Hamilton's optico-mechanical analogy is a conceptual parallel between trajectories in

classical mechanics Classical mechanics is a Theoretical physics, physical theory describing the motion of objects such as projectiles, parts of Machine (mechanical), machinery, spacecraft, planets, stars, and galaxies. The development of classical mechanics inv ...

and wavefronts in

optics Optics is the branch of physics that studies the behaviour and properties of light, including its interactions with matter and the construction of optical instruments, instruments that use or Photodetector, detect it. Optics usually describes t ...

, introduced by

William Rowan Hamilton Sir William Rowan Hamilton (4 August 1805 – 2 September 1865) was an Irish astronomer, mathematician, and physicist who made numerous major contributions to abstract algebra, classical mechanics, and optics. His theoretical works and mathema ...

around 1831. It may be viewed as linking Huygens' principle of optics with

Maupertuis' principle In classical mechanics, Maupertuis's principle (named after Pierre Louis Maupertuis, 1698 – 1759) states that the path followed by a physical system is the one of least length (with a suitable interpretation of ''path'' and ''length''). It is a ...

of mechanics. Lanczos, C. (1949/1970). Lanczos wrote on p. 136: " aupertuis... thus pointed to that remarkable analogy between optical and mechanical phenomena which was observed much earlier by John Bernoulli and which was later fully developed in Hamilton's ingenious optico-mechanical theory. This analogy played a fundamental role in the development of modern wave-mechanics." Arnold, V.I. (1974/1978), p. 252. While Hamilton discovered the analogy in 1831, it was not applied practically until Hans Busch used it to explain electron beam focusing in 1925. According to

Cornelius Lanczos __NOTOC__ Cornelius (Cornel) Lanczos (, ; born as Kornél Lőwy, until 1906: ''Löwy (Lőwy) Kornél''; February 2, 1893 – June 25, 1974) was a Hungarian-Jewish, Hungarian-American and later Hungarian-Irish mathematician and physicist. Accordi ...

, the analogy has been important in the development of ideas in quantum physics.

Erwin Schrödinger Erwin Rudolf Josef Alexander Schrödinger ( ; ; 12 August 1887 – 4 January 1961), sometimes written as or , was an Austrian-Irish theoretical physicist who developed fundamental results in quantum field theory, quantum theory. In particul ...

cites the analogy in the very first sentence of his paper introducing his

wave mechanics Wave mechanics may refer to: * the mechanics of waves * the application of the quantum wave equation, especially in position and momentum spaces * the resonant interaction of three or more waves, which includes the "three-wave equation" See al ...

. Later in the body of his paper he says: Quantitative and formal analysis based on the analogy use the

Hamilton–Jacobi equation In physics, the Hamilton–Jacobi equation, named after William Rowan Hamilton and Carl Gustav Jacob Jacobi, is an alternative formulation of classical mechanics, equivalent to other formulations such as Newton's laws of motion, Lagrangian mecha ...

; conversely the analogy provides an alternative and more accessible path for introducing the Hamilton–Jacobi equation approach to mechanics. The orthogonality of mechanical trajectories characteristic of geometrical optics to the optical wavefronts characteristic of a full wave equation, resulting from the variational principle, leads to the corresponding differential equations.

Hamilton's analogy

The propagation of light can be considered in terms of rays and wavefronts in ordinary physical three-dimensional space. The

wavefronts In physics, the wavefront of a time-varying ''wave field'' is the set ( locus) of all points having the same ''phase''. The term is generally meaningful only for fields that, at each point, vary sinusoidally in time with a single temporal frequ ...

are two-dimensional curved surfaces; the rays are one-dimensional curved lines. Hamilton's analogy amounts to two interpretations of a figure like the one shown here. In the optical interpretation, the green

are lines of constant

phase Phase or phases may refer to: Science *State of matter, or phase, one of the distinct forms in which matter can exist *Phase (matter), a region of space throughout which all physical properties are essentially uniform *Phase space, a mathematica ...

and the orthogonal red lines are the rays of

geometrical optics Geometrical optics, or ray optics, is a model of optics that describes light Wave propagation, propagation in terms of ''ray (optics), rays''. The ray in geometrical optics is an abstract object, abstraction useful for approximating the paths along ...

. In the mechanical interpretation, the green lines denote constant values of

action Action may refer to: * Action (philosophy), something which is done by a person * Action principles the heart of fundamental physics * Action (narrative), a literary mode * Action fiction, a type of genre fiction * Action game, a genre of video gam ...

derived by applying

Hamilton's principle In physics, Hamilton's principle is William Rowan Hamilton's formulation of the principle of stationary action. It states that the dynamics of a physical system are determined by a variational problem for a functional based on a single funct ...

to mechanical motion and the red lines are the orthogonal object

trajectories A trajectory or flight path is the path that an object with mass in motion follows through space as a function of time. In classical mechanics, a trajectory is defined by Hamiltonian mechanics via canonical coordinates; hence, a complete traje ...

. The orthogonality of the wavefronts to rays (or equal-action surfaces to trajectories) means we can compute one set from the other set. This explains how

Kirchhoff's diffraction formula Kirchhoff's diffraction formula (also called Fresnel–Kirchhoff diffraction formula) approximates light intensity and phase in optical diffraction: light fields in the boundary regions of shadows. The approximation can be used to model light p ...

predicts a wave phenomenon – diffraction – using only geometrical ray tracing. Rays traced from the source to an aperture give a wavefront that becomes sources for rays reaching the diffraction pattern where they are summed using complex phases from the orthogonal wavefronts. The wavefronts and rays or the equal-action surfaces and trajectories are dual objects linked by orthogonality. On one hand, a ray can be regarded as the orbit of a particle of light. It successively punctures the wave surfaces. The successive punctures can be regarded as defining the trajectory of the particle. On the other hand, a wave-front can be regarded as a level surface of displacement of some quantity, such as

electric field An electric field (sometimes called E-field) is a field (physics), physical field that surrounds electrically charged particles such as electrons. In classical electromagnetism, the electric field of a single charge (or group of charges) descri ...

intensity, hydrostatic pressure, particle number density, oscillatory phase, or

probability amplitude In quantum mechanics, a probability amplitude is a complex number used for describing the behaviour of systems. The square of the modulus of this quantity at a point in space represents a probability density at that point. Probability amplitu ...

. Then the physical meaning of the rays is less evident.

Huygens' principle; Fermat's principle

The Hamilton optico-mechanical analogy is closely related to

Fermat's principle Fermat's principle, also known as the principle of least time, is the link between geometrical optics, ray optics and physical optics, wave optics. Fermat's principle states that the path taken by a Ray (optics), ray between two given ...

and thus to the

Huygens–Fresnel principle The Huygens–Fresnel principle (named after Netherlands, Dutch physicist Christiaan Huygens and France, French physicist Augustin-Jean Fresnel) states that every point on a wavefront is itself the source of spherical wavelets, and the secondary w ...

. Fermat's principle states that the rays between wavefronts will take the path least time; the concept of successive wavefronts derives from Huygens principle.

Extended Huygens' principle

Going beyond ordinary three-dimensional physical space, one can imagine a higher dimensional abstract configuration "space", with a dimension a multiple of 3. In this space, one can imagine again rays as one-dimensional curved lines. Now the wavefronts are hypersurfaces of dimension one less than the dimension of the space. Such a multi-dimensional space can serve as a configuration space for a multi-particle system.

Classical limit of the Schrödinger equation

Albert Messiah Albert Messiah (23 September 1921, Nice – 17 April 2013, Paris) was a French physicist. He studied at the Ecole Polytechnique. He spent the Second World War in the Free France forces: he embarked on 22 June 1940 at Saint-Jean-de-Luz for Engla ...

considers a

classical limit The classical limit or correspondence limit is the ability of a physical theory to approximate or "recover" classical mechanics when considered over special values of its parameters. The classical limit is used with physical theories that predict n ...

of the Schrödinger equation. He finds there an optical analogy. The trajectories of his particles are orthogonal to the surfaces of equal phase. He writes "In the language of optics, the latter are the wave fronts, and the trajectories of the particles are the rays. Hence the classical approximation is equivalent to the geometric optics approximation: we find once again, as a consequence of the Schrödinger equation, the basic postulate of the theory of matter waves."

History

Hamilton's optico-mechanical analogy played a critical part in the thinking of Schrödinger, one of the originators of quantum mechanics. Section 1 of his paper published in December 1926 is titled "The Hamiltonian analogy between mechanics and optics". Section 1 of the first of his four lectures on wave mechanics delivered in 1928 is titled "Derivation of the fundamental idea of wave mechanics from Hamilton's analogy between ordinary mechanics and geometrical optics". In a brief paper in 1923, de Broglie wrote : "Dynamics must undergo the same evolution that optics has undergone when undulations took the place of purely geometrical optics." In his 1924 thesis, though

Louis de Broglie Louis Victor Pierre Raymond, 7th Duc de Broglie (15 August 1892 – 19 March 1987) was a French theoretical physicist and aristocrat known for his contributions to quantum theory. In his 1924 PhD thesis, he postulated the wave nature of elec ...

did not name the optico-mechanical analogy, he wrote in his introduction, In the opinion of

Léon Rosenfeld Léon Rosenfeld (; 14 August 1904 in Charleroi – 23 March 1974) was a Belgian physicist and a communist activist. Rosenfeld was born into a secular Jewish family. He was a polyglot who knew eight or nine languages and was fluent in at lea ...

, a close colleague of

Niels Bohr Niels Henrik David Bohr (, ; ; 7 October 1885 – 18 November 1962) was a Danish theoretical physicist who made foundational contributions to understanding atomic structure and old quantum theory, quantum theory, for which he received the No ...

, "... Schrödinger asinspired by Hamilton's beautiful comparison of classical mechanics and geometrical optics ..." The first textbook in English on wave mechanics devotes the second of its two chapters to "Wave mechanics in relation to ordinary mechanics". It opines "... de Broglie and Schrödinger have turned this false analogy into a true one by using the natural Unit or Measure of Action, , .... ... We must now go into Hamilton's theory in more detail, for when once its true meaning is grasped the step to wave mechanics is but a short one—indeed now, after the event, almost seems to suggest itself." According to one textbook, "The first part of our problem, namely, the establishment of a system of first-order equations satisfying the spacetime symmetry condition, can be solved in a very simple way, with the help of the analogy between mechanics and optics, which was the starting point for the development of wave mechanics and which can still be used—with reservations—as a source of inspiration." Recently the concept has been extended to wavelength dependent regime.

References

Bibliography of cited sources

* Arnold, V.I. (1974/1978). ''Mathematical Methods of Classical Mechanics'', translated by K. Vogtmann, A. Weinstein, Springer, Berlin, . * Biggs, H.F. (1927). ''Wave Mechanics. An Introductory Sketch'', Oxford University Press, London. * de Broglie, L. (1923). Waves and quanta, ''Nature'' 112: 540. * de Broglie, L., ''Recherches sur la théorie des quanta'' (Researches on the quantum theory), Thesis (Paris), 1924; de Broglie, L., ''Ann. Phys.'' (Paris) 3, 22 (1925)
English translation by A.F. Kracklauer
* Cohen, R.S, Stachel, J.J., editors, (1979). ''Selected papers of

'', D. Reidel Publishing Company, Dordrecht, . * Jammer, M. (1966). ''The Conceptual Development of Quantum Mechanics'', MGraw–Hill, New York. * Frenkel, J. (1934). ''Wave mechanics. Advanced General Theory'', Oxford University Press, London. * Kemble, E.C. (1937). ''The Fundamental Principles of Quantum Mechanics, with Elementary Applications'', McGraw–Hill, New York. * Hamilton, W.R., (1834). On the application to dynamics of a general mathematical method previously applied to optics, ''British Association Report'', pp. 513–518, reprinted in ''The Mathematical Papers of Sir William Rowan Hamilton'' (1940), ed. A.W. Conway, A.J. McConnell, volume 2, Cambridge University Press, London. * Lanczos, C. (1949/1970). ''The Variational Principles of Mechanics'', 4th edition, University of Toronto Press, Toronto, . * Messiah, A. (1961). ''Quantum Mechanics'', volume 1, translated by G.M. Temmer from the French ''Mécanique Quantique'', North-Holland, Amsterdam. * Rosenfeld, L. (1971). Men and ideas in the history of atomic theory, ''Arch. Hist. Exact Sci.'', 7: 69–90. Reprinted on pp. 266–296 of Cohen, R.S, Stachel, J.J. (1979). * Schrödinger, E. (1926). An undulatory theory of the mechanics of atoms and molecules, ''Phys. Rev.'', second series 28 (6): 1049–1070. * Schrödinger, E. (1926/1928). ''Collected papers on Wave Mechanics'', translated by J.F. Shearer and W.M. Deans from the second German edition, Blackie & Son, London. * Schrödinger, E. (1928). ''Four Lectures on Wave Mechanics. Delivered at the Royal Institution, London, on 5th, 7th, 12th, and 14th March, 1928'', Blackie & Son, London. * Synge, J.L. (1954). ''Geometrical Mechanics and de Broglie Waves'', Cambridge University Press, Cambridge UK. {{refend Hamiltonian mechanics Quantum mechanics Wave mechanics