This Quantum World/Appendix/Relativity/Lorentz transformations

We want to express the coordinates ${\displaystyle t}$ and ${\displaystyle 𝐫=(x,y,z)}$ of an inertial frame ${\displaystyle {ℱ}_1}$ in terms of the coordinates ${\displaystyle t^{\prime }}$ and ${\displaystyle {𝐫}^{\prime }=(x^{\prime },y^{\prime },z^{\prime })}$ of another inertial frame ${\displaystyle {ℱ}_2.}$ We will assume that the two frames meet the following conditions:

1. their spacetime coordinate origins coincide (${\displaystyle t^{\prime }=0,{𝐫}^{\prime }=0}$ mark the same spacetime location as ${\displaystyle t=0,𝐫=0}$),
2. their space axes are parallel, and
3. ${\displaystyle {ℱ}_2}$ moves with a constant velocity ${\displaystyle 𝐰}$ relative to ${\displaystyle {ℱ}_1.}$

What we know at this point is that whatever moves with a constant velocity in ${\displaystyle {ℱ}_1}$ will do so in ${\displaystyle {ℱ}_2.}$ It follows that the transformation ${\displaystyle t,𝐫\to t^{\prime },{𝐫}^{\prime }}$ maps straight lines in ${\displaystyle {ℱ}_1}$ onto straight lines in ${\displaystyle {ℱ}_2.}$ Coordinate lines of ${\displaystyle {ℱ}_1,}$ in particular, will be mapped onto straight lines in ${\displaystyle {ℱ}_2.}$ This tells us that the dashed coordinates are linear combinations of the undashed ones,

${\displaystyle t^{\prime }=At+𝐁\cdot 𝐫,{𝐫}^{\prime }=C𝐫+(𝐃\cdot 𝐫)𝐰+t.}$

We also know that the transformation from ${\displaystyle {ℱ}_1}$ to ${\displaystyle {ℱ}_2}$ can only depend on ${\displaystyle 𝐰,}$ so ${\displaystyle A,}$ ${\displaystyle 𝐁,}$ ${\displaystyle C,}$ and ${\displaystyle 𝐃}$ are functions of ${\displaystyle 𝐰.}$ Our task is to find these functions. The real-valued functions ${\displaystyle A}$ and ${\displaystyle C}$ actually can depend only on ${\displaystyle w=|𝐰|={}_{+}\sqrt{𝐰\cdot 𝐰},}$ so ${\displaystyle A=a(w)}$ and ${\displaystyle C=c(w).}$ A vector function depending only on ${\displaystyle 𝐰}$ must be parallel (or antiparallel) to ${\displaystyle 𝐰,}$ and its magnitude must be a function of ${\displaystyle w.}$ We can therefore write ${\displaystyle 𝐁=b(w)𝐰,}$ ${\displaystyle 𝐃=[d(w)/w^2]𝐰,}$ and ${\displaystyle =e(w)𝐰.}$ (It will become clear in a moment why the factor ${\displaystyle w^{-2}}$ is included in the definition of ${\displaystyle 𝐃.}$) So,

${\displaystyle t^{\prime }=a(w)t+b(w)𝐰\cdot 𝐫,{𝐫}^{\prime }={\displaystyle c(w)𝐫+d(w)\frac{𝐰\cdot 𝐫}{w^2}𝐰+e(w)𝐰t.}}$

Let's set ${\displaystyle 𝐫}$ equal to ${\displaystyle 𝐰t.}$ This implies that ${\displaystyle {𝐫}^{\prime }=(c+d+e)𝐰t.}$ As we are looking at the trajectory of an object at rest in ${\displaystyle {ℱ}_2,}$ ${\displaystyle {𝐫}^{\prime }}$ must be constant. Hence,

${\displaystyle c+d+e=0.}$

Let's write down the inverse transformation. Since ${\displaystyle {ℱ}_1}$ moves with velocity ${\displaystyle -𝐰}$ relative to ${\displaystyle {ℱ}_2,}$ it is

${\displaystyle t=a(w)t^{\prime }-b(w)𝐰\cdot {𝐫}^{\prime },𝐫={\displaystyle c(w){𝐫}^{\prime }+d(w)\frac{𝐰\cdot {𝐫}^{\prime }}{w^2}𝐰-e(w)𝐰t^{\prime }.}}$

To make life easier for us, we now chose the space axes so that ${\displaystyle 𝐰=(w,0,0).}$ Then the above two (mutually inverse) transformations simplify to

${\displaystyle t^{\prime }=at+bwx,x^{\prime }=cx+dx+ewt,y^{\prime }=cy,z^{\prime }=cz,}$

${\displaystyle t=a{t}^{\prime }-bw{x}^{\prime },x=c{x}^{\prime }+d{x}^{\prime }-ew{t}^{\prime },y=c{y}^{\prime },z=c{z}^{\prime }.}$

Plugging the first transformation into the second, we obtain

${\displaystyle t=a(at+bwx)-bw(cx+dx+ewt)=(a^2-be{w}^2)t+(abw-bcw-bdw)x,}$

${\displaystyle x=c(cx+dx+ewt)+d(cx+dx+ewt)-ew(at+bwx)}$

     ${\displaystyle =(c^2+2cd+d^2-be{w}^2)x+(cew+dew-aew)t,}$

${\displaystyle y=c^{2}y,}$

${\displaystyle z=c^{2}z.}$

The first of these equations tells us that

${\displaystyle a^2-be{w}^2=1}$  and  ${\displaystyle abw-bcw-bdw=0.}$

The second tells us that

${\displaystyle c^2+2cd+d^2-be{w}^2=1}$  and  ${\displaystyle cew+dew-aew=0.}$

Combining ${\displaystyle abw-bcw-bdw=0}$ with ${\displaystyle c+d+e=0}$ (and taking into account that ${\displaystyle w\ne 0}$), we obtain ${\displaystyle b(a+e)=0.}$

Using ${\displaystyle c+d+e=0}$ to eliminate ${\displaystyle d,}$ we obtain ${\displaystyle e^2-be{w}^2=1}$ and ${\displaystyle e(a+e)=0.}$

Since the first of the last two equations implies that ${\displaystyle e\ne 0,}$ we gather from the second that ${\displaystyle e=-a.}$

${\displaystyle y=c^{2}y}$ tells us that ${\displaystyle c^2=1.}$ ${\displaystyle c}$ must, in fact, be equal to 1, since we have assumed that the space axes of the two frames a parallel (rather than antiparallel).

With ${\displaystyle c=1}$ and ${\displaystyle e=-a,}$ ${\displaystyle c+d+e=0}$ yields ${\displaystyle d=a-1.}$ Upon solving ${\displaystyle e^2-be{w}^2=1}$ for ${\displaystyle b,}$ we are left with expressions for ${\displaystyle b,c,d,}$ and ${\displaystyle e}$ depending solely on ${\displaystyle a}$:

${\displaystyle b=\frac{1-a^2}{a{w}^2},c=1,d=a-1,e=-a.}$

Quite an improvement!

To find the remaining function ${\displaystyle a(w),}$ we consider a third inertial frame ${\displaystyle {ℱ}_3,}$ which moves with velocity ${\displaystyle 𝐯=(v,0,0)}$ relative to ${\displaystyle {ℱ}_2.}$ Combining the transformation from ${\displaystyle {ℱ}_1}$ to ${\displaystyle {ℱ}_2,}$

${\displaystyle t^{\prime }=a(w)t+\frac{1-a^2(w)}{a(w)w}x,x^{\prime }=a(w)x-a(w)wt,}$

with the transformation from ${\displaystyle {ℱ}_2}$ to ${\displaystyle {ℱ}_3,}$

${\displaystyle t^{″}=a(v)t^{\prime }+\frac{1-a^2(v)}{a(v)v}{x}^{\prime },x^{″}=a(v)x^{\prime }-a(v)v{t}^{\prime },}$

we obtain the transformation from ${\displaystyle {ℱ}_1}$ to ${\displaystyle {ℱ}_3}$:

${\displaystyle t^{″}=a(v)[a(w)t+\frac{1-a^2(w)}{a(w)w}x]+\frac{1-a^2(v)}{a(v)v}[a(w)x-a(w)wt]}$

     ${\displaystyle =\underset{\star }{\underbrace{[a(v)a(w)-\frac{1-a^2(v)}{a(v)v}a(w)w]}}t+[\dots ]x,}$

${\displaystyle x^{″}=a(v)[a(w)x-a(w)wt]-a(v)v[a(w)t+\frac{1-a^2(w)}{a(w)w}x]}$

     ${\displaystyle =\underset{\star \star }{\underbrace{[a(v)a(w)-a(v)v\frac{1-a^2(w)}{a(w)w}]}}x-[\dots ]t.}$

The direct transformation from ${\displaystyle {ℱ}_1}$ to ${\displaystyle {ℱ}_3}$ must have the same form as the transformations from ${\displaystyle {ℱ}_1}$ to ${\displaystyle {ℱ}_2}$ and from ${\displaystyle {ℱ}_2}$ to ${\displaystyle {ℱ}_3}$, namely

${\displaystyle t^{″}=\underset{\star }{\underbrace{a(u)}}t+\frac{1-a^2(u)}{a(u)u}x,x^{″}=\underset{\star \star }{\underbrace{a(u)}}x-a(u)ut,}$

where ${\displaystyle u}$ is the speed of ${\displaystyle {ℱ}_3}$ relative to ${\displaystyle {ℱ}_1.}$ Comparison of the coefficients marked with stars yields two expressions for ${\displaystyle a(u),}$ which of course must be equal:

${\displaystyle a(v)a(w)-\frac{1-a^2(v)}{a(v)v}a(w)w=a(v)a(w)-a(v)v\frac{1-a^2(w)}{a(w)w}.}$

It follows that ${\displaystyle [1-a^2(v)]a^2(w)w^2=[1-a^2(w)]a^2(v)v^2,}$ and this tells us that

${\displaystyle K=\frac{1-a^2(w)}{a^2(w)w^2}=\frac{1-a^2(v)}{a^2(v)v^2}}$

is a universal constant. Solving the first equality for ${\displaystyle a(w),}$ we obtain

${\displaystyle a(w)=1/\sqrt{1+K{w}^2}.}$

This allows us to cast the transformation

${\displaystyle t^{\prime }=at+bwx,x^{\prime }=cx+dx+ewt,y^{\prime }=cy,z^{\prime }=cz,}$

into the form

${\displaystyle t^{\prime }=\frac{t+Kwx}{\sqrt{1+K{w}^2}},x^{\prime }=\frac{x-wt}{\sqrt{1+K{w}^2}},y^{\prime }=y,z^{\prime }=z.}$

Trumpets, please! We have managed to reduce five unknown functions to a single constant.

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