teodorakis said:
dear JesseM thank you for your replies, both in this thread and in other threads
now i understand the length contraction in the direction of motion and i understand the constantnes of vertical length but one thing bothers me... Dilation in horizontal clocks, how do we observe the light in same speed in horizontal clocks, i know the formula is so simple length contracts and for light to be in speed c the time must dilate according to the formula x=ct but i can't seem to visulaize that both lights' speed is constant and time dilates.:)
Well, suppose the distance between the mirrors in the clock's rest frame is L, so in the clock's rest frame the time for it to make a two-way trip is 2L/c. Then in the frame where it's moving at speed v, the distance between the mirrors is reduced to L/gamma, where gamma=1/squareroot(1 - v^2/c^2). So suppose the light leaves the back mirror when the back mirror is at position x=0 at t=0 in the observer's frame, meaning in this frame the front mirror is at positon x=L/gamma at t=0. Then the light has position as a function of time given by x(t) = c*t, while the front mirror has position as a function of time given by x(t) = v*t + L/gamma. So to find when the light catches up with the front mirror in this frame, set these two equations equal, so c*t = v*t + L/gamma, which can be rearranged as t=L/(gamma*(c-v)). Plugging this back into x(t)=c*t, the light must catch up with the front mirror at position x=cL/(gamma*(c-v)). So now when the light is reflected back from the front mirror, its new position as a function of time must be x(t)=-c*(t - L/(gamma*(c-v))) + cL/(gamma*(c-v))...you can see that if you plug in t=L/(gamma*(c-v)) into this equation, then the light will be at position x=cL/(gamma*(c-v)) as it should be, and that the light is moving at speed c in the -x direction. Meanwhile, the back mirror started at position x=0 at t=0 and is moving in the +x direction at speed v, so its position as a function of time is just x(t) = v*t. So to figure out when the light returns to the back mirror, set both sides equal:
v*t = -c*(t - L/(gamma*(c-v))) + cL/(gamma*(c-v))
t*(c+v) = 2cL/(gamma*(c-v))
t= 2cL/(gamma*(c-v)*(c+v)) = 2cL/(gamma*(c^2 - v^2))
Now, 1/gamma can be written as squareroot(c^2 - v^2)/c, so the above can be rewritten as:
t = 2L*squareroot(c^2 - v^2)/(c^2 - v^2) = 2L/squareroot(c^2 - v^2)
And since gamma = c/squareroot(c^2 - v^2), this means 1/squareroot(c^2 - v^2) = gamma/c, so the above can be rewritten as t = gamma*2L/c. This is the total time in the observer's frame for the light to make a round trip from the back mirror to the front mirror and return to the back mirror. The total round-trip time in the clock's own frame was just 2L/c, so this shows that the round-trip time in the observer's frame has been expanded by a factor of gamma, just as the time dilation equation predicts.
If you're worried about the
one-way times (back-to-front and front-to-back) and how they can be equal in the clock's frame but unequal in the observer's frame, here you have to get into the relativity of simultaneity and how watches traveling along with the front and back mirror which are synchronized in the light clock's own frame would be out-of-sync in the observer's frame--you might want to take a look at the numerical example I gave in [post=1561633]this post[/post].
