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Electromagnetic Mass of a Moving Electron.

545

transformation must be of the form

\xi ={\frac {a'x+b't+c'}{ax+bt+c}}

,

$\tau ={\frac {a''x+b''t+c''}{ax+bt+c}}$ ,

Now ξ will not in general be infinite unless x is infinite, and also when x and t are zero ξ and τ are also zero. Hence the transformation must be of the simpler form

${\begin{array}{llll}\xi =a'x+b't&&{\frac {x=b''\xi -b'\tau }{\triangle }}\\&\mathrm {or} &&\triangle =(a'b''-b'a'')\\\tau =a''x+b''t&&t={\frac {-a''\xi +a'\tau }{\triangle }}\end{array}}$

the coefficients a', b', a", b" being functions of the relative velocity v.

Now if a point starts from A at time t=0 and travels with B, its coordinate ξ is always zero by virtue of the relation x=vt.

Hence

b'=-a'v\,

i.e.

\xi =a'(x-vt)\,

Now consider what is involved in saying that if a point moves along the axis of x relative to A with the velocity v of light, it also moves with velocity c relative to B. If a point moves from the position x at time t to the position x+δx at time t+δt let the corresponding changes in ξ and τ be δξ, δτ.

Then