Galileo's hint may have been a bit too obsscure for you, but it is what you need. The rest of what you need is that the distance between the planets as seen by the captain depends on how fast he is going. Use the Lonrentz factor to find the distance in terms of the velocity and use time = distance/velocity and you can solve for velocity.Tonyt88 said:A rocket flies between two planets that are one light-year apart. What should the rocket's speed be so that the time elapsed on the captain's watch is one year?
I figure I need to use the Lorentz factor:
1/(sqrt(1 - v^2/c^2))
But exactly how would i go about solving it.
AstroGuy said:I have 3 possible helps...
1) No rocket can go at the speed of light, so the question is pointless.
2) Off the top of my head, I would figure that you'd set the rocket speed for c and in one year, the captains watch would read 1 year, when you get to the next planet- his watch would be time dilated too...
3) Check out http://en.wikipedia.org/wiki/Time_dilation
Look under 'Overview"
it could be that you are looking for
The formula for determining time dilation in special relativity is:
Δ t = (gamma)Δ t0
where
Δ t is a time interval measured by an observer in a stationary frame of reference,
Δ t0 is that same time interval as measured by an observer in the moving frame,
and (gamma) is the Lorentz factor, ( your formula of 1/(sqrt(1 - v^2/c^2))
v is the relative speed between the clock and the stationary system, and
c is the speed of light.
If you are looking for the time interval as measured by an observer in the moving frame (the spaceship captain) set Δ t0
to 1 year, but ...hmmm...
gamma times 1=gamma. Damn. You would also need to know the time elapsed for the stationary observer in that case to solve for v.
i say go with option #2.
Hope this helps more than hinders!
Yes, but you don't have to go at the speed of light. The distance between the planets are 1 lightyear apart as seen from the planets frame. It has to take one hour as seen from the ship's frame.dimachka said:if in any referance frame you are moving at the speed of light, then you are moving at the speed of light in all reference frames...
You are mixing quantities measured in different frames! The question never says that it took one year in the planet's frame. The one light year distance is in the planet's frame and the duration of one year for the trip is in the ship's frame.dimachka said:Sure, but if in the planet's reference frame you have moved 1 light year in 1 year, you were going at the speed of light. This necessarily means you would have to go at the speed of light in any frame, if you don't believe me, plug it into your trusty lorentz transformations.
Galileo and OlderDan already suggested the solution. I will simply be a bit more specific. Let's call "t" the time measured in the ship's frame and "d" the distance measured between the two planets in the ship's frame. Then t= one year and "d" is unknown.Tonyt88 said:A rocket flies between two planets that are one light-year apart. What should the rocket's speed be so that the time elapsed on the captain's watch is one year?
I figure I need to use the Lorentz factor:
1/(sqrt(1 - v^2/c^2))
But exactly how would i go about solving it.
dimachka said:I'm sorry, but that is just plain wrong, If you use that logic it is possible to go an arbitrarily long distance in an arbitrarily short amount of time by just going closer to the speed of light. What i said was correct.
It is possible to go an arbitrarily long distance in an arbitrarily short amount of time, if you are talking about distance measured in one reference frame and time in another reference frame. This is the basis of the famous twin problem in Special Relativity. The traveling twin can get to a planet that is 20 light years away as measured by the stationary twin, then turn around and come back, all in one year of the traveling twin's time. He can do this because from his frame of reference the distant planet is only half a light year away, and after he turns around he is only half a light year from earth.dimachka said:I'm sorry, but that is just plain wrong, If you use that logic it is possible to go an arbitrarily long distance in an arbitrarily short amount of time by just going closer to the speed of light. What i said was correct.
Time dilation of a rocket is a phenomenon in which time appears to pass slower for an object moving at high speeds, such as a rocket, compared to a stationary observer. This is due to the effects of special relativity, which states that time and space are not absolute and can be affected by an object's motion and gravitational fields.
Time dilation of a rocket occurs because as the rocket moves at high speeds, it approaches the speed of light. As it approaches this speed, time begins to slow down for the rocket in relation to the stationary observer. This is due to the time and space being relative to the observer's frame of reference.
The formula for calculating time dilation of a rocket is t = t0/√(1-(v2/c2)), where t is the time experienced by the rocket, t0 is the time experienced by the stationary observer, v is the velocity of the rocket, and c is the speed of light.
Time dilation of a rocket can affect aging in two ways. First, for the person on the rocket, time will appear to pass slower compared to someone on Earth. This means that the person on the rocket will age slower than the person on Earth. Second, when the rocket returns to Earth, the person on the rocket will have experienced less time, resulting in them being younger than the person on Earth.
No, time dilation of a rocket can only be observed in extreme cases where objects are moving at extremely high speeds, close to the speed of light. In everyday life, the effects of time dilation are negligible and cannot be observed without specialized equipment. However, GPS satellites have to take into account the effects of time dilation due to their high speeds in order to accurately measure time and location on Earth.