- #36
Gokul43201
Staff Emeritus
Science Advisor
Gold Member
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- 24
Since this (what follows) is the claim you are making, let's, for the sake of science and sanity, address it.
Here's what you said :
Does this new knowledge change anything ? If not, let's proceed.
This is the first statement you are making about things necessarily traveling at or near the speed of light, so you must first tell us what framework you are working under. Clearly, you are not basing this statement on the framework of SR (or are you ?). Are you using the "Galilean framework", where the speed of the light beam at P1 is v+c ? Or are you using some other system of thought for understanding the kinematics of fast moving objects ?
Opening this clause with 'yet' means that what follows is related to the preceding clause (talking about "raw power" and "matching speeds"). So, this indicates that you expect the motions of the rockets, subsequent to firing the lasers to affect the possibility of one beam overtaking the other. The only way this might be true, in any system of thought, is if the kinematics of the beams (with respect to an observer at rest in this frame) is coupled forever to the kinematics of the source that emitted it - some kind of "entanglement" is suggested. Alternatively, you might be suggesting that the kinematics of the beams is being described with respect to one of the two rockets, but there is no such mention in the clause. So, this clause merely leaves the reader saying "uhhh?"
Nevertheless, let's accept it and analyze what it might be saying. You then use the word(s) "over take" (by which I'll assume you mean the single word 'overtake'), which is not well-defined. Does A have to lag behind B in order to 'overtake' B ? If A and B are traveling side-by-side and A speeds up, does it 'overtake' B ? Either way, you are claiming that the beam from P2 does not get ahead of the beam from P1 (with respect to the observer at rest ?). There is no suggested reason why this must be true, given that we have no idea what system of science is being used in this discussion. In both Galilean and SR frameworks, this statement will indeed be true, and in fact, in both frameworks it would be true independent of the subsequent dynamics of the rockets. For now let's accept it as true, and proceed.
This is like saying : "Today is a warm day, and hence Chopin never played piano. Prove me wrong."
Anyway, there are other issues to sort out with this clause too.
You talk of the "speed of light for R2". So, you seem to suggest that speeds are observer dependent (though you haven't mention how an observer measures the speed of light). So why, until this point, have to never mentioned the frame in which various speeds that you talk of are measured ? Let's ignore that too for now.
You are saying that, at some point of time, R2 was "accelerating near R1". I assume that by "accelerating" you are referring to a positive acceleration with respect to the direction vector pointing from P2 to D (as measured by the observer at rest). As I explained earlier, monotonic acceleration of R2 can not result in the final specified condition of matching speeds and positions. The only way R2 can be positively accelerating beside R1 with the same instantaneous velocity as R1, is if it had already overtaken R1, then slowed down to a speed below R1's (still maintaining a lead over R1) and then subsequently sped up again, allowing R1 to catch up with it (rather than the other way round). But there is absolutely no mention that this the the second time the rockets will be side by side, or that it is R1 that comes up to R2 from behind. In fact, the opposite is suggested.
Yes, this follows your statement that R2 "starts flying with R1". However, you claim that speeds and positions can be matched after some period of positive acceleration. This is not possible.Anomalous said:
Here's what you said :
I assume that all speeds spoken of are measured by an observer at rest in the rest frame of P1, P2 and D. Even simple, non-relativistic kinematics will show you that if R2's speed is monotonically increasing, and R1's is constant, then if R2 covers the same distance as R1 in less (or equal) time than R1, then R2's final velocity will greatly exceed R1's. The only way they can match positions and speeds is if R2 slows down as it approaches R1.
Does this new knowledge change anything ? If not, let's proceed.
There are several points to address here :
This is the first statement you are making about things necessarily traveling at or near the speed of light, so you must first tell us what framework you are working under. Clearly, you are not basing this statement on the framework of SR (or are you ?). Are you using the "Galilean framework", where the speed of the light beam at P1 is v+c ? Or are you using some other system of thought for understanding the kinematics of fast moving objects ?
Opening this clause with 'yet' means that what follows is related to the preceding clause (talking about "raw power" and "matching speeds"). So, this indicates that you expect the motions of the rockets, subsequent to firing the lasers to affect the possibility of one beam overtaking the other. The only way this might be true, in any system of thought, is if the kinematics of the beams (with respect to an observer at rest in this frame) is coupled forever to the kinematics of the source that emitted it - some kind of "entanglement" is suggested. Alternatively, you might be suggesting that the kinematics of the beams is being described with respect to one of the two rockets, but there is no such mention in the clause. So, this clause merely leaves the reader saying "uhhh?"
Nevertheless, let's accept it and analyze what it might be saying. You then use the word(s) "over take" (by which I'll assume you mean the single word 'overtake'), which is not well-defined. Does A have to lag behind B in order to 'overtake' B ? If A and B are traveling side-by-side and A speeds up, does it 'overtake' B ? Either way, you are claiming that the beam from P2 does not get ahead of the beam from P1 (with respect to the observer at rest ?). There is no suggested reason why this must be true, given that we have no idea what system of science is being used in this discussion. In both Galilean and SR frameworks, this statement will indeed be true, and in fact, in both frameworks it would be true independent of the subsequent dynamics of the rockets. For now let's accept it as true, and proceed.
Now where did this come from ? Starting off with "and hence", indicates that what follows must be derived from what preceded. Where is the logical connect ? If it is just our failing to connect the dots, do show us how they are connected.
This is like saying : "Today is a warm day, and hence Chopin never played piano. Prove me wrong."
Anyway, there are other issues to sort out with this clause too.
You talk of the "speed of light for R2". So, you seem to suggest that speeds are observer dependent (though you haven't mention how an observer measures the speed of light). So why, until this point, have to never mentioned the frame in which various speeds that you talk of are measured ? Let's ignore that too for now.
You are saying that, at some point of time, R2 was "accelerating near R1". I assume that by "accelerating" you are referring to a positive acceleration with respect to the direction vector pointing from P2 to D (as measured by the observer at rest). As I explained earlier, monotonic acceleration of R2 can not result in the final specified condition of matching speeds and positions. The only way R2 can be positively accelerating beside R1 with the same instantaneous velocity as R1, is if it had already overtaken R1, then slowed down to a speed below R1's (still maintaining a lead over R1) and then subsequently sped up again, allowing R1 to catch up with it (rather than the other way round). But there is absolutely no mention that this the the second time the rockets will be side by side, or that it is R1 that comes up to R2 from behind. In fact, the opposite is suggested.
