Negative squares using the space time interval invariance

[ersteller]

Hallo
I'm new to this (wonderful) forum, and to SR too...
I've a general question about the space time interval invariance.
Say we have two points A and B, at rest each other, at distance AB.
Now A and B simultaneously in their reference frame emit a flash of light.
The space time interval between these two events is spacelike and equals -(AB)².
Now a fast spaceship C travels from A toward B and is reached by the two flashes at the middle point between A and B. For C the two flashes are not emitted simultaneously, and I want to use the invariance of the space time interval to compute T, that is the difference in time (measured by C) between the two flashes. The distance between A and B measured by C is shortened by the Lorentz contraction: AB_c < AB. The space time interval measured by C should be:
(CT)² - (AB_c)²
and this number should equal -(AB)². It results
(CT)² = (AB_c)² - (AB)² < 0.

So, how can I find T, as a square root of a negative number?

Sorry if the question is stupid...
er

 

[Mentz114]

This is a space-time diagram of your scenario as I understand it. The first is from A and B's rest frame, the second is from the ship frame. I think you can read off the time between flashes on the diagram. The ship is traveling at 0.42c in the A,B frame.

I think you must have made a mistake, if you're trying to take the sqrt of a negative number. With this signature (+,-,-,-) a timelike interval is negative, so just ignore the sign, take the square root, the put the sign back.

 

[ersteller]

Thank you

With this signature (+,-,-,-) a SPACElike interval is negative, and this is our case.

And for sure (CT)² = (AB_C)² - (AB)² IS negative.

What I find very interesting in your answer is when you say: "just ignore the sign, take the square root, the put the sign back"... Really so simple?

Thank you very much!
er

 

[Mentz114]

Thank you

With this signature (+,-,-,-) a SPACElike interval is negative, and this is our case.

And for sure (CT)² = (AB_C)² - (AB)² IS negative.

What I find very interesting in your answer is when you say: "just ignore the sign, take the square root, the put the sign back"... Really so simple?

Thank you very much!
er

I don't know if space-like intervals are invariant ( they are, see below) so ignore my advice.

The flashes are at the same time in the A,B frame (t_A-t_B=0) but clearly not when the diagram is boosted by -0.412c. We're talking about a change in simultaneity here, and I'm not sure how proper length comes into it. I'll try and work it out later.

[later]

Spacelike intervals are invariant, so it seems there's not much point in using one to explain a change in simultaneity. In my diagrams, the interval is sqrt(-100) in both frames. The quantity you want is one side of the triangle that defines the interval.

If two events ( t_A,x_A), (t_B,x_B) are boosted by \gamma the transformed time coords are (Y is gamma, b is beta)

t'_A = Yt_A+Ybx_A
t'_B = Yt_B+Ybx_B

so in your scenario
t'_A - t'_B = Yb(x_A - x_B)

which shows that the change in simultaneity depends on the spatial separation, and the relative velocity.

 

[ersteller]

Thank you.

My point (now) is not to *find* a number, but only to understand: By using the invariance of the spacetime interval, all quantities in SR kinematics can be found, as I've understood. So my question, that perhaps you have already answered, is: Why have I a negative square in this case?
You said: "just ignore the sign, take the square root, the put the sign back" and perhaps this is the simple answer (but I don't really understand WHY...)

Thanks again
er

 

[Mentz114]

Thank you.

My point (now) is not to *find* a number, but only to understand: By using the invariance of the spacetime interval, all quantities in SR kinematics can be found, as I've understood. So my question, that perhaps you have already answered, is: Why have I a negative square in this case?
You said: "just ignore the sign, take the square root, then put the sign back" and perhaps this is the simple answer (but I don't really understand WHY...)

Thanks again
er

The sign of a spacelike interval depends on the signature convention, so there's no harm in changing the sign and then taking the square root and putting sign back.

I still can't see how to get the t'_A - t'_B in my last post without doing a Lorentz transformation. I'll have another try later.

 

[ersteller]

The sign of a spacelike interval depends on the signature convention, so there's no harm in changing the sign and then taking the square root and putting sign back.

Very good! Now I can do my simple calculation without harm!
Thank you!

I still can't see how to get the t'_A - t'_B in my last post without doing a Lorentz transformation. I'll have another try later.

Here perhaps I can help you: From the invariance of the spacetime interval

(CT)² - (AB_c)² = (AB)²

(and without problems arising from the 'negative square'...) one can immediately find T... or not?

Ciao
er

 

[Mentz114]

Very good! Now I can do my simple calculation without harm!
Thank you!
Here perhaps I can help you: From the invariance of the spacetime interval

(CT)² - (AB_c)² = (AB)²

(and without problems arising from the 'negative square'...) one can immediately find T... or not?

Ciao
er

I think that should be

(CT)² - (AB_c)² = -(AB)²

so

(CT)²= (AB)²( 1/(1-b²) - 1 ) = b²Y²(AB)²

as above. But by using a Lorentz contraction, have you not assumed that an LT connects the frames ?

(it's late so don't assume I've done the math correctly).

 

[ersteller]

You're right, I forgot a minus sign...

(CT)² - (AB_c)² = - (AB)²

that is

(CT)² = (AB)² (\frac{1}{\gamma^{2}} - 1) (<0 but no more a problem...)

But by using a Lorentz contraction, have you not assumed that an LT connects the frames ?

Yes, I must admit!
er

 

[Mentz114]

Now I am confused ( nothing new there ). This is wrong

[STRIKE](CT)²= (AB)²( 1/(1-b²) - 1 ) = b²Y²(AB)²[/STRIKE]

but is this ?

t'_A = Yt_A+Ybx_A
t'_B = Yt_B+Ybx_B

so in your scenario
t'_A - t'_B = Yb(x_A - x_B)

Now I have doubts the validity of (AB_C)=1/Y(AB). This sort of length contraction is because the moving frames perception of simultaneity when measuring the ends of a timelike interval. These events are not causally connected so can length contraction be applied ?

 

[ersteller]

These events are not causally connected so can length contraction be applied ?

I guess YES, but is perhaps better to wait for an explanation...

Now I've less doubts, thank you...
er

 

[Mentz114]

This has been resolved in this thread

https://www.physicsforums.com/showthread.php?t=430049

where it is shown that this is correct -

(CT)²= (AB)²( 1/(1-b²) - 1 ) = b²Y²(AB)²

but I couldn't justify it (except that it gives the correct result).