found the formula for determining the Lorentz factor for ~c (which I still have to compute for the length foreshortening mentioned) and for determining KE to accelerate a specified mass to that. My compiler doesn't support the necessary floating point accuracy so I'd also have to convert the problem to huge integer arithmetic... and then solve for mass. Fun exercise. You're probably way more qualified to guesstimate.phyzguy said:Why don't you try to do the calculation?
Ibix said:The "hundred years" bit is flexible and depends on your choice of synchronisation convention. And you are moving into GR territory with talk of the universe (is it really too much trouble for you to write the whole word?) expanding. So the answer is "it depends". The universe around you would be cold and dark by the time one second passed for you, however.
Note that @phyzguy's point about energy consumption makes this purely academic.
Whether c changes has everything to do with what we mean when we ask whether "c changes". What physical experiment can you do to compare c at one time and place with c at another time and place? For instance, what unchanging standard will you cart around to do your speed tests with?dm4b said:Whether, or not, this behavior is consistent, constant, or w/e, has nothing to do with how we choose to define c. Likewise, with the mass of an electron.
Frames don't do anything. All that's happened here is that (loosely) you took a short-cut to the end of the universe. It doesn't affect anyone else.Chris Miller said:Thanks. Figured the universe (sorry, as a programmer I tend to use variables more than I should maybe) would blink out for me at that velocity. Interesting that my space-time frame could impact the entire universe like that.
Chris Miller said:found the formula for determining the Lorentz factor for ~c (which I still have to compute for the length foreshortening mentioned) and for determining KE to accelerate a specified mass to that. My compiler doesn't support the necessary floating point accuracy so I'd also have to convert the problem to huge integer arithmetic... and then solve for mass. Fun exercise. You're probably way more qualified to guesstimate.
Indeed. And the ##\gamma## factor ought to be well within the capability of a double precision number anyway. Sounds like @Chris Miller is doing something wrong somewhere.phyzguy said:If you take the time to learn the physics involved, you will find that it is a simple calculation that takes seconds. No compiler or conversion to huge integers required - except the "wet" compiler between your ears.
jbriggs444 said:Whether c changes has everything to do with what we mean when we ask whether "c changes". What physical experiment can you do to compare c at one time and place with c at another time and place? For instance, what unchanging standard will you cart around to do your speed tests with?
And what makes you think that it is c that is changing rather than your standard?
That seems to miss the key point that in order to meaningfully ask whether c changes, one must know what it means to ask whether c changes.dm4b said:You're only reinforcing my point. Light did what it does, long before we arrived on the scene and started asking "what we mean when we ask whether 'c changes'"
The point is that whether c changes is not a question about light, it is a question about your system of units.dm4b said:You're only reinforcing my point. Light did what it does, long before we arrived on the scene and started asking "what we mean when we ask whether 'c changes'"
Dale said:The point is that whether c changes is not a question about light, it is a question about your system of units.
jbriggs444 said:That seems to miss the key point that in order to meaningfully ask whether c changes, one must know what it means to ask whether c changes.
Our replies are anthropocentric because we're answering a question asked by a human being. Sure light does what it does. That's an empty tautology. The question is what does it do? And does it do it faster or slower now than it did then. That question is not particularly well posed. If we are going to ask it at all, we'd better nail down the question before we go haring off after answers.dm4b said:Do you guys not realize how anthropocentric your replies are?
Sure, one can break past that limitation by asking a different question. Asking if c varies is a question about the units. Asking if the fine structure constant varies is a question about the physics of light.dm4b said:Also, it's not just a question of units, as one can try to break past that limitation (even if the theories that do so are rather implausible sounding)
Exactly. C is not dimensionless. The fine structure constant is.dm4b said:To quote Sean Carol:
"The whole game of varying-c theories, then, is to find ways that the real dimensionless constants of nature (like the strengths of the fundamental forces, or ratios of particle masses) could change in perfect harmony such as to give you the impression that what’s really changing is c
dm4b said:Do you guys not realize how anthropocentric your replies are? Again, this is only reinforcing my original point. Light doesn't care about any of this, or what we're capable of asking, understanding, defining, measuring, or about any other human based activity.