Relativity radio signal Question

In summary, the spaceship leaves Earth at 12 noon, and at that time, the spaceship's clock is set to be synchronised with Earth time. A radio signal is sent from Earth at 2pm, and a shuttle is launched from Earth at 4pm and travels directly towards the spaceship at a constant speed of 0.6c.
  • #1
Lissajoux
82
0

Homework Statement



A spaceship leaves Earth at 12 noon. At that time the spaceship clock is set to be synchronised with Earth time. It travels through space in a straight line at a constant speed 0⋅60 c.

A radio signal is sent to the spaceship from Earth at 2pm.

A shuttle is launched from the Earth at 4pm and travels directly towards the spaceship at a constant speed of 0⋅80 c.

a) In the Earth frame of reference, relative to the spaceship what are:

i. the speeds of the radio message and of the shuttle.
ii. the corresponding times in Earth frame for the arrival at the spaceship of the radio message and of the shuttle.

b) In the spaceship frame of reference:

i. at what times did the signal and the shuttle leave the Earth?
ii. what are the speeds of the signal and of the shuttle?
iii. what are the times for the radio message and for the shuttle to arrive at the spaceship?

Homework Equations



Within the problem statement and solution attempt.

The Attempt at a Solution



In this question can ignore the acceleration periods and all gravitational effects.

Really not sure how to go about this, but this is what I have so far:

a) [itex]v=0.6c=1.8\times 10^{8}ms^{-1} , u_{x}=c=3\times 10^{8}ms^{-1}[/itex]

i. use equation:

[tex]V=\frac{u_{x}v}{1+\frac{u_{x}v}{c^{2}}}[/tex]

therefore:

[tex]V_{signal}=3\times 10^{8}ms^{-1}[/tex] and [tex]V_{shuttle}=2.838\times 10^{8}ms^{-1}[/tex]

ii. Not sure how to do this, i.e. what equations to use. Assume I need to use the results from part i. somehow.

b) At the moment I'm unsure how to adapt the calculations to take into account the dilations resulting from being in the spaceship's frame of reference. Some advice here would be great to get me going with this part.
 
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  • #2
The weird relativity effects you've learned about only come into play when you go from one reference frame to another. In part (a), however, you're only talking about one reference frame, that of the Earth. In that frame, you observe that the spaceship, the signal, and the shuttle move at certain speeds. To find the relative velocities, you just subject the relevant velocities from each other, and to see when two of them meet, you do the same calculation you would have done with Newtonian physics.

In contrast, in part (b), now the observer is in a new frame of reference, so you need to "translate" the quantities of the original frame to this new one, by applying the velocity-addition formula, the Lorentz transformations, etc.
 
  • #3
Yes so I gathered that the first part of the question where everything is considered in the Earth's reference frame is pretty simple, as don't need to consider any relativistic effects.

So I have that for a)i) the speeds to the signal and shuttle are just [itex]c[/itex] and [itex]0.8c[/itex] as given in the question brief.

For part a)ii) using simultaneous equations type method I have that the signal will reach the ship after 3 seconds, and the shuttle will reach the ship after 6 seconds.

All correct so far?

Then getting onto part b) of the question, which is rather more tricky as need to consider relativity effects due to being in the spaceship's reference frame.

Knowing that the spaceship is traveling at 0.6c can find the value of the Lorentz factor:

[tex]\gamma=\frac{1}{\sqrt{1-\left(\frac{v}{c}\right)^{2}}}=\frac{1}{\sqrt{1-\left(0.6\right)^{2}}}=\frac{1}{\sqrt{0.64}}=1.25[/tex]

So I need to use this value to account for the relativistic effects experienced by the spaceship. I've just considered that the ship is moving at 0.6c, do I need to consider that the signal and the shuttle are moving at c and 0.8c aswell? I assume they'll each have their own reference frame too, so just need to consider [itex]\gamma[/tex] due to [itex]v_{spaceship}[/itex]?

Know that 'moving clocks run slower'.

So for b)iii) for the signal arrival time:

[tex]t=\frac{t_{E}}{\gamma}=\frac{3}{1.25}=2.4s[/tex]

And for the shuttle arrival time:

[tex]t=\frac{t_{E}}{\gamma}=\frac{6}{1.25}=4.8s[/tex]

Correct? I'm sure the calculations are, not sure if these are indeed for the arrival times or for the times they left Earth at obviously those times earlier than they were received, but they won't be due to contraction, arhh confusing. I think this is for part b)iii) but not sure how to figure out part b)i).

For b)ii) if the time for the signal to reach the ship in Earth reference frame is 3s, then the distance of the ship away is calculated as [itex]d=s\times t=c\times 3=9\times 10^{8}m[/tex]. But there's length contraction in the spaceship's reference frame, so that the distance is perceived by them as:

[tex]d=\frac{9\times 10^{8}}{1.25}=7.2\times 10^{8}m[/tex]

So the perceived speed:

[tex]s=\frac{d}{t}=\frac{7.2\times 10^{8}}{2.4}=3\times 10^{8}m/s[/tex]

Then need to do the same for the shuttle:

If the time for the shuttle to reach the ship in Earth reference frame is 6s, then the distance of the ship away is calculated as [itex]d=s\times t=0.8c\times 6=1.44\times 10^{9}m[/tex]. But there's length contraction in the spaceship's reference frame, so that the distance is perceived by them as:

[tex]d=\frac{1.44\times 10^{9}}{1.25}=1.15\times 10^{9}m[/tex]

So the perceived speed:

[tex]s=\frac{d}{t}=\frac{1.15\times 10^{9}}{6}=1.92\times 10^{8}m/s[/tex]

Correct?

Then for part b)i) to calculate the time the signal and shuttle were sent:

Surely this is just 2.4 and 4.8 seconds, as calculated earlier.

--

Hopefully that all makes sense, sorry it's a bit all over the place.

I think I'm nearly there, though the method is a bit mixed up. Sure should be able to calculate everything I need in order, i.e. part i) then part ii) then part iii).

Hopefully too I'm getting somewhere with all this now and not too far off some right answers! :smile:
 
  • #4
Lissajoux said:
Yes so I gathered that the first part of the question where everything is considered in the Earth's reference frame is pretty simple, as don't need to consider any relativistic effects.

So I have that for a)i) the speeds to the signal and shuttle are just [itex]c[/itex] and [itex]0.8c[/itex] as given in the question brief.

For part a)ii) using simultaneous equations type method I have that the signal will reach the ship after 3 seconds, and the shuttle will reach the ship after 6 seconds.

All correct so far?
Hours, not seconds. :smile: I got a different answer for when the shuttle catches up to ship.
Then getting onto part b) of the question, which is rather more tricky as need to consider relativity effects due to being in the spaceship's reference frame.

Knowing that the spaceship is traveling at 0.6c can find the value of the Lorentz factor:

[tex]\gamma=\frac{1}{\sqrt{1-\left(\frac{v}{c}\right)^{2}}}=\frac{1}{\sqrt{1-\left(0.6\right)^{2}}}=\frac{1}{\sqrt{0.64}}=1.25[/tex]

So I need to use this value to account for the relativistic effects experienced by the spaceship. I've just considered that the ship is moving at 0.6c, do I need to consider that the signal and the shuttle are moving at c and 0.8c aswell? I assume they'll each have their own reference frame too, so just need to consider [itex]\gamma[/tex] due to [itex]v_{spaceship}[/itex]?
Yes. Since you're only looking at what happens from the spaceship's point of view, that's the only gamma you have to worry about.
Know that 'moving clocks run slower'.

So for b)iii) for the signal arrival time:

[tex]t=\frac{t_{E}}{\gamma}=\frac{3}{1.25}=2.4s[/tex]

And for the shuttle arrival time:

[tex]t=\frac{t_{E}}{\gamma}=\frac{6}{1.25}=4.8s[/tex]

Correct? I'm sure the calculations are, not sure if these are indeed for the arrival times or for the times they left Earth at obviously those times earlier than they were received, but they won't be due to contraction, arhh confusing. I think this is for part b)iii) but not sure how to figure out part b)i).
These aren't correct. From the equations for a Lorentz transformation, Δt'=γ(Δt-βΔx), you can see time dilation only applies when Δx=0, but the emission and reception of the radio signal occurs at different points in space (in both frames).

Try drawing a spacetime diagram for this problem. You have enough info from part (a) to write down the spacetime coordinates in the Earth frame for the various events. You can then calculate the coordinates in the ship's frame. From those, you can figure out the answers for part (b).
For b)ii) if the time for the signal to reach the ship in Earth reference frame is 3s, then the distance of the ship away is calculated as [itex]d=s\times t=c\times 3=9\times 10^{8}m[/tex]. But there's length contraction in the spaceship's reference frame, so that the distance is perceived by them as:

[tex]d=\frac{9\times 10^{8}}{1.25}=7.2\times 10^{8}m[/tex]

So the perceived speed:

[tex]s=\frac{d}{t}=\frac{7.2\times 10^{8}}{2.4}=3\times 10^{8}m/s[/tex]

Then need to do the same for the shuttle:

If the time for the shuttle to reach the ship in Earth reference frame is 6s, then the distance of the ship away is calculated as [itex]d=s\times t=0.8c\times 6=1.44\times 10^{9}m[/tex]. But there's length contraction in the spaceship's reference frame, so that the distance is perceived by them as:

[tex]d=\frac{1.44\times 10^{9}}{1.25}=1.15\times 10^{9}m[/tex]

So the perceived speed:

[tex]s=\frac{d}{t}=\frac{1.15\times 10^{9}}{6}=1.92\times 10^{8}m/s[/tex]

Correct?

Then for part b)i) to calculate the time the signal and shuttle were sent:

Surely this is just 2.4 and 4.8 seconds, as calculated earlier.

--

Hopefully that all makes sense, sorry it's a bit all over the place.

I think I'm nearly there, though the method is a bit mixed up. Sure should be able to calculate everything I need in order, i.e. part i) then part ii) then part iii).

Hopefully too I'm getting somewhere with all this now and not too far off some right answers! :smile:
 
  • #5
vela said:
Hours, not seconds. :smile: I got a different answer for when the shuttle catches up to ship.

This is how I figured out when they would all meet.. I plotted a quick table of how far each travels in each hour, and compared the results. I hope I can indeed do it this rather simple way, and this makes sense:

Ship | Signal | Shuttle
-------------------------
1.8 | 3.0 | 2.4
3.6 | 6.0 | 4.8
5.4 | 9.0 | 7.2
7.2 | 12.0 | 9.6
9.0 | 15.0 | 12.0
10.8 | 18.0 | 14.4
12.6 | 21.0 | 16.8

So the signal reaches the ship after 3 hours and.. the shuttle reaches the ship after 3 hours. Oh, that doesn't make sense. Hmm, sure this method seemed to work earlier. Now I'm confused.

vela said:
These aren't correct. From the equations for a Lorentz transformation, Δt'=γ(Δt-βΔx), you can see time dilation only applies when Δx=0, but the emission and reception of the radio signal occurs at different points in space (in both frames).

Could you expain this a bit more?

So, in the spaceship's frame of reference, the signal is perceived to leave Earth at 2pm and the shuttle at 4pm?, since the spaceship clock and the Earth clock are synchronised to the same time.

Perhaps I've just completely messed that up. I'm really not sure on this bit of the question.
 
  • #6
Lissajoux said:
This is how I figured out when they would all meet.. I plotted a quick table of how far each travels in each hour, and compared the results. I hope I can indeed do it this rather simple way, and this makes sense:

Ship | Signal | Shuttle
-------------------------
1.8 | 3.0 | 2.4
3.6 | 6.0 | 4.8
5.4 | 9.0 | 7.2
7.2 | 12.0 | 9.6
9.0 | 15.0 | 12.0
10.8 | 18.0 | 14.4
12.6 | 21.0 | 16.8

So the signal reaches the ship after 3 hours and.. the shuttle reaches the ship after 3 hours. Oh, that doesn't make sense. Hmm, sure this method seemed to work earlier. Now I'm confused.
You're not accounting for the fact that the ship has a two-hour head start on the signal and a four-hour head start on the shuttle.

Let t be the time the ship has been traveling. The ship's position is then given by xship(t)=0.6ct. You can also write down a function that gives the position of the signal as a function of t (for t>2): xsignal=c(t-2). Set the two equal to each other and solve for t. You can similarly solve for when the shuttle reaches the ship.
Could you expain this a bit more?
Time dilation let's you compare your clock to a moving clock. What it doesn't let you do is compare the difference between two clocks at different points in space in your frame to the difference between the two clocks in the moving frame. For instance, consider two events that are simultaneous in the rest frame, so Δt=0. In a moving frame, they won't be simultaneous, so Δt'≠0. It's clear that the time dilation formula, ∆t'≠γ∆t, doesn't apply.

Because relativity mixes space and time, the time difference between two events a moving observer sees depends on the spatial separation of the events. The time dilation formula tells you what happens in the special case where Δx=0.
So, in the spaceship's frame of reference, the signal is perceived to leave Earth at 2pm and the shuttle at 4pm?, since the spaceship clock and the Earth clock are synchronised to the same time.

Perhaps I've just completely messed that up. I'm really not sure on this bit of the question.
An observer on the ship would say the signal left Earth when a clock on Earth read 2:00 PM, as would an observer on Earth. His own clock would read 2:30 PM. From his perspective, the Earth's clock was moving, so it ran more slowly.
 
  • #7
So define these: [itex]x_{ship}=0.6t[/itex] and [itex]x_{signal}=c(t-2)[/itex]

Hence: [itex]0.6ct=c(t-2)[/itex]

Now solve for [itex]t[/itex]

.. except I'm having a daft moment, and I'm not sure if I've done this right! :blushing: ..

[tex]0.6ct=ct-2c\implies 2c=0.4ct\implies t=\frac{2}{0.4}=5[/tex] hours

So the signal reaches the ship after [itex]t=5[/itex] hours

That all correct? :smile:

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Then do almost exactly the same for the shuttle and the ship:

So define these: [itex]x_{ship}=0.6t[/itex] and [itex]x_{shuttle}=c(t-4)[/itex]

Hence: [itex]0.6ct=c(t-4)[/itex]

Now solve for [itex]t[/itex]

[tex]0.6ct=ct-4c\implies 4c=0.4ct\implies t=\frac{4}{0.4}=10[/tex] hours

So the shuttle reaches the ship after [itex]t=10[/itex] hours

That all correct too? :smile:

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Now the times are known for the signal and shuttle both sent from Earth to reach the ship.

So that's part 3 of the question, calculated first, hmm.

I'm not sure how much of the previous post is correct/incorrect, you quoted it in your reply post without any comments :frown:
 
  • #8
Lissajoux said:
So define these: [itex]x_{ship}=0.6t[/itex] and [itex]x_{signal}=c(t-2)[/itex]

Hence: [itex]0.6ct=c(t-2)[/itex]

Now solve for [itex]t[/itex]

.. except I'm having a daft moment, and I'm not sure if I've done this right! :blushing: ..

[tex]0.6ct=ct-2c\implies 2c=0.4ct\implies t=\frac{2}{0.4}=5[/tex] hours

So the signal reaches the ship after [itex]t=5[/itex] hours

That all correct? :smile:
Yes. To clarify, t represents the time the ship has been traveling. The signal only takes 3 hours to go from Earth to the ship. It reaches the ship at t=5 h because it leaves Earth two hours after the ship left.
Then do almost exactly the same for the shuttle and the ship:

So define these: [itex]x_{ship}=0.6t[/itex] and [itex]x_{shuttle}=c(t-4)[/itex]

Hence: [itex]0.6ct=c(t-4)[/itex]

Now solve for [itex]t[/itex]

[tex]0.6ct=ct-4c\implies 4c=0.4ct\implies t=\frac{4}{0.4}=10[/tex] hours

So the shuttle reaches the ship after [itex]t=10[/itex] hours

That all correct too? :smile:
No, because the shuttle does not travel at the speed of light.
Now the times are known for the signal and shuttle both sent from Earth to reach the ship.

So that's part 3 of the question, calculated first, hmm.

I'm not sure how much of the previous post is correct/incorrect, you quoted it in your reply post without any comments :frown:
The rest of your post relied on a misapplication of time dilation, so it's all wrong.
 
  • #9
No, because the shuttle does not travel at the speed of light.

OK, well I'm not sure, but how about this...

So define these: [itex]x_{ship}=0.6t[/itex] and [itex]x_{shuttle}=0.8c(t-4)[/itex]

Hence: [itex]: 0.6ct=0.8c(t-4)[/itex]

Now solve for [itex]t[/itex]:

[tex]0.6ct=0.8ct-3.2c\implies 3.2c=0.2ct\\implies t=\frac{3.2}{0.2}=16 hours[/tex]

So the shuttle reaches the ship after [itex]: t=16 hours [/itex]

I'm sure that's not correct, but I don't know where I'm going wrong :frown:

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Now as the value of signal arrival time correctly calculated as [itex]t=5 years[/itex]

The speed of the signal is known to be [itex]v_{signal}=c=3\times 10^{8}ms^{-1}[/itex]

Which equates to: [itex]v_{signal}=c=3\times 10^{8}ms^{-1}[/itex]

Can calculate the distance of the Earth away from the ship as:

[tex]d=(v_{signal})(t)=(9.46\times 10^{15}m years^{-1})(5 years)=4.73\times 10^{16}m=5 light years[/tex]

.. getting anywhere? :shy:

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Then need to do the same for the shuttle, once I know it's correct time or arrival with ship.
 
  • #10
Lissajoux said:
OK, well I'm not sure, but how about this...

So define these: [itex]x_{ship}=0.6t[/itex] and [itex]x_{shuttle}=0.8c(t-4)[/itex]

Hence: [itex]: 0.6ct=0.8c(t-4)[/itex]

Now solve for [itex]t[/itex]:

[tex]0.6ct=0.8ct-3.2c\implies 3.2c=0.2ct\\implies t=\frac{3.2}{0.2}=16 hours[/tex]

So the shuttle reaches the ship after [itex]: t=16 hours [/itex]

I'm sure that's not correct, but I don't know where I'm going wrong :frown:
I'm not sure what you're finding confusing about this. You're just using distance=speed x time.

Your sentence "So the shuttle reaches the ship after t=16 hours" is a bit ambiguous. It can be interpreted two ways, and the more common interpretation is wrong. It sounds like you're saying the shuttle catches up to the ship after traveling for 16 hours. That's wrong. The ship has traveled for t=16 hours, but the shuttle has traveled for only t-4=16-4=12 hours.
Now as the value of signal arrival time correctly calculated as [itex]t=5 years[/itex]

The speed of the signal is known to be [itex]v_{signal}=c=3\times 10^{8}ms^{-1}[/itex]

Which equates to: [itex]v_{signal}=c=3\times 10^{8}ms^{-1}[/itex]

Can calculate the distance of the Earth away from the ship as:

[tex]d=(v_{signal})(t)=(9.46\times 10^{15}m years^{-1})(5 years)=4.73\times 10^{16}m=5 light years[/tex]

.. getting anywhere? :shy:

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Then need to do the same for the shuttle, once I know it's correct time or arrival with ship.
Where did you get years from? Even if you used hours instead of years, your answer is wrong for the reason I explained above regarding the interpretation of your sentence. I also explained in my previous post that while the ship has traveled for 5 hours, the signal has only traveled for 3 hours because it left the Earth 2 hours after the ship did.

So how far is the ship when the signal catches up? You can calculate it two ways. If you look at the signal, it will have propagated for three hours; in this time, it travels 3 light-hours away from Earth. If you look at the ship, it will have been traveling for five hours. Since it's moving with a speed of 0.6c, it will be at a distance of (5 hours)x(0.6 c) = 3 light-hours away from Earth. Just as you'd expect, the signal and the ship are at the same distance from Earth, which has to be the case when they meet.
 
  • #11
I'll have another go at this.

So according to someone in the Earth's reference frame the shuttle has traveled for [itex]t=16hours[/itex] but according to someone on the shuttle or someone on the ship, both in the ship's reference frame, the shuttle has only traveled for [itex]T=t-4=16-4=12 hours[/itex]?

The similar case for the signal, but person in Earth ref frame records [itex]t=5hours[/tex] but person in the ship ref frame records [itex]T=t-2=5-2=3 hours[/itex]?

Then I'm still not sure about this, something like this:

Signal travels for 3 hours before it reaches the ship, which equates to a travel distance of [itex]d=3\times0.6c=1.8 light hours[/itex]. That's how far away the Earth is from the ship when the signal arrives.

Probably slightly different. Basically wasn't sure whether to use 3 or 5, and whether to use 0.6c or 0.8c, as the values in the equation.

Would need to do the same thing for the signal, and maybe should get the same distance, even though the ship will have traveled further in the time between the two arrivals this should be accounted for in the calculations I assume.

Hopefully this is getting there. I do appreciate the help. :smile:
 
  • #12
Lissajoux said:
I'll have another go at this.

So according to someone in the Earth's reference frame the shuttle has traveled for [itex]t=16hours[/itex] but according to someone on the shuttle or someone on the ship, both in the ship's reference frame, the shuttle has only traveled for [itex]T=t-4=16-4=12 hours[/itex]?
No.
The similar case for the signal, but person in Earth ref frame records [itex]t=5hours[/tex] but person in the ship ref frame records [itex]T=t-2=5-2=3 hours[/itex]?
No.
Then I'm still not sure about this, something like this:

Signal travels for 3 hours before it reaches the ship, which equates to a travel distance of [itex]d=3\times0.6c=1.8 light hours[/itex]. That's how far away the Earth is from the ship when the signal arrives.
No.
Probably slightly different. Basically wasn't sure whether to use 3 or 5, and whether to use 0.6c or 0.8c, as the values in the equation.

Would need to do the same thing for the signal, and maybe should get the same distance, even though the ship will have traveled further in the time between the two arrivals this should be accounted for in the calculations I assume.

Hopefully this is getting there. I do appreciate the help. :smile:
You obviously have no understanding of what the expressions for xship and xsignal represent or even what the variable t stands for. I'll admit I'm frustrated. I've already explained it a couple of times, and you seem to completely ignore what I've written. You need to spend some time thinking about it and figuring it out for yourself.
 
  • #13
I've gone back to the start and read through everything again. Hopefully I've been able to get this back on track now.

Part A - Earth reference frame:

Speed of signal and shuttle:

[itex]v_{signal}=c[/itex] and [itex]v_{shuttle}=0.8c[/itex]

There's no relativistic effects to worry about here, we're in the Earth's reference frame. So the values are just those given in the question. Simple.

Finding when signal and shuttle reach the ship:

Still considering everything in Earth reference frame.

Define [itex]t[/itex] as the time the ship has been travelling.

Ship position given by: [itex]x_{ship}(t)=0.6ct[/itex] since the ship leaves the Earth at time [itex]t[/itex] at speed [itex]0.6c[/itex].

Signal position given by: [itex]x_{signal}(t)=c(t-2)[/itex] since the signal leaves the Earth 2 hours after the ship, hence [itex]t-2[/itex], and travels at speed [itex]c[/itex].

Set these expressions equal to find [itex]t[/itex] which gives when they meet. So:

[tex]0.6ct=c(t-2)\implies 0.4ct=2c\implies t=\frac{2}{0.4}=5 hours[/tex]

So the signal reaches the ship after the ship has traveled 5 hours. But the signal left 2 hours later from Earth, so it has only traveled for 3 hours.

So according to the ship, the signal takes 3 hours to reach the ship from Earth.

The do the same for the shuttle:

Ship position given by: [itex]x_{ship}(t)=0.6ct[/itex] since the ship leaves the Earth at time [itex]t[/itex] at speed [itex]0.6c[/itex]. This is the same as the previous case.

Signal position given by: [itex]x_{signal}(t)=0.8c(t-4)[/itex] since the signal leaves the Earth 4 hours after the ship, hence [itex]t-4[/itex], and travels at speed [itex]0.8c[/itex].

Set these expressions equal to find [itex]t[/itex] which gives when they meet. So:

[tex]0.6ct=0.8c(t-4)\implies 0.2ct=3.2c\implies t=\frac{3.2}{0.2}=16 hours[/tex]

So the shuttle reaches the ship after the ship has traveled 16 hours. But the shuttle left 4 hours later from Earth, so it has only traveled for 12 hours.

So according to the ship, the shuttle takes 12 hours to reach the ship from Earth.

I don't see what's wrong with any of that. Already established the method was correct for calculating ship-signal interaction time. Just need to account for that shuttle moving at [itex]0.8c[/itex] not [itex]c[/itex] within the [itex]d=s\times t[/itex] equation for the shuttle, and have done this. Also accounted for the departure time difference. I hope that's now all good.

By the way this is the section in lecture notes I have:

http://img38.imageshack.us/i/rela1.jpg" [Broken]

So that's part A done, onto part B..

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Part B - Ship reference frame:

Now need to account for the relativistic effects, due to the speed of the shuttle.

The Lorentz factor:

[tex]\gamma=\frac{1}{\sqrt{1-\left(\frac{v}{c}\right)^{2}}}=\frac{1}{\sqrt{1-\left(0.6\right)^{2}}}=\frac{1}{\sqrt{0.64}}=1.25[/tex]

Finding when signal and shuttle left the Earth:

According to Earth reference frame, the signal took [itex]t_{signal}[E]=3 hours[/tex] to reach the ship. So using that and the value of [itex]\gamma[/itex]:

[tex]t_{signal}=\frac{t_{signal}[E]}{\gamma}=\frac{3}{1.25}=2.4hours[/tex]

So the ship thinks the signal takes 2.4 hours to reach the ship.

According to Earth reference frame, the shuttle took [itex]t_{shuttle}[E]=12 hours[/tex] to reach the ship. So using that and the value of [itex]\gamma[/itex]:

[tex]t_{signal}=\frac{t_{shuttle}[E]}{\gamma}=\frac{12}{1.25}=9.6hours[/tex]

So the ship thinks the shuttle takes 9.6 hours to reach the ship.

So these are the times the ship thinks the signal and shuttle have been travelling, so they left the Earth the respective times earlier.

Finding speeds of the signal and the shuttle:

Person on Earth perceived the signal to be traveling at [itex]v_{signal}=c[/itex] and arrived at the shuttle in [itex]t_{signal}[E]=3 hours[/itex]. Person on the ship perceived the signal to arrive after [itex]t_{signal}=2.4 hours[/itex].

So through a simple calculation:

[tex]d=s\times t=c\times 3=3.24times 10^{12}m[/tex]

So that's the distance a person on Earth perceives the ship to be away from Earth. However for the person on the ship, there is length contraction to account for:

[tex]d=\frac{d[E]}{\gamma}=\frac{3.24 \times 10^{12}m}{1.25}=2.59\times 10^{12}m[/tex]

So the distance of Earth<->Ship appears to be less for the person on the ship.

The ship perceives the signal to take 2.4hours to reach it.

So again, simple calculation to get the velocity of the signal:

[tex]v_{signal}=\frac{2.59\times 10^{12}m}{2.4hours}=2.9977..\times 10^{8}m/s=0.9992c[/tex]

Then do the same but for the shuttle, I havn't detailed that right now incase there was any issues with this method.

Finding the arrival times of the signal and shuttle at the ship:

The signal took [itex]t_{signal}=2.4 hours[/itex] and the shuttle took [itex]t_{shuttle}=12 hours[/itex], these were calculated in part i.

Again, by the way, this is the section in my lecture notes:

http://img98.imageshack.us/i/rela2.jpg" [Broken]

- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -

Sorry for frustrating you.. I really am trying to get all this :smile:
 
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  • #14
Lissajoux said:
Part B - Ship reference frame:

Now need to account for the relativistic effects, due to the speed of the shuttle.

The Lorentz factor:

[tex]\gamma=\frac{1}{\sqrt{1-\left(\frac{v}{c}\right)^{2}}}=\frac{1}{\sqrt{1-\left(0.6\right)^{2}}}=\frac{1}{\sqrt{0.64}}=1.25[/tex]

Finding when signal and shuttle left the Earth:

According to Earth reference frame, the signal took [itex]t_{signal}[E]=3 hours[/tex] to reach the ship. So using that and the value of [itex]\gamma[/itex]:

[tex]t_{signal}=\frac{t_{signal}[E]}{\gamma}=\frac{3}{1.25}=2.4hours[/tex]

So the ship thinks the signal takes 2.4 hours to reach the ship.

According to Earth reference frame, the shuttle took [itex]t_{shuttle}[E]=12 hours[/tex] to reach the ship. So using that and the value of [itex]\gamma[/itex]:

[tex]t_{signal}=\frac{t_{shuttle}[E]}{\gamma}=\frac{12}{1.25}=9.6hours[/tex]

So the ship thinks the shuttle takes 9.6 hours to reach the ship.

So these are the times the ship thinks the signal and shuttle have been travelling, so they left the Earth the respective times earlier.

Finding speeds of the signal and the shuttle:

Person on Earth perceived the signal to be traveling at [itex]v_{signal}=c[/itex] and arrived at the shuttle in [itex]t_{signal}[E]=3 hours[/itex]. Person on the ship perceived the signal to arrive after [itex]t_{signal}=2.4 hours[/itex].

So through a simple calculation:

[tex]d=s\times t=c\times 3=3.24times 10^{12}m[/tex]

So that's the distance a person on Earth perceives the ship to be away from Earth. However for the person on the ship, there is length contraction to account for:

[tex]d=\frac{d[E]}{\gamma}=\frac{3.24 \times 10^{12}m}{1.25}=2.59\times 10^{12}m[/tex]

So the distance of Earth<->Ship appears to be less for the person on the ship.

The ship perceives the signal to take 2.4hours to reach it.

So again, simple calculation to get the velocity of the signal:

[tex]v_{signal}=\frac{2.59\times 10^{12}m}{2.4hours}=2.9977..\times 10^{8}m/s=0.9992c[/tex]

Then do the same but for the shuttle, I havn't detailed that right now incase there was any issues with this method.

Finding the arrival times of the signal and shuttle at the ship:

The signal took [itex]t_{signal}=2.4 hours[/itex] and the shuttle took [itex]t_{shuttle}=12 hours[/itex], these were calculated in part i.

Again, by the way, this is the section in my lecture notes:

http://img98.imageshack.us/i/rela2.jpg" [Broken]

- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -

Sorry for frustrating you.. I really am trying to get all this :smile:

You're just repeating the calculations you did earlier, which I pointed out earlier were wrong.
 
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  • #15
Unfortunately I cannot see where I am going wrong. Looking at those lecture notes, this appears to be exactly what I should be doing. Perhaps you could help with where I am going wrong. The advice really is appreciated, I don't mean for it to sound like I'm having a go if it comes across that way. I just want to know what is wrong or right and how to get things sorted out, because at the moment I don't see what to change.
 
  • #16
I already told you where you're going wrong, way back in post 4, and again in posts 6 and 8.
 
  • #17
I've gone back to your previous posts and this is what youv'e said:

These aren't correct. From the equations for a Lorentz transformation, Δt'=γ(Δt-βΔx), you can see time dilation only applies when Δx=0, but the emission and reception of the radio signal occurs at different points in space (in both frames).

Time dilation let's you compare your clock to a moving clock. What it doesn't let you do is compare the difference between two clocks at different points in space in your frame to the difference between the two clocks in the moving frame. For instance, consider two events that are simultaneous in the rest frame, so Δt=0. In a moving frame, they won't be simultaneous, so Δt'≠0. It's clear that the time dilation formula, ∆t'≠γ∆t, doesn't apply.

Because relativity mixes space and time, the time difference between two events a moving observer sees depends on the spatial separation of the events. The time dilation formula tells you what happens in the special case where Δx=0.

I think this is the point I went wrong from then.

So you're saying that the time dilation formula I used previously:

[tex]t=\frac{t_{E}}{\gamma}=\frac{6}{1.25}=4.8s[/tex]

(that's just for an example of a previous calculation)

Or rather more generally:

[tex]t'=\gamma t[/tex]

This cannot be applied to this problem?

I'll assume that's the case. Right considering what's going on again..

So the two clocks, the one of Earth and the one on the ship, are synchronised to the same time of 12 noon at the point the ship leaves the Earth. That's known. Also we're in the ship's reference frame.

The signal leaves Earth at 2pm, according to the person on Earth. The person on the ship.. also thinks the signal left Earth at 2pm?

But surely his clock won't still be reading the same time as on Earth, it'll be later on (perceives that Earth clock runs slow as Earth moving) right? So how do I calculate that he thinks it's 2pm? i.e. what equation do I use?

*click*

oh, perhaps I can use this now:

[tex]t=\gamma t' \implies t=(1.25)\times (2.00)=2.5\rightarrow 2:30pm[/tex]

?

Sorry, I know you said time dilation formula cannot be applied, but how else to I calculate the time difference?

I'm sure need to account for that [itex]\gamma[/itex] somewhere, maybe I just wasn't using it in the right way before then. I also know I may have mixed up t and t' in the order they should be there.

So that would answer finding out what time the ship clock would read, but not really as to why they know it left at 2pm as how do I apply this backwards to deduce this? Unless I'm missing something obvious.. probably.

Obviously can do similar method with the shuttle but want to get these steps correct first, so I havn't mentioned it at the moment. Hopefully what I've said makes sense.

I am sort of understanding what you're saying now and where I'm going wrong with what I've been doing, or at least I think so. Just trying to think about the things a bit differently. It's clearly something that's taking me a while to get around.
 
  • #18
Lissajoux said:
So you're saying that the time dilation formula I used previously:

[tex]t=\frac{t_{E}}{\gamma}=\frac{6}{1.25}=4.8s[/tex]

(that's just for an example of a previous calculation)

Or rather more generally:

[tex]t'=\gamma t[/tex]

This cannot be applied to this problem?
Yes and no. Yes, in the sense that you can't apply it the way you have. No, in the sense that you can use it for an appropriate situation, like the one you mention below.
So the two clocks, the one of Earth and the one on the ship, are synchronised to the same time of 12 noon at the point the ship leaves the Earth. That's known. Also we're in the ship's reference frame.

The signal leaves Earth at 2pm, according to the person on Earth. The person on the ship.. also thinks the signal left Earth at 2pm?

But surely his clock won't still be reading the same time as on Earth, it'll be later on (perceives that Earth clock runs slow as Earth moving) right? So how do I calculate that he thinks it's 2pm? i.e. what equation do I use?

*click*

oh, perhaps I can use this now:

[tex]t=\gamma t' \implies t=(1.25)\times (2.00)=2.5\rightarrow 2:30pm[/tex]

?
This calculation is correct. The formula applies because the clock on Earth doesn't move with respect to the Earth. It's always at x=0, so Δx=0.

A more general way to analyze this problem is to use the Lorentz transformations to map the coordinates of events in one frame into the other frame. In the Earth frame, the event of the signal being sent is at the coordinates (ct,x)=(2 lh, 0 lh) [lh = light-hour]. Using the Lorentz transformations, you'll find

[tex]ct' = \gamma(ct - \beta x) = 1.25 [2~\textrm{lh} - 0.6\cdot 0~\textrm{lh}] = 2.5~\textrm{lh}[/tex]

[tex]x' = \gamma(x - \beta ct) = 1.25 [0~\textrm{lh} - 0.6\cdot 2~\textrm{lh})] = -1.5~\textrm{lh}[/tex]

where [itex]\beta = v/c[/itex]. What this says is from the ship observer's point of view, the signal left Earth when the ship's clock read 2:30 and the Earth was 1.5 lh away.

Earlier, you found that the signal reaches the ship when t=5 h and the ship is x=3 lh away, as observed in the Earth frame. Try calculating the coordinates of this event in the ship's frame.
 
  • #19
The signal reaches the ship when [itex]t=5~\textrm{h}[/itex] and the ship is [itex]x=3~\textrm{lh}[/itex] away, as observed in the Earth frame.

Using Lorentz transformations:

[tex]ct' = \gamma(ct - \beta x) = 1.25 [5~\textrm{lh} - 0.6\cdot 3~\textrm{lh}] = 4~\textrm{lh}[/tex]

[tex]x' = \gamma(x-\beta ct)=1.25[3~\textrm{lh}-1\cdot 5~\textrm{lh}]=-2.5~\textrm{lh}[/tex]

So to the observer on the ship, the signal arrives at 4:00 and at that point the Earth is 2.5lh away.

Hows that now? :smile:
 
  • #20
Great! So now you have answers for (i), when the signal left Earth, and (iii), when the ship received it, as observed in the ship's frame of reference. You should now be able to find that the speed of the signal is c.
 
  • #21
Note there is an alternate way to get the same results. You can use time dilation to calculate the time on the ship's clock at the time the signal was emitted. (Why?)

[tex]t' = \gamma t = 1.25(2~\textrm{h}) = 2.5~\textrm{h}[/tex]

At this time, the ship has traveled (as measured in the ship's frame) a distance of

[tex]x' = vt' = 0.6c (2.5~\textrm{h}) = 1.5~\textrm{lh}[/tex]

Since light has the same speed in every frame, the signal will take 1.5 hours to reach the ship, so the ship will receive the signal at t=2.5 h+1.5 h=4.0 h.
 
  • #22
... surely I've found the time the signal was received by the ship, and how far away the Earth was from the ship at that time. Where does the time the signal left the Earth come from that? Sorry to ask a stupid question! :blushing:

So now I can apply this method for the shuttle as well yes:

The shuttle reaches the ship when [itex]t=16~\textrm{h}[/itex] and the ship is [itex]x=12~\textrm{lh}[/itex] away, as observed in the Earth frame. These are the correct values? They were calculated earlier in part A.

Using Lorentz transformations:

[tex]ct' = \gamma(ct - \beta x) = 1.25 [16~\textrm{lh} - 0.6\cdot 12~\textrm{lh}] = 11~\textrm{lh}[/tex]

[tex]x' = \gamma(x-\beta ct)=1.25[12~\textrm{lh}-1\cdot 16~\textrm{lh}]=-5.0~\textrm{lh}[/tex]

So to the observer on the ship, the signal arrives at 11:00 and at that point the Earth is 5.0lh away.

That's correct? :smile:

Then from these calculations can find the speeds of the signal and of the shuttle, in the ship's reference frame.

I know the time the signal got to the ship (4:00) but don't know the time it left Earth (just asked you that) and I know the distance is [itex]2.5~\textrm{lh}[/itex]. Can I then just use [itex]s=\frac{d}{t}[/itex]? Or is there a relativistic equation to use instead? :shy:
 
  • #23
vela said:
Note there is an alternate way to get the same results. You can use time dilation to calculate the time on the ship's clock at the time the signal was emitted. (Why?)

[tex]t' = \gamma t = 1.25(2~\textrm{h}) = 2.5~\textrm{h}[/tex]

At this time, the ship has traveled (as measured in the ship's frame) a distance of

[tex]x' = vt' = 0.6c (2.5~\textrm{h}) = 1.5~\textrm{lh}[/tex]

Since light has the same speed in every frame, the signal will take 1.5 hours to reach the ship, so the ship will receive the signal at t=2.5 h+1.5 h=4.0 h.

Sorry I saw this after my last post.

Ok that looks a good way. Got used to this way now though :wink:
 
  • #24
Lissajoux said:
... surely I've found the time the signal was received by the ship, and how far away the Earth was from the ship at that time. Where does the time the signal left the Earth come from that? Sorry to ask a stupid question! :blushing:
Reread post 18.
 
  • #25
Lissajoux said:
Sorry I saw this after my last post.

Ok that looks a good way. Got used to this way now though :wink:
I personally prefer the Lorentz transformation method as well. The other method can be less work, but you have to know when you can apply the various formulas, which, as you have found out, isn't always obvious.

I think seeing both ways, however, is useful. I recommend you solve the shuttle part of the problem both ways.
 
  • #26
Oh yes I see it now (I think! :shy:)

vela said:
What this says is from the ship observer's point of view, the signal left Earth when the ship's clock read 2:30 and the Earth was 1.5 lh away.

So according the the ship, the signal left Earth at 2:30 and at that time of departure, the ship and the Earth were [itex]1.5~\textrm{lh}[/itex] apart.

I just found that the signal arrives at the ship at 4:00. So that's a time difference of [itex]4.00~\textrm{h}-2.5~\textrm{h}=1.5~\textrm{h}[/itex].

The distance difference between signal sent and signal received times:

[tex]2.5~\textrm{lh}-1.5~\textrm{lh}=1~\textrm{lh}[/tex]

So then the speed of the signal:

[tex]v=\frac{d}{t}=\frac{1~\textrm{lh}}{1.5~\textrm{h}}= ~\textrm{shouldn't this be c?}[/tex]

.. where have I gone wrong there then? :frown:

Also, were my calculations correct for the shuttle? Using the method used for the signal.
 
  • #27
Lissajoux said:
Lissajoux said:
Oh yes I see it now (I think! :shy:)

So according the the ship, the signal left Earth at 2:30 and at that time of departure, the ship and the Earth were [itex]1.5~\textrm{lh}[/itex] apart.

I just found that the signal arrives at the ship at 4:00. So that's a time difference of [itex]4.00~\textrm{h}-2.5~\textrm{h}=1.5~\textrm{h}[/itex].

The distance difference between signal sent and signal received times:

[tex]2.5~\textrm{lh}-1.5~\textrm{lh}=1~\textrm{lh}[/tex]

So then the speed of the signal:

[tex]v=\frac{d}{t}=\frac{1~\textrm{lh}}{1.5~\textrm{h}}= ~\textrm{shouldn't this be c?}[/tex]

.. where have I gone wrong there then? :frown:
Yes, it should be c. Try drawing a spacetime diagram (in the ship's frame) to find your mistake.
Also, were my calculations correct for the shuttle? Using the method used for the signal.
Your method is correct, but your answers from part A are wrong for the shuttle.
 
  • #28
So according the the ship, the signal left Earth at 2:30 and at that time of departure, the ship and the Earth were [itex]1.5~\textrm{lh}[/itex] apart.

I just found that the signal arrives at the ship at 4:00. So that's a time difference of [itex]4.00~\textrm{h}-2.5~\textrm{h}=1.5~\textrm{h}[/itex].

The distance difference between signal sent and signal received times:

[tex]2.5~\textrm{lh}-1.5~\textrm{lh}=1~\textrm{lh}[/tex]

.. I still can't see what's wrong with that. :frown:

- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -

The shuttle reaches the ship when [itex]t=8~\textrm{h}[/itex] and the ship is [itex]x=4~\textrm{lh}[/itex] away, as observed in the Earth frame.

Using Lorentz transformations:

[tex]ct' = \gamma(ct - \beta x) = 1.25 [8~\textrm{lh} - 0.6\cdot 4~\textrm{lh}] = 7~\textrm{lh}[/tex]

[tex]x' = \gamma(x-\beta ct)=1.25[4~\textrm{lh}-1\cdot 8~\textrm{lh}]=-5.0~\textrm{lh}[/tex]

So to the observer on the ship, the shuttle arrives at 7:00 and at that point the Earth is 5.0lh away.

Is that part correct now? :smile:
 
  • #29
Lissajoux said:
.. I still can't see what's wrong with that. :frown:

- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -

The shuttle reaches the ship when [itex]t=8~\textrm{h}[/itex] and the ship is [itex]x=4~\textrm{lh}[/itex] away, as observed in the Earth frame.

Using Lorentz transformations:

[tex]ct' = \gamma(ct - \beta x) = 1.25 [8~\textrm{lh} - 0.6\cdot 4~\textrm{lh}] = 7~\textrm{lh}[/tex]

[tex]x' = \gamma(x-\beta ct)=1.25[4~\textrm{lh}-1\cdot 8~\textrm{lh}]=-5.0~\textrm{lh}[/tex]

So to the observer on the ship, the shuttle arrives at 7:00 and at that point the Earth is 5.0lh away.

Is that part correct now? :smile:
Nope.
 
  • #30
Hmm. :grumpy:

Method:

[itex]x_{ship}=0.6t[/itex] and [itex]x_{shuttle}=0.8c(t-4)[/itex]

Hence: [itex]0.6ct=0.8c(t-4)[/itex]

Now solve for [itex]t[/itex]:

[tex]0.6ct=0.8ct-3.2c\implies 3.2c=0.2ct\implies t=\frac{3.2}{0.2}=16[/tex]hours

Therefore:

[tex]t=16~\textrm{h}[/tex]

[tex]x=16-4=12~\textrm{lh}[/tex]

[tex]\beta=\frac{v}{c}={0.8}{c}[/itex]? (not sure on this though, as it stayed as [itex]0.6c[/itex] in the formula for the signal so why change it for the shuttle, this is ship speed then?)

These are the (possible) Lorentz transforms:

[tex]ct' = \gamma(ct - \beta x) = 1.25 [16~\textrm{lh} - 0.6\cdot 12~\textrm{lh}] = 11~\textrm{lh}[/tex]

[tex]ct' = \gamma(ct - \beta x) = 1.25 [16~\textrm{lh} - 0.8\cdot 12~\textrm{lh}] = 8~\textrm{lh}[/tex]

[tex]x' = \gamma(x-\beta ct)=1.25[12~\textrm{lh}-1\cdot 16~\textrm{lh}]=-5.0~\textrm{lh}[/tex]

So to the observer on the ship, the shuttle arrives at 11:00 and at that point the Earth is 5.0lh away.

- - - - - - - - - - -

So that's all my variables in the Lorentz equations, where am I going wrong?? :confused:

- - - - - - - - - - -

[tex]v=\frac{d}{t}=\frac{1~\textrm{lh}}{1.5~\textrm{h}} = ~\textrm{shouldn't this be c?}[/tex]

Also still not sure where I'm going wrong with this? :frown:
 
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  • #31
I don't think my pointing out the error is a good idea because I'm not getting a sense that you understand the calculations. You just seem to be following a recipe; you're not demonstrating an understanding of why you're doing certain calculations or what the results mean. The reason I'm saying this is because this error, like some of your previous errors, is a very elementary one. It's not a subtle mistake; it's a blatant one, which you should easily be able to find on your own.
 
  • #32
(Ignore my previous post if you read it, this is the better replacement)

Right I've gone back through my calculations to try and make sense of it all and spot where I've gone wrong.

So in the Earth reference frame, the signal reaches the ship at [itex]t=5.0~\textrm{h}[/itex] and at that time the Earth and the ship are a distance of [itex]x=3.0~\textrm{lh}[/itex] apart.

Then using Lorentz transforms:

[tex]ct' = \gamma(ct - \beta x) = 1.25 [5~\textrm{lh} - 0.6\cdot 3~\textrm{lh}] = 4~\textrm{lh}[/tex]

[tex]x' = \gamma(x-\beta ct)=1.25[3~\textrm{lh}-1\cdot 5~\textrm{lh}]=-2.5~\textrm{lh}[/tex]

So in the ship's reference frame, the signal reaches the ship at [itex]t=4.0~\textrm{h}[/itex] and at that time the Earth and the ship are a distance of [itex]x=2.5~\textrm{lh}[/itex] apart.

This seems to make sense since to someone on the ship in the ship's reference frame, the clock on Earth appears to be running slow, and there is also length contraction making the preceived distance to Earth shorter.

Ok, right so hopefully that's all good.

Then if I know, in the ship's reference frame, what time the signal left the Earth and what distance away the Earth was at that time, I can find the distance traveled by the signal and the time taken. Hence I can find the speed of the signal.

In the Earth frame, the event of the signal being sent is at the coordinates [itex](ct,x)=(2 lh, 0 lh)[/itex]. Using the Lorentz transformations:

[tex]ct' = \gamma(ct - \beta x) = 1.25 [2~\textrm{h} - 0.6\cdot 0~\textrm{h}] = 2.5~\textrm{h}[/tex]

[tex]x' = \gamma(x - \beta ct) = 1.25 [0~\textrm{lh} - 0.6\cdot 2~\textrm{lh})] = -1.5~\textrm{lh}[/tex]

So from the ship's reference frame, the signal left Earth when the ship's clock read 2:30 and the Earth was [itex]1.5~\textrm{lh}[/itex] away.

We've already established that everything above is correct, at least I believe so, through previous posts.

Then I somehow seem to be going wrong from this step onwards.

I've then calculated that:

[tex]\Delta t=4.0-2.5=1.5~\textrm{h}[/tex]

[tex]\Delta d=2.5-1.5=1.0~\textrm{lh}[/tex]

I can do this right.

So then simply did:

[tex]v=\frac{1.0~\textrm{lh}}{1.5~\textrm{h}}=\frac{2}{3}c[/tex]

That's just a calculation, don't see how that could be wrong.

.. and then I've run out of ideas.I've checked through everything. I can't spot where I've gone wrong, it's obviously more of a subtle mistake to me. Perhaps you could hint at which part in that method I've detailed I've gone wrong please? Then I should hopefully be able to see it :smile:
 
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  • #33
I've just looked through my notes again and thought I could use this to find the speed of the signal:

[tex]u_{x}'=\frac{u_{x}-v}{1-\frac{u_{x}v}{c^{2}}}=\frac{c-0.6c}{1-\frac{0.6c^{2}}{c^{2}}}=\frac{(1-0.6)c}{1-0.6}=\frac{c}{1}=c[/tex]

where [itex]u_{x}'[/itex] is the speed of the signal in the ship's reference frame and the speed of the signal in the Earth's reference frame is [itex]u_{x}[/itex]

yes?
 
  • #34
Lissajoux said:
(Ignore my previous post if you read it, this is the better replacement)

Right I've gone back through my calculations to try and make sense of it all and spot where I've gone wrong.

So in the Earth reference frame, the signal reaches the ship at [itex]t=5.0~\textrm{h}[/itex] and at that time the Earth and the ship are a distance of [itex]x=3.0~\textrm{lh}[/itex] apart.

Then using Lorentz transforms:

[tex]ct' = \gamma(ct - \beta x) = 1.25 [5~\textrm{lh} - 0.6\cdot 3~\textrm{lh}] = 4~\textrm{lh}[/tex]

[tex]x' = \gamma(x-\beta ct)=1.25[3~\textrm{lh}-1\cdot 5~\textrm{lh}]=-2.5~\textrm{lh}[/tex]

So in the ship's reference frame, the signal reaches the ship at [itex]t=4.0~\textrm{h}[/itex] and at that time the Earth and the ship are a distance of [itex]x=2.5~\textrm{lh}[/itex] apart.

This seems to make sense since to someone on the ship in the ship's reference frame, the clock on Earth appears to be running slow, and there is also length contraction making the preceived distance to Earth shorter.
This is a perfect example of what I'm talking about. First, the numbers are wrong. This part should be just plug-and-chug. Now it could be a careless mistake, in which case, you should have easily found it, or it could be you're just plugging numbers in somewhat randomly because you don't understand what the variables stand for. If this is the case, you need to learn what the variables mean.

Second, the interpretation is wrong. In part A, you found that the ship and signal meet at x=3 lh. Note that you were solving for where in space this event occurred; you weren't solving for how far away from Earth it occurred. The distance between the Earth and the ship happens to also be 3 lh because the Earth is at the origin in the Earth frame. In the ship's frame, however, the Earth isn't at the origin, so x' isn't the distance between the ship and Earth when it receives the signal.

The Lorentz transformations convert the coordinates of an event in one frame to the coordinates of the same event in a different frame. In this particular case, you found that the ship and signal meet at the spacetime coordinates (ct, x) = (5 lh, 3 lh) as observed in the Earth's frame. The transformed coordinates (ct', x') tell you where in spacetime the ship and signal meet as observed in the ship's frame. To repeat, x' is not the distance between the ship and Earth.
Then if I know, in the ship's reference frame, what time the signal left the Earth and what distance away the Earth was at that time, I can find the distance traveled by the signal and the time taken. Hence I can find the speed of the signal.

In the Earth frame, the event of the signal being sent is at the coordinates [itex](ct,x)=(2 lh, 0 lh)[/itex]. Using the Lorentz transformations:

[tex]ct' = \gamma(ct - \beta x) = 1.25 [2~\textrm{h} - 0.6\cdot 0~\textrm{h}] = 2.5~\textrm{h}[/tex]

[tex]x' = \gamma(x - \beta ct) = 1.25 [0~\textrm{lh} - 0.6\cdot 2~\textrm{lh})] = -1.5~\textrm{lh}[/tex]

So from the ship's reference frame, the signal left Earth when the ship's clock read 2:30 and the Earth was [itex]1.5~\textrm{lh}[/itex] away.

We've already established that everything above is correct, at least I believe so, through previous posts.

Then I somehow seem to be going wrong from this step onwards.

I've then calculated that:

[tex]\Delta t=4.0-2.5=1.5~\textrm{h}[/tex]

[tex]\Delta d=2.5-1.5=1.0~\textrm{lh}[/tex]

I can do this right.

So then simply did:

[tex]v=\frac{1.0~\textrm{lh}}{1.5~\textrm{h}}=\frac{2}{3}c[/tex]

That's just a calculation, don't see how that could be wrong.

.. and then I've run out of ideas.


I've checked through everything. I can't spot where I've gone wrong, it's obviously more of a subtle mistake to me. Perhaps you could hint at which part in that method I've detailed I've gone wrong please? Then I should hopefully be able to see it :smile:
As I suggested a few posts ago, draw spacetime diagrams for this problem. I think it'll help you clarify what's going on in the problem.
 
  • #35
Back in post 18 I believe we established that according to the ship, the signal left Earth when the ships clock read 2.5h and the ship at that time was 1.5lh away from the earth. Then in post 19, that according to the ship the signal was received when the ships clock read 4.0h and at that point the ship was 2.5lh from earth. So that'a a time difference of 1.5h, and a distance difference of 1.0lh. So why is any of that now incorrect? (or have I just plugged the wrong numbers into those lorentz transforms? ;))
 
<h2>1. What is the theory of relativity?</h2><p>The theory of relativity, developed by Albert Einstein, is a fundamental principle of physics that explains the relationship between space and time. It states that the laws of physics are the same for all observers in uniform motion, and the speed of light is constant in all inertial frames of reference.</p><h2>2. How does relativity relate to radio signals?</h2><p>Relativity has a significant impact on the behavior of radio signals. The theory predicts that the speed of light is the same for all observers, regardless of their relative motion. This means that radio signals, which travel at the speed of light, will also be constant for all observers.</p><h2>3. Can relativity affect the accuracy of radio signals?</h2><p>Yes, relativity can affect the accuracy of radio signals. The theory predicts that time and space are relative, and as a result, the frequency and wavelength of radio signals can be affected by the relative motion of the observer. This effect is known as the Doppler shift.</p><h2>4. How is relativity used in GPS systems?</h2><p>GPS systems rely on the principles of relativity to function accurately. The satellites that make up the GPS system are moving at high speeds relative to the Earth's surface, causing a time dilation effect. Without accounting for this effect, the GPS system would be off by several kilometers.</p><h2>5. Is there any evidence to support the theory of relativity?</h2><p>Yes, there is a vast amount of evidence to support the theory of relativity. One of the most famous examples is the observation of the bending of light around massive objects, such as stars, which was predicted by the theory. Additionally, many experiments have been conducted that confirm the predictions of relativity, including the famous Hafele-Keating experiment.</p>

1. What is the theory of relativity?

The theory of relativity, developed by Albert Einstein, is a fundamental principle of physics that explains the relationship between space and time. It states that the laws of physics are the same for all observers in uniform motion, and the speed of light is constant in all inertial frames of reference.

2. How does relativity relate to radio signals?

Relativity has a significant impact on the behavior of radio signals. The theory predicts that the speed of light is the same for all observers, regardless of their relative motion. This means that radio signals, which travel at the speed of light, will also be constant for all observers.

3. Can relativity affect the accuracy of radio signals?

Yes, relativity can affect the accuracy of radio signals. The theory predicts that time and space are relative, and as a result, the frequency and wavelength of radio signals can be affected by the relative motion of the observer. This effect is known as the Doppler shift.

4. How is relativity used in GPS systems?

GPS systems rely on the principles of relativity to function accurately. The satellites that make up the GPS system are moving at high speeds relative to the Earth's surface, causing a time dilation effect. Without accounting for this effect, the GPS system would be off by several kilometers.

5. Is there any evidence to support the theory of relativity?

Yes, there is a vast amount of evidence to support the theory of relativity. One of the most famous examples is the observation of the bending of light around massive objects, such as stars, which was predicted by the theory. Additionally, many experiments have been conducted that confirm the predictions of relativity, including the famous Hafele-Keating experiment.

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