a better school than any that Ohm had taught in previously and it had a well equipped physics laboratory. As he had done for so much of his life, Ohm continued his private studies reading the texts of the leading French mathematicians Lagrange, Legendre, Laplace, Biot and Poisson. He moved on to reading the works of Fourier and Fresneland he began his own experimental work in the school physics laboratory after he had learnt of Oersted's discovery of electromagnetism in 1820. At first his experiments were conducted for his own educational benefit as were the private studies he made of the works of the leading mathematicians.

The Jesuit Gymnasium of Cologne failed to continue to keep up the high standards that it had when Ohm began to work there so, by 1825, he decided that he would try again to attain the job he really wanted, namely a post in a university. Realising that the way into such a post would have to be through research publications, he changed his attitude towards the experimental work he was undertaking and began to systematically work towards the publication of his results [1]:-
Overburdened with students, finding little appreciation for his conscientious efforts, and realising that he would never marry, he turned to science both to prove himself to the world and to have something solid on which to base his petition for a position in a more stimulating environment.
In fact he had already convinced himself of the truth of what we call today "Ohm's law" namely the relationship that the current through most materials is directly proportional to the potential difference applied across the material. The result was not contained in Ohm's firsts paper published in 1825, however, for this paper examines the decrease in the electromagnetic force produced by a wire as the length of the wire increased. The paper deduced mathematical relationships based purely on the experimental evidence that Ohm had tabulated.

In two important papers in 1826, Ohm gave a mathematical description of conduction in circuits modelled on Fourier's study of heat conduction. These papers continue Ohm's deduction of results from experimental evidence and, particularly in the second, he was able to propose laws which went a long way to explaining results of others working on galvanic electricity. The second paper certainly is the first step in a comprehensive theory which Ohm was able to give in his famous book published in the following year.

What is now known as Ohm's law appears in this famous book Die galvanische Kette, mathematisch bearbeitet (1827) in which he gave his complete theory of electricity. The book begins with the mathematical background necessary for an understanding of the rest of the work. We should remark here that such a mathematical background was necessary for even the leading German physicists to understand the work, for the emphasis at this time was on a non-mathematical approach to physics. We should also remark that, despite Ohm's attempts in this introduction, he was not really successful in convincing the older German physicists that the mathematical approach was the right one. To some extent, as Caneva explains in [1], this was Ohm's own fault:-
... in neither the introduction nor the body of the work, which contained the more rigorous development of the theory, did Ohm bring decisively home either the underlying unity of the whole or the connections between fundamental assumptions and major deductions. For example, although his theory was conceived as a strict deductive system based on three fundamental laws, he nowhere indicated precisely which of their several mathematical and verbal expressions he wished to be taken as the canonical form.
It is interesting that Ohm's presents his theory as one of contiguous action, a theory which opposed the concept of action at a distance. Ohm believed that the communication of electricity occurred between "contiguous particles" which is the term Ohm himself uses. The paper [8] is concerned with this idea, and in particular with illustrating the differences in scientific approach between Ohm and that of Fourier and Navier. A detailed study of the conceptual framework used by Ohm in formulating Ohm's law is given in [6].
As we described above, Ohm was at the Jesuit Gymnasium of Cologne when he began his important publications in 1825. He was given a year off work in which to concentrate on his research beginning in August 1826 and although he only received the less than generous offer of half pay, he was able to spend the year in Berlin working on his publications. Ohm had believed that his publications would lead to his receiving an offer of a university post before having to return to Cologne but by the time he was due to begin teaching again in September 1827 he was still without such an offer.
Although Ohm's work strongly influenced theory, it was received with little enthusiasm. Ohm's feeling were hurt, he decided to remain in Berlin and, in March 1828, he formally resigned his position at Cologne. He took some temporary work teaching mathematics in schools in Berlin.
He accepted a position at Nüremberg in 1833 and although this gave him the title of professor, it was still not the university post for which he had strived all his life. His work was eventually recognised by the Royal Society with its award of the Copley Medal in 1841. He became a foreign member of the Royal Society in 1842. Other academies such as those in Berlin and Turin elected him a corresponding member, and in 1845 he became a full member of the Bavarian Academy.

This belated recognition was welcome but there remains the question of why someone who today is a household name for his important contribution struggled for so long to gain acknowledgement. This may have no simple explanation but rather be the result of a number of different contributary factors. One factor may have been the inwardness of Ohm's character while another was certainly his mathematical approach to topics which at that time were studied in his country a non-mathematical way. There was undoubtedly also personal disputes with the men in power which did Ohm no good at all. He certainly did not find favour with Johannes Schultz who was an influential figure in the ministry of education in Berlin, and with Georg Friedrich Pohl, a professor of physics in that city.
Electricity was not the only topic on which Ohm undertook research, and not the only topic in which he ended up in controversy. In 1843 he stated the fundamental principle of physiological acoustics, concerned with the way in which one hears combination tones. However the assumptions which he made in his mathematical derivation were not totally justified and this resulted in a bitter dispute with the physicist August Seebeck. He succeeded in discrediting Ohm's hypothesis and Ohm had to acknowledge his error. See [10] for details of the dispute between Ohm and Seebeck.

In 1849 Ohm took up a post in Munich as curator of the Bavarian Academy's physical cabinet and began to lecture at the University of Munich. Only in 1852, two years before his death, did Ohm achieve his lifelong ambition of being appointed to the chair of physics at the University of Munich.

Sunday, March 27, 2011

Michael Faraday


Michael Faraday

Well Michael Faraday was not an Engineer so does not fit the profile of this site but his contribution to fundamental of electricity are unmatched. Without his contribution to the field electrical engineering would not be plausible.


Michael Faraday was one of the greatest scientists of the 19th century. His early life closely paralleled that of Benjamin Franklin. Both were part of a large family; both were apprenticed in the printing trade; both read voraciously and became self-educated; and both loved science.


Faraday was born in Newington, Surrey, England, on September 22, 1791. His father, a blacksmith, could not afford a formal education for Michael, and so the boy received just the bare essentials and was apprenticed to a bookbinder.In some ways this apprenticeship was a stroke of good fortune for Michael because it gave him the opportunity to read all that he desired. He studied thearticles about electricity in the Encyclopaedia Britannica, read a chemistry textbook, and was very interested in magnetism. In 1812 Faraday obtained tickets to attend the lectures of Humphry Davy at the Royal Institution.Faraday took 386 pages of notes and had them bound in leather and sent to SirJoseph Banks (1743-1820), who was president of the Royal Society of London,with the hope of making a favorable impression. Unfortunately, Banks never responded. No matter--Faraday then sent a copy directly to Davy along with a job application to be Davy's assistant. Davy was very impressed, but he alreadyhad an assistant. However, shortly thereafter, Davy fired his assistant forbrawling, contacted Faraday, and offered him the job of "washing bottles." This was not exactly what Faraday had in mind, but it was a step in the right direction and he accepted.
In 1813 Davy resigned his post at the Royal Institution, married a wealthy widow, and began an extended trip through Europe. The trip afforded Faraday theopportunity to meet such famous men as Italian physicist Alessandro Volta and French chemist Louis-Nicolas Vauquelin (1763-1829). In 1820, Danish physicist Hans Christian Oersted (1777-1851) had discovered that an electric currentproduced a magnetic field. This had set off a flurry of investigation by other scientists, among them Faraday, who was now back in England. Within a yearof Oersted's discovery, Faraday had built a device which essentially consisted of a hinged wire, a magnet and a chemical battery. When the current was turned on, a magnetic field was set up in the wire, and it began to spin aroundthe magnet. Faraday had just invented the electric motor.


Faraday's motor was certainly an interesting device, but it was treated as atoy. But Faraday had a greater goal in sight. Oersted had converted electriccurrent into a magnetic force; Faraday intended to reverse the process and create electricity from magnetism. Taking an iron ring, Faraday wrapped half ofit with a coil of wire that was attached to a battery and switch. André Marie Ampère (1775-1836) had shown that electricity would set up amagnetic field in the coil. The other half of the ring was wrapped with a wire that led to a galvanometer. In theory, the first coil would set up a magnetic field that the second coil would intercept and convert back to electric current which the galvanometer would register. Faraday threw the switch and received instant gratification: the experiment worked, a device that became known as the transformer. However, the result was not exactly what he expected. Instead of registering a continuous current, the galvanometer moved only whenthe circuit was opened or closed. Ampère had observed the same effecta decade earlier but ignored it because it did not fit his theories. Decidingto make the theory fit the observation, instead of the other way around, Faraday concluded that when the current was turned on or off, it caused magnetic"lines of force" from the first coil to expand or contract across the secondcoil, inducing a momentary flow of current in the second coil. In this way Faraday discovered the principle of electrical induction.


Meanwhile, in the United States, physicist Joseph Henry had independently made the same discovery. Faraday's affiliation with Davy had been suffering because Davy was extremely jealous of his former assistant, who was now eclipsinghim. The situation escalated following Faraday's invention of the transformer; Davy claimed the idea for the experiment had been his. When Faraday was nominated to become a member of the Royal Society in 1824, Davy cast the only negative vote.
Having shown that magnetism could produce electricity, Faraday's next goal was to produce a continuous current instead of just a momentary spurt. This time he decided to reverse an experiment made by Dominique Arago (1786-1853). In1824 Arago had discovered that a rotating copper disk deflected a magnetic needle. This, explained Faraday, was an example of magnetic induction. Faradayplanned to use a magnetic field to set up an electric current. In 1831 Faraday took a copper disk and spun it between the poles of a permanent magnet. This set up an electric current in the disk which could be passed through a wire and put to work. So long as the wheel spun, current was produced. This simple experiment produced the greatest electrical invention in history: the electric generator. It took five decades and other inventions to make generatorspractical, but Faraday had pointed the way.
Faraday is especially remembered for his use of intuition in his scientific discoveries, making minimal use of mathematics. Unfortunately, he suffered a mental breakdown in 1839 from which he never fully recovered, and he was forced to leave the laboratory work to others. In addition to his inventions, he had compiled a number of notable discoveries: "magnetic lines of force," the compound benzene, how to liquify various gasses, and the laws of electrolysis.He also developed the concept of a "field"--a force, like magnetism or electric fields or gravity, that extends throughout space and is produced by magnets or electric charge or, in the case of gravity, mass. James Clerk Maxwell later developed his famous equations describing electromagnetism using this concept, acknowledging his debt to Faraday.


On August 25, 1867, Faraday died at Hampton Court, Middlesex, England. His accomplishments were all the more remarkable considering he had had no formal training in science or mathematics, yet was able to establish the fundamentalnature of electricity and magnetism.


Read more: Michael Faraday Biography (1791-1867) http://www.madehow.com/inventorbios/30/Michael-Faraday.html#ixzz1HlhKGoCL

Thursday, March 24, 2011

Jacob Millman

Dr. Millman, who was an expert on radar, electronic circuits and pulse-circuit techniques, was born in Russia and came to the United States in 1913.
He earned a Ph.D. from the Massachusetts Institute of Technology in 1935. Except for three years during World War II, when he was a scientist with the Radiation Laboratory at M.I.T., he was a professor of engineering at City College of New York from 1936 to 1952.
From 1952 until he retired in 1976, he taught at Columbia University. He was named chairman of the department of electrical engineering in 1965 and, at his retirement, became the Charles Batchelor Professor Emeritus of Electrical Engineering.
He was the author or co-author of eight textbooks on electronics and computer science.
His most notable achievement was the formulation of Millman's Theorem (otherwise known as the Parallel generator theorem), which is named after him. 
His Notable books are:
  • Pulse, Digital, and Switching Waveforms: Devices and Circuits for Their Generation and Processing by Jacob Millman June 1965

  • Integrated Electronics: Analog and Digital Circuits and Systems by Jacob Millman June 1972

  • Operational Amplifiers by Jacob Millman, Christos C. Halkias January 1975

  • Electronic Fundamentals and Applications: For Engineers and Scientists by Jacob Millman, Christos C. Halkias

  • Microelectronics: Digital and Analog Circuits and Systems by Jacob Millman

  • Microelectronics (2nd Edition) by Arvin Grabel, Jacob Millman

 ----------------------------------------------------------------------------------------

William Shockley

William Shockley


William Shockley was born in London, England, on 13th February, 1910, the son of William Hillman Shockley, a mining engineer born in Massachusetts and his wife, Mary (née Bradford) who had also been engaged in mining, being a deputy mineral surveyor in Nevada.

The family returned to the United States in 1913 and William Jr. was educated in California, taking his B.Sc. degree at the California Institute of Technology in 1932. He studied at Massachusetts Institute of Technology under Professor J.C. Slater and obtained his Ph.D. in 1936, submitting a thesis on the energy band structure of sodium chloride. The same year he joined Bell Telephone Laboratories, working in the group headed by Dr. C.J. Davisson and remained there (with brief absences for war service, etc.) until 1955. He resigned his post of Director of the Transistor Physics Department to become Director of the Shockley Semi-conductor Laboratory of Beckman Instruments, Inc., at Mountain View, California, for research development and production of new transistor and other semiconductor devices. In 1963 he was named first Alexander M. Poniatoff Professor of Engineering Science at Stanford University, where he will act as professor-at-large in engineering and applied sciences.

During World War II he was Research Director of the Anti-submarine Warfare Operations Research Group and he afterwards served as Expert Consultant in the offce of the Secretary for War.

He held two visiting lectureships: in 1946 at Princeton University, and in 1954 at the California Institute of Technology. For one year (1954-1955) he was Deputy Director and Research Director of the Weapons System Evaluation Group in the Defence Department.

Shockley's research has been centred on energy bands in solids; order and disorder in alloys; theory of vacuum tubes; self-diffusion of copper; theories of dislocations and grain boundaries; experiment and theory on ferromagnetic domains; experiments on photoelectrons in silver chloride; various topics in transistor physics and operations research on the statistics of salary and individual productivity in research laboratories.

His work has been rewarded with many honours. He received the Medal for Merit in 1946, for his work with the War Department; the Morris Leibmann Memorial Prize of the Institute of Radio Engineers in 1952; the following year, the Oliver E. Buckley Solid State Physics Prize of the American Physical Society, and a year later the Cyrus B. Comstock Award of the National Academy of Sciences. The crowning honour - the Nobel Prize for Physics - was bestowed on him in 1956, jointly with his two former colleagues at the Bell Telephone Laboratories, John Bardeen and Walter H. Brattain.

In 1963 he was selected as recipient of the Holley Medal of the American Society of Mechanical Engineers.

Dr. Shockley has been a member of the Scientific Advisory Panel of the U.S. Army since 1951 and he has served on the Air Force Scientific Advisory Board since 1958. In 1962 he was appointed to the President's Scientific Advisory Committee. He has received honorary science doctorates from the University of Pennsylvania, Rutgers University and Gustavus Adolphus Colleges (Minn.).

In addition to numerous articles in scientific and technical journals, Shockley has written Electrons and Holes in Semiconductors (1950) and has edited Imperfections of Nearly Perfect Crystals (1952). He has taken out more than 50 U.S. patents for his inventions.

Dr. Shockley has been married twice, and has three children by his first marriage to Jean (née Bailey). This union ended in divorce; his second wife is Emmy Lanning.
--
From Nobel Lectures, Physics 1942-1962, Elsevier Publishing Company, Amsterdam, 1964