Need help understanding the twins

[JesseM]

You are confused.

Twin1 is trying to calculate.

Twin2 knows what to do.

It needs to be established in twin1 all the timing.

This has been done.

Once that is done, twin1 can calculate twin2.

We have done that.

The twins are imaginary characters in a thought-experiment, we are trying to calculate which twin will be older given the premises of the thought experiment. If we are given specific values for a, BT, and t, then we can calculate twin2's final age using the equation (c/a)*sinh(a*BT/c) + t + BT, yes? But you haven't given us any way to calculate twin1's final age given the same information, and thus no way to calculate whether twin1 will be older or younger than twin2 at the end (and we can define 'the end' for twin1 in terms of taking his age T' when he receives a signal from twin2 and subtracting D/c from T', but this doesn't help in calculating what age he will actually be at the end given specific values for a, BT, and t).

For example, suppose we know that BT=0.5 years, a=2 light years/year^2, and t=5 years. In this case, twin2's elapsed time will be (1/2)*sinh(1) + 5 + 0.5 = 6.0876 years. Does your method give you a way to use this information to calculate a specific numeric value for twin1's elapsed time? Mine does.

 

[cfrogue]

The twins are imaginary characters in a thought-experiment, we are trying to calculate which twin will be older given the premises of the thought experiment. If we are given specific values for a, BT, and t, then we can calculate twin2's final age using the equation (c/a)*sinh(a*BT/c) + t + BT, yes? But you haven't given us any way to calculate twin1's final age given the same information, and thus no way to calculate whether twin1 will be older or younger than twin2 at the end (and we can define 'the end' for twin1 in terms of taking his age T' when he receives a signal from twin2 and subtracting D/c from T', but this doesn't help in calculating what age he will actually be at the end given specific values for a, BT, and t).

For example, suppose we know that BT=0.5 years, a=2 light years/year^2, and t=5 years. In this case, twin2's elapsed time will be (1/2)*sinh(1) + 5 + 0.5 = 6.0876 years. Does your method give you a way to use this information to calculate a specific numeric value for twin1's elapsed time? Mine does.

Point taken.

I will provide a specific example.

 

[cfrogue]

The twins are imaginary characters in a thought-experiment, we are trying to calculate which twin will be older given the premises of the thought experiment. If we are given specific values for a, BT, and t, then we can calculate twin2's final age using the equation (c/a)*sinh(a*BT/c) + t + BT, yes? But you haven't given us any way to calculate twin1's final age given the same information, and thus no way to calculate whether twin1 will be older or younger than twin2 at the end (and we can define 'the end' for twin1 in terms of taking his age T' when he receives a signal from twin2 and subtracting D/c from T', but this doesn't help in calculating what age he will actually be at the end given specific values for a, BT, and t).

For example, suppose we know that BT=0.5 years, a=2 light years/year^2, and t=5 years. In this case, twin2's elapsed time will be (1/2)*sinh(1) + 5 + 0.5 = 6.0876 years. Does your method give you a way to use this information to calculate a specific numeric value for twin1's elapsed time? Mine does.

I have looked at your example.

v = cosh(aBT/c) = cosh(1) = 1.54308063482 c

It seems your acceleration is too high.

 

[JesseM]

I have looked at your example.

v = cosh(aBT/c) = cosh(1) = 1.54308063482 c

It seems your acceleration is too high.

You're using an incorrect equation for v, the correct equation given on the http://math.ucr.edu/home/baez/physics/Relativity/SR/rocket.html ), which makes sense since you can have an arbitrarily high proper acceleration for arbitrarily long periods of proper time without ever exceeding c.

 

[cfrogue]

You're using an incorrect equation for v, the correct equation given on the http://math.ucr.edu/home/baez/physics/Relativity/SR/rocket.html ), which makes sense since you can have an arbitrarily high proper acceleration for arbitrarily long periods of proper time without ever exceeding c.

OK, OK, you are right.

Thanks for the calculator link.

Alright v = 0.7615941559557649c.

 

[cfrogue]

You're using an incorrect equation for v, the correct equation given on the http://math.ucr.edu/home/baez/physics/Relativity/SR/rocket.html ), which makes sense since you can have an arbitrarily high proper acceleration for arbitrarily long periods of proper time without ever exceeding c.

OK, after the burn of twin1 do you agree
d = (c2/a) [ch(aT/c) - 1]

Or, am I going to have to fight with you over this?

 

[JesseM]

OK, after the burn of twin1 do you agree
d = (c2/a) [ch(aT/c) - 1]

Or, am I going to have to fight with you over this?

In the launch frame where twin1 was at rest before accelerating (and twin2 remains at rest for time t after twin1 finishes accelerating), yes I agree this is the distance at the moment twin1 finishes his burn.

 

[cfrogue]

In the launch frame where twin1 was at rest before accelerating (and twin2 remains at rest for time t after twin1 finishes accelerating), yes I agree this is the distance at the moment twin1 finishes his burn.

So, do you agree from the accelerated frame

d = 1/a * ( cosh(a BT) - 1 )

is the distance between the ships?

 

[JesseM]

So, do you agree from the accelerated frame

d = 1/a * ( cosh(a BT) - 1 )

is the distance between the ships?

The relativistic rocket equations only work in inertial frames...by "accelerated frame" do you just mean the inertial frame where twin1 is at rest after he finishes his burn? If so, then no, this is incorrect. (1/a)*(cosh(a*BT) - 1) would be the distance in this frame between the position where twin1 started his burn and the position where he stopped his burn, but in this frame twin2 is continuing to move at v=tanh(a*BT) throughout the time twin1 is accelerating, and in this frame twin1's acceleration lasts for a time of t=(1/a)*sinh(a*BT). So by the time twin1 finishes his acceleration, twin2 will have moved a distance of vt = (1/a)*sinh(a*BT)*tanh(a*BT) from the position where twin1 started his acceleration, and twin1 will have moved a distance of (1/a)*(cosh(a*BT) - 1) in the opposite direction, so their distance at the time twin1 stops accelerating will be (1/a)*(sinh(a*BT)*tanh(a*BT) + cosh(a*BT) - 1).

 

[cfrogue]

The relativistic rocket equations only work in inertial frames...by "accelerated frame" do you just mean the inertial frame where twin1 is at rest after he finishes his burn? If so, then no, this is incorrect. (1/a)*(cosh(a*BT) - 1) would be the distance in this frame between the position where twin1 started his burn and the position where he stopped his burn, but in this frame twin2 is continuing to move at v=tanh(a*BT) throughout the time twin1 is accelerating, and in this frame twin1's acceleration lasts for a time of t=(1/a)*sinh(a*BT). So by the time twin1 finishes his acceleration, twin2 will have moved a distance of vt = (1/a)*sinh(a*BT)*tanh(a*BT) from the position where twin1 started his acceleration, and twin1 will have moved a distance of (1/a)*(cosh(a*BT) - 1) in the opposite direction, so their distance at the time twin1 stops accelerating will be (1/a)*(sinh(a*BT)*tanh(a*BT) + cosh(a*BT) - 1).

show me a mainstream paper.

 

[JesseM]

show me a mainstream paper.

I don't know of any mainstream paper that specifically considers the problem of how the distance between twins changes when one moves inertially while the other accelerates away at constant proper acceleration, and looks at this from the perspective of a frame where the inertial twin is not at rest. However, most of the reasoning here is a pretty basic application of SR principles:

1. Do you disagree that if twin1 has velocity v=tanh(a*BT) after he finishes accelerating in the launch frame, while twin2 is at rest in this frame, then if we transform into a new inertial frame where twin1 is at rest after he finishes accelerating, then twin2 must have a constant velocity v=tanh(a*BT) in this frame?

2. Do you disagree that if it takes time t1 = (1/a)*sinh(a*BT) in this frame from the beginning to the end of twin1 accelerating, then if twin2 has velocity v=tanh(a*BT) in this frame, he will have moved a distance of v*t1 = (1/a)*sinh(a*BT)*tanh(a*BT) between the time twin1 starts accelerating and the time he stops accelerating?

3. Do you disagree that in this frame twin1 moves a distance of (1/a)*(cosh(a*BT) - 1) in this frame between the time he starts accelerating and the time he stops?

4. If you don't disagree with any of the above, then the only remaining question should be whether twin1 and twin2 moved in the same direction from the point where twin1 started accelerating, or in opposite directions. I admit I didn't think this part through very carefully, after further consideration I think the answer should be that they both moved in the same direction (since twin1's initial speed and direction was the same as twin2's, but twin2 continued to move at the same speed and direction while twin1's speed dropped to zero) and that therefore twin1's distance covered should be subtracted from twin2's distance covered rather than added, in which case the distance would be (1/a)*(sinh(a*BT)*tanh(a*BT) - cosh(a*BT) + 1).

 

[cfrogue]

I don't know of any mainstream paper that specifically considers the problem of how the distance between twins changes when one moves inertially while the other accelerates away at constant proper acceleration, and looks at this from the perspective of a frame where the inertial twin is not at rest. However, most of the reasoning here is a pretty basic application of SR principles:

1. Do you disagree that if twin1 has velocity v=tanh(a*BT) after he finishes accelerating in the launch frame, while twin2 is at rest in this frame, then if we transform into a new inertial frame where twin1 is at rest after he finishes accelerating, then twin2 must have a constant velocity v=tanh(a*BT) in this frame?

2. Do you disagree that if it takes time t1 = (1/a)*sinh(a*BT) in this frame from the beginning to the end of twin1 accelerating, then if twin2 has velocity v=tanh(a*BT) in this frame, he will have moved a distance of v*t1 = (1/a)*sinh(a*BT)*tanh(a*BT) between the time twin1 starts accelerating and the time he stops accelerating?

3. Do you disagree that in this frame twin1 moves a distance of (1/a)*(cosh(a*BT) - 1) in this frame between the time he starts accelerating and the time he stops?

4. If you don't disagree with any of the above, then the only remaining question should be whether twin1 and twin2 moved in the same direction from the point where twin1 started accelerating, or in opposite directions. I admit I didn't think this part through very carefully, after further consideration I think the answer should be that they both moved in the same direction (since twin1's initial speed and direction was the same as twin2's, but twin2 continued to move at the same speed and direction while twin1's speed dropped to zero) and that therefore twin1's distance covered should be subtracted from twin2's distance covered rather than added, in which case the distance would be (1/a)*(sinh(a*BT)*tanh(a*BT) - cosh(a*BT) + 1).

What was wrong with my original method of the D/c business?

 

[JesseM]

What was wrong with my original method of the D/c business?

The fact that it doesn't actually give you a way to calculate twin1's final age when twin2 stops accelerating (i.e. the age he is when he receives the light signal, minus D/c) given known values for the variables BT, a, and t that determine twin2's final age. If you think it does, then please show me how you'd calculate a numerical value for twin1's final age given the example values I gave, namely BT=0.5 years, a=2 light years/year^2, and t=5 years.

Again, my method does allow you to calculate twin1's final age given a set of values like this. I can show you the details of the calculation if you're interested.

 

[marxmarvelous]

At Johns Hopkins as a Jr. Instructor the "twins" paradox was never aproached. Likely there has been two generations of teachers who think there is an "answer" to the paradox.

Einstein gave it in 1915; GR. He termed the paradox as "a failure of epistemology." Western 'Greek think" begins with postulates land thru a system of logic arrives at solutions. An unspoken postulate in the twins thing is that the mass environment of neither twin is necessary for fiddling with the SR transformation formulas. Wrong so he thought up GR. If one wants to map wrinkles onto faces of the "twins" one must use the GR equations to the travels of both.
Einstein was largely ignored by the media after he kept repeating that immigrants to palestine must get along with Palestinians and that an international police force must have the power to insure the planet that no nuclear weapons existed anywhere. He also insisted that infinities in formulas weren't physical simply imperfect postulates producing math artifacts. He died before the media was allowed to accept infinite densities here and there.
I expect to be told I am wrong. Could someone carry this century old "twin" thought to a physicist with whom I can discuss this. Thanks

 

[cfrogue]

At Johns Hopkins as a Jr. Instructor the "twins" paradox was never aproached. Likely there has been two generations of teachers who think there is an "answer" to the paradox.

Einstein gave it in 1915; GR. He termed the paradox as "a failure of epistemology." Western 'Greek think" begins with postulates land thru a system of logic arrives at solutions. An unspoken postulate in the twins thing is that the mass environment of neither twin is necessary for fiddling with the SR transformation formulas. Wrong so he thought up GR. If one wants to map wrinkles onto faces of the "twins" one must use the GR equations to the travels of both.
Einstein was largely ignored by the media after he kept repeating that immigrants to palestine must get along with Palestinians and that an international police force must have the power to insure the planet that no nuclear weapons existed anywhere. He also insisted that infinities in formulas weren't physical simply imperfect postulates producing math artifacts. He died before the media was allowed to accept infinite densities here and there.
I expect to be told I am wrong. Could someone carry this century old "twin" thought to a physicist with whom I can discuss this. Thanks

Good, this is not the normal twins paradox.

 

[cfrogue]

The fact that it doesn't actually give you a way to calculate twin1's final age when twin2 stops accelerating (i.e. the age he is when he receives the light signal, minus D/c) given known values for the variables BT, a, and t that determine twin2's final age. If you think it does, then please show me how you'd calculate a numerical value for twin1's final age given the example values I gave, namely BT=0.5 years, a=2 light years/year^2, and t=5 years.

Again, my method does allow you to calculate twin1's final age given a set of values like this. I can show you the details of the calculation if you're interested.

Yes, I am interested.

No, I cannot give a specific example and you know this.

I would need to actually know the distance between the two when twin2 entered the frame.

For me this does not matter. But for some it does.

So, I am interested how you decide t'.

 

[JesseM]

Yes, I am interested.

OK, I'll get to this soon, but first I want to ask a few more questions about how your own approach is supposed to work:

No, I cannot give a specific example and you know this.

I would need to actually know the distance between the two when twin2 entered the frame.

You can calculate the distance between the two in the final rest frame when twin2 finishes his acceleration given BT, a, and t, but it seems to me that even with this information your approach does not tell us who is older. As I said in post #186, if we are analyzing things from the perspective of the inertial frame where they are at rest after acceleration, then in this frame twin1 moves a distance of (c/a)*(cosh(a*BT/c) - 1) during his acceleration phase, after which he is at rest in this frame. Meanwhile we know that twin2 moves inertially for a proper time of (c/a)*sinh(a*BT/c) + t before beginning to accelerate, and in this frame twin2 is moving at constant velocity v=c*tanh(a*BT/c) before beginning to accelerate, so according to the time dilation equation the coordinate time in this frame before twin2 begins to accelerate must be gamma times the proper time, i.e. gamma*[(c/a)*sinh(a*BT/c) + t], and the coordinate distance twin2 covers in this time is just given by velocity*coordinate time, or gamma*c*tanh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t]. Then during twin2's acceleration phase, twin2 will cover an additional distance of (c/a)*(cosh(a*BT/c) - 1). So, the total distance twin2 travels from the origin (the point where the two twins first separated) in this frame is:

gamma*c*tanh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t] + (c/a)*(cosh(a*BT/c) - 1)

Whereas the total distance twin1 travels from the origin in this frame is:

(c/a)*(cosh(a*BT/c) - 1)

So, subtracting the second from the first shows that the final distance between them will be:

gamma*c*tanh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t]

Since gamma is 1/sqrt(1 - v^2/c^2), we can plug in v=c*tanh(a*BT/c), showing that gamma = 1/sqrt(1 - tanh^2(a*BT/c)). And making use of the hyperbolic trig identities here, we known tanh(x) = sinh(x)/cosh(x), so gamma = 1/sqrt(1 - sinh^2/cosh^2) = 1/[sqrt(1/cosh^2)*sqrt(cosh^2 - sinh^2)], and since another identity says that cosh^2 - sinh^2 = 1, this reduces to 1/sqrt(1/cosh^2) = cosh(a*BT/c). So with gamma = cosh(a*BT/c), the final distance between them can be rewritten as:

c*cosh(a*BT/c)*tanh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t]

And again making use of the fact that tanh(x) = sinh(x)/cosh(x), this reduces to:

c*sinh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t]

So if you plug in BT=0.5 years, a=2 light years/year^2, and t=5 years, this becomes:

sinh(1)*[sinh(1) + 5] = 1.1752011936438014*[1.1752011936438014 + 5] = 7.25710381376082 light years.

But even with the final distance known, can you calculate a numerical value for the final age of twin1?

 

[cfrogue]

OK, I'll get to this soon, but first I want to ask a few more questions about how your own approach is supposed to work:

You can calculate the distance between the two in the final rest frame when twin2 finishes his acceleration given BT, a, and t, but it seems to me that even with this information your approach does not tell us who is older. As I said in post #186, if we are analyzing things from the perspective of the inertial frame where they are at rest after acceleration, then in this frame twin1 moves a distance of (c/a)*(cosh(a*BT/c) - 1) during his acceleration phase, after which he is at rest in this frame. Meanwhile we know that twin2 moves inertially for a proper time of (c/a)*sinh(a*BT/c) + t before beginning to accelerate, and in this frame twin2 is moving at constant velocity v=c*tanh(a*BT/c) before beginning to accelerate, so the time in this frame before twin2 begins to accelerate must be gamma times the proper time, i.e. gamma*[(c/a)*sinh(a*BT/c) + t], and the distance twin2 covers in this time is just given by velocity*time, or gamma*c*tanh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t]. Then during twin2's acceleration phase, twin2 will cover an additional distance of (c/a)*(cosh(a*BT/c) - 1). So, the total distance twin2 travels from the origin (the point where the two twins first separated) in this frame is:

gamma*c*tanh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t] + (c/a)*(cosh(a*BT/c) - 1)

Whereas the total distance twin1 travels from the origin in this frame is:

(c/a)*(cosh(a*BT/c) - 1)

So, subtracting the second from the first shows that the final distance between them will be:

gamma*c*tanh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t]

Since gamma is 1/sqrt(1 - v^2/c^2), we can plug in v=c*tanh(a*BT/c), showing that gamma = 1/sqrt(1 - tanh^2(a*BT/c)). And making use of the hyperbolic trig identities here, we known tanh(x) = sinh(x)/cosh(x), so gamma = 1/sqrt(1 - sinh^2/cosh^2) = 1/[sqrt(1/cosh^2)*sqrt(cosh^2 - sinh^2)], and since another identity says that cosh^2 - sinh^2 = 1, this reduces to 1/sqrt(1/cosh^2) = cosh(a*BT/c). So with gamma = cosh(a*BT/c), the final distance between them can be rewritten as:

c*cosh(a*BT/c)*tanh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t]

And again making use of the fact that tanh(x) = sinh(x)/cosh(x), this reduces to:

c*sinh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t]

So if you plug in BT=0.5 years, a=2 light years/year^2, and t=5 years, this becomes:

sinh(1)*[sinh(1) + 5] = 1.1752011936438014*[1.1752011936438014 + 5] = 7.25710381376082 light years.

But even with the final distance known, can you calculate a numerical value for the final age of twin1?

I am going to need some time to follow your argument.


But even with the final distance known, can you calculate a numerical value for the final age of twin1?

Yes, why not?

It is the same type of problem.

I sub off the distance of the twin1 accel phase and then I sub the distance of the twin2 accel phase.

I am left with the distance of the relative motion phase and thus, d/v = t'.

No?

 

[JesseM]

I am going to need some time to follow your argument.But even with the final distance known, can you calculate a numerical value for the final age of twin1?

Yes, why not?

It is the same type of problem.

I sub off the distance of the twin1 accel phase and then I sub the distance of the twin2 accel phase.

I am left with the distance of the relative motion phase and thus, d/v = t'.

No?

Sure, that works. But I thought your calculation method was supposed to involve subtracting D/c from the time twin1 receives the signal--that doesn't appear to happen anywhere in the method above.

My method for calculating twin1's time from the perspective of the final rest frame was basically similar but without the need to consider distances. I would just say that since we know twin2 moved inertially at v=c*tanh(a*BT/c) before beginning to accelerate, and we know twin2 experienced a proper time of [(c/a)*sinh(a*BT/c) + t] before beginning to accelerate, the according to the time dilation equation the coordinate time in this frame before twin2 accelerates would just be gamma times the proper time, i.e. gamma*[(c/a)*sinh(a*BT/c) + t]. As I showed in my previous post, if v=c*tanh(a*BT/c) then gamma=cosh(a*BT/c), so the coordinate time before twin2 accelerates can also be written as cosh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t]. Then the coordinate time for twin2 to accelerate in this frame is (c/a)*sinh(a*BT/c), so the total coordinate time from start to finish is cosh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t] + (c/a)*sinh(a*BT/c).

Now, we know that in this frame it took twin1 a coordinate time of (c/a)*sinh(a*BT/c) to do his own acceleration, so the coordinate time from the end of twin1's acceleration to the end of twin2's acceleration must be:

[cosh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t] + (c/a)*sinh(a*BT/c)] - (c/a)*sinh(a*BT/c)

Which just reduces to cosh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t]...since twin1 was at rest throughout this period, this would also be the proper time for twin1 from the end of his acceleration to the moment when twin2 stopped his own acceleration. And we know the proper time for twin1 during his acceleration was BT, so add them together and we have twin1's total proper time from start to finish:

BT + cosh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t]

Since gamma = cosh(a*BT/c) is greater than 1, this total proper time will naturally be larger than twin2's total proper time from start to finish, i.e. BT + (c/a)*sinh(a*BT/c) + t. So, twin1 will be older than twin2 at the moment twin2 stops his acceleration and we compare their ages in the final rest frame.

 

[cfrogue]

Sure, that works. But I thought your calculation method was supposed to involve subtracting D/c from the time twin1 receives the signal--that doesn't appear to happen anywhere in the method above.

My method for calculating twin1's time from the perspective of the final rest frame was basically similar but without the need to consider distances. I would just say that since we know twin2 moved inertially at v=c*tanh(a*BT/c) before beginning to accelerate, and we know twin2 experienced a proper time of [(c/a)*sinh(a*BT/c) + t] before beginning to accelerate, the according to the time dilation equation the coordinate time in this frame before twin2 accelerates would just be gamma times the proper time, i.e. gamma*[(c/a)*sinh(a*BT/c) + t]. As I showed in my previous post, if v=c*tanh(a*BT/c) then gamma=cosh(a*BT/c), so the coordinate time before twin2 accelerates can also be written as cosh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t]. Then the coordinate time for twin2 to accelerate in this frame is (c/a)*sinh(a*BT/c), so the total coordinate time from start to finish is cosh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t] + (c/a)*sinh(a*BT/c).

Now, we know that in this frame it took twin1 a coordinate time of (c/a)*sinh(a*BT/c) to do his own acceleration, so the coordinate time from the end of twin1's acceleration to the end of twin2's acceleration must be:

[cosh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t] + (c/a)*sinh(a*BT/c)] - (c/a)*sinh(a*BT/c)

Which just reduces to cosh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t]...since twin1 was at rest throughout this period, this would also be the proper time for twin1 from the end of his acceleration to the moment when twin2 stopped his own acceleration. And we know the proper time for twin1 during his acceleration was BT, so add them together and we have twin1's total proper time from start to finish:

BT + cosh(a*BT/c)*[(c/a)*sinh(a*BT/c) + t]

Since gamma = cosh(a*BT/c) is greater than 1, this total proper time will naturally be larger than twin2's total proper time from start to finish, i.e. BT + (c/a)*sinh(a*BT/c) + t. So, twin1 will be older than twin2 at the moment twin2 stops his acceleration and we compare their ages in the final rest frame.

Since you said I am stupid in the other thread, what would make you think I could follow this unless you are stupid.

You are inconsistent.

 

[JesseM]

Since you said I am stupid in the other thread, what would make you think I could follow this unless you are stupid.

You are inconsistent.

I didn't say you were stupid, I said your argument was stupid. An intelligent person can make a stupid argument if they are too confident of their own correctness and are too quick to be snidely dismissive of the counterarguments made by others and not really pay attention to what people tell them, as seems to be the case with you on all of these threads.

 

[cfrogue]

I didn't say you were stupid, I said your argument was stupid. An intelligent person can make a stupid argument if they are too confident of their own correctness and are too quick to be snidely dismissive of the counterarguments made by others and not really pay attention to what people tell them, as seems to be the case with you on all of these threads.

Yes, maybe read this to yourself.

You can already tell I understand SR.

Have you considered yet I might be seeing something?

Answer the time dilation in the other thread and I will run you into a contradiction.

I think you can see this though.


Anyway, you said I was stupid. No matter, I am not.

But, I am going to look through your length argument here.

I will confess, you seem to have something with it.

Note how I am not so arrogant as to assume I know everything.

 

[Al68]

You can already tell I understand SR.

LOL. Are you aware that length contraction is a major part of SR?

 

[cfrogue]

LOL. Are you aware that length contraction is a major part of SR?

LOL, what is that?

 

[JesseM]

Yes, maybe read this to yourself.

You can already tell I understand SR.

No, I certainly wouldn't agree with that, you seem to understand some things but then you make really basic mistakes, like arguing that the past light cone would not look like a contracting light sphere if you plotted it over time. If you want to understand SR, I think you really need to find a text that develops it in a step-by-step manner (http://www.oberlin.edu/physics/dstyer/Einstein/SRBook.pdf . Your posts on relativity seem to be a fine example of this.

Anyway, you said I was stupid.

No, in fact I did not, I said your argument was stupid and that's all that I meant (if you want my real opinion of you, I think you are probably fairly intelligent but suffering from the type of overselfconfidence issue discussed above). But you love to tell me I'm wrong about the content of my own statements and opinions, apparently.

 

[cfrogue]

No, I certainly wouldn't agree with that, you seem to understand some things but then you make really basic mistakes, like arguing that the past light cone would not look like a contracting light sphere if you plotted it over time. If you want to understand SR, I think you really need to find a text that develops it in a step-by-step manner (http://www.oberlin.edu/physics/dstyer/Einstein/SRBook.pdf . Your posts on relativity seem to be a fine example of this.

No, in fact I did not, I said your argument was stupid and that's all that I meant (if you want my real opinion of you, I think you are probably fairly intelligent but suffering from the type of overselfconfidence issue discussed above). But you love to tell me I'm wrong about the content of my own statements and opinions, apparently.

Yea, anyway, let's operate in the sphere thread with this logic.