Terrell rotation or Terrell effect is the visual distortion that a passing object would appear to undergo, according to the special theory of relativity if it were travelling at a significant fraction of the speed of light. This behaviour was described independently by both Roger Penrose and James Terrell. Penrose's article was submitted 29 July 1958 and published in January 1959.[1] Terrell's article was submitted 22 June 1959 and published 15 November 1959.[2] The general phenomenon was noted already in 1924 by Austrian physicist Anton Lampa.[3]
This phenomenon was popularized by Victor Weisskopf in a Physics Today article.[4]
Due to an early dispute about priority and correct attribution, the effect is also sometimes referred to as the Penrose–Terrell effect, the Terrell–Penrose effect or the Lampa–Terrell–Penrose effect, but not the Lampa effect.
Further detail
Comparison of the measured length contraction of a cube versus its visual appearance. The view is from the front of the cube at a distance four times the length of the cube's sides, three-quarters of the way from bottom to top, as projected onto a vertical screen (so that the vertical lines of the cube may initially be parallel).
Terrell's and Penrose's papers pointed out that although special relativity appeared to describe an "observed contraction" in moving objects, these interpreted "observations" were not to be confused with the theory's literal predictions for the visible appearance of a moving object. Thanks to the differential timelag effects in signals reaching the observer from the object's different parts, a receding object would appear contracted, an approaching object would appear elongated (even under special relativity) and the geometry of a passing object would appear skewed, as if rotated. By R.Penrose: "the light from the trailing part reaches the observer from behind the sphere, which it can do since the sphere is continuously moving out of its way".[2][1]
A globe, moving at various speeds to the right, is observed from three diameters distance from its nearest point on the surface (marked by a red cross). The left image shows the globe's measured, Lorentz-contracted shape. The right image shows the visual appearance of the globe.
For images of passing objects, the apparent contraction of distances between points on the object's transverse surface could then be interpreted as being due to an apparent change in viewing angle, and the image of the object could be interpreted as appearing instead to be rotated. A previously popular description of special relativity's predictions, in which an observer sees a passing object to be contracted (for instance, from a sphere to a flattened ellipsoid), was wrong. A sphere maintains its circular outline since, as the sphere moves, light from further points of the Lorentz-contracted ellipsoid takes longer to reach the eye.[2][1]
Terrell's and Penrose's papers prompted a number of follow-up papers,[5][6][7][8][9][10][11][12] mostly in the American Journal of Physics, exploring the consequences of this correction. These papers pointed out that some existing discussions of special relativity were flawed and "explained" effects that the theory did not actually predict – while these papers did not change the actual mathematical structure of special relativity in any way, they did correct a misconception regarding the theory's predictions.
A representation of the Terrell effect can be seen in the physics simulator "A Slower Speed of Light," published by MIT.
See also
Length contraction
Stellar aberration
References and further reading
Roger Penrose (1959). "The Apparent Shape of a Relativistically Moving Sphere". Proceedings of the Cambridge Philosophical Society. 55 (1): 137–139. Bibcode:1959PCPS...55..137P. doi:10.1017/S0305004100033776.
James Terrell (1959). "Invisibility of the Lorentz Contraction". Physical Review. 116 (4): 1041–1045. Bibcode:1959PhRv..116.1041T. doi:10.1103/PhysRev.116.1041.
Anton Lampa (1924). "Wie erscheint nach der Relativitätstheorie ein bewegter Stab einem ruhenden Beobachter?". Zeitschrift für Physik (in German). 27 (1): 138–148. Bibcode:1924ZPhy...27..138L. doi:10.1007/BF01328021. S2CID 119547027.
Victor F. Weisskopf (1960). "The visual appearance of rapidly moving objects". Physics Today. 13 (9): 24. Bibcode:1960PhT....13i..24W. doi:10.1063/1.3057105. S2CID 36707809.
Mary L. Boas (1961). "Apparent shape of large objects at relativistic speeds". American Journal of Physics. 29 (5): 283–286. Bibcode:1961AmJPh..29..283B. doi:10.1119/1.1937751.
Eric Sheldon (1988). "The twists and turns of the Terrell Effect". American Journal of Physics. 56 (3): 199–200. Bibcode:1988AmJPh..56..199S. doi:10.1119/1.15687.
James Terrell (1989). "The Terrell Effect". American Journal of Physics. 57 (1): 9–10. Bibcode:1989AmJPh..57....9T. doi:10.1119/1.16131.
Eric Sheldon (1989). "The Terrell Effect: Eppure si contorce!". American Journal of Physics. 57 (6): 487. Bibcode:1989AmJPh..57..487S. doi:10.1119/1.16144.
John Robert Burke and Frank J. Strode (1991). "Classroom exercises with the Terrell effect". American Journal of Physics. 59 (10): 912–915. Bibcode:1991AmJPh..59..912B. doi:10.1119/1.16670.
G. D. Scott and H. J. van Driel (1970). "Geometrical Appearances at Relativistic Speeds". American Journal of Physics. 38 (8): 971–977. Bibcode:1970AmJPh..38..971B. doi:10.1119/1.1976550.
P. M. Mathews and M. Lakshmanan (1972). "On the Apparent Visual Forms of Relativistically Moving Objects". Nuovo Cimento B. 12B (11): 168–181. Bibcode:1972NCimB..12..168M. doi:10.1007/BF02895571. S2CID 118733638.
G.D. Scott and M. R. Viner (1965). "The geometrical appearance of large objects moving at relativistic speeds". American Journal of Physics. 33 (7): 534–536. Bibcode:1965AmJPh..33..534S. doi:10.1119/1.1971890.
External links
A webpage explaining the Penrose-Terrell Effect
An animation demonstrating the effect
Extensive explanations and visualizations of the appearance of moving objects
vte
Roger Penrose
Books
The Emperor's New Mind (1989) Shadows of the Mind (1994) The Road to Reality (2004) Cycles of Time (2010) Fashion, Faith, and Fantasy in the New Physics of the Universe (2016)
Coauthored books
The Nature of Space and Time (with Stephen Hawking) (1996) The Large, the Small and the Human Mind (with Abner Shimony, Nancy Cartwright and Stephen Hawking) (1997) White Mars or, The Mind Set Free (with Brian W. Aldiss) (1999)
Academic works
Techniques of Differential Topology in Relativity (1972) Spinors and Space-Time: Volume 1, Two-Spinor Calculus and Relativistic Fields (with Wolfgang Rindler) (1987) Spinors and Space-Time: Volume 2, Spinor and Twistor Methods in Space-Time Geometry (with Wolfgang Rindler) (1988)
Concepts
Twistor theory Spin network Abstract index notation Black hole bomb Geometry of spacetime Cosmic censorship Weyl curvature hypothesis Penrose inequalities Penrose interpretation of quantum mechanics Moore–Penrose inverse Newman–Penrose formalism Penrose diagram Penrose–Hawking singularity theorems Penrose inequality Penrose process Penrose tiling Penrose triangle Penrose stairs Penrose graphical notation Penrose transform Penrose–Terrell effect Orchestrated objective reduction/Penrose–Lucas argument FELIX experiment Trapped surface Andromeda paradox Conformal cyclic cosmology
Related
Lionel Penrose (father) Oliver Penrose (brother) Jonathan Penrose (brother) Shirley Hodgson (sister) John Beresford Leathes (grandfather) Illumination problem Quantum mind
vte
Relativity
Special
relativity
Background
Principle of relativity (Galilean relativity Galilean transformation) Special relativity Doubly special relativity
Fundamental
concepts
Frame of reference Speed of light Hyperbolic orthogonality Rapidity Maxwell's equations Proper length Proper time Relativistic mass
Formulation
Lorentz transformation
Phenomena
Time dilation Mass–energy equivalence Length contraction Relativity of simultaneity Relativistic Doppler effect Thomas precession Ladder paradox Twin paradox Terrell rotation
Spacetime
Light cone World line Minkowski diagram Biquaternions Minkowski space
Spacetime curvature.png
General
relativity
Background
Introduction Mathematical formulation
Fundamental
concepts
Equivalence principle Riemannian geometry Penrose diagram Geodesics Mach's principle
Formulation
ADM formalism BSSN formalism Einstein field equations Linearized gravity Post-Newtonian formalism Raychaudhuri equation Hamilton–Jacobi–Einstein equation Ernst equation
Phenomena
Black hole Event horizon Singularity Two-body problem
Gravitational waves: astronomy detectors (LIGO and collaboration Virgo LISA Pathfinder GEO) Hulse–Taylor binary
Other tests: precession of Mercury lensing (together with Einstein cross and Einstein rings) redshift Shapiro delay frame-dragging / geodetic effect (Lense–Thirring precession) pulsar timing arrays
Advanced
theories
Brans–Dicke theory Kaluza–Klein Quantum gravity
Solutions
Cosmological: Friedmann–Lemaître–Robertson–Walker (Friedmann equations) Lemaître–Tolman Kasner BKL singularity Gödel Milne
Spherical: Schwarzschild (interior Tolman–Oppenheimer–Volkoff equation) Reissner–Nordström
Axisymmetric: Kerr (Kerr–Newman) Weyl−Lewis−Papapetrou Taub–NUT van Stockum dust discs
Others: pp-wave Ozsváth–Schücking metric
In computational physics: Numerical relativity
Scientists
Poincaré Lorentz Einstein Hilbert Schwarzschild de Sitter Weyl Eddington Friedmann Lemaître Milne Robertson Chandrasekhar Zwicky Wheeler Choquet-Bruhat Kerr Zel'dovich Novikov Ehlers Geroch Penrose Hawking Taylor Hulse Bondi Misner Yau Thorne Weiss others
Hellenica World - Scientific Library
Retrieved from "http://en.wikipedia.org/"
All text is available under the terms of the GNU Free Documentation License