Relativity and variable time - there is an alternate formulation where time is always linear. Has it been studied?

Question

Lorentz, Einstein et. al. assume time is the variable which changes in a gravity well or as speed approaches $c$. That's the commonly accepted model.

For nearly 50 years I've wondered if anyone else has considered introducing a hypothetical, "universal" rate of reaction U. Wherever t appears in all physical, chemical or electromagnetic formulae, it would be replaced with (U t). The product (U t) behaves precisely as t alone. However, in a case where t slows to 1/2, in this approach t remains the same, but U decreases by 1/2.

For an observer moving close to light speed, their chemical and physical reactions are slowed, including their atomic clock which measures time in their reference frame. From their perspective, the effect is identical to time itself slowing - but time is still progressing as it always has. Only their relative measurement of time has changed.

Since it's only a variable substitution, every formula in the cannon is unchanged. The only difference is that time is linear and universal - with U varying to compensate for relativity.

There is no observable, physical reason to believe in the U factor, but it makes the time ordinate linear and should make all the math easier.

Now, when doing an integral of time in an accelerating reference frame, it's possible to do a simple integration in t without t varying while it's being integrated.

I haven't taken the time to dig into this deeply, but it appears that mass itself might not be changing while its inertial changes because momentum = m v = m/U dx/dt. By factoring U as part of m, them m = m/U and once again, the rate of reaction changed - not the actual mass.

I asked this ages ago in physics classes and the answer was basically "we don't do it that way." That wasn't very satisfying.

Has anyone ever looked at this approach?

Answer 1

That's essentially what the Lorentz factor is. It's a unitless constant which scales the measured time or length in one frame to give the measured time or length in another frame. The important thing to notice is that "time slowing down to 1/2" is still dependent on a given reference frame and there's nothing universal about it. Additionally, time is always linear for a given frame. It's more so about how a reference frame will measure changes in time for other frames. But this wouldn't even be a problem since special relativity only concerns inertial frames (i.e., frames of constant velocity). So there's still not much of a benefit to the math. The Lorentz factor is still an important idea though and is one of the things which helped convince other physicists of Einstein's work.

Answer 2

Nothing prevents you from choosing a reference frame and labeling events in spacetime according to that frame. That's essentially how GPS works: GPS time isn't controlled by the clocks on the satellites, but by a notional clock at sea level. What relativity tells you is that this choice is arbitrary.

Answer 3

Let me try to translate your thoughts into main stream physics words and then you can see if I understood you correctly.

You are searching for a variable, call it $t$, that has two properties:

1. This variable is reference frame independent (coordinate free)
2. There exists a linear transformation (call it $U$) that is dependent on the velocity with respect to which someone moves relative to the person that defines the laws of the universe with $U=1$. With this linear transformation one can relate your time to any other time.

Fortunately, this is a known quantity called proper time. It is an invariant quantity. For each instance in "time", we can calculate the $U$ needed for other people to translate whatever their notion of time is to ours, thus recovering what we understand as laws of physics.

Read up proper time to get a better understanding. It is indeed the thing you are asking for. (notice that in the "proper frame" I am sitting in the coordinate 0.)