The Relativity of Time Dilation: Is Time Dilation Truly Relative?

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Discussion Overview

The discussion revolves around the concept of time dilation in the context of special relativity, particularly focusing on the relativity of motion and how it affects the aging of individuals in different reference frames. Participants explore the implications of two astronauts moving relative to each other at high velocities and the resulting effects on their perceived passage of time.

Discussion Character

  • Exploratory
  • Debate/contested
  • Mathematical reasoning

Main Points Raised

  • One participant questions how the relativity of motion impacts time dilation, suggesting that if both astronauts perceive each other as moving, time dilation might cancel out.
  • Another participant responds that the answer to who ages more quickly depends on the reference frame used for comparison.
  • A later reply distinguishes between two scenarios: one where both astronauts are in uniform motion and see each other's time as dilated equally, and another where one astronaut turns around, leading to different elapsed times on their clocks.
  • Some participants argue that the key to understanding the paradox lies in the acceleration of one of the astronauts, which differentiates their experiences from those in inertial frames.
  • Mathematical expressions are presented to illustrate the relationship between time experienced by an observer on Earth and a moving astronaut, emphasizing that time dilation does not cancel out due to differences in relative velocities.
  • There is a discussion about the implications of traveling at the speed of light, with one participant questioning the mathematical representation of time at that limit and the energy requirements for approaching it.

Areas of Agreement / Disagreement

Participants express differing views on the implications of relative motion on time dilation, with no consensus reached on whether time dilation cancels out or how to best interpret the scenarios presented.

Contextual Notes

Some mathematical expressions and assumptions about reference frames are discussed, but there are unresolved questions regarding the implications of acceleration and the limits of speed approaching that of light.

paintonfire
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Please forgive if this question is not up to snuff. Indeed, I am a painter, and very much the amature physics enthusiast.

One of Einstein's classic thought problems that interested me was the idea of two astronauts passing each other at a high velocity in open space. The idea was that in this case motion was completely relative... it was equally proper to say astronaut A was zooming by astronaut B as it was to say the opposite.

If motion is completely relative in this sense, then how does this figure into the time dilation problem (i.e., the space traveler who leaves Earth at a high rate of speed. For those left on earth, time passes much more quickly than for our intrepid traveler.) Sadly, if our astronaut ever returns, all of his or her loved ones are all long dead, etc.

If motion through the universe is completely relative, indeed, if it is equally proper to say that the Earth left our astronaut at a high rate of speed, then does time dilation not cancel out? Or is there some objective way to measure the relative velocities and distances involved so that we know who is aging more quickly than whom?

Any feedback regarding this question would be greatly appreciated.
 
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paintonfire said:
who is aging more quickly than whom?
This question is relative too. The answer depends on how their ages are being compared -- it depends on which reference frame you consult to answer the question.
 
paintonfire said:
Please forgive if this question is not up to snuff. Indeed, I am a painter, and very much the amature physics enthusiast.

One of Einstein's classic thought problems that interested me was the idea of two astronauts passing each other at a high velocity in open space. The idea was that in this case motion was completely relative... it was equally proper to say astronaut A was zooming by astronaut B as it was to say the opposite.

If motion is completely relative in this sense, then how does this figure into the time dilation problem (i.e., the space traveler who leaves Earth at a high rate of speed. For those left on earth, time passes much more quickly than for our intrepid traveler.) Sadly, if our astronaut ever returns, all of his or her loved ones are all long dead, etc.

If motion through the universe is completely relative, indeed, if it is equally proper to say that the Earth left our astronaut at a high rate of speed, then does time dilation not cancel out? Or is there some objective way to measure the relative velocities and distances involved so that we know who is aging more quickly than whom?

Any feedback regarding this question would be greatly appreciated.
There are two main situations and they are indeed very different:

1. If the twins observe each other from passing rockets that are in uniform rectilinear motion they will each see the other's time as being dilated by the same amount

2. If one twin flies away and turns around and comes back to compare clocks with the twin that continued in rectilinear and uniform motion, then, the twin that turned around would notice that less time has elapsed on his clock. The mathematics of this situation are shown nicely here.
 
Yes. In short, the key to the paradox is that one of the subjects (twins/spaceships/planets/whatever) changes its acceleration, thus distinguishing itself from the other, inertial objects.
 
paintonfire said:
If motion through the universe is completely relative, indeed, if it is equally proper to say that the Earth left our astronaut at a high rate of speed, then does time dilation not cancel out? Or is there some objective way to measure the relative velocities and distances involved so that we know who is aging more quickly than whom?

Any feedback regarding this question would be greatly appreciated.

don't cancel:

you must think something like this: you have a person in earth, he is moving at speed v1(as Earth is moving) for that person, time is passing "normaly".
another person goes to make a space trip, before spaceship starts moving, time is passing normaly to both persons, when spaship start moving at a v2 speed, happens that v2>v1. the diference between then, is the velocity that person in space is from the person on earth, so that diference, is what you need to take in count...

the expression to calc that is: t_1= \frac {t_2}{ \sqrt{1-v_2^2/c^2}} (1)

where t_1 is the time in inertial observer, and t_2 is the time in moving body.
v_2 is moving body speed...

if v_2=0, t_1=t_2, if v_2=c, is impossible as t_2/0 is inf...(the prove that bodys can't go faster than c)so, for the guy in Earth who is counting time t_1, t_2 is bigger, as denominator is always smaller or equal to 1 and bigger than 0

for the guy in spaceship who is counting time as t_2, t_2= t_1 \cdot \sqrt{1- v_2^2/c^2}

and he knows that t_1 for him, is smaller, as product is always smaller or equal to 1 and bigger than 0
 
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where t_1 is the time in inertial observer, and t_2 is the time in moving body.
v_2 is moving body speed...
t_2 should be the time lapse at rest while t_1 is the time lapse of the moving body relative to t_2.

if v_2=0, t_1=t_2, if v_2=c, is impossible as t_2/0 is inf...(the prove that bodys can't go faster than c)

But shouldn't it be t_2*0? Which would establish the fact that no time would pass for the object traveling at c when compared to their earthly counterparts as opposed to t_2/0. The reason why we can't travel at v_2 >= c is because no matter how much energy we add, v_2 would only creep towards c. We can add more and more energy but v_2 would only seem to stand still as it gets closer and closer to c.
 
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ranger said:
t_2 should be the time lapse at rest while t_1 is the time lapse of the moving body relative to t_2.
But shouldn't it be t_2*0? Which would establish the fact that no time would pass for the object traveling at c when compared to their earthly counterparts as opposed to t_2/0. The reason why we can't travel at v_2 >= c is because no matter how much energy we add, v_2 would only creep towards c. We can add more and more energy but v_2 would only seem to stand still as it gets closer and closer to c.

ups, in tex i made a mistake, puted \fract and forgot a } instead of \frac...so it hapears t_2*Y factor instead of t_1= \frac {t_2}{ \sqrt{1-v_2^2/c^2}}

already repair it...tks for hint...
 
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