1) Given L = 11m and l = 5.9 x 10-7 m
The limit for lowest resolution: 2 D d = 0.005 fringe
Then:
d = (0.005 fringe)/ 2 = 0.0025 fringe
and since:
D d = Lv2/ (c2)
v = {(D d)( l) c2)/ L}½
v = {(0.0025)( 5.9 x 10-7 m)(3 x 108 ms-1)/11
m}½
2)
We have: x' = 60m, t' = 8 x 10-8 s and y' = y, z' = z
v = 0.6c = 1.8 x 108 m/s
Then:
x = [60m + (1.8 x 108 m/s)( 8 x 10-8 s)]/ (0.64)½
x = [60m + 14.4m]/ 0.8 = 74.4m/0.8 = 93m
and t =
[(8 x 10-8 s)+ (1.8 x 108 ms-1)(60m)/(3 x 108 ms-1)2/0.8
t = 2.5 x 10-7 s/ 0.8 = 2.33 x 10-7 s
The space time coordinates are: (93 m, 2.33 x 10-7 s)
3) The problem requires zero relative motion, i.e. defined specifically in the
x-direction so the equations:
t = t' + x'v/c2/(1 - v2/c2)½
and
t' = t - xv/c2/(1 - v2/c2)½
are immediately simplified by the terms in x becoming zero, so:
t = t'/(1 - v2/c2)½
and
t' = t /(1 - v2/c2)½
Here: t = time passage on Earth clock
and t' = time passage on astronaut's clock
For t = 1 Earth year = 365 ¼ days:
t' = (365 ¼ days)/ [1 - (0.9c)2/c2]½
=
(365 ¼ days)/(1 - 0.81)½
t' = (365 ¼ days)/0.436 = 837.7 days
This is the time elapsed on the astronaut's clock when the Earth has made one revolution equal to 365 ¼ days. In other words, each of his days is roughly equal to 2.29 Earth days. Hence, his clock is obviously running slower than the Earth clock.
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