Page:The Meaning of Relativity - Albert Einstein (1922).djvu/23

where the integrand in the last integral is the functional determinant of the ${\displaystyle x_{\nu }'}$ with respect to the ${\displaystyle x_{\nu }}$, and this by (3) is equal to the determinant ${\displaystyle |b_{\mu \nu }|}$ of the coefficients of substitution, ${\displaystyle b_{\nu \alpha }}$. If we form the determinant of the ${\displaystyle \delta _{\mu \alpha }}$ from equation (4), we obtain, by means of the theorem of multiplication of determinants,

${\displaystyle 1=\left|\delta _{\alpha \beta }\right|=\left|\sum \limits _{\nu }b_{\nu \alpha }b_{\nu \beta }\right|=\left|b_{\mu \nu }\right|^{2};\left|b_{\mu \nu }\right|=\pm 1}$

(6)

If we limit ourselves to those transformations which have the determinant +1,^[1] and only these arise from continuous variations of the systems of co-ordinates, then ${\displaystyle V}$ is an invariant.

Invariants, however, are not the only forms by means of which we can give expression to the independence of the particular choice of the Cartesian co-ordinates. Vectors and tensors are other forms of expression. Let us express the fact that the point with the current co-ordinates ${\displaystyle x_{\nu }}$ lies upon a straight line. We have

${\displaystyle x_{\nu }-A_{\nu }=\lambda B_{\nu }{\text{ (}}\nu {\text{ from 1 to 3).}}}$

Without limiting the generality we can put

${\displaystyle \sum B_{\nu }^{2}=1.}$

If we multiply the equations by ${\displaystyle b_{\beta \nu }}$ (compare (3a) and (5)) and sum for all the ${\displaystyle \nu }$'s, we get

${\displaystyle x_{\beta }'-A_{\beta }'=\lambda B_{\beta }'}$

1. There are thus two kinds of Cartesian systems which are designated as "right-handed" and "left-handed" systems. The difference between these is familiar to every physicist and engineer. It is interesting to note that these two kinds of systems cannot be defined geometrically, but only the contrast between them.