The Velocity Addition Formula
Velocity Addition Formula
Updated: May 31, 2026
On the Electrodynamics of Moving Bodies
Einstein-EDoMB-1905-Section §5
https://www.fourmilab.ch/etexts/einstein/specrel/www/
Einstein: Relativity, The Special and the General Theory, 1920, Chapter VI page 19, Chapter XIII page 45
https://www.google.com/books/edition/Relativity/n8QKAAAAIAAJ?hl=en&gbpv=1
Both sources show the velocity-addition-formula as it is today.
Shown: V = ( v + w ) / ( 1 + vw/c² )
SRT = spezielle Relativitätstheorie, Special Relativity
rf = reduction factor ( 1 + vw/c² ) in the v-a-f.
As in most of SRT, we use left ← to ← right equation logic ( an assignment operator so-called ) rather than high school left = to = right, an identity.
5 ← 2 + 3
2 + 3 = 5
On occasion we change notation without changing anything on the ground. Bring in an arrow ← for assignment and an asterisk* for relativistic output velocity-V*.
Classical addition: V ← ( v + w )
SRT addition: V* ← ( v + w ) / ( 1 + vw/c² )
In the set-up that follows we have only the special case of speed-w equal to speed-c, the speed-of-light. That simplifies the reduction factor to:
rf = ( 1 + v/c )
#### 1920-Chapter VI
Chapter VI has a simple rendering of right-hand-side speeds v and w. A “carriage” has speed-v on an “embankment.” A “man” has speed-w on the carriage. Chapter VI has the carriage and the man moving alike in one unit of time, and then variables v and w double as distance numbers.
Distances v and w are in effect serial distances, not parallel distances. Rename the embankment as “pavement.” At time t =1, distance-v is distance of carriage-zero from pavement origin-zero. At time t =1, distance-w is distance on the carriage floor, pavement point of serial distance v + w. Distance-w is not distance from pavement origin-zero, not a distance parallel to distance-v.
Switch variables v and w back to speeds and you have what Section §5 calls the “composition of velocities.”
V = v + w
#### Lorentz Transforms
Lorentz Transforms: minus-sign, shown in EDoMB-1905 Section §3 and used in Section §4 ( length contraction and time dilation. ) Shown in Halliday & Resnick as equations 37-2I:
x′ = gamma • ( x – vt )
t′ = gamma • ( t – vx / c² )
Lorentz Transforms: plus-sign, shown in H&R as equations 37-22.
x = gamma • ( x′ + vt′ )
t = gamma • ( t′ + vx′ / c² )
This plus-sign pair is shown neither in Section §5 ( v-a-f ) nor in 1920-Chapter XIII ( v-a-f ):
#### Derive the v-a-f Section §5
Section §5 has a statement which invokes the minus-sign pair of Section §3. Quote: “With the help of Section §3 equations we solve for x and t.” The statement does not lead to a display of the plus-sign pair. A single additive-spatial is shown. It is not an LT. Gamma is missing:
x = ( w′ + v ) • t / rf
It is this equations which leads to the v-a-f:
Shown: V* = ( v + w ) / ( 1 + vw/c² )
Special case: w = c
V* = ( v + c ) / ( 1 + vc/c² )
V* = ( v + c ) / ( 1 + v/c )
V* = c
#### Derive the v-a-f H&R Chapter 37
H&R Chapter 37-3 has a similar statement: Quote: “Simply solve equations 37-21 for x.” The plus-sign LT pair is then shown but the algebra of “solve for” is not shown. Chapter 37-4 then has derivation of the v-a-f from the plus-sign pair, that derivation shown as Equations 37-29.
The general idea is simple. Speed is distance divided by time. In the plus-sign LT pair, change distance-x′ to distance-wt′:
x = gamma • ( wt′ + vt′ )
t = gamma • ( t′ + vwt′ / c² )
Divide:
V* = x / t
Gamma divides out. Time-t′ divides out.
V* = ( v + w ) / ( 1 + vw/c² )
#### Three SRT problems
V* = ( v + w ) / ( 1 + vw/c² )
Use the special case of w = c shown in Section §5.
V* = ( v + c ) / ( 1 + v/c )
V* = c
rf reduction factor = ( 1 + v/c )
V* = ( v + c ) / rf
In terms of Chapter VI, speed w = c converts the “man” on the carriage floor into a photon on the carriage, a photon of speed-c, a figure of speech because a photon does not really exist. The photon is fired off by a laser gun bolted to carriage-zero, not bolted to pavement-zero, and such a laser gun moves on the pavement at speed-v. Classical mechanics gives the photon ( aka the man ) pavement speed:
V = v + c.
Problem #1: Symmetric
Section §5 quote: “v and w enter into the resultant velocity in a symmetrical manner.” It’s a version of the distributive law:
Symmetric: V* = c ← v* + c* ← ( v + c ) / rf
Asymmetric: V* = c ← V / rf ← ( v + c ) / rf
In our special case of w = c, symmetric calls for addition of v* + c*. Speed-c* asterisk, not doable.
c* = c / rf ( c* less than c ) cannot exist.
Also: Symmetric transforms input variables before they are added. The arrow cannot transform its own right-hand-side.
Problem #2: V* = c ← ( v + c ) / rf
If you transform one or both of distance-time doing the photon’s destination on the pavement, you must transform everything on the pavement. You must transform distance-time doing speed-v and you have:
No good: V* = c ← ( v* + c ) / rf
Problem #3: In Section §4, gamma is basically a length contraction effect, although it appears in time dilation also, reducing time dilation from ( 1 – v²/c² ) to the sqrt ( 1 – v²/c² ) which is 1/gamma. H&R Chapter 37, deriving the v-a-f, has the quotient of plus-sign spatial and temporal, where gamma divides out. Question: length contraction is simply not there, or it is still there but can be ignored?
When the carriage goes down the pike at speed-v, it must suffer length contraction of second order effect v²/c², which is much smaller than first order effect v/c in the reduction factor. Is length contraction so small that it can be ignored?
1920-Chapters VI and XIII doing the v-a-f make no mention of the carriage affected by length contraction.
#### A numbers game
The speed-of-light is 12 inches per second. Lay a foot-rule on the table top.
## Minus-sign subtraction: A photon goes 12 inches on the table top. During that interval of time, the ruler goes 4 inches on the table top: ruler-0 goes from table-0 to table-4. The ruler observes the photon. At time t = 1 sec, the ruler finds the photon at ruler-8, an on-ruler speed of 8 inches per second. Too slow. Doctor up time on the ruler so for example the photon duration is only 2/3 second. The ruler then says photon-on-ruler has speed c = 12 ips.
You can doctor up space-time on the moving ruler without changing any of the table top numbers: time of 1 sec, photon location of table-12, ruler-0 location of table-4.
## Plus-sign addition. A photon goes 12 inches on the RULER, in 1 sec according to the ruler clock. During that interval of time, the ruler goes 4 inches on the table top. The table top observes the photon. At time t = 1 sec, the table top finds the photon at table-16, a distance addition of 4 + 12, for a table top speed of 16 ips, too fast. You can transform the stationary table clock at table-16 so that it reads 4/3 sec, not 1 sec, and then photon speed on the table is c = 12 ips.
You cannot transform the stationary table clock at inch-16 unless you also transform the stationary table clock at inch-4, in which case the ruler has not moved at speed of 4 ips.
Addition is not the inverse of subtraction.
Ruler ← table minus table
The fictional ruler is output.
Table ← table plus ruler
The fictional ruler is one of the two inputs. It won’t work.
#### Conclusion:
The special case v-a-f with w = c is obviously correct in some sense. No photon can have speed V = v + c.
V* = ( v + c ) / ( 1 + v/c )
V* = c
Problem: The LT’s switched over from minus-sign to plus-sign conjure up untenable propositions. The plus-sign pair is shown neither in 1905 nor in 1920.
How do you get the v-a-f if you can’t use the plus-sign LT’s? Here’s the introductory equation of Section §5:
x = ( w′ + v ) • t / rf
It is the composition of distances. How do you get it? You look at the minus-sign LT’s of Section §3 and “solve for x.” The algebra of “solve for” is not shown. The previous version of this blog tried to figure it out. We spilled a lot of ink. The fact is, nobody knows what’s going on here.
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