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Relativity of simultaneity

December 14, 2023

In physics, the relativity of simultaneity is the concept that distant simultaneity – whether two spatially separated events occur at the same time – is not absolute, but depends on the observer's reference frame. This possibility was raised by mathematician Henri Poincaré in 1900, and thereafter became a central idea in the special theory of relativity.

On spaceships, map-clocks may look unsynchronized.
Event B is simultaneous with A in the green reference frame, but it occurred before in the blue frame, and will occur later in the red frame.
Events A, B, and C occur in different order depending on the motion of the observer. The white line represents a plane of simultaneity being moved from the past to the future.

Description edit

According to the special theory of relativity introduced by Albert Einstein, it is impossible to say in an absolute sense that two distinct events occur at the same time if those events are separated in space. If one reference frame assigns precisely the same time to two events that are at different points in space, a reference frame that is moving relative to the first will generally assign different times to the two events (the only exception being when motion is exactly perpendicular to the line connecting the locations of both events).

For example, a car crash in London and another in New York appearing to happen at the same time to an observer on Earth, will appear to have occurred at slightly different times to an observer on an airplane flying between London and New York. Furthermore, if the two events cannot be causally connected, depending on the state of motion, the crash in London may appear to occur first in a given frame, and the New York crash may appear to occur first in another. However, if the events are causally connected, precedence order is preserved in all frames of reference.[1]

History edit

Main articles: History of special relativity, History of Lorentz transformations, and Lorentz ether theory

In 1892 and 1895, Hendrik Lorentz used a mathematical method called "local time" t' = t – v x/c2 for explaining the negative aether drift experiments.[2] However, Lorentz gave no physical explanation of this effect. This was done by Henri Poincaré who already emphasized in 1898 the conventional nature of simultaneity and who argued that it is convenient to postulate the constancy of the speed of light in all directions. However, this paper did not contain any discussion of Lorentz's theory or the possible difference in defining simultaneity for observers in different states of motion.[3][4] This was done in 1900, when Poincaré derived local time by assuming that the speed of light is invariant within the aether. Due to the "principle of relative motion", moving observers within the aether also assume that they are at rest and that the speed of light is constant in all directions (only to first order in v/c). Therefore, if they synchronize their clocks by using light signals, they will only consider the transit time for the signals, but not their motion in respect to the aether. So the moving clocks are not synchronous and do not indicate the "true" time. Poincaré calculated that this synchronization error corresponds to Lorentz's local time.[5][6] In 1904, Poincaré emphasized the connection between the principle of relativity, "local time", and light speed invariance; however, the reasoning in that paper was presented in a qualitative and conjectural manner.[7][8]

Albert Einstein used a similar method in 1905 to derive the time transformation for all orders in v/c, i.e., the complete Lorentz transformation. Poincaré obtained the full transformation earlier in 1905 but in the papers of that year he did not mention his synchronization procedure. This derivation was completely based on light speed invariance and the relativity principle, so Einstein noted that for the electrodynamics of moving bodies the aether is superfluous. Thus, the separation into "true" and "local" times of Lorentz and Poincaré vanishes – all times are equally valid and therefore the relativity of length and time is a natural consequence.[9][10][11]

In 1908, Hermann Minkowski introduced the concept of a world line of a particle[12] in his model of the cosmos called Minkowski space. In Minkowski's view, the naïve notion of velocity is replaced with rapidity, and the ordinary sense of simultaneity becomes dependent on hyperbolic orthogonality of spatial directions to the worldline associated to the rapidity. Then every inertial frame of reference has a rapidity and a simultaneous hyperplane.

In 1990 Robert Goldblatt wrote Orthogonality and Spacetime Geometry, directly addressing the structure Minkowski had put in place for simultaneity.[13] In 2006 Max Jammer, through Project MUSE, published Concepts of Simultaneity: from antiquity to Einstein and beyond. The book culminates in chapter 6, "The transition to the relativistic conception of simultaneity". Jammer indicates that Ernst Mach demythologized the absolute time of Newtonian physics.

Naturally the mathematical notions preceded physical interpretation. For instance conjugate diameters of a hyperbola, are related as space and time. The principle of relativity can be expressed as the arbitrariness of which pair are taken to represent space and time in a plane.[14]

Thought experiments edit

See also: Einstein's thought experiments

Einstein's train edit

 
Einstein imagined a stationary observer who witnessed two lightning bolts simultaneously striking both ends of a moving train. He concluded that an observer standing on the train would measure the bolts to strike at different times.

Einstein's version of the experiment[15] presumed that one observer was sitting midway inside a speeding traincar and another was standing on a platform as the train moved past. As measured by the standing observer, the train is struck by two bolts of lightning simultaneously, but at different positions along the axis of train movement (back and front of the train car). In the inertial frame of the standing observer, there are three events which are spatially dislocated, but simultaneous: standing observer facing the moving observer (i.e., the center of the train), lightning striking the front of the train car, and lightning striking the back of the car.

Since the events are placed along the axis of train movement, their time coordinates become projected to different time coordinates in the moving train's inertial frame. Events which occurred at space coordinates in the direction of train movement happen earlier than events at coordinates opposite to the direction of train movement. In the moving train's inertial frame, this means that lightning will strike the front of the train car before the two observers align (face each other).

The train-and-platform edit

 
The train-and-platform experiment from the reference frame of an observer on board the train
 
Reference frame of an observer standing on the platform (length contraction not depicted)

A popular picture for understanding this idea is provided by a thought experiment similar to those suggested by Daniel Frost Comstock in 1910[16] and Einstein in 1917.[17][15] It also consists of one observer midway inside a speeding traincar and another observer standing on a platform as the train moves past.

A flash of light is given off at the center of the traincar just as the two observers pass each other. For the observer on board the train, the front and back of the traincar are at fixed distances from the light source and as such, according to this observer, the light will reach the front and back of the traincar at the same time.

For the observer standing on the platform, on the other hand, the rear of the traincar is moving (catching up) toward the point at which the flash was given off, and the front of the traincar is moving away from it. As the speed of light is finite and the same in all directions for all observers, the light headed for the back of the train will have less distance to cover than the light headed for the front. Thus, the flashes of light will strike the ends of the traincar at different times.

 
The spacetime diagram in the frame of the observer on the train.
 
The same diagram in the frame of an observer who sees the train moving to the right.

Spacetime diagrams edit

It may be helpful to visualize this situation using spacetime diagrams. For a given observer, the t-axis is defined to be a point traced out in time by the origin of the spatial coordinate x, and is drawn vertically. The x-axis is defined as the set of all points in space at the time t = 0, and is drawn horizontally. The statement that the speed of light is the same for all observers is represented by drawing a light ray as a 45° line, regardless of the speed of the source relative to the speed of the observer.

In the first diagram, the two ends of the train are drawn as grey lines. Because the ends of the train are stationary with respect to the observer on the train, these lines are just vertical lines, showing their motion through time but not space. The flash of light is shown as the 45° red lines. The points at which the two light flashes hit the ends of the train are at the same level in the diagram. This means that the events are simultaneous.

In the second diagram, the two ends of the train moving to the right, are shown by parallel lines. The flash of light is given off at a point exactly halfway between the two ends of the train, and again form two 45° lines, expressing the constancy of the speed of light. In this picture, however, the points at which the light flashes hit the ends of the train are not at the same level; they are not simultaneous.

Lorentz transformation edit

The relativity of simultaneity can be demonstrated using the Lorentz transformation, which relates the coordinates used by one observer to coordinates used by another in uniform relative motion with respect to the first.

Assume that the first observer uses coordinates labeled t, x, y, and z, while the second observer uses coordinates labeled t′, x′, y′, and z′. Now suppose that the first observer sees the second observer moving in the x-direction at a velocity v. And suppose that the observers' coordinate axes are parallel and that they have the same origin. Then the Lorentz transformation expresses how the coordinates are related:

 
 
 
 
where c is the speed of light. If two events happen at the same time in the frame of the first observer, they will have identical values of the t-coordinate. However, if they have different values of the x-coordinate (different positions in the x-direction), they will have different values of the t' coordinate, so they will happen at different times in that frame. The term that accounts for the failure of absolute simultaneity is the vx/c2.
 
A spacetime diagram showing the set of points regarded as simultaneous by a stationary observer (horizontal dotted line) and the set of points regarded as simultaneous by an observer moving at v = 0.25c (dashed line)

The equation t′ = constant defines a "line of simultaneity" in the (x′, t′) coordinate system for the second (moving) observer, just as the equation t = constant defines the "line of simultaneity" for the first (stationary) observer in the (x, t) coordinate system. From the above equations for the Lorentz transform it can be seen that t' is constant if and only if tvx/c2 = constant. Thus the set of points that make t constant are different from the set of points that makes t' constant. That is, the set of events which are regarded as simultaneous depends on the frame of reference used to make the comparison.

Graphically, this can be represented on a spacetime diagram by the fact that a plot of the set of points regarded as simultaneous generates a line which depends on the observer. In the spacetime diagram, the dashed line represents a set of points considered to be simultaneous with the origin by an observer moving with a velocity v of one-quarter of the speed of light. The dotted horizontal line represents the set of points regarded as simultaneous with the origin by a stationary observer. This diagram is drawn using the (x, t) coordinates of the stationary observer, and is scaled so that the speed of light is one, i.e., so that a ray of light would be represented by a line with a 45° angle from the x axis. From our previous analysis, given that v = 0.25 and c = 1, the equation of the dashed line of simultaneity is t − 0.25x = 0 and with v = 0, the equation of the dotted line of simultaneity is t = 0.

In general the second observer traces out a worldline in the spacetime of the first observer described by t = x/v, and the set of simultaneous events for the second observer (at the origin) is described by the line t = vx. Note the multiplicative inverse relation of the slopes of the worldline and simultaneous events, in accord with the principle of hyperbolic orthogonality.

Accelerated observers edit

 
Roundtrip radar-time isocontours.

The Lorentz-transform calculation above uses a definition of extended-simultaneity (i.e. of when and where events occur at which you were not present) that might be referred to as the co-moving or "tangent free-float-frame" definition. This definition is naturally extrapolated to events in gravitationally-curved spacetimes, and to accelerated observers, through use of a radar-time/distance definition that (unlike the tangent free-float-frame definition for accelerated frames) assigns a unique time and position to any event.[18]

The radar-time definition of extended-simultaneity further facilitates visualization of the way that acceleration curves spacetime for travelers in the absence of any gravitating objects. This is illustrated in the figure at right, which shows radar time/position isocontours for events in flat spacetime as experienced by a traveler (red trajectory) taking a constant proper-acceleration roundtrip. One caveat of this approach is that the time and place of remote events are not fully defined until light from such an event is able to reach our traveler.

See also edit

References edit

  1. ^ Mamone-Capria, Marco (2012), "Simultaneity as an invariant equivalence relation", Foundations of Physics, 42 (11): 1365–1383, arXiv:1202.6578, Bibcode:2012FoPh...42.1365M, doi:10.1007/s10701-012-9674-4, S2CID 254513121
  2. ^ Lorentz, Hendrik Antoon (1895), Versuch einer Theorie der electrischen und optischen Erscheinungen in bewegten Körpern , Leiden: E.J. Brill
  3. ^ Poincaré, Henri (1898–1913), "The Measure of Time" , The foundations of science, New York: Science Press, pp. 222–234
  4. ^ Galison, Peter (2003), Einstein's Clocks, Poincaré's Maps: Empires of Time, New York: W.W. Norton, ISBN 0-393-32604-7
  5. ^ Poincaré, Henri (1900), "La théorie de Lorentz et le principe de réaction" , Archives Néerlandaises des Sciences Exactes et Naturelles, 5: 252–278. See also the English translation.
  6. ^ Darrigol, Olivier (2005), "The Genesis of the theory of relativity" (PDF), Séminaire Poincaré, 1: 1–22, Bibcode:2006eins.book....1D, doi:10.1007/3-7643-7436-5_1, ISBN 978-3-7643-7435-8
  7. ^ Poincaré, Henri (1904–1906), "The Principles of Mathematical Physics" , Congress of arts and science, universal exposition, St. Louis, 1904, vol. 1, Boston and New York: Houghton, Mifflin and Company, pp. 604–622
  8. ^ Holton, Gerald (1988), Thematic Origins of Scientific Thought: Kepler to Einstein, Harvard University Press, ISBN 0-674-87747-0
  9. ^ Einstein, Albert (1905), "Zur Elektrodynamik bewegter Körper" (PDF), Annalen der Physik, 322 (10): 891–921, Bibcode:1905AnP...322..891E, doi:10.1002/andp.19053221004. See also: English translation.
  10. ^ Miller, Arthur I. (1981), Albert Einstein's special theory of relativity. Emergence (1905) and early interpretation (1905–1911), Reading: Addison–Wesley, ISBN 0-201-04679-2
  11. ^ Pais, Abraham (1982), Subtle is the Lord: The Science and the Life of Albert Einstein, New York: Oxford University Press, ISBN 0-19-520438-7
  12. ^ Minkowski, Hermann (1909), "Raum und Zeit" , Physikalische Zeitschrift, 10: 75–88
    • Various English translations on Wikisource: Space and Time
  13. ^ A.D. Taimanov (1989) "Review of Orthogonality and Spacetime Geometry", Bulletin of the American Mathematical Society 21(1)
  14. ^ Whittaker, E.T. (1910). A History of the Theories of Aether and Electricity (1 ed.). Dublin: Longman, Green and Co. p. 441.
  15. ^ a b Einstein, Albert (2017), Relativity - The Special and General Theory, Samaira Book Publishers, pp. 30–33, ISBN 978-81-935401-7-6[permanent dead link], Chapter IX 2020-10-12 at the Wayback Machine
  16. ^ The thought experiment by Comstock described two platforms in relative motion. See: Comstock, D.F. (1910), "The principle of relativity" , Science, 31 (803): 767–772, Bibcode:1910Sci....31..767C, doi:10.1126/science.31.803.767, PMID 17758464, S2CID 33246058.
  17. ^ Einstein's thought experiment used two light rays starting at both ends of the platform. See: Einstein A. (1917), Relativity: The Special and General Theory , Springer
  18. ^ Dolby, Carl E.; Gull, Stephen F. (December 2001). "On radar time and the twin "paradox"". American Journal of Physics. 69 (12): 1257–1261. arXiv:gr-qc/0104077. Bibcode:2001AmJPh..69.1257D. doi:10.1119/1.1407254. S2CID 119067219.

External links edit

  •   Special relativity at Wikibooks

December 14, 2023
relativity, simultaneity, this, article, lead, section, short, adequately, summarize, points, please, consider, expanding, lead, provide, accessible, overview, important, aspects, article, october, 2022, physics, relativity, simultaneity, concept, that, distan. This article s lead section may be too short to adequately summarize the key points Please consider expanding the lead to provide an accessible overview of all important aspects of the article October 2022 In physics the relativity of simultaneity is the concept that distant simultaneity whether two spatially separated events occur at the same time is not absolute but depends on the observer s reference frame This possibility was raised by mathematician Henri Poincare in 1900 and thereafter became a central idea in the special theory of relativity On spaceships map clocks may look unsynchronized Event B is simultaneous with A in the green reference frame but it occurred before in the blue frame and will occur later in the red frame Events A B and C occur in different order depending on the motion of the observer The white line represents a plane of simultaneity being moved from the past to the future Contents 1 Description 2 History 3 Thought experiments 3 1 Einstein s train 3 2 The train and platform 3 2 1 Spacetime diagrams 4 Lorentz transformation 5 Accelerated observers 6 See also 7 References 8 External linksDescription editAccording to the special theory of relativity introduced by Albert Einstein it is impossible to say in an absolute sense that two distinct events occur at the same time if those events are separated in space If one reference frame assigns precisely the same time to two events that are at different points in space a reference frame that is moving relative to the first will generally assign different times to the two events the only exception being when motion is exactly perpendicular to the line connecting the locations of both events For example a car crash in London and another in New York appearing to happen at the same time to an observer on Earth will appear to have occurred at slightly different times to an observer on an airplane flying between London and New York Furthermore if the two events cannot be causally connected depending on the state of motion the crash in London may appear to occur first in a given frame and the New York crash may appear to occur first in another However if the events are causally connected precedence order is preserved in all frames of reference 1 History editMain articles History of special relativity History of Lorentz transformations and Lorentz ether theory In 1892 and 1895 Hendrik Lorentz used a mathematical method called local time t t v x c2 for explaining the negative aether drift experiments 2 However Lorentz gave no physical explanation of this effect This was done by Henri Poincare who already emphasized in 1898 the conventional nature of simultaneity and who argued that it is convenient to postulate the constancy of the speed of light in all directions However this paper did not contain any discussion of Lorentz s theory or the possible difference in defining simultaneity for observers in different states of motion 3 4 This was done in 1900 when Poincare derived local time by assuming that the speed of light is invariant within the aether Due to the principle of relative motion moving observers within the aether also assume that they are at rest and that the speed of light is constant in all directions only to first order in v c Therefore if they synchronize their clocks by using light signals they will only consider the transit time for the signals but not their motion in respect to the aether So the moving clocks are not synchronous and do not indicate the true time Poincare calculated that this synchronization error corresponds to Lorentz s local time 5 6 In 1904 Poincare emphasized the connection between the principle of relativity local time and light speed invariance however the reasoning in that paper was presented in a qualitative and conjectural manner 7 8 Albert Einstein used a similar method in 1905 to derive the time transformation for all orders in v c i e the complete Lorentz transformation Poincare obtained the full transformation earlier in 1905 but in the papers of that year he did not mention his synchronization procedure This derivation was completely based on light speed invariance and the relativity principle so Einstein noted that for the electrodynamics of moving bodies the aether is superfluous Thus the separation into true and local times of Lorentz and Poincare vanishes all times are equally valid and therefore the relativity of length and time is a natural consequence 9 10 11 In 1908 Hermann Minkowski introduced the concept of a world line of a particle 12 in his model of the cosmos called Minkowski space In Minkowski s view the naive notion of velocity is replaced with rapidity and the ordinary sense of simultaneity becomes dependent on hyperbolic orthogonality of spatial directions to the worldline associated to the rapidity Then every inertial frame of reference has a rapidity and a simultaneous hyperplane In 1990 Robert Goldblatt wrote Orthogonality and Spacetime Geometry directly addressing the structure Minkowski had put in place for simultaneity 13 In 2006 Max Jammer through Project MUSE published Concepts of Simultaneity from antiquity to Einstein and beyond The book culminates in chapter 6 The transition to the relativistic conception of simultaneity Jammer indicates that Ernst Mach demythologized the absolute time of Newtonian physics Naturally the mathematical notions preceded physical interpretation For instance conjugate diameters of a hyperbola are related as space and time The principle of relativity can be expressed as the arbitrariness of which pair are taken to represent space and time in a plane 14 Thought experiments editSee also Einstein s thought experiments Einstein s train edit nbsp Einstein imagined a stationary observer who witnessed two lightning bolts simultaneously striking both ends of a moving train He concluded that an observer standing on the train would measure the bolts to strike at different times Einstein s version of the experiment 15 presumed that one observer was sitting midway inside a speeding traincar and another was standing on a platform as the train moved past As measured by the standing observer the train is struck by two bolts of lightning simultaneously but at different positions along the axis of train movement back and front of the train car In the inertial frame of the standing observer there are three events which are spatially dislocated but simultaneous standing observer facing the moving observer i e the center of the train lightning striking the front of the train car and lightning striking the back of the car Since the events are placed along the axis of train movement their time coordinates become projected to different time coordinates in the moving train s inertial frame Events which occurred at space coordinates in the direction of train movement happen earlier than events at coordinates opposite to the direction of train movement In the moving train s inertial frame this means that lightning will strike the front of the train car before the two observers align face each other The train and platform edit nbsp The train and platform experiment from the reference frame of an observer on board the train nbsp Reference frame of an observer standing on the platform length contraction not depicted A popular picture for understanding this idea is provided by a thought experiment similar to those suggested by Daniel Frost Comstock in 1910 16 and Einstein in 1917 17 15 It also consists of one observer midway inside a speeding traincar and another observer standing on a platform as the train moves past A flash of light is given off at the center of the traincar just as the two observers pass each other For the observer on board the train the front and back of the traincar are at fixed distances from the light source and as such according to this observer the light will reach the front and back of the traincar at the same time For the observer standing on the platform on the other hand the rear of the traincar is moving catching up toward the point at which the flash was given off and the front of the traincar is moving away from it As the speed of light is finite and the same in all directions for all observers the light headed for the back of the train will have less distance to cover than the light headed for the front Thus the flashes of light will strike the ends of the traincar at different times nbsp The spacetime diagram in the frame of the observer on the train nbsp The same diagram in the frame of an observer who sees the train moving to the right Spacetime diagrams edit It may be helpful to visualize this situation using spacetime diagrams For a given observer the t axis is defined to be a point traced out in time by the origin of the spatial coordinate x and is drawn vertically The x axis is defined as the set of all points in space at the time t 0 and is drawn horizontally The statement that the speed of light is the same for all observers is represented by drawing a light ray as a 45 line regardless of the speed of the source relative to the speed of the observer In the first diagram the two ends of the train are drawn as grey lines Because the ends of the train are stationary with respect to the observer on the train these lines are just vertical lines showing their motion through time but not space The flash of light is shown as the 45 red lines The points at which the two light flashes hit the ends of the train are at the same level in the diagram This means that the events are simultaneous In the second diagram the two ends of the train moving to the right are shown by parallel lines The flash of light is given off at a point exactly halfway between the two ends of the train and again form two 45 lines expressing the constancy of the speed of light In this picture however the points at which the light flashes hit the ends of the train are not at the same level they are not simultaneous Lorentz transformation editThe relativity of simultaneity can be demonstrated using the Lorentz transformation which relates the coordinates used by one observer to coordinates used by another in uniform relative motion with respect to the first Assume that the first observer uses coordinates labeled t x y and z while the second observer uses coordinates labeled t x y and z Now suppose that the first observer sees the second observer moving in the x direction at a velocity v And suppose that the observers coordinate axes are parallel and that they have the same origin Then the Lorentz transformation expresses how the coordinates are related t t v x c 2 1 v 2 c 2 displaystyle t frac t v x c 2 sqrt 1 v 2 c 2 nbsp x x v t 1 v 2 c 2 displaystyle x frac x v t sqrt 1 v 2 c 2 nbsp y y displaystyle y y nbsp z z displaystyle z z nbsp where c is the speed of light If two events happen at the same time in the frame of the first observer they will have identical values of the t coordinate However if they have different values of the x coordinate different positions in the x direction they will have different values of the t coordinate so they will happen at different times in that frame The term that accounts for the failure of absolute simultaneity is the vx c2 nbsp A spacetime diagram showing the set of points regarded as simultaneous by a stationary observer horizontal dotted line and the set of points regarded as simultaneous by an observer moving at v 0 25c dashed line The equation t constant defines a line of simultaneity in the x t coordinate system for the second moving observer just as the equation t constant defines the line of simultaneity for the first stationary observer in the x t coordinate system From the above equations for the Lorentz transform it can be seen that t is constant if and only if t vx c2 constant Thus the set of points that make t constant are different from the set of points that makes t constant That is the set of events which are regarded as simultaneous depends on the frame of reference used to make the comparison Graphically this can be represented on a spacetime diagram by the fact that a plot of the set of points regarded as simultaneous generates a line which depends on the observer In the spacetime diagram the dashed line represents a set of points considered to be simultaneous with the origin by an observer moving with a velocity v of one quarter of the speed of light The dotted horizontal line represents the set of points regarded as simultaneous with the origin by a stationary observer This diagram is drawn using the x t coordinates of the stationary observer and is scaled so that the speed of light is one i e so that a ray of light would be represented by a line with a 45 angle from the x axis From our previous analysis given that v 0 25 and c 1 the equation of the dashed line of simultaneity is t 0 25x 0 and with v 0 the equation of the dotted line of simultaneity is t 0 In general the second observer traces out a worldline in the spacetime of the first observer described by t x v and the set of simultaneous events for the second observer at the origin is described by the line t vx Note the multiplicative inverse relation of the slopes of the worldline and simultaneous events in accord with the principle of hyperbolic orthogonality Accelerated observers edit nbsp Roundtrip radar time isocontours The Lorentz transform calculation above uses a definition of extended simultaneity i e of when and where events occur at which you were not present that might be referred to as the co moving or tangent free float frame definition This definition is naturally extrapolated to events in gravitationally curved spacetimes and to accelerated observers through use of a radar time distance definition that unlike the tangent free float frame definition for accelerated frames assigns a unique time and position to any event 18 The radar time definition of extended simultaneity further facilitates visualization of the way that acceleration curves spacetime for travelers in the absence of any gravitating objects This is illustrated in the figure at right which shows radar time position isocontours for events in flat spacetime as experienced by a traveler red trajectory taking a constant proper acceleration roundtrip One caveat of this approach is that the time and place of remote events are not fully defined until light from such an event is able to reach our traveler See also editAndromeda paradox Causal structure Einstein s thought experiments Ehrenfest s paradox Einstein synchronisationReferences edit Mamone Capria Marco 2012 Simultaneity as an invariant equivalence relation Foundations of Physics 42 11 1365 1383 arXiv 1202 6578 Bibcode 2012FoPh 42 1365M doi 10 1007 s10701 012 9674 4 S2CID 254513121 Lorentz Hendrik Antoon 1895 Versuch einer Theorie der electrischen und optischen Erscheinungen in bewegten Korpern Leiden E J Brill Poincare Henri 1898 1913 The Measure of Time The foundations of science New York Science Press pp 222 234 Galison Peter 2003 Einstein s Clocks Poincare s Maps Empires of Time New York W W Norton ISBN 0 393 32604 7 Poincare Henri 1900 La theorie de Lorentz et le principe de reaction Archives Neerlandaises des Sciences Exactes et Naturelles 5 252 278 See also the English translation Darrigol Olivier 2005 The Genesis of the theory of relativity PDF Seminaire Poincare 1 1 22 Bibcode 2006eins book 1D doi 10 1007 3 7643 7436 5 1 ISBN 978 3 7643 7435 8 Poincare Henri 1904 1906 The Principles of Mathematical Physics Congress of arts and science universal exposition St Louis 1904 vol 1 Boston and New York Houghton Mifflin and Company pp 604 622 Holton Gerald 1988 Thematic Origins of Scientific Thought Kepler to Einstein Harvard University Press ISBN 0 674 87747 0 Einstein Albert 1905 Zur Elektrodynamik bewegter Korper PDF Annalen der Physik 322 10 891 921 Bibcode 1905AnP 322 891E doi 10 1002 andp 19053221004 See also English translation Miller Arthur I 1981 Albert Einstein s special theory of relativity Emergence 1905 and early interpretation 1905 1911 Reading Addison Wesley ISBN 0 201 04679 2 Pais Abraham 1982 Subtle is the Lord The Science and the Life of Albert Einstein New York Oxford University Press ISBN 0 19 520438 7 Minkowski Hermann 1909 Raum und Zeit Physikalische Zeitschrift 10 75 88 Various English translations on Wikisource Space and Time A D Taimanov 1989 Review of Orthogonality and Spacetime Geometry Bulletin of the American Mathematical Society 21 1 Whittaker E T 1910 A History of the Theories of Aether and Electricity 1 ed Dublin Longman Green and Co p 441 a b Einstein Albert 2017 Relativity The Special and General Theory Samaira Book Publishers pp 30 33 ISBN 978 81 935401 7 6 permanent dead link Chapter IX Archived 2020 10 12 at the Wayback Machine The thought experiment by Comstock described two platforms in relative motion See Comstock D F 1910 The principle of relativity Science 31 803 767 772 Bibcode 1910Sci 31 767C doi 10 1126 science 31 803 767 PMID 17758464 S2CID 33246058 Einstein s thought experiment used two light rays starting at both ends of the platform See Einstein A 1917 Relativity The Special and General Theory Springer Dolby Carl E Gull Stephen F December 2001 On radar time and the twin paradox American Journal of Physics 69 12 1257 1261 arXiv gr qc 0104077 Bibcode 2001AmJPh 69 1257D doi 10 1119 1 1407254 S2CID 119067219 External links edit nbsp Special relativity at Wikibooks Retrieved from https en wikipedia org w index php title Relativity of simultaneity amp oldid 1180635079, wikipedia, wiki, book, books, library,

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