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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 40: APPENDIX II: MINKOWSKI'S FOUR-DIMENSIONAL SPACE (WORLD)
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.

APPENDIX II
MINKOWSKI'S FOUR-DIMENSIONAL SPACE ("WORLD")

WE can characterise the Lorentz transformation still more simply if we introduce the imaginary in place of , as time-variable. If, in accordance with this, we insert and similarly for the accented system ', then the condition which is identically satisfied by the transformation can be expressed thus:

That is, by the afore-mentioned choice of "co-ordinates," (11a) is transformed into this equation.

We see from (12) that the imaginary time co-ordinate enters into the condition of transformation in exactly the same way as the space co-ordinates , , . It is due to this fact that, according to the theory of relativity, the "time" enters into natural laws in the same form as the space co-ordinates , , .

A four-dimensional continuum described by the "co-ordinates" , , , , was called "world" by Minkowski, who also termed a point-event a "world-point." From a "happening" in three-dimensional space, physics becomes, as it were, an "existence" in the four-dimensional "world."

This four-dimensional "world" bears a close similarity to the three-dimensional "space" of (Euclidean) analytical geometry. If we introduce into the latter a new Cartesian co-ordinate system (', ', ') with the same origin, then ', ', ', are linear homogeneous functions of , , , which identically satisfy the equation The analogy with (12) is a complete one. We can regard Minkowski's "world" in a formal manner as a four-dimensional Euclidean space (with imaginary time co-ordinate); the Lorentz transformation corresponds to a "rotation" of the co-ordinate system in the four-dimensional "world."