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Relativity: The Special & the General Theory / A Popular Exposition, 3rd ed. cover

Relativity: The Special & the General Theory / A Popular Exposition, 3rd ed.

Chapter 30: XXVI: THE SPACE-TIME CONTINUUM OF THE SPECIAL THEORY OF RELATIVITY CONSIDERED AS A EUCLIDEAN CONTINUUM
By Albert Einstein
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About This Book

Aimed at readers with some mathematical background, the work explains the principles and consequences of both the special and general theories of relativity without heavy formalism. It reexamines space, time, simultaneity, and coordinate systems to introduce the Lorentz transformation and the resulting behavior of moving clocks and measuring rods, including velocity addition. It then develops the equivalence principle and presents gravity as a manifestation of spacetime geometry, outlines the qualitative form of the gravitational field equations, and surveys empirical tests and observable implications for light propagation and planetary motion, with diagrams and appendices to clarify key points.

XXVI

THE SPACE-TIME CONTINUUM OF THE SPECIAL THEORY OF RELATIVITY CONSIDERED AS A EUCLIDEAN CONTINUUM

WE are now in a position to formulate more exactly the idea of Minkowski, which was only vaguely indicated in Section XVII. In accordance with the special theory of relativity, certain co-ordinate systems are given preference for the description of the four-dimensional, space-time continuum. We called these "Galileian co-ordinate systems." For these systems, the four co-ordinates , , , , which determine an event or—in other words—a point of the four-dimensional continuum, are defined physically in a simple manner, as set forth in detail in the first part of this book. For the transition from one Galileian system to another, which is moving uniformly with reference to the first, the equations of the Lorentz transformation are valid. These last form the basis for the derivation of deductions from the special theory of relativity, and in themselves they are nothing more than the expression of the universal validity of the law of transmission of light for all Galileian systems of reference.

Minkowski found that the Lorentz transformations satisfy the following simple conditions. Let us consider two neighbouring events, the relative position of which in the four-dimensional continuum is given with respect to a Galileian reference-body by the space co-ordinate differences , , and the time-difference . With reference to a second Galileian system we shall suppose that the corresponding differences for these two events are ', ', ', '. Then these magnitudes always fulfil the condition[23] The validity of the Lorentz transformation follows from this condition. We can express this as follows: The magnitude which belongs to two adjacent points of the four-dimensional space-time continuum, has the same value for all selected (Galileian) reference-bodies. If we replace , , , , by , , , , we also obtain the result that is independent of the choice of the body of reference. We call the magnitude the "distance" apart of the two events or four-dimensional points.

Thus, if we choose as time-variable the imaginary variable instead of the real quantity , we can regard the space-time continuum—in accordance with the special theory of relativity—as a "Euclidean" four-dimensional continuum, a result which follows from the considerations of the preceding section.


[23]Cf. Appendices I and II. The relations which are derived there for the co-ordinates themselves are valid also for co-ordinate differences, and thus also for co-ordinate differentials (indefinitely small differences).