{

{ F¹² = H′_z F³⁴ = -E′_z

which quantities become equal to H_x ... E_x in the case of the special relativity theory, and besides

J¹ = i_x ... J⁴ = ρ

we get instead of (63)

{ rot H′ - ∂E′/∂t = i

(63a) {

{ div E′ = ρ

The equations (60), (62) and (63) give thus a generalisation of Maxwell’s field-equations in vacuum, which remains true in our chosen system of co-ordinates.

The energy-components of the electro-magnetic field.