grav-universe said:
SR leans more toward direct observation rather than explanation, which is fine, mostly resulting from experiments with aberration and M-M type experiments, but I would like to know more about the how's and why's involved. I have come to some of my own conclusions, but will only ask questions leading toward my particular areas of interest to see what responses the members here will make, which should be very instructive.
Q1) Why is the time dilation between frames for the ticks of a light clock the same as that of mechanical clocks, radioactive decay, vibrations of cesium atoms, etc? How are they
related?
If I am standing next to a light clock that have the mirrors 149896229 meters apart, I will measure 1 sec for a light pulse to make the round trip. It doesn't really matter how I measure the second except that some methods will be less prone to error. (I can use an atomic clock, a stopwatch, a cheap wristwatch or say to myself, "One thousand, one".)
Now consider someone traveling at 0.866c relative to me in a direction perpendicular to the path of my light pulse. He has his own light clock, identical to mine, and he also measures how long it takes for his light pulse to make the round trip. Since we both measure the speed of light to be the same relative to ourselves, he also measures 1 sec per tick of his clock.
He is also watching my clock. From his perspective the my light pulse has to travel a diagonal path to travel between the mirrors. Since my pulse has to travel at the same speed as his, it will take a longer time to make the round trip from mirror to mirror.(twice as long in fact.) Which means I have to say "one thousand, one" twice before his clock completes one tick. He however said it once for the same tick. I have to agree that he said it once for each tick of his clock, otherwise we would have a physical contradiction on our hands.
So the answer is that the reason the light clock, cesium clock, mechanical clock in the same frame all agree is that they are all measuring the same time interval, it is just that a frame moving relative to that frame will measure the interval (by its devices) differently
Q2) Why do rods in an M-M type experiment in a moving frame contract in such a way that the result will be null? In other words, why is it so important to a body that light be transmitted isotropically that it must contract in order to do so? Why not just stay the same?
The fact that light is measured to have a constant speed in all frames, quite frankly just seems to be the way that universe is put together. Every experiment to date has verified this.
We can go back to the light clock again. Only this time, we have a second clock aligned at a right angle to the first. A person stationary to these clock will see pulses emitted from them take the same time to make the round trip.
If we look at this from the perspective of someone traveling along the line joining the light clocks, he must also agree that both of them tick( per round trip) at the same rate. In his case each leg of the round trip for the clock parallel to the relative motion will take different times (relativity of simultaneity). If he adds up the legs of the trip, given that the speed of light is constant for both legs, he determines that this clock must be shorter than the other clock. Like this:
[URL]http://home.earthlink.net/~parvey/sitebuildercontent/sitebuilderpictures/length_con2.gif[/URL]
So we have the different frames measuring the distance between the mirrors differently.
It's kind of like two people facing in different directions. They are each asked how far to the left one point is from the other. Since each defines "left" according the direction they are facing, they will give a different answer. This is more or less how Relativity deals with time and space. The measurements of time and space are frame dependent just the way left and right are dependent on the way you face.
