From: Eric Gisse on

Henri Wilson wrote:
> On 22 Aug 2005 16:27:40 -0700, "Jeff Root" <jeff5(a)freemars.org> wrote:

[snip]

>
> A perfect clock should not change its rate no matter what happens to it..
>
> Real clocks as used in the GPS system DO speed up slightly when placed in free
> fall.

Speeding up in proper time? No. Speeding up in observed time? Yes.

> I am merely accepting observed facts.

You accept only the facts that support your worldview, the rest get
handwaved away or ignored.

Read up on one one of the test sattelites for the GPS system. You have
been arguing this for years, you know what I am talking about. I have
mentioned it dozens of times, as have others.

> I suggest that there are several reasons for the change in GPS clocks ...and
> none involves GR.

Just because you say it, doesn't mean it is true. For how many years
will you repeat lies?

Remember Henri, you are irrelevant. Nothing you say or do will ever
influence any physical theory nor the implementation of one. All you
can do is blow hot air.

How are those fabled experiments that you mentioned several months
back? Still in the planning phase? Remember, a month in the lab saves a
day in the library.

>
> >
> > -- Jeff, in Minneapolis
>
>
> HW.
> www.users.bigpond.com/hewn/index.htm
>
> Sometimes I feel like a complete failure.
> The most useful thing I have ever done is prove Einstein wrong.

From: Jeff Root on
Henri Wilson replied to Jeff Root:

>> Moving the portable clock also has no effect on the period of
>> that clock. It continues to keep perfect time. It is an ideal
>> clock, made by Santa Claus under God's direct supervision, so
>> it keeps perfect time nomatter what happens to it or what kind
>> of environment it is in. Heat and cold, electric fields,
>> magnetic fields, high g forces-- nothing affects the perfect
>> accuracy of this clock.
>>
>> Actually, the best real clocks come very, very close to that
>> ideal. They are tested under all kinds of extreme conditions,
>> and if any variation is detected, the design is changed so the
>> condition no longer causes any variation. The testing never
>> stops, either. The clocks continue to be carefully tested
>> years after they've been made. They are used every day for
>> all kinds of precision measurements, positioning, and finding
>> exact locations of things, often to within a few inches, all
>> around the world. So it is very important that they be both
>> accurate and precise, to do the jobs they're used for.
>>
>> You suggested above that the portable clock might tick some
>> number of times per shaft rotation when at the bottom of the
>> shaft, and a different number of times per shaft rotation when
>> at the top of the shaft. I'm going to ask you:
>>
>> What makes you think that the clock might tick a different
>> number of times per shaft rotation depending on where it is?
>
> A perfect clock should not change its rate no matter what
> happens to it..

Right.

> Real clocks as used in the GPS system DO speed up slightly when
> placed in free fall.

What makes you think that?

> I am merely accepting observed facts.

Which are... what? Spell out those "observed facts" for me.

-- Jeff, in Minneapolis

From: jgreen on

Jeff Root wrote:
> Henri Wilson replied to Jeff Root:
>
> > >> Jim has every right to assume that most contributors to this
> > >> NG have some kind of intelligence which enables them to
> > >> occasionally apply their own deductive powers in cases when
> > >> every minute detail is not spelled out as though for a 2yo
> > >> kid..
> > >
> > > Sure. But it still isn't clear what he meant by "two clocks",
> > > or how those two clocks are connected to the axle. George
> > > guessed that each of the two clocks has its own motor or other
> > > mechanism to make it run, since that is what makes them clocks.
> > > I, on the other hand, guess that Jim was talking about clock
> > > hands at each end of the axle, being driven by the rotation
> > > of the axle, which is, in turn, driven at its bottom end.
> > >
> > > George's guess may be right, or mine, or maybe both are wrong
> > > and Jim's concept is something else. Only Jim can say.
> >
> > If you have been following my discussion with George Dishman, you
> > would know what Jim and I mean.
> >
> > The rotation of the shaft itself can be used as a fixed time
> > duration reference.
>
> That was my guess of what Jim was trying to say. The rotating
> shaft, or axle, serves as a clock. However, when I suggested
> that to him, he replied that there are definitely two clocks:
> one at the bottom of the axle and one at the top. So it isn't
> clear what he really meant.
>
> > Its period doesn't need to be measured by any clocks. It can
> > be assigned the value of ONE time unit. If each of its ends is
> > connected to a rotating 'hand', the two hands must always be
> > rotating at the same angular speed and will both remain in
> > absolute synch.
>
> I agree, given certain certain restrictions on exactly what
> you mean by "angular speed" and "synch". The simplest way to
> do it would be for the 'hands' to just be marks on the side of
> the rotating axle-- or just a stripe running up and down the
> side of the axle. An ideal observer at the bottom would see
> the stripe twisted slightly by the time delay of the light
> from more distant parts of the axle taking longer to reach him,
> as Jim pointed out to me, but of course that twist is constant
> when the axle is rotating at constant speed, and it is only a
> simple illusion, not an actual twist in the axle. It isn't
> the effect you and Jim are interested in.

>
> Given that situation, the stripe will actually always be
> exactly straight up and down. The top end of the stripe will
> always be directly above the bottom end. Although an observer
> at the bottom will see the top end lagging behind slightly,
> and an observer at the top end will see the bottom lagging
> behind slightly. An observer at the middle will see both ends
> lagging behind slightly.

> Question: If I asked these observers what was the TRUE nature of the line, should they not ALL use their "knowledge", and agree that the line is straight and vertical?
ie, observers can be MISTAKEN in what they see, and draw WRONG
conclusions.

Apart from that, you misunderstand; I say if time is passing at a
different rate, the twist will INCREASE if GR is correct. ie a constant
force must be acting to slow one end.

> > The shaft's period can be assigned the value ONE at both top
> > and bottom.
>
> Again I agree, with certain restrictions. The restrictions
> happen to be crucial to understanding what is going on, but
> I'm going to put off discussing them until we are sure we
> agree on the more basic aspects.
>
> > If a clock is sent from the bottom to the top and emits a
> > different number of ticks per shaft rotation at each location,
> > then the clock has obviously suffered some kind of physical
> > change as a consequence of being moved. The shaft period
> > certainly didn't change just because a clock was sent from one
> > end to the other.
>
> Okay. Your version of the thought experiment has two separate
> 'clocks': one is the huge, rotating axle, turning at a constant
> rate; the other is portable, ticking at a constant rate.
>
> I agree that moving a clock or an observer from one place to
> another has no effect on the period of the rotating axle.
> It seems awfully silly to say that it does. Sometimes when
> people say things that sound silly, or ridiculous, it is
> because they are speaking in their own dialect, and not yours.
> You might both think you are speaking the same language, and
> not even realize that you are using two different dialects,
> each with its own set of meanings. So what someone says in
> his own dialect can make perfect sense in that dialect, and
> sound like nonsense in the other.
>
> I'm attempting to communicate with you in your dialect.
>
> I agree that moving from place to place has no effect on the
> axle. That isn't much, but it is something we can agree on.
>
> Moving the portable clock also has no effect on the period of
> that clock. It continues to keep perfect time. It is an ideal
> clock, made by Santa Claus under God's direct supervision, so
> it keeps perfect time nomatter what happens to it or what kind
> of environment it is in. Heat and cold, electric fields,
> magnetic fields, high g forces-- nothing affects the perfect
> accuracy of this clock.

OK; You say two clocks, connected top and bottom are really only ONE,
so I will ignore the top one, as it always reads the same as the
bottom. Now let's look at the atomic clock floating about near the top
one! What will it read after a lapse??

(attn George)
Once the axle is spinning, let it rotate on frictionless bearings, with
very energy efficient clocks (or one with hands at each end of the
axle, if you prefer). No motors now driving- why a twisting?
>
> Actually, the best real clocks come very, very close to that
> ideal. They are tested under all kinds of extreme conditions,
> and if any variation is detected, the design is changed so the
> condition no longer causes any variation. The testing never
> stops, either. The clocks continue to be carefully tested
> years after they've been made. They are used every day for
> all kinds of precision measurements, positioning, and finding
> exact locations of things, often to within a few inches, all
> around the world. So it is very important that they be both
> accurate and precise, to do the jobs they're used for.

Not worth a pinch of rocking horse manure!
If GR is correct, they will even vary with the moon's position, not to
mention the sun etc. It follows, that if these clocks are NOT altering
their periods, points on the earht's crust must be changing velocity
(speed). I doubt that this causes earthquakes.
>
> You suggested above that the portable clock might tick some
> number of times per shaft rotation when at the bottom of the
> shaft, and a different number of times per shaft rotation when
> at the top of the shaft. I'm going to ask you:
>
> What makes you think that the clock might tick a different
> number of times per shaft rotation depending on where it is?

Because Henri (devil's advocate) Wilson realises (sigh), that IF real
time is passing at a DIFFERENT rate with altitude, THAT is absolutely
required.

Jim Greenfield
c'=c+v

From: bz on
"Jeff Root" <jeff5(a)freemars.org> wrote in news:1124860833.471978.230810
@g43g2000cwa.googlegroups.com:

> Right.
>
>> Real clocks as used in the GPS system DO speed up slightly when
>> placed in free fall.
>
> What makes you think that?
>
>> I am merely accepting observed facts.
>
> Which are... what? Spell out those "observed facts" for me.
>

http://groups-
beta.google.com/group/sci.physics.relativity/msg/381bfc0f1f69748e?
dmode=source&hl=en

--
bz

please pardon my infinite ignorance, the set-of-things-I-do-not-know is an
infinite set.

bz+nanae(a)ch100-5.chem.lsu.edu
From: Paul B. Andersen on
Henri Wilson wrote:
> On Mon, 22 Aug 2005 10:40:34 +0200, "Paul B. Andersen"
> <paul.b.andersen(a)deletethishia.no> wrote:
>
>
>>Henri Wilson wrote:
>>
>>>The rotation of the shaft itself can be used as a fixed time duration
>>>reference.
>>>Its period doesn't need to be measured by any clocks. It can be assigned the
>>>value of ONE time unit. If each of its ends is connected to a rotating 'hand',
>>>the two hands must always be rotating at the same angular speed and will both
>>>remain in absolute synch.
>>>
>>>The shaft's period can be assigned the value ONE at both top and bottom.
>>>
>>>If a clock is sent from the bottom to the top and emits a different number of
>>>ticks per shaft rotation at each location, then the clock has obviously
>>>suffered some kind of physical change as a consequence of being moved. The
>>>shaft period certainly didn't change just because a clock was sent from one end
>>>to the other.
>>
>>Why is that obvious, Henri?
>>Why do you find it impossible that the shaft simply IS rotating
>>at a different rotational frequency at different heights?
>>It doesn't help that YOU call one rotation "one time unit",
>>if the lengths of those "time units" are different when
>>measured by local clocks, does it?
>
>
> It depends on how difficult you want life to be.
>
> You can either take the simple attitude that "the period of Jupiter represents
> a constant duration of time " or you can become quite absurd and claim that "it
> changes depending on how it is measured", ....whether you use a cesium clock or
> an egg timer..
>
> You people seem obsessed with measurement. Don't you inderstand that the
> universe functioned perfectly well before human eyes even evolved?
>
> Time exists without human life.
> Jupiter rotated well before the Earth cooled.
> Its rotation period has occupied a fairly constant length of time ever since.
> It can be used safely as an 'absolute' time standard.
>
> So let's just define it as ONE TIME UNIT.
>
>
>>The only kind of "time" of interest in physics is the "time"
>>that have physical consequences, and determines the pace of
>>local physical processes such as clocks.
>
>
> The definition of Jupiter's period as ONE TIME UNIT has EXTREME PHYSICAL
> SIGNIFICANCE.

To Jupiter.
But it is of no use if you want to boil your eggs.
Then you will have to use a local clock running with
the pace governed by the same laws of physics which
determine the coagulation of your egg.

Paul