Understanding Relativity: A Blind Man's Perspective on Time and Physics

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In summary, the clocks in a railway station are synchronized by seeing the clock but not hearing the clock. A similar clock is also synchronized by the station master by the same way (say yesterday when the train halted at the station). If a blind man is sitting inside the last compartment of the train, he can only hear the time. When the last compartment crosses the first clock, he can hear that clock and the clock inside the train is telling the same time, but the clock at the other end of the platform is telling a time in the past. However, when the blind man approaches the other clock, he can hear that clock is moving fast (telling the time faster) and finally when he reaches the other clock, he can hear the clock
  • #36
What everyone seems to forget is that relativistic effects can only be observed across two reference frames. Lorentz transform equations relate measurements of two observers with a non-zero relative velocity. In order to maintain the universal validity of the laws of physics we need Lorentz transform between two inertial frames, and generally covariant transformation laws for non-inertial frames. This is indeed the very essence of the Special and the General relativity theories.
 
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  • #37
DaleSpam:

Thanks for taking the time to type all that up.

I'm afraid I still don't get it though. Why is it any more difficult to identify the "equal and opposite pairs" in this case than it is in the simple case of constant gravity = m*9.8 m/s^2 that we all worked with when we first learn Newton's laws? We were told that if a rock rests on a table, its weight exerts a force = mg on the table, and the table (thanks to molecular deformation, we later learned) exerts the same magnitude force upward. The same would happen in the rocket ship, right? The hardest one to grasp when we were kids was the equal and opposite force when we allowed that rock to fall toward Earth - but we accepted that the Earth moves upward ever so slightly - even though we certainly never saw any evidence to that effect.

[EDIT: I originally typed "as long as the spaceman holds the rocket" in the next paragraph ... oops. sorry if I confused anyone.]

Is it any harder to believe that the spaceship moves "up" (or "forward") when the rock is released in it? After all, as long as the spaceman holds the rock, the thrusters are accelerating the total mass of spaceship + spaceman + rock. When he releases the rock, the thrusters suddenly are accelerating only spaceship + spaceman (until the rock strikes the floor), so the spaceship will accelerate slightly faster forward.

Isn't this all the same thing? Mustn't it be, if we are to take the Equivalence Principle seriously? Newton derived his laws in the (approximately) constant gravitational field of the Earth before he ever put together the concept of gravity as the force the holds the planets in place as well as pull rocks to Earth. Can't our spaceman do exactly the same thing?
 
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  • #38
YellowTaxi said:
But I didn't understand why you said 'only for a small region of time' for the falling guy.
because: If the g field varies (over time - or whatever), actually it doesn't matter to the falling guy. For him g is always 'invisible' whatever its actual value my seem to the guy on the platform.
I asked the same question on this thread a while ago, see dicerandom's answer in post #9--even in a very small room, if you had two test particles on opposite sides of the room they would begin to drift together over an extended period of time due to tidal forces, just like what happens if you have a large room and you observe what happens to test particles on opposite sides for a brief period of time--see the bottom illustration in this article.
 
  • #39
There are a number of points that need clarifying within the above arguments. Einstein said in non-inertial frames Newton's law do not hold good - this is not the same as the statement "Newtons' laws are violated." They don't hold good because we cannot adhere to the classical definition of space-time in which we can measure a unit of length and time regardless of our position. In non-inertial frame this is no longer valid, different position in space-time may have different metrics, which cause a straight line to appear as a curved line etc. The Euclidean geometry does not hold and must be replaced with a non-Euclidean geometry. The notion of straight line which is used to define Newton's laws no longer has the same meaning.
As to your question, if I understand it correctly, no it is not any different. In fact it is the very point that Einstein used to explain his equivalence principle. That a man in an elevator or a rocket will be unable to distinguish his system from a gravitational system since he will observe an object at rest (in another frame) to be falling with an acceleration which is independent of the mass of the object. Since this peculiar behavior belongs to gravitational systems, hence he concluded that a gravitational system is no different to an accelerated system. A fact further supported by experiments of Eotvos who verified the equivalence of the gravitational mass with the inertial mass.
 
  • #40
Thanks, harryjoon. One question in response: the point about Newton's laws not holding in a non-inertial frame is due to relativistic effects, is it not? In the limit of small velocities (and small accelerations or small gravitational fields), are Newton's laws not as good an approximation as they are in inertial frames?
 
  • #41
belliott4488 said:
DaleSpam:

Thanks for taking the time to type all that up.

I'm afraid I still don't get it though. Why is it any more difficult to identify the "equal and opposite pairs" in this case than it is in the simple constant gravity = m*9.8 m/s^2 that we all worked with when we first learn Newton's laws? We were told that if a rock rests on a table, its weight exerts a force = mg on the table, and the table (thanks to molecular deformation, we later learned) exerts the same magnitude force upward. The same would happen in the rocket ship, right? The hardest one to grasp when we were kids was the equal and opposite force when we allowed that rock to fall toward Earth - but we accepted that the Earth moves upward ever so slightly - even though we certainly never saw any evidence to that effect.

Is it any harder to believe that the spaceship moves "up" (or "forward") when the rock is released in it? After all, as long as the spaceman holds the rocket, the thrusters are accelerating the total mass of spaceship + spaceman + rock. When he releases the rock, the thrusters suddenly are accelerating only spaceship + spaceman (until the rock strikes the floor), so the spaceship will accelerate slightly faster forward.

Isn't this all the same thing? Mustn't it be, if we are to take the Equivalence Principle seriously? Newton derived his laws in the (approximately) constant gravitational field of the Earth before he ever put together the concept of gravity as the force the holds the planets in place as well as pull rocks to Earth. Can't our spaceman do exactly the same thing?
Even if you can make correct predictions in a Newtonian accelerating frame by introducing "fictitious forces", doesn't the very fact that you have to include forces not present in inertial frames mean that the laws of physics have a different form in this frame? For example, in an inertial frame the forces on a test particle depend only on its distance from other objects which exert gravitational forces on it, but this is no longer true in a non-inertial frame with 'fictitious forces'. If you wrote down the equations of motion for a given system of particles, the equations couldn't have the same form in non-inertial frames as they do in inertial ones.
 
  • #42
belliott4488 said:
The hardest one to grasp when we were kids was the equal and opposite force when we allowed that rock to fall toward Earth - but we accepted that the Earth moves upward ever so slightly - even though we certainly never saw any evidence to that effect.

Is it any harder to believe that the spaceship moves "up" (or "forward") when the rock is released in it? After all, as long as the spaceman holds the rocket, the thrusters are accelerating the total mass of spaceship + spaceman + rock. When he releases the rock, the thrusters suddenly are accelerating only spaceship + spaceman (until the rock strikes the floor), so the spaceship will accelerate slightly faster forward.

Isn't this all the same thing? Mustn't it be, if we are to take the Equivalence Principle seriously? Newton derived his laws in the (approximately) constant gravitational field of the Earth before he ever put together the concept of gravity as the force the holds the planets in place as well as pull rocks to Earth. Can't our spaceman do exactly the same thing?
You are thinking about effects that are many orders of magnitude smaller than what we are talking about here. The inertial forces are relatively large forces (2000 N on the rocket and .2 N on a .1 kg ball), the gravitational force between them would be about 6.7E-9 N or even less because of the geometry. However, the important point is that all of the inertial forces point in the same direction! Because they are all in the same direction they cannot possibly form equal-and-opposite pairs that satisfy the 3rd law.

I really don't know what more I can do here. I have given a very clear and concrete example fully worked out. I have shown my reasoning step-by-step and backed up my claims with explicit demonstrations. Please do the math yourself. Work a few of these problems and see that the inertial forces do not follow Newton's 3rd law. If you cannot see that from what I have already presented then I am sure that further write-ups on my part will not be helpful. There is really no substitute for getting down into the details and going through the work yourself.

PS Please don't take this wrong. There is nothing wrong with needing to work a few examples to understand a concept, particularly in this case. Most people go through all of their college physics courses without ever working a problem in a non-inertial reference frame.
 
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  • #43
JesseM said:
Even if you can make correct predictions in a Newtonian accelerating frame by introducing "fictitious forces", doesn't the very fact that you have to include forces not present in inertial frames mean that the laws of physics have a different form in this frame? For example, in an inertial frame the forces on a test particle depend only on its distance from other objects which exert gravitational forces on it, but this is no longer true in a non-inertial frame with 'fictitious forces'. If you wrote down the equations of motion for a given system of particles, the equations couldn't have the same form in non-inertial frames as they do in inertial ones.
Right, but that means Newton's laws are also "violated" on the surface of the Earth when we make the approximation that g is a constant, independent of height. I know that's only an approximation, but I wouldn't have called that a "violation" of Newton's laws; I would have said that it's an application of those laws that is as correct as the initial assumption, i.e. of a constant force.

My main point was really that I don't see how Newton's laws of motion say anything about the source or the nature of the forces. They simply say, "you give me a force, and I'll tell you how object will react to it." As far as that goes, they work equally well on the Earth's surface (which really is non-inertial, after all, not that anyone claims Newton's laws don't apply there) and in the accelerating rocketship/elevator.
 
  • #44
belliott4488 said:
Right, but that means Newton's laws are also "violated" on the surface of the Earth when we make the approximation that g is a constant, independent of height. I know that's only an approximation, but I wouldn't have called that a "violation" of Newton's laws; I would have said that it's an application of those laws that is as correct as the initial assumption, i.e. of a constant force.

My main point was really that I don't see how Newton's laws of motion say anything about the source or the nature of the forces. They simply say, "you give me a force, and I'll tell you how object will react to it." As far as that goes, they work equally well on the Earth's surface (which really is non-inertial, after all, not that anyone claims Newton's laws don't apply there) and in the accelerating rocketship/elevator.
But Newton's laws of motion aren't the whole of what is meant by Newtonian physics--the three laws of motion are insufficient in themselves to calculate the dynamical behavior of objects given their initial conditions. You also need some set of force laws, such as the equation of Newtonian gravitation. For Galilei-invariant force laws like Newtonian gravity, the law will obey the same equations in every inertial frame, but the same equations will not give correct predictions in a non-inertial frame.
 
  • #45
JesseM said:
But Newton's laws of motion aren't the whole of what is meant by Newtonian physics--the three laws of motion are insufficient in themselves to calculate the dynamical behavior of objects given their initial conditions. You also need some set of force laws, such as the equation of Newtonian gravitation. For Galilei-invariant force laws like Newtonian gravity, the law will obey the same equations in every inertial frame, but the same equations will not give correct predictions in a non-inertial frame.
Oh, absolutely ... and to describe electromagnetic forces fully, you should have Maxwell's equations, too. I think the post that I initially responded to referred only to the laws of motion, however. Of course I agree that Newton's Law of gravity won't do you much good in an accelerating rocketship far from any gravitational field.

I think this is all kind of tangential to the original post. It asked about why Newton's laws are said to be violated in accelerating frames. If that referred to the law of gravity, then fine - there's a simple enough answer. If it refers to the laws of motion, however, then I think it's misleading to say that these laws are "violated." Yes, additional conditions, in the form of inertial forces, must be added, but then the laws still work.
 
  • #46
belliott4488 said:
If it refers to the laws of motion, however, then I think it's misleading to say that these laws are "violated." Yes, additional conditions, in the form of inertial forces, must be added, but then the laws still work.
No they dont!
 
  • #47
DaleSpam said:
No they dont!
Again I ask you, why not? You said earlier that the 3rd law doesn't work, but I responded (https://www.physicsforums.com/showpost.php?p=1671401&postcount=37") by pointing out that in fact it does, much as it does for the case of a constant gravitational field, to which this case is equivalent.

Do you in fact believe that Newton's 3rd law is violated in the approximation of a constant gravitational field that is typically invoked for motion on the Earth's surface? If so, then at least you're consistent, although rather unconventional, since that approximation is often used in the presentation of Newton's Laws for the first time in introductory Physics.

[Edit: I'm adding more, while I wait to see a response ...]
One more thing: Suppose I'm riding in my rocket ship/space elevator, and I'm doing all kinds of Physics - I'm shooting pool, I'm tossing balls through the air (it's a big elevator), I'm playing with pendula, I'm spinning gyroscopes - at what point will I find myself unable to explain or predict what I'm seeing simply by applying Newton's laws and the assumption of a constant force field, which I'll call, for lack of a better term, "gravity"? If you tell me the laws of motion break down, then I'll be able to tell that I'm in an accelerating frame and not in a constant gravitational field, and the Principle of Equivalence just got shot to Hell.
 
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  • #48
belliott4488 said:
Again I ask you, why not? You said earlier that the 3rd law doesn't work, but I responded (https://www.physicsforums.com/showpost.php?p=1671401&postcount=37") by pointing out that in fact it does, much as it does for the case of a constant gravitational field, to which this case is equivalent.
Show your work and justify your claim that it is equivalent.

belliott4488 said:
Do you in fact believe that Newton's 3rd law is violated in the approximation of a constant gravitational field that is typically invoked for motion on the Earth's surface? If so, then at least you're consistent, although rather unconventional, since that approximation is often used in the presentation of Newton's Laws for the first time in introductory Physics.
In Newtonian physics gravity is a real force with two bodies interacting. It satisfies the 3rd law, and I have no problem with the approximation to a uniform field.

The fact that the uniform approximation has the same form as the inertial force is irrelevant here. The two situations are not equivalent wrt the 3rd law because the gravitational force is due to the interaction with another body and the inertial force is not.
 
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  • #49
belliott4488 said:
One more thing: Suppose I'm riding in my rocket ship/space elevator, and I'm doing all kinds of Physics - I'm shooting pool, I'm tossing balls through the air (it's a big elevator), I'm playing with pendula, I'm spinning gyroscopes - at what point will I find myself unable to explain or predict what I'm seeing simply by applying Newton's laws and the assumption of a constant force field, which I'll call, for lack of a better term, "gravity"? If you tell me the laws of motion break down, then I'll be able to tell that I'm in an accelerating frame and not in a constant gravitational field, and the Principle of Equivalence just got shot to Hell.
What body is causing this "gravity"? Or in other words, where do you put your reaction force to "gravity"?
 
  • #50
DaleSpam:

As I said in an earlier response to JesseM, I completely agree that Newton's Law of Gravity does not apply in the accelerating frame - this is trivially true. My point is that the Laws of Motion say nothing about the source or nature of the force. They simply say, "give me a force and I'll tell you how objects will react to it."

As for your request that I "show my work" to show that a constant gravitational field is equivalent to a frame undergoing constant acceleration ... um, hasn't that been done - a lot? I know you know the Principle of Equivalence, which I keep mentioning just as a short-hand because I assume we all know the argument. Otherwise, Google it - you'll find a better explanation than I'll come up with off the top of my head, which is fine since it's not my argument.

As far as I can tell, our only real disagreement has to do with the reaction forces, or the "equal and opposite pairs," as we've called them. Did you disagree with my examples? So long as the objects are accelerated along with the frame, something is applying a force, which is what the inertial "reaction force" is reacting to. To the observer in the accelerating frame, he detects this mysterious force (the nature of which is immaterial to him, since he only needs to call it "F" in his equations), and sees that an equal and opposite force is needed to support it so that it doesn't fall to the floor.

When he drops the object, he feels - with his very sensitive feet - that the "ground" is accelerating upwards toward the object, as it must, since as far as he's concerned it feels the equal and opposite force. We, in our inertial frame outside the spaceship, attribute this to the increase in acceleration due to the slight decrease in accelerated mass, but the result is all the same.

I hate to keep appealing to authority, but doesn't Einstein's Principle of Equivalence make this kind of a non-issue? His whole point is that an observer in an accelerating frame cannot distinguish between his accelerating frame and a frame at rest in a constant gravitational field. If he could detect a violation of Newton's laws, then he could make the distinction. All of GR depends on this principle, so I don't see how you think it could be so wrong.
 
  • #51
OK, belliott. I am willing to engage in a discussion about GR and the equivalence principle, but first I want you to address directly the following:

In my example I purposfully set up a scenario without gravitation so that there would be no confusion about if a given force was real or inertial. So, in the context of my example (i.e. flat spacetime, no gravity) I have performed an analysis demonstrating a clear violation of Newton's 3rd law in an accelerated reference frame. You are claiming that there is no such violation, so where did I make my error? Can you demonstrate that Newton's 3rd law is, in fact, satisfied in my scenario?
 
  • #52
DaleSpam said:
OK, belliott. I am willing to engage in a discussion about GR and the equivalence principle,
Nah, I don't think we need to go into GR - I haven't gotten the impression we have any disagreement there, unless you think it's all a crock, but you don't impress me as a crackpot :wink:, so I think we're fine just staying on-topic.
DaleSpam said:
... but first I want you to address directly the following:

In my example I purposfully set up a scenario without gravitation so that there would be no confusion about if a given force was real or inertial. So, in the context of my example (i.e. flat spacetime, no gravity) I have performed an analysis demonstrating a clear violation of Newton's 3rd law in an accelerated reference frame. You are claiming that there is no such violation, so where did I make my error? Can you demonstrate that Newton's 3rd law is, in fact, satisfied in my scenario?
I agree this is the crux of our disagreement, but I don't see where you have demonstrated a "clear violation of Newton's 3rd law." You did show how the laws didn't work if the spaceman attempted to do Physics as if he were in an inertial frame, but then you showed how the 1st and 2nd laws did work if he invoked the fictitious inertial force. About the 3rd law, you simply said, "... all of the inertial forces act in the same direction, so they do not form 3rd law pairs. The inertial forces violate the 3rd law because there are no equal and opposite inertial forces."

This is what I've already responded to - I don't understand why you say this. First, the inertial forces are in the direction opposite to the acceleration, right? so if there were no other forces at work any objects under the influence of those forces would all be moving in that direction, which they aren't - at least, not until the spaceman drops the rock.

Let me go through it one more time, and tell me what it is that you object to (I've already been through this twice, but maybe you haven't been reading all the posts). If the spaceman stands in his rocket ship holding a rock, he feels that the rock exerts a "downward" force of ma on his hand. As long as he holds the rock motionless in his frame, he sees that he's exerting an equal and opposite force upward, ie. ma in the "upward" direction. We would describe it differently from outside, in our inertial coordinates, but you know how to do that and it doesn't matter for this discussion.

Now if he let's go of the rock and sees it fall to the floor, he will, of course, see it accelerate at a in the "downward" direction - again, we outside observers would say that it was moving inertially, but in his coordinates he would say it accelerates. If you now ask, "where's the force equal and opposite to the force he sees that causes this perceived acceleration?" the answer is essentially the same as it is when a student asks about the force equal and opposite to the gravitational force on a falling apple. In that case, the Earth is accelerated upward by a minuscule amount; in this case the rocket ship is accelerated "upward" when the spaceman releases the rock. In his frame, this is simply due to the equal and opposite force pulling "up" on the floor (which he can detect). In our frame, we see the additional acceleration on the ship because the rocket motor is now producing a greater acceleration of a' = F/M instead of the original acceleration a = F/(M+m), where F is the thrust of the rocket motor, m is the mass of the rocket, and M is the total remaining mass being accelerated by the motor.

Once the rock lands on the floor, the motor must now accelerate it as well (according to our inertial frame), so the acceleration we see returns to its original value, and the spaceman no longer feels the additional acceleration. (As an interesting side-note, his description would most likely be that he initially feels a downward force on his body, which he might call his "weight", due to the fictitious force, but when he drops the rock and feels the additional force, he would call that an inertial reaction force since he sees the floor (and himself) accelerating :"upward" in response to the equal and opposite force from the rock. In our inertial frame, we'd say it's all inertial reaction forces, just two different values for the two different acceleration magnitudes.)

That's not super rigorous, but do you really want me to go through the algebra? The reason I keep referring to the Equivalence Principle is just that I'm assuming you've seen this before and you know that the calculations in the accelerated frame are identical to the calculations in a constant gravitational field, so I'm not bothering to copy them here. I will, if you insist - or if you think there really is a subtlety there that I'm missing but will show up in the calculations.

I'll add one more thing, which is just to reinforce that I agree completely that the fictitious forces in non-inertial frames screw up the calculations. This is particularly evident in rotating frames, where we can't even attribute the centrifugal or Coriolis force to an apparent gravitational field. Nonetheless, we can write down expressions for what these forces look like in the coordinates of the rotating frame - in all their ugliness - and then do Physics using Newton's laws. This is a pain, but as far as I know, it works - do you disagree?

Again, my whole point boils down to this: whatever the origin of the forces, if you can write down expressions for them, then you can use Newton's laws to describe the resulting motion in the coordinates of the accelerated frame. I don't think you've actually denied this, except to assert that there aren't any equal and opposite forces. Can you show where this is true and you would be unable to describe the motion in the accelerated frame?

If you still think so, then how about we try the simple case of the spaceman tossing the rock in the air and recording its trajectory (just one dimension is fine, of course)? I predict that his application of Newton's laws will correctly describe the motion he observes. I'll gladly go through it in detail if you like, but I'd ask that you do the same so that we can see where our calculations diverge.
 
  • #53
belliott4488 said:
I agree this is the crux of our disagreement, but I don't see where you have demonstrated a "clear violation of Newton's 3rd law." You did show how the laws didn't work if the spaceman attempted to do Physics as if he were in an inertial frame, but then you showed how the 1st and 2nd laws did work if he invoked the fictitious inertial force. About the 3rd law, you simply said, "... all of the inertial forces act in the same direction, so they do not form 3rd law pairs. The inertial forces violate the 3rd law because there are no equal and opposite inertial forces."

This is what I've already responded to - I don't understand why you say this.
In SI units the inertial force on the rocket is (-2000,0,0) and the inertial force on the ball is (-0.2,0,0). I didn't explicitly mention the inertial force on the exhaust, but if the exhaust masses 1 kg then the inertial force on the exhaust is (-2,0,0). These are all of the inertial forces that exist in the example, they are all of different magnitudes and in the same direction so none of them are equal nor opposite to each other, so they cannot form 3rd law pairs. There are no missing forces and no missing bodies so the 3rd law is violated in the accelerated frame.


belliott4488 said:
First, the inertial forces are in the direction opposite to the acceleration, right?
Yes.

belliott4488 said:
so if there were no other forces at work any objects under the influence of those forces would all be moving in that direction, which they aren't - at least, not until the spaceman drops the rock.
I don't understand your comment here.

belliott4488 said:
Let me go through it one more time, and tell me what it is that you object to (I've already been through this twice, but maybe you haven't been reading all the posts). If the spaceman stands in his rocket ship holding a rock, he feels that the rock exerts a "downward" force of ma on his hand. As long as he holds the rock motionless in his frame, he sees that he's exerting an equal and opposite force upward, ie. ma in the "upward" direction. We would describe it differently from outside, in our inertial coordinates, but you know how to do that and it doesn't matter for this discussion.

Now if he let's go of the rock and sees it fall to the floor, he will, of course, see it accelerate at a in the "downward" direction - again, we outside observers would say that it was moving inertially, but in his coordinates he would say it accelerates.
Yes.

belliott4488 said:
If you now ask, "where's the force equal and opposite to the force he sees that causes this perceived acceleration?" ... in this case the rocket ship is accelerated "upward" when the spaceman releases the rock. In his frame, this is simply due to the equal and opposite force pulling "up" on the floor (which he can detect). In our frame, we see the additional acceleration on the ship because the rocket motor is now producing a greater acceleration of a' = F/M instead of the original acceleration a = F/(M+m), where F is the thrust of the rocket motor, m is the mass of the rocket, and M is the total remaining mass being accelerated by the motor.
This is where you need to run the numbers. I understand what you are saying here, but since you have not run the numbers you don't realize that you are wrong in your conclusions: the resulting forces in this slightly more detailed scenario will still not satisfy Newton's 3rd law. Do you want to do the math or do you want me to do it?

belliott4488 said:
That's not super rigorous, but do you really want me to go through the algebra?
Yes. I honestly believe that is the best way to understand non-inertial frames and inertial forces.

belliott4488 said:
The reason I keep referring to the Equivalence Principle is just that I'm assuming you've seen this before and you know that the calculations in the accelerated frame are identical to the calculations in a constant gravitational field, so I'm not bothering to copy them here. I will, if you insist - or if you think there really is a subtlety there that I'm missing but will show up in the calculations.
I will be glad to discuss GR later, but before we can have a productive conversation about the equivalence principle and curved spacetime we need to come to a mutual understanding about non-inertial reference frames and ficticious forces in flat space.

belliott4488 said:
I'll add one more thing, which is just to reinforce that I agree completely that the fictitious forces in non-inertial frames screw up the calculations. This is particularly evident in rotating frames, where we can't even attribute the centrifugal or Coriolis force to an apparent gravitational field. Nonetheless, we can write down expressions for what these forces look like in the coordinates of the rotating frame - in all their ugliness - and then do Physics using Newton's laws. This is a pain, but as far as I know, it works - do you disagree?
Newton's 1st and 2nd laws I agree. Newton's 3rd law I disagree. In fact, you can make an arbitrarily accelerating reference frame with arbitrarily ugly inertial forces and you can use those inertial forces to correctly predict the outcome of traditional (non-relativistic) physics experiments in the non-inertial frame. But those inertial forces will always violate the 3rd law.


belliott4488 said:
Again, my whole point boils down to this: whatever the origin of the forces, if you can write down expressions for them, then you can use Newton's laws to describe the resulting motion in the coordinates of the accelerated frame. I don't think you've actually denied this, except to assert that there aren't any equal and opposite forces. Can you show where this is true and you would be unable to describe the motion in the accelerated frame?
I never made such a claim. I have been very consistent with my statements.

In a non-inertial reference frame objects experiencing no real forces accelerate. This is a violation of Newton's 1st and 2nd law, however it is a "repairable" violation in the sense that we can introduce inertial forces. These inertial forces modify the normal laws but can be used to correctly predict the motion of objects in the non-inertial frame, but they do not satisfy Newton's 3rd law. This last is a "non-repairable" violation.

belliott4488 said:
If you still think so, then how about we try the simple case of the spaceman tossing the rock in the air and recording its trajectory (just one dimension is fine, of course)? I predict that his application of Newton's laws will correctly describe the motion he observes. I'll gladly go through it in detail if you like, but I'd ask that you do the same so that we can see where our calculations diverge.
Sounds good. I will do that, and I predict that his application of Newton's first two laws, including the inertial forces, will correctly describe the motion he observes and that the inertial forces will not satisfy the 3rd law.

So that we can be consistent let's use the following:
mass of the ball = .1 kg
mass of the rocket (including ball) = 1000 kg
mass of the exhaust at t=1 s (if needed) = 1 kg
thrust of the engine = 2000 N
transformation equation between inertial and non-inertial frame: x' = x-t²
ball released gently at t=t'=1s

If I missed something just specify it explicitly.
 
  • #54
DaleSpam said:
In SI units the inertial force on the rocket is (-2000,0,0) and the inertial force on the ball is (-0.2,0,0). I didn't explicitly mention the inertial force on the exhaust, but if the exhaust masses 1 kg then the inertial force on the exhaust is (-2,0,0). These are all of the inertial forces that exist in the example, they are all of different magnitudes and in the same direction so none of them are equal nor opposite to each other, so they cannot form 3rd law pairs. There are no missing forces and no missing bodies so the 3rd law is violated in the accelerated frame.

Sorry, I do think you're missing some forces here, specifically the "real" forces that cause the objects to accelerate and hence to give rise to the inertial reaction forces in the first place. In fact, I believe inertial reaction forces are often defined as the equal and opposite forces applied by massive objects back on whatever is applying the forces on them. Here are the specifics for your case:

1. The ball: In the accelerating frame the ball is subject to an inertial force of -2 N, as you've said. It has this because it is being accelerated along with the rocket (relative to the inertial frame), which means it is motionless in the accelerated frame. So, if it is subect to this force in this frame, why isn't it moving? Simply because the spaceman is holding it in his hand, exerting an equal and opposite force of +2 N. Better yet, he can place it on a spring scale, which will show the "weight" of the ball as 2 N, which of course means that the spring is exerting a +2 N force "upward" on the ball.

2. The rocket: In the accelerating frame the spaceman notices that the ball has a "weight" (2 N), he has a weight (his mass X the acceleration), and he quickly deduces that the rocket itself must have weight, so something must be holding it up, since it is motionless in his frame. Looking out his port hole, he sees the rocket plume and realizes that the rocket motor is supplying thrust in the "upward" direction, which must be exactly equal and opposite to the "weight" of the rocket+spaceman+ball. In other words, the rocket is "hovering" in his frame due to the thrust force, which is exactly equal and opposite to the inertial force on the rocket. We know that this must be, because the thrust of the motor is exactly what is needed to accelerate this same mass in the inertial system to the acceleration that produces the "weight" in the accelerated system.

DaleSpam said:
belliott4488 said:
If you now ask, "where's the force equal and opposite to the force he sees that causes this perceived acceleration?" the answer is essentially the same as it is when a student asks about the force equal and opposite to the gravitational force on a falling apple. In that case, the Earth is accelerated upward by a minuscule amount; in this case the rocket ship is accelerated "upward" when the spaceman releases the rock. In his frame, this is simply due to the equal and opposite force pulling "up" on the floor (which he can detect). In our frame, we see the additional acceleration on the ship because the rocket motor is now producing a greater acceleration of a' = F/M instead of the original acceleration a = F/(M+m), where F is the thrust of the rocket motor, m is the mass of the rocket, and M is the total remaining mass being accelerated by the motor.
This is where you need to run the numbers. I understand what you are saying here, but since you have not run the numbers you don't realize that you are wrong in your conclusions: the resulting forces in this slightly more detailed scenario will still not satisfy Newton's 3rd law. Do you want to do the math or do you want me to do it?

Okay, let's do this more carefully, then. First, let's look at it in inertial coordinates, where we know we have no disagreement. Before the spaceman releases the ball, the rocket thrust is accelerating the entire system of rocket + ball, so the acceleration is [tex]a_1=F/(M+m)[/tex], where, as before, [tex]F[/tex] is the thrust of the motor, [tex]m[/tex] is the mass of the ball (I think it was a rock last time ...), and [tex]M[/tex] is the remaining accelerated mass. After he releases the ball, the thrust is applied only to the remaining mass, so the acceleration is now [tex]a_2 = F/M[/tex]. After the ball hits the floor and comes to rest, the acceleration will return to its initial value.

What is the difference in the acceleration: it's simply
[tex]\delta a = a_2 - a_1 =\frac{F}{M} - \frac{F}{(M+m)} = \frac{F}{(M+m)} * \frac{m}{M} [/tex]

But since the original acceleration is [tex]a_1=\frac{F}{(M+m)}[/tex] we have,
[tex]\delta a = a_1 * \frac{m}{M}[/tex]

Now, what does the spaceman see in the accelerated frame? He feels the ball with its "weight" of [tex]ma[/tex], and when he releases it, he sees it accelerate "downward" with an acceleration of [tex]a[/tex]. He also feels the floor accelerate upward, however, due to the equal and opposite force exerted by the ball on the floor. What acceleration does he detect? Well, the force is given by [tex]ma[/tex], so that is the force "upward" on the floor. That force must accelerate the entire rocket (minus ball), so it produces an acceleration
[tex]a = \frac{F}{M} = a*\frac{m}{M}[/tex]
which is the same acceleration we saw from the inertial point of view. Therefore by assuming a force equal and opposite to the inertial force he felt on the ball, he predicts exactly the same resulting acceleration as we did in the inertial frame.

I didn't explicitly plug any specific numbers in there, but since I have the same result for both frames, plugging in arbitrary numbers isn't going to prove anything.

For some reason the forum produces a database error if I post my whole response, so I'll leave this one here, and then post the rest in a subsequent response.
 
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  • #55
This is the remainder of my response, which the Forum wouldn't let me post in one piece:

DaleSpam said:
Sounds good. I will do that, and I predict that his application of Newton's first two laws, including the inertial forces, will correctly describe the motion he observes and that the inertial forces will not satisfy the 3rd law.

So that we can be consistent let's use the following:
mass of the ball = .1 kg
mass of the rocket (including ball) = 1000 kg
mass of the exhaust at t=1 s (if needed) = 1 kg
thrust of the engine = 2000 N
transformation equation between inertial and non-inertial frame: x' = x-t²
ball released gently at t=t'=1s

If I missed something just specify it explicitly.
Okay, let's go through this. I'm not sure I really see the point, since we're just applying the 1st and 2nd laws, which you've already agreed work fine in the accelerated system, but since if you believe the error in my reasoning will be revealed, then on we go ...

Let's define some variables so that the equations aren't just a mash-up of numbers:

mass of ball: [tex]m_b = 0.1 \,\text{kg}[/tex]
mass of rocket (including ball and spaceman): [tex]m_r = 1000.0 \,\text{kg}[/tex]
thrust of rocket motor: [tex]T=2000.0 \,\text{N}[/tex]

We're using primed coordinates, velocities, and accelerations for the accelerating system, unprimed for the inertial system.
I'm going to override your specification that the ball is released at t=1 s (gently - that's good! :-) we don't need any extraneous forces, here!), since there's nothing important happening 1 s before then to start our clocks. I'll just say that t=0 at the moment of release and avoid unnecessary extra terms that look like (t - 1s); if you've gone ahead with your definition, then there will be a lot of "t-1" factors that we can easily correct for.

I'll also say that the origins of both coordinate systems are aligned with the point of release of the ball at t=0, so that point is x = x' = 0 as well.

Then we have initial velocities, all at time t = 0:
rocket initial velocity in accel. stytem: [tex] v'_{r0} = 0\,\text{km/sec}[/tex]
rocket initial velocity in inertial system: [tex] v_{r0} = 10.0 \,\text{km/sec}[/tex]
ball initial velocity in accel. system: [tex]v'_{b0} = 0.1 \,\text{km/sec}[/tex]
ball initial velocity in inertial systme: [tex]v_{b0} = v_{r0} + v'_{b0} = 10.1 \,\text{km/sec}[/tex]

For the acceleration of the rocket in the inertial frame we have:
[tex]a = F/m_r = 2 \,\text{km/sec}^2[/tex]

Next we'll work out the trajectory of the ball in the inertial frame, where we are in agreement about everything.
The position of the rocket (i.e. the origin of the accel. frame) in the inertial frame is
[tex]x_r(t) = v_r t + \frac{1}{2}at^2[/tex]
where [tex]v_r(t) = v_{r0}+at[/tex]

The ball moves inertially once it's released, so its position in the inertial frame is simply
[tex]x_b(t) = v_{b0} t [/tex]

So, what is the distance from the point of release in the rocket (i.e. the spaceman's hand) to the ball at time t? It will be:
[tex]h(t) = x_b - x_r = v_{b0} t - v_r t - \frac{1}{2}at^2 = (v_{b0}-v_r)t - \frac{1}{2}at^2 [/tex]

Now let's go to the accelerated frame. The ball is subject to the inertial force in the "downward" direction, so its postion will be:
[tex]x'_b(t) = v'_b t - \frac{1}{2}at^2 [/tex]

But we note that since the ball's (constant) velocity in the inertial frame is just
[tex]v_b = v_{b0} = v_r + v'_b[/tex]
we get
[tex]v'_b = v_b - v_r[/tex]
so
[tex]x'_b(t) = (v_{b0}-v_r)t - \frac{1}{2}at^2 = h(t)[/tex]

In other words, by invoking Newton's Laws in his accelerated frame, the spaceman predicts exactly the same answer that we do in our inertial frame.
 
  • #56
Hi belliott, here is my work. I have attached free-body diagrams for all four parts of this problem. All forces are indicated on the diagrams and the accelerations are worked out for the rocket and the ball. Note in particular that I have highlighted the blue 3rd law pair for the thrust and the green third law pair for the contact force. Note also that none of the inertial forces in black are part of a 3rd law pair, i.e. they do not satisfy the 3rd law.

Below are the resulting equations of motion where capital X indicates the position of the rocket, lower-case x indicates the position of the ball, subscript 1 indicates when the ball is held, subscript 2 indicates when the ball is released, unprimed is the inertial coordinate system, primed is the accelerated coordinate system with transformation equation between the two x' = x - t² and inertial forces of -2m on every mass in the accelerated frame.

The equations of motion for the inertial frame while the ball is held (upper left) are:
[tex]\begin{array}{l}
X_1=t^2 \\
x_1=t^2
\end{array}[/tex]

The equations of motion for the accelerated frame while the ball is held (lower left) are:
[tex]\begin{array}{l}
X_1'=0=X_1-t^2 \\
x_1'=0=x_1-t^2
\end{array}[/tex]As you can see, these equations transform correctly, indicating agreement between the frames. As you can also see, the inertial forces were required in order to achieve this agreement.

Evaluating the above expressions at t=1 for the initial conditions of the next part gives:
[tex]\begin{array}{l}
X_1(1)=x_1(1)=1 \\
V_1(1)=v_1(1)=2
\end{array}[/tex]

[tex]\begin{array}{l}
X_1'(1)=x_1'(1)=0 \\
V_1'(1)=v_1'(1)=0
\end{array}[/tex]

The equations of motion for the inertial frame while the ball is dropped (upper right) are:
[tex]\begin{array}{l}
X_2=1.0001 t^2-0.0002 t+0.0001 \\
x_2=2. t-1.
\end{array}[/tex]

The equations of motion for the accelerated frame while the ball is dropped (lower right) are:[tex]\begin{array}{l}
X_2'=0.0001 t^2-0.0002 t+0.0001=X_2-t^2 \\
x_2'=-t^2+2. t-1.=x_2-t^2
\end{array}[/tex]As you can see, these equations again transform correctly, indicating agreement between the frames. As you can also see, the inertial forces were again required in order to achieve this agreement.

Bottom line: in the accelerating frame the inertial forces do not follow Newton's 3rd law, as shown in the free-body diagrams, but are required in order to satisfy Newton's 1st and 2nd laws and to obtain the correct equations for motion. In order to satisfy Newton's 1st and 2nd laws the 3rd law is violated. I didn't look at your posts in detail, but from my cursory reading nothing even appeared to address the 3rd law nor rebut my claims that it is violated.
 

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  • #57
belliott4488 said:
Sorry, I do think you're missing some forces here, ... The ball: ... the spaceman is holding it in his hand, exerting an equal and opposite force of +2 N.
You are correct, I neglected that force (+0.2 N contact force on the ball) in the initial description. I have included it and it's 3rd law pair (-0.2 N contact force on the rocket/spaceman) in my analysis above.

belliott4488 said:
Okay, let's do this more carefully, then. First, let's look at it in inertial coordinates, where we know we have no disagreement. Before the spaceman releases the ball, the rocket thrust is accelerating the entire system of rocket + ball, so the acceleration is [tex]a_1=F/(M+m)[/tex], where, as before, [tex]F[/tex] is the thrust of the motor, [tex]m[/tex] is the mass of the ball (I think it was a rock last time ...), and [tex]M[/tex] is the remaining accelerated mass. After he releases the ball, the thrust is applied only to the remaining mass, so the acceleration is now [tex]a_2 = F/M[/tex]. After the ball hits the floor and comes to rest, the acceleration will return to its initial value.

What is the difference in the acceleration: it's simply
[tex]\delta a = a_2 - a_1 =\frac{F}{M} - \frac{F}{(M+m)} = \frac{F}{(M+m)} * \frac{m}{M} [/tex]

But since the original acceleration is [tex]a_1=\frac{F}{(M+m)}[/tex] we have,
[tex]\delta a = a_1 * \frac{m}{M}[/tex]
Yes.

belliott4488 said:
Now, what does the spaceman see in the accelerated frame? He feels the ball with its "weight" of [tex]ma[/tex], and when he releases it, he sees it accelerate "downward" with an acceleration of [tex]a[/tex]. He also feels the floor accelerate upward, however, due to the equal and opposite force exerted by the ball on the floor. What acceleration does he detect? Well, the force is given by [tex]ma[/tex], so that is the force "upward" on the floor. That force must accelerate the entire rocket (minus ball), so it produces an acceleration
[tex]a = \frac{F}{M} = a*\frac{m}{M}[/tex]
which is the same acceleration we saw from the inertial point of view. Therefore by assuming a force equal and opposite to the inertial force he felt on the ball, he predicts exactly the same resulting acceleration as we did in the inertial frame.
OK, there are several errors in this analysis. First and most importantly, you left out the thrust force (2000 N) acting on the rocket. Second, you left out the inertial force of the rocket (-1999.8 N). These two forces are sufficient to account for the acceleration and obtain agreement between the two frames. By arbitrarily adding another 0.2 N force on the rocket you wind up with disagreement between the frames since the delta acceleration in the non-inertial frame would be twice the delta in the inertial frame.
 
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  • #58
belliott4488 said:
This is the remainder of my response, which the Forum wouldn't let me post in one piece:
I think there must be a limit on the number of LaTeX objects in a post because I was getting database errors replying too.

belliott4488 said:
Okay, let's go through this. I'm not sure I really see the point, since we're just applying the 1st and 2nd laws, which you've already agreed work fine in the accelerated system, but since if you believe the error in my reasoning will be revealed, then on we go ...
I have consistently agreed that, by including the inertial forces, the 1st and 2nd laws work. I have consistently stated that the inertial forces required for the 1st and 2nd law violate the 3rd law.

belliott4488 said:
Let's define some variables so that the equations aren't just a mash-up of numbers:
...

We're using primed coordinates, velocities, and accelerations for the accelerating system, unprimed for the inertial system.
I'm going to override your specification that the ball is released at t=1 s ... I'll just say that t=0 at the moment of release ...

I'll also say that the origins of both coordinate systems are aligned with the point of release of the ball at t=0, so that point is x = x' = 0 as well.

Then we have initial velocities, all at time t = 0:
...

For the acceleration of the rocket in the inertial frame we have:
[tex]a = F/m_r = 2 \,\text{km/sec}^2[/tex]
This is incorrect. It should be
[tex]a = F/(m_r - m_b) = 2.0002 \,\text{m/s}^2[/tex]
for t>0

belliott4488 said:
Next we'll work out the trajectory of the ball in the inertial frame, where we are in agreement about everything.
The position of the rocket (i.e. the origin of the accel. frame) in the inertial frame is
[tex]x_r(t) = v_r t + \frac{1}{2}at^2[/tex]
where [tex]v_r(t) = v_{r0}+at[/tex]
I think you mean [tex]x_r(t) = v_{r0} t + \frac{1}{2}at^2[/tex]. I corrected the following equations too.

belliott4488 said:
The ball moves inertially once it's released, so its position in the inertial frame is simply
[tex]x_b(t) = v_{b0} t [/tex]

So, what is the distance from the point of release in the rocket (i.e. the spaceman's hand) to the ball at time t? It will be:
[tex]h(t) = x_b - x_r = v_{b0} t - v_{r0} t - \frac{1}{2}at^2 = (v_{b0}-v_{r0})t - \frac{1}{2}at^2 [/tex]
OK

belliott4488 said:
Now let's go to the accelerated frame. The ball is subject to the inertial force in the "downward" direction, so its postion will be:
[tex]x'_b(t) = v'_{b0} t - \frac{1}{2}at^2 [/tex]

But we note that since the ball's (constant) velocity in the inertial frame is just
[tex]v_{b0} = v_{r0} + v'_{b0}[/tex]
we get
[tex]v'_{b0} = v_{b0} - v_{r0}[/tex]
so
[tex]x'_b(t) = (v_{b0}-v_{r0})t - \frac{1}{2}at^2 = h(t)[/tex]

In other words, by invoking Newton's Laws in his accelerated frame, the spaceman predicts exactly the same answer that we do in our inertial frame.
This is fine, your frame is accelerating at a different rate than mine, but everything works out OK.

However, you never addressed the 3rd law question here. Where is the 3rd law pair for the -0.20002 N "inertial force in the 'downward' direction" on the ball? You have an inertial force on the rocket of -2000 N which exactly balances the thrust of 2000 N, but that force is neither equal nor opposite. Again, from your own work, it is clear that in order to get Newton's 1st and 2nd laws to work in the accelerated frame you must postulate inertial forces which violate the 3rd law.
 
  • #59
DaleSpam said:
This is fine, your frame is accelerating at a different rate than mine, but everything works out OK.

However, you never addressed the 3rd law question here. Where is the 3rd law pair for the -0.20002 N "inertial force in the 'downward' direction" on the ball? You have an inertial force on the rocket of -2000 N which exactly balances the thrust of 2000 N, but that force is neither equal nor opposite. Again, from your own work, it is clear that in order to get Newton's 1st and 2nd laws to work in the accelerated frame you must postulate inertial forces which violate the 3rd law.
Let us analys the problem logically.I think there is no need to eloborate the problem with putting y,z co-ordinate(we can take x co-ordinate which is the only relevant one in this example) .
Initally the relative velocity will be zero and hence there will be no relative change in position between the ball and spacecraft floor because ball is physically connected to the spacecraft by the person who holds it.
A thrust,applied to the spacecraft will accelerate both spacecraft and ball.F= (M+m)a will be the equation of motion.But again the relative velocity and relative motion will be zero because both the bodies are accelerated at same rate.
At the instance the ball is released,it will have a velocity which will be the velocity of spacecraft and ball at that instance as calculated from the above equation.the ball will continue it's state of motion with that uniform velocity.The position of ball after 't' seconds will be decided by this velocity.
Once the ball is released,the equation of motion will be F=Ma'.the position of spacecraft floor after 't' seconds can be calculated from a'.
In both these None of the laws are violated.
Now,if we don't have a clear picture as above.ie. we don't have a third reference which is absolute with respect to both object,still we can calculate the position of ball after 't' seconds by introducing a fictious force.
Since we know this is a fictious force,it is not necessary for it to have an equal and opposite pair.
Still if it is so necessary,i can say there is a fictious equal and opposite pair for it ,by using the same logic.
 
  • #60
newTonn said:
Let us analys the problem logically.I think there is no need to eloborate the problem with putting y,z co-ordinate(we can take x co-ordinate which is the only relevant one in this example) .
Initally the relative velocity will be zero and hence there will be no relative change in position between the ball and spacecraft floor because ball is physically connected to the spacecraft by the person who holds it.
A thrust,applied to the spacecraft will accelerate both spacecraft and ball.F= (M+m)a will be the equation of motion.But again the relative velocity and relative motion will be zero because both the bodies are accelerated at same rate.
At the instance the ball is released,it will have a velocity which will be the velocity of spacecraft and ball at that instance as calculated from the above equation.the ball will continue it's state of motion with that uniform velocity.The position of ball after 't' seconds will be decided by this velocity.
Once the ball is released,the equation of motion will be F=Ma'.the position of spacecraft floor after 't' seconds can be calculated from a'.
In both these None of the laws are violated.
Correct, this is all done in the inertial reference frame.

newTonn said:
Now,if we don't have a clear picture as above.ie. we don't have a third reference which is absolute with respect to both object,still we can calculate the position of ball after 't' seconds by introducing a fictious force.
Since we know this is a fictious force,it is not necessary for it to have an equal and opposite pair.
If it is not necessary for a force to have an equal and opposite pair then Newton's 3rd law is not a law.

newTonn said:
Still if it is so necessary,i can say there is a fictious equal and opposite pair for it ,by using the same logic.
No, you cannot, as I have demonstrated twice now. Inertial forces violate Newton's 3rd law. You are welcome to try to demonstrate otherwise, but handwaving like this is insufficient.
 
  • #61
DaleSpam said:
If it is not necessary for a force to have an equal and opposite pair then Newton's 3rd law is not a law..
In this case ,when we introduce a fictious force,we misinterpret that the change in relative position of floor and ball is due to the acceleration of ball(ball is accused of having a force),instead the actual relative motion is because of the acceleration of floor.
 
  • #62
YellowTaxi said:
In all honesty I only looked at this thread because I was wondering if there were any startling similarities between how things might 'look' for a blind man, and how they look to people who have eyes to perceive the transmission of light. Actually I'm rather disappointed that the subject being discussed hasn''t really addressed that question, and has veered off into a different direction altogether to what I expected. But maybe I misunderstood what the OP was getting at. I didn't follow all that he said.
I am really sorry,i was not able to communicate the problem properly.
I was keeping quite because the discussion was going in another direction.
Now i will come back to my point with another example.
Consider a clock similar to the clock we are using to explain the time dilation.The difference in this clock,is instead of light,we are using sound as signal and instead of mirrors we are using a sound sensor.
When stationary,a tick sound is produced from the speaker attatched to the first sensor.when this sound reach the sensor on the opposite side(say ,L meter apart),it will produce a tick.consider this interval is set as one second.

Now if the clock is set in a moving object,we can hear that the clock starts slowing down.As the velocity of clock is increased,it become more slower.And if the speed exeeds the speed of sound you will not hear the ticks any more.Time will be stopped? or in other words,relative velocity is restricted to the speed of sound.

All the transformation equations will work in this case also,by replacing 'c' with the velocity of sound.

So,if i claim that you will be aged lesser or even stop ageing,if you are traveling together with this clock,Do anybody agree with me?.
If no,why?and why this reasoning is not applicable in the case of light.
 
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  • #63
newTonn said:
In this case ,when we introduce a fictious force,we misinterpret that the change in relative position of floor and ball is due to the acceleration of ball(ball is accused of having a force),instead the actual relative motion is because of the acceleration of floor.
Which is exactly why the laws of motion are violated in an accelerated frame.
 
  • #64
newTonn said:
I am really sorry,i was not able to communicate the problem properly.
I was keeping quite because the discussion was going in another direction.
Now i will come back to my point with another example.
Consider a clock similar to the clock we are using to explain the time dilation.The difference in this clock,is instead of light,we are using sound as signal and instead of mirrors we are using a sound sensor.
When stationary,a tick sound is produced from the speaker attatched to the first sensor.when this sound reach the sensor on the opposite side(say ,L meter apart),it will produce a tick.consider this interval is set as one second.

Now if the clock is set in a moving object,we can hear that the clock starts slowing down.As the velocity of clock is increased,it become more slower.And if the speed exeeds the speed of sound you will not hear the ticks any more.Time will be stopped? or in other words,relative velocity is restricted to the speed of sound.

All the transformation equations will work in this case also,by replacing 'c' with the velocity of sound.

So,if i claim that you will be aged lesser or even stop ageing,if you are traveling together with this clock,Do anybody agree with me?.
If no,why?and why this reasoning is not applicable in the case of light.
This is actually more along the line of where I thought you were going originally. I very much understand your point, as I had the same idea for a period of about 5 years. I will respond in more depth later, since I think I have some thoughts on the subject that may be useful to you also.
 
  • #65
DaleSpam said:
Which is exactly why the laws of motion are violated in an accelerated frame.
If you agree my statement,Action reaction pair is spacecraft and thrust.Ball is at uniform motion.Then how comes the law is violated?
 
  • #66
newTonn said:
If you agree my statement,Action reaction pair is spacecraft and thrust.Ball is at uniform motion.Then how comes the law is violated?
I refer you back to https://www.physicsforums.com/showpost.php?p=1674418&postcount=56", and in particular the free-body diagrams. What part did you not understand?

Regarding your "sound clock". The difference between sound waves and light waves is that light waves propagate at the speed of light in any reference frame and sound waves only propagate at the speed of sound in the rest frame of the medium. Basically, this can be understood in the fact that sound propagates through a medium and light propagates through empty space. When you are moving through the air you can perform a number of experiments to determine the velocity of the air, but when you are moving through empty space there is no experiment you can do to determine the "velocity" of empty space.

So, to go back to your sound clock. Let's suppose that your sound clock consisted of an enclosed cylinder of a length such that the sound would go from the speaker, echo off the far side, and return to a microphone mounted next to the speaker over a period of 1 second. Now, let's mount this clock on a supersonic jet traveling at mach 2 wrt the air. The clock will still tick at a rate of 1 second because the sound travels at mach 1 wrt the air inside the clock, which is traveling at mach 2 wrt the ground. So, in the ground frame, the sound in the clock is traveling at 3 times the speed of sound. This is the difference between sound and light.
 
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  • #67
DaleSpam said:
Regarding your "sound clock". The difference between sound waves and light waves is that light waves propagate at the speed of light in any reference frame and sound waves only propagate at the speed of sound in the rest frame of the medium. Basically, this can be understood in the fact that sound propagates through a medium and light propagates through empty space. When you are moving through the air you can perform a number of experiments to determine the velocity of the air, but when you are moving through empty space there is no experiment you can do to determine the "velocity" of empty space.

So, to go back to your sound clock. Let's suppose that your sound clock consisted of an enclosed cylinder of a length such that the sound would go from the speaker, echo off the far side, and return to a microphone mounted next to the speaker over a period of 1 second. Now, let's mount this clock on a supersonic jet traveling at mach 2 wrt the air. The clock will still tick at a rate of 1 second because the sound travels at mach 1 wrt the air inside the clock, which is traveling at mach 2 wrt the ground. So, in the ground frame, the sound in the clock is traveling at 3 times the speed of sound. This is the difference between sound and light.
Thanks for your response on the problem.
As mentioned in your explanation,if a similar enclosed cylinder is used for the light clock,please note that the enclosed vaccum is a separate entity and will have a velocity equal to that of the apparatus(clock) and at least in the case of relative motion it will be similar to that of the air inside the sound clock.
So all the equations will works similar as in the case of sound clock. The relative position of the observer inside spacecraft with the enclosed vacuum will remain same.So,Of course in the ground frame,the light has to travel with a speed greater than 'c',to satisfy this.(if the ship is traveling near to 'c'.)
 
  • #68
newTonn said:
As mentioned in your explanation,if a similar enclosed cylinder is used for the light clock,please note that the enclosed vaccum is a separate entity and will have a velocity equal to that of the apparatus(clock) and at least in the case of relative motion it will be similar to that of the air inside the sound clock.
What do you mean? In what way is the empty space inside something an "entity", and how would you propose to measure the velocity of the vacuum? I can think of a couple of very easy ways to measure the velocity of air, but not vacuum.

I cannot think of any physical meaning to empty space having a velocity.
 
  • #69
DaleSpam said:
What do you mean? In what way is the empty space inside something an "entity", and how would you propose to measure the velocity of the vacuum? I can think of a couple of very easy ways to measure the velocity of air, but not vacuum.

I cannot think of any physical meaning to empty space having a velocity.
please try to shift a vacuum chamber from one place to another.You can see the vacuum inside the chamber shifting from one place to another.
 
  • #70
That has no physical meaning. In order for something to move it must have a velocity. Please answer the question: How do you propose to measure the velocity of the vacuum?

If there is no way to physically measure its velocity then there is no physical meaning of assigning it a velocity. The vacuuum does not in any physical sense move, it is not an entity to which velocity may be assigned. All that happens is that the particles of the clock move as do any particles in the environment. Where there are no particles there is empty space or vacuum. The vacuum itself is not a thing to which a velocity may be assigned, it is simply the absence of things.
 

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