Relativistic Problem: Mr. C's Observation

In summary: That is why the situation is not symmetrical.In summary, the conversation discusses a scenario where three boys, A, B, and C, synchronize their watches and then A starts flying at high speed. When A returns, they observe that their watches show different times. The complication arises when trying to determine who was moving and whose clock was slower. However, in Special Relativity, we select a single frame of reference to analyze the scenario. In this case, it is the frame where all three boys start and end at rest. In this frame, it is clear that A's clock ran slower while he was flying. This shows that motion is relative and only becomes a problem when one is accelerated, breaking the symmetry of the situation.
  • #1
khamaar
14
0
I was thinking,

Suppose there are three boys in one room. A B C. They time there watches perfectly with each other. In each of their watches the time is 6:00. Boy A starts flying around with velocity {[3^(1/2)]/2}.c...he flies and boys B sees that the time on A's watch is ticking slowly. But boy A thinks that it is B who is moving and so when he looks at B's clock he thinks that it is ticking slowly. The boy B and A come to rest after 30 mins.(on B's clock)... Now they talk with each other, A and B... A says that since B was moving with high speed( As he thinks), his clock ticked slower and that's why B's clock is at 6:15...and he is looking at B's clock ticking at 6:15. B says that "no"...U moved with high speed, my clock is at 7:00, urs is at 6:30...B claims that since A was moving his clock slowed down...and he is looking at A's clock and in it is 7:00 pm...


Mr. C comes, he observes both watches...what is this? what will he see? Why is it that A , and B, aftter B's flight; are looking at the same watches and observing different times?
 
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  • #2
You're only complicating things by having a third observer C who remains stationary with respect to B during the entire scenario. In Special Relativity, we select any single inertial (non-accelerating) frame of reference from which to describe, analyze and calculate what happens. The easiest frame of reference to do this with your scenario is the one in which all three boys start and end at rest. During the time that A is flying around at high speed, his clock will run slower than time as defined by the frame of reference. The clocks for B and C will also run at the normal time defined by the frame of reference. At the end when A stops near B and C, everyone will observe and agree that A's clock has accumulated less time the clocks for B and C (which read the same time). This is really a very simple problem. Why do you think it is any more complicated than what I have described?
 
  • #3
Here is the complication. How do u tell that it was "A" who moved with the speed i mentioned. What if "A" claims that it was the surrounding (containing the "B" and "C") that moved. Doesn't "A" have the right to say that? Isnt Motion relative?...If "A" does have the right to say that, then he also has the right to say, that it is actually the time of the surrounding which dilated, and hence, "A" has the authority to claim that the clocks of "B" & "C" have accumulated less time, and so what he sees is if his clock is at 6:30, their clocks would be at 6:15... Whose clock is showing more time??...isnt "A" 's argument correct?
 
  • #4
In order that there be any problem, A and B must be stationary, and at the same place, with respect to each other at both beginning and ending but in relative motion in between. That is only possible if at least one accelerated and was not in inertial motion. According to you, that was A. That breaks the symmetry.
 

FAQ: Relativistic Problem: Mr. C's Observation

What is the concept of "relativity" in physics?

The concept of relativity in physics refers to the theory of special relativity, which was developed by Albert Einstein in the early 20th century. It states that the laws of physics are the same for all observers in uniform motion, regardless of their relative velocities. This means that there is no absolute frame of reference and that time, space, and mass are all relative to the observer's perspective.

Who is Mr. C and what is his observation?

Mr. C is a fictional character used in a thought experiment to illustrate the principles of special relativity. In this scenario, Mr. C is standing on a train platform and observes two events: a lightning strike hitting the front and back of a moving train. His observation is that the two lightning strikes occurred at the same time, but this observation is different from that of an observer on the train, who would see the front lightning strike first and the back one later.

How does time dilation affect Mr. C's observation?

Time dilation is a consequence of special relativity, where time appears to pass slower for objects moving at high speeds. In Mr. C's observation, the time between the two lightning strikes would appear to be the same for him, but it would seem longer for the observer on the train due to their relative velocity. This is because time is relative to the observer's frame of reference.

What is the significance of Mr. C's observation in the theory of relativity?

Mr. C's observation highlights the fundamental principles of special relativity, including the relativity of time, space, and mass. It shows that these concepts are not absolute but are relative to the observer's frame of reference. This thought experiment has been used to help understand and explain the consequences of special relativity in various real-world scenarios.

Can Mr. C's observation be applied to other scenarios?

Yes, the principles illustrated in Mr. C's observation can be applied to many other scenarios, such as the famous "twin paradox" or the behavior of particles in particle accelerators. The concept of relativity has also been applied to other fields, such as economics and psychology, to understand the relativity of values and perceptions.

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