Richard Feynman book The Character of Physical Law
Source: The Character of Physical Law (1965), chapter 2, “The Relation of Mathematics to Physics”
Source: The Character of Physical Law (1965), chapter 2, “ The Relation of Mathematics to Physics http://www.youtube.com/watch?v=M9ZYEb0Vf8U”
Richard Feynman book The Character of Physical Law
Source: The Character of Physical Law (1965), chapter 2, “The Relation of Mathematics to Physics”
Nicolas Léonard Sadi Carnot (1796–1832) French physicist, the "father of thermodynamics" (1796–1832)
p, 125
Reflections on the Motive Power of Heat (1824)
Kurt Lewin (1890–1947) German-American psychologist
Source: 1930s, The conflict between Aristotelian and Galileian modes of thought in contemporary psychology, 1931, p. 147.
Joseph Yates (judge) (1722–1770) English barrister and judge
4 Burr. Part IV., 2368.
Dissenting in Millar v Taylor (1769)
Gottlob Frege book The Foundations of Arithmetic
Gottlob Frege (1950 [1884]). The Foundations of Arithmetic. p. 99.
Aldo Capitini (1899–1968) Italian philosopher and political activist
‘In Remembrance of Aldo Capitini’
Hymn
Giordano Bruno (1548–1600) Italian philosopher, mathematician and astronomer
VIII 2, as quoted in The Acentric Labyrinth (1995) by Ramon Mendoza
De immenso (1591)
Alfred de Zayas (1947) American United Nations official
2018, Report submitted to the UN Human Rights Council
Albert A. Michelson (1852–1931) American physicist
Light Waves and Their Uses. By Albert A. Michelson. Published by The University of Chicago Press, 1903, pp 23-25.
Context: Before entering into these details, however, it may be well to reply to the very natural question: What would be the use of such extreme refinement in the science of measurement? Very briefly and in general terms the answer would be that in this direction the greater part of all future discovery must lie. The more important fundamental laws and facts of physical science have all been discovered, and these are so firmly established that the possibility of their ever being supplanted in consequence of new discoveries is exceedingly remote. Nevertheless, it has been found that there are apparent exceptions to most of these laws, and this is particularly true when the observations are pushed to a limit, i. e., whenever the circumstances of experiment are such that extreme cases can be examined. Such examination almost surely leads, not to the overthrow of the law, but to the discovery of other facts and laws whose action produces the apparent exceptions.As instances of such discoveries, which are in most cases due to the increasing order of accuracy made possible by improvements in measuring instruments, may be mentioned: first, the departure of actual gases from the simple laws of the so-called perfect gas, one of the practical results being the liquefaction of air and all known gases; second, the discovery of the velocity of light by astronomical means, depending on the accuracy of telescopes and of astronomical clocks; third, the determination of distances of stars and the orbits of double stars, which depend on measurements of the order of accuracy of one-tenth of a second—an angle which may be represented as that which a pin's head subtends at a distance of a mile. But perhaps the most striking of such instances are the discovery of a new planet by observations of the small irregularities noticed by Leverier in the motions of the planet Uranus, and the more recent brilliant discovery by Lord Rayleigh of a new element in the atmosphere through the minute but unexplained anomalies found in weighing a given volume of nitrogen. Many instances might be cited, but these will suffice to justify the statement that "our future discoveries must be looked for in the sixth place of decimals." It follows that every means which facilitates accuracy in measurement is a possible factor in a future discovery, and this will, I trust, be a sufficient excuse for bringing to your notice the various methods and results which form the subject matter of these lectures.