From: PD on
On Feb 18, 3:19 pm, Ste <ste_ro...(a)hotmail.com> wrote:
> On 18 Feb, 18:40, PD <thedraperfam...(a)gmail.com> wrote:
>
>
>
> > On Feb 18, 11:24 am, Ste <ste_ro...(a)hotmail.com> wrote:
>
> > > On 18 Feb, 14:34, PD <thedraperfam...(a)gmail.com> wrote:
>
> > > > On Feb 18, 8:25 am, Ste <ste_ro...(a)hotmail.com> wrote:
>
> > > > > > Let's make this a little more concrete. Let's say that S1 and S2
> > > > > > flash, emitting pulses that radiate in all directions, and that the
> > > > > > detectors intercept a portion of the light from those pulses. (If you
> > > > > > want, think of S1 and S2 as firecrackers.)
>
> > > > > No, because that needlessly complicates the matter. The important
> > > > > thing is establishing where a single photon would land.
>
> > > > Yes, it complicates the matter because you haven't specified which
> > > > photon. Do you mean the one that is aimed at the detector when fired
> > > > but does not hit it because of the acceleration of the detector, or do
> > > > you mean the one that is not aimed at the detector when fired but DOES
> > > > hit it because of the acceleration of the detector? This is important,
> > > > you see, because if you restrict the attention to one of those, you
> > > > might get the (false) impression that the detector sees no light at
> > > > all.
>
> > > Well I'm assuming that the source emits one photon at a time. And of
> > > course I refer to the photon that is aimed at the detector when fired,
> > > but does *not* hit due to the acceleration of the detector.
>
> > Ah, ok, then I have no objection to your conclusion, although I have
> > no idea what you hope to learn about relativity about such a scenario.
>
> I'm basically trying to figure out how light can possibly travel at a
> constant speed, or at least *appear* to do so, when measured from any
> frame.

Then losing photons by letting them miss detectors will not tell you
that. What you need to do is capture light with the detectors and use
the information from the light captured to tell you the speed with
which it arrived. Surely you see that. This is why I suggested you
consider the less abstract and more concrete case of the sources being
firecrackers, you see. :>)
From: paparios on
On 18 feb, 18:19, Ste <ste_ro...(a)hotmail.com> wrote:
> On 18 Feb, 18:40, PD <thedraperfam...(a)gmail.com> wrote:

>
> > Ah, ok, then I have no objection to your conclusion, although I have
> > no idea what you hope to learn about relativity about such a scenario.
>
> I'm basically trying to figure out how light can possibly travel at a
> constant speed, or at least *appear* to do so, when measured from any
> frame.

Carl Sagan, in his book Cosmos (chapter 8), gives the following
example, which may serve to you:

"...Imagine that I am riding a bicycle toward you. As I approach an
intersection I
nearly collide, so it seems to me, with a horse-drawn cart. I swerve
and barely avoid being
run over. Now think of the event again, and imagine that the cart and
the bicycle are both
traveling close to the speed of light. If you are standing down the
road, the cart is traveling
at right angles to your line of sight. You see me, by reflected
sunlight, traveling toward
you. Would not my speed be added to the speed of light, so that my
image would get to you
considerably before the image of the cart? Should you not see me
swerve before you see the
cart arrive? Can the cart and I approach the intersection
simultaneously from my point of
view, but not from yours? Could I experience a near collision with the
cart while you
perhaps see me swerve around nothing and pedal cheerfully on toward
the town of Vinci?
These are curious and subtle questions. They challenge the obvious.
There is a reason that
no one thought of them before Einstein. From such elementary
questions, Einstein
produced a fundamental rethinking of the world, a revolution in
physics...."

Miguel Rios
From: JT on
On 18 Feb, 22:56, "papar...(a)gmail.com" <papar...(a)gmail.com> wrote:
> On 18 feb, 18:19, Ste <ste_ro...(a)hotmail.com> wrote:
>
> > On 18 Feb, 18:40, PD <thedraperfam...(a)gmail.com> wrote:
>
> > > Ah, ok, then I have no objection to your conclusion, although I have
> > > no idea what you hope to learn about relativity about such a scenario.
>
> > I'm basically trying to figure out how light can possibly travel at a
> > constant speed, or at least *appear* to do so, when measured from any
> > frame.
>
> Carl Sagan, in his book Cosmos (chapter 8), gives the following
> example, which may serve to you:
>
> "...Imagine that I am riding a bicycle toward you. As I approach an
> intersection I
> nearly collide, so it seems to me, with a horse-drawn cart. I swerve
> and barely avoid being
> run over. Now think of the event again, and imagine that the cart and
> the bicycle are both
> traveling close to the speed of light. If you are standing down the
> road, the cart is traveling
> at right angles to your line of sight. You see me, by reflected
> sunlight, traveling toward
> you. Would not my speed be added to the speed of light, so that my
> image would get to you
> considerably before the image of the cart? Should you not see me
> swerve before you see the
> cart arrive? Can the cart and I approach the intersection
> simultaneously from my point of
> view, but not from yours? Could I experience a near collision with the
> cart while you
> perhaps see me swerve around nothing and pedal cheerfully on toward
> the town of Vinci?
> These are curious and subtle questions. They challenge the obvious.
> There is a reason that
> no one thought of them before Einstein. From such elementary
> questions, Einstein
> produced a fundamental rethinking of the world, a revolution in
> physics...."
>
> Miguel Rios

Muhahahahah yeah the physic of i did not see it coming, you are
hilarious.

JT
From: Inertial on


"Ste" <ste_rose0(a)hotmail.com> wrote in message news:0e2132fc-921d-4b19-867f-48f47188b266(a)l19g2000yqb.googlegroups.com...
> On 17 Feb, 21:12, "Inertial" <relativ...(a)rest.com> wrote:
>> "Ste" <ste_ro...(a)hotmail.com> wrote in message
>>
>> >> > Now, let us suppose we have two source and two detectors again:
>>
>> >> > D1 D2 D3
>>
>> >> > S1 S2 S3
>>
>> >> > S1 and D1 are stationary in the frame, and do not move. D2 is also
>> >> > stationary in the frame. S2, S3, and D3 are all moving in the y+
>> >> > direction (i.e. same as the previous scenario) at a constant speed
>> >> > (which is close to 'c'). Just to be sure we understand, the same setup
>> >> > a few moments back in time would have looked like this:
>>
>> >> > D1 D2
>>
>> >> > D3
>>
>> >> > S1
>>
>> >> > S2 S3
>>
>> >> Your diagram contradicts your description .. you show in the diagram that
>> >> S1
>> >> and D1 have moved apart (as have S3 and D3), but you said they do not.
>> >> D3,
>> >> S2 and S3 have also moved to the left. I think you need to draw your
>> >> diagram again.
>>
>> > No, I think you need to look at the diagram in a monospaced font.
>>
>> I did and am. I suggest YOU look at what YOU posted. Having an extra line
>> between the D1 line and the S1 line has nothing to do with fonts.
>
> There is no "extra line".

Yes .. there is. Your denials don't help fix the problem

> D3 is moving with S2 and S3 (and D3 should
> be in line with S3).

Here is what you posted

===
D1 D2 D3



S1 S2 S3
===

Notice: three lines between D1 and S1 (and D3 and S3)

then

===
D1 D2

D3


S1

S2 S3
===

Four lines between D1 and S1. That is an EXRTA LINE that shows D1 and S2 moving apart (same for D3 and S3)

I apologise for the incorrect claims about S2 being in the wrong place ... that must have only been a glitch in my newsreader .. looking at your original source it is ok

Just try to take more care next time so that your diagrams are not misleading
From: JT on
On 14 Feb, 20:42, Ste <ste_ro...(a)hotmail.com> wrote:
> No takers for this simple question then?
>
> Consider this setup:
>
> S1   D2
>
> D1   S2
>
> We've got sources S1 and S2, paired with detectors D1 and D2. They're
> all mechanically connected, so that a movement in one of them
> produces
> a movement in all the others - in other words, their relative
> distances are always maintained. Each source is transmitting a
> regular
> pulse of light to its counterpart detector (so S1 is transmitting to
> D1, etc.), and both sources are transmitting simultaneously with each
> other.
>
> Now, we calculate that a pulse has just been emitted from both
> sources, and we suddenly accelerate the whole setup "upwards" (i.e.
> relative to how it's oriented on the page now) to near the speed of
> light, and we complete this acceleration before the signals reach
> either detector.
>
> Now, do both detectors *still* receive their signals simultaneously,
> or does one receive its signal before the other? And are the signals
> identical, or do they suffer from Doppler shifting, etc?

Imagine this...
Imagine object A and B travelling parallell vectors in space, A
travels 0.1 c and B travel 0.9 c.

For some reason the both pass lined up between sensor C and D at same
moment x, when the sensor beams reach their front both ships emit one
puls forward and one puls backward.


The four lightpulses can not possible travel invariant thru the space
of C and D, for them to travel invariant in C and D space the two
backward pulses must travel aligned and parallell forever and so must
the two front pulses.


And if they do there something weird going on within A and B,
especially the light do not spread uniform around B the light puls
infront is contracted and expands at c-v=0.1 c relative restframe B
in
the space and the lightfront at back expands at 1.9 c relative B.


The expansion of the two lightpulses is not uniform and invariant in
frame B unless there is shorter meters at the front then at the back.
At even higher velocities like 0.999... c the deformation is even
clearer.


For example consider that the two light pulses have been travelling
for a year after B passed between C and D and emitted the two pulses
now B suddenly come to halt/stop. Now anyone must surely realise that
the pulses never traveled invariant at B and at speed c to begin
with.
One pulse is a lightyear away the other one is just in front off B.


The assertions of SR is ridculous i would go so far to say they are a
deliberate hoax.


JT