Can Two Different Coordinate Systems Explain the Zero Relative Speed of Light?

In summary, light travels at a constant speed and does not experience acceleration. At any given moment, the light pulse is moving tangentially to the observer and the change in its distance to the observer is 0. Light does not have a defined inertial frame, so it cannot be co-moving with an observer. The speed of the light pulse is always c, and it is never stationary relative to the observer.
  • #1
penomade
24
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Suppose a beam of light is approaching you from a distant source. As it comes closer to you, it doesn’t hit you; instead it misses you by a 10 meter distance. How can the rate of acceleration of that beam relative to you, be explained(in non-jargon language)? What would the speed of that be, when it reaches the closest distance of 10 meters, relative to you?
 
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  • #2
penomade said:
How can the rate of acceleration of that beam relative to you, be explained(in non-jargon language)?
What acceleration? Light moves at a constant speed.
penomade said:
What would the speed of that be, when it reaches the closest distance of 10 meters, relative to you?
299792458 m/s
 
  • #3
This is on the presumption that because that beam of light travels at an angle, its speed reduces as it gets closer to you. In fact this is my question.
 
  • #4
penomade said:
its speed reduces as it gets closer to you.
No, it doesn't.
 
  • #5
This is on the presumption that because that beam of light travels at an angle, its speed reduces as it gets closer to you. In fact this is my question.

You can't make a presumption like that, unless you're writing a sci-fi novel. Light travels in straight lines only and at one speed only (in free space). This rule neglects general relativity effects, of course, but I don't think that's what you are referring to or you would have mentioned that.
 
  • #6
At the point it reaches the 10 meter distance, it doesn't get any closer to you. That means it doesn't move relative to you. And in a minute fraction of time later, it would be traveling away from you.
 
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  • #7
penomade said:
At the point it reaches the 10 meter distance, it doesn't get any closer to you. That means it doesn't move relative to you. And in a minute fraction of time later, it would be traveling away from you.
It isn't instantaneously at rest in your frame; it is moving uniformly in your frame. Light has no defined inertial frame so you can't perform a boost to some frame such that you are co - moving with light.
 
  • #8
DiracPool said:
You can't make a presumption like that, unless you're writing a sci-fi novel. Light travels in straight lines only and at one speed only (in free space). This rule neglects general relativity effects, of course, but I don't think that's what you are referring to or you would have mentioned that.
I don't mean the beam is behaving strangely. I just mean instead of coming straight on to you, it passes by you. this is what I mean by an angle.
 
  • #9
penomade said:
Suppose a beam of light is approaching you from a distant source. As it comes closer to you, it doesn’t hit you; instead it misses you by a 10 meter distance. How can the rate of acceleration of that beam relative to you, be explained(in non-jargon language)? What would the speed of that be, when it reaches the closest distance of 10 meters, relative to you?
The speed of the beam is always c and the acceleration is 0. However, I think that what you are asking is what are the first and second time derivatives of the distance to the beam. You can get that simply by transforming to polar coordinates and calculating dr/dt etc. Those quantities are not physically meaningful, merely a reflection of the coordinates, i.e. there is no real force causing an acceleration.
 
  • #10
WannabeNewton said:
It isn't instantaneously at rest in your frame; it is moving uniformly in your frame. Light has no defined inertial frame so you can't perform a boost to some frame such that you are co - moving with light.
Perhaps I,d better put it this way, at first the beam is coming on to you. at that period it has a positive speed. then when it's leaving you, it has a negative speed, as it were. In between there should be a moment that it's neither getting closer nor getting away from you(relative to you). what's that?
 
  • #11
DaleSpam said:
The speed of the beam is always c and the acceleration is 0. However, I think that what you are asking is what are the first and second time derivatives of the distance to the beam. You can get that simply by transforming to polar coordinates and calculating dr/dt etc. Those quantities are not physically meaningful, merely a reflection of the coordinates, i.e. there is no real force causing an acceleration.
Let's forget about acceleration, for the moment. Instead, I use the word speed. what about that? Is it true that at one moment a photon is stationary relative to me.
 
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  • #12
penomade said:
Let's forget about acceleration. Instead, I use the word speed. what about that? Is it true that at one moment a photon is stationary relative to me.
No, it is not true that at any moment a light pulse is stationary relative to you. What is true is that at some moment the light pulse is moving tangentially to you. It is also true that at the same moment the change in the light pulse's distance to you is 0.
 
  • #13
Perhaps I,d better put it this way, at first the beam is coming on to you. at that period it has a positive speed. then when it's leaving you, it has a negative speed, as it were.

As it IS, there is no such thing as negative speed. There is negative velocity in relation to position.

In between there should be a moment that it's neither getting closer nor getting away from you(relative to you). what's that?

THAT, is exactly what that is. It's neither getting closer nor farther from you at that specific instant it is passing you. It's hard to see exactly what your quandry is, but I think you don't have a grasp on the special nature of what light is, it doesn't behave in the same manner a car does when it whizzes by you, which I think you're trying to equate it to.
 
  • #14
DiracPool said:
It's hard to see exactly what your quandry is, but I think you don't have a grasp on the special nature of what light is, it doesn't behave in the same manner a car does when it whizzes by you, which I think you're trying to equate it to.
I don't think that his confusion is related specifically to light. I think that it is more of a confusion about definitions of speed and velocity. If you are standing on a sidewalk next to a highway then the cars are traveling at ~100 km/h velocity relative to you. At no time is their velocity 0, and at no time is their speed 0. However, the distance to them is first decreasing, then momentarily constant, then increasing.
 
  • #15
I think I might be getting a better fix on the question now. The problem with the question is why you are transfixed on when a photon is stationary relative to you. What deeper meaning to this are you looking for?

Is it true that at one moment a photon is stationary relative to me.


The answer is that it is true all the time. Any time you want to take an instantaneous snapshot of space time, yes, there it is, the photon is stationary relative to you. It doesn't matter if it is 100 light years, 100 miles or 10 meters away. When it is approaching you, it approaches you at the speed of c with a positive velocity, if you will, and when it leaves you, it also leaves at c, relative to you. The only thing that changes that instant it passes you is the position value, which would be zero (forget about the ten meters, just have it pass right through you). The moment it passes you, though, "zero dark photon," has no effect on intertial reference frames or relative motion so I'm not sure where you are going with it.
 
  • #16
If you define in your inertial frame the +x direction to be the direction the massive particle is traveling in at constant speed then v = ||v||i where i is the usual cartesian unit vector. The speed ||v|| is constant so nowhere does it suddenly become zero unless it is zero at t = 0 when you first measure its speed. You don't even need to look at light.
 
  • #17
DaleSpam said:
I don't think that his confusion is related specifically to light. I think that it is more of a confusion about definitions of speed and velocity. If you are standing on a sidewalk next to a highway then the cars are traveling at ~100 km/h velocity relative to you. At no time is their velocity 0, and at no time is their speed 0. However, the distance to them is first decreasing, then momentarily constant, then increasing.
Granted. Let's talk about your example first. If you agree that speed involves movement, and movement involves distance, then if there is no change of distance, than there is no movement.
Although the movement of the car is tangential, but at the very moment it is, on its path, at the perpendicular line of my sight, it does not have the slightest movement relative to me. That's, after all, what the meaning of movement is: "changing distance". therefore, it is, just for one moment, stationary relative to me.
 
  • #18
DiracPool said:
I think I might be getting a better fix on the question now. The problem with the question is why you are transfixed on when a photon is stationary relative to you. What deeper meaning to this are you looking for?

The answer is that it is true all the time. Any time you want to take an instantaneous snapshot of space time, yes, there it is, the photon is stationary relative to you. It doesn't matter if it is 100 light years, 100 miles or 10 meters away. When it is approaching you, it approaches you at the speed of c with a positive velocity, if you will, and when it leaves you, it also leaves at c, relative to you. The only thing that changes that instant it passes you is the position value, which would be zero (forget about the ten meters, just have it pass right through you). The moment it passes you, though, "zero dark photon," has no effect on intertial reference frames or relative motion so I'm not sure where you are going with it.
What made me think of this, is this alleged paradox.http://www.phys.unsw.edu.au/einsteinlight/jw/module4_pole_paradox.htm
Maybe you can help me find a valid answer. I will also present my humble solution.(which I have partly done).
 
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  • #19
penomade said:
If you agree that speed involves movement
I agree.

penomade said:
, and movement involves distance,
I disagree. Movement involves a change in position wrt time, not a change in distance wrt time. This is the source of your confusion, I believe.

penomade said:
Although the movement of the car is tangential, but at the very moment it is, on its path, at the perpendicular line of my sight, it does not have the slightest movement relative to me.
No, it is moving tangentially relative to you.

penomade said:
That's, after all, what the meaning of movement is: "changing distance". therefore, it is, just for one moment, stationary relative to me.
No, see above.
 
  • #20
penomade said:
Granted. Let's talk about your example first. If you agree that speed involves movement, and movement involves distance, then if there is no change of distance, than there is no movement.
Although the movement of the car is tangential, but at the very moment it is, on its path, at the perpendicular line of my sight, it does not have the slightest movement relative to me. That's, after all, what the meaning of movement is: "changing distance". therefore, it is, just for one moment, stationary relative to me.
Just because, for an instant, it is not getting closer to you does not mean it is stationary relative to you. If you are measuring the light's position using the radius vector with respect to you, realize that there are two components to the velocity: the radial component (which would be zero at that moment) and the tangential component (which equals c, as usual).

(If you really believe that the speeding car does not have the slightest movement relative to you, why not reach out and touch it?)
 
  • #21
Doc Al said:
(If you really believe that the speeding car does not have the slightest movement relative to you, why not reach out and touch it?)

Interesting question. I think you put it politely. May be what you mean is, better said, why don't I go and stand exactly at the foot of the perpendicular!
I am thinking about it.
 
  • #22
penomade said:
What made me think of this, is this alleged paradox.http://www.phys.unsw.edu.au/einsteinlight/jw/module4_pole_paradox.htm
Maybe you can help me find a valid answer. I will also present my humble solution.(which I have partly done).
The resolution to this "paradox" is the relativity of simultaneity (as it usually is). The barn doors are closed at the same moment in the barn's frame, but in the right door closes much earlier than the left door in the pole's frame.
 
  • #23
Just for reference, if an object is moving in a straight line at speed v wrt me and its closest point of approach is a distance r0 from me then the distance from me is [itex]r(t)=\sqrt{v^2 t^2 + {r_0}^2}[/itex] where t is the time before or after the point of closest approach.

[tex]r'(t)=\frac{v^2 t}{\sqrt{v^2 t^2 + {r_0}^2}}[/tex]
[tex]r''(t)=\frac{v^2 {r_0}^2}{\left(v^2 t^2 + {r_0}^2\right)^{3/2}}[/tex]

Again, r' is the time rate of change of the distance between the object and me, it is not the speed of the object wrt me. That is v.
 
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  • #24
DaleSpam said:
The resolution to this "paradox" is the relativity of simultaneity (as it usually is). The barn doors are closed at the same moment in the barn's frame, but in the right door closes much earlier than the left door in the pole's frame.
Thank you Dale, I just give it a thought and return.
 
  • #25
The OP's question is a good one and clearly shows an intuitive reach that exceeds his grasp of some basics... just needs clarification of fundamentals about lengths and times - values, deltas, infinitesimal differentials, and instantaneous values.
 
  • #26
DaleSpam said:
Again, r' is the time rate of change of the distance between the object and me, it is not the speed of the object wrt me. That is v.
Let me try to back up a bit and talk about coordinates/reference frames:

A reference frame is a set of xy (and maybe z) coordinates. Speed is the change in position in that coordinate system (divided by time). If you happen to be located at the origin of that coordinate system, the object you are observing does not have to be moving directly toward or away from you to have a measurable speed. Consider, for example, constant speed motion from (3,0) to (0,3) in a coordinate system.

Examples of 1 dimensional motion are often used to simplify problems, but that shouldn't trick one into thinking motion is all directly toward or away from the origin of the reference frame.

In the Navy, we used what is called a "maneuvering board" to transform bearing and distance to a target (polar coordinates) to two different Cartesian coordinate systems centered on our ship, to calculate the distance and speed of another ship relative to us (and closest point of approach), in our moving frame of reference and in a frame stationary with respect to the water: http://gcaptain.com/maritime/tools/files/MoBoard.pdf [Broken]
 
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1. What does zero relative speed of light mean?

The zero relative speed of light refers to the concept that, from an observer's perspective, light appears to travel at the same speed regardless of their own motion. This is known as the speed of light being constant in all inertial frames of reference.

2. How is zero relative speed of light related to the theory of relativity?

The theory of relativity, specifically the Special Theory of Relativity, states that the speed of light is constant for all observers, regardless of their relative motion. This is known as the principle of relativity and is a fundamental concept in understanding the zero relative speed of light.

3. Does zero relative speed of light mean that light has no motion at all?

No, the zero relative speed of light does not mean that light has no motion. Light still travels at the speed of light, which is approximately 299,792,458 meters per second in a vacuum. The term "relative" refers to the fact that the speed of light appears the same to all observers, regardless of their own motion.

4. What experiments have been conducted to support the concept of zero relative speed of light?

One of the most famous experiments to support the zero relative speed of light is the Michelson-Morley experiment, which was conducted in 1887. This experiment aimed to measure the speed of light in different directions to determine if it was affected by the movement of the Earth through the hypothetical "ether." The results of this experiment supported the idea of a constant speed of light, regardless of the observer's motion.

5. Are there any exceptions to the zero relative speed of light?

According to the theory of relativity, the speed of light is constant for all observers in inertial frames of reference. However, there are some theories, such as the theory of general relativity, that suggest the speed of light may vary in extreme gravitational fields. Additionally, the speed of light may also appear to vary in non-inertial frames of reference, such as those experiencing acceleration.

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