It has already happened 3 times and all Orogenesis are consecutive to
Moon crash on this Earth !
( Caledonian, Hercynian & Alpine orogenesis 120 centuries ago )
The last time it was 11700 years ago indeed right in the middle of
the Pacific at the geometric centre of what is known now as the
Pacific Ring of Fire.
( when the Sun was in the Lion hence the Sphinx symbol made by the
Antediluvian meaning that anticipation of that event )
The present fraud masquerading as Geology is unable to understand
first the real environment of pressure into which we are immersed
... then where from we come and where we are heading to ...
Nor of course the origin of forces putting us in motion every minutes
since birth of Planet from the Sun a mere 170 millions years ago and
its consecutive drift on the plane of Ecliptics towards Pluto ever
since !
I have a simple suggestion to you so as to bring a permanent answer to
your well commendable questioning, next time don't ask one of those
Universilities brainwashed idiots masquerading as Geologist or Science
Teacher, ask instead the rocks in the fields, the strata's of
alternate Carbonate & Clay bedding, the folded bedding seen in the
apparent Relief !!! Ask a toad or a frog for a better answer as to why
they are such ... ask fossils why they are imbedded in vertical
positions in the 1000 m thick Red Sandstone of Scotland with all their
colours of scales & freshness of eyes maintained intact !
... of course for economic reasons learn the idiocies foraged down
your throat by the sycophants of that fraudulous alleged Geology
science , but don't trust them at all with their narrow views and
short minded answers LEARN BY YOURSELF AND NEVER TRUST ANY OF THAT
UNIVERSILITIES RABBLE
Indeed they are unable on some other fields to cure their very own
diseases ... the ones they pretend to cure in others !
With kindest regards
Sir Jean-Paul Turcaud
Exploration Geologist & Offshore Consultant
Mobile +33 650 171 464
Australia Mining Pioneer
Founder of the True Geology
http://www.tnet.com.au/~warrigal/grule.html
http://users.indigo.net.au/don/tel/index.html
http://members.iimetro.com.au/~hubbca/turcaud.htm
http://www.abc.net.au/rn/talks/bbing/stories/s28534.htm
> ( when the Sun was in the Lion hence the Sphinx symbol made by the
> Antediluvian meaning that anticipation of that event )
WTF?
A mere technically, since the barycenter of all the planets of the solar
system lies within the interior of the sun.
߃--¹¹
Not always. The barycenter of the solar system sometimes
lies outside the Sun. This occurs, for example, when an
alignment of several planets including the Giants takes
place in a given region of the ecliptic.
Yes. The center of mass of Jupiter and the Sun lies outside the Sun --
742300 km or 1.066 radii from the center of the Sun.
The barycenter shift for Saturn is 0.587 solar radius, for Neptune
0.333 solar radius, for Uranus 0.180 solar radius, and the others are
even less. (All of 9.6 km for Mercury!)
So when Jupiter and Saturn have roughly the same heliocentric longitude,
the barycenter can be several hundred thousand km outside the Sun; when
they're opposite, the barycenter will be inside the Sun.
Interpolating JPL's DE410 ephemeris at 5-day intervals over its 120-year
time span (1900 to 2019) shows that the Solar System barycenter is
outside the Sun just over 60% of the time.
-- Bill Owen
ßf--¹¹
A mere technicality, Sol and Luna move against the fixed stars
and are wanderers, therefore "planets".
So is Barnard's Planet, Halley's Planet, Pluto, ISS... nothing is fixed,
everything is a planet.
Saul Levy
I was pleased to read the different answers from the gutless
australian turds ...it can be noted indeed that the shithead
Antipodean beasts remain carefully anonymous, expound their ignorance
shamelessly, repeat like the toads they are what has been foraged in
their thick degenerate morons 's skulls by the official bodies of
deceit & official Geology teaching institutions such as Curtin,
Monash, Sydney Universities & the ANU in Canberra. In brief they
demonstrate to the world at large what a congregation of hopeless
froggish australian Toads they are, and what Hell it is to go to such
debased country & what shame it is to have achieved some exceptional
feats of geological intelligence, courage, abnegation, sacrifice
indeed for such australian manure to benefit in centuries to
come !!!
. Never any of those fatly paid Universilities parasites, by the
way, has ever questioned a single one of their infinitively hopeless
theories whatever ! Indeed according to their Sci000nce the Earth was
'Created' by accretion of banging meteorites following that famous Big
Bang
NOTE
( ou Gros Boum ! ... oh la la, Quelle Grande Intelligence Révélée en
cela par les Bètes Intellectuelles ! )
( of what great & amazing discoveriezzz are able all those
Intellectual Beasts rooming the campus & paddocks of Oxford, Caltech,
ze MITH or the ANU ... I am flabbergasted !!!)
Any child of 4 knowns that explosion following firing is not going to
put together material blasted away in the process ... to bring it back
together again compression factors SUPERIOR to the original
environment are required ... but the Universilities brainwashed beasts
making profession indeed of high learning of course superbly ignore
this !
All through my personal scrutiny of official Geology theories* , I
have discovered that not only all were not only false without
exception & moreover misleading, but further infantile attempts by
primitive & crude minds to adapt what the blinded fools were seeing to
reach interpretation of past events having modelled Relief ... What I
have discovered in fact are not so much the overall fraud related to
that ridiculous circus of Intellectual Geology Clowns indeed, but the
fact that the same childish inductive or deductive mechanical logic or
say dishonest sophisms were the basis of all Certitudes of that
present alleged knowledge on our History & the History of our Solar
System ... further still I have found the same flaws in awareness &
reasoning in all the other Intellectual beasts making profession of
knowledge in other fields like chemistry, palaeontology, archaeology,
medecine etc
The noted beliefs of all religious sects is a good indicator of the
state of degeneracy & easy mind programming of the Human Race ....
just to realise that such Human Animal 's immediate response to any of
his fears & questioning is bleating prayers is in this a strong
confirmation that the COUNTRY OF THE BLIND well described by H.G Wells
in that short novel of that name, is a perfect analogy of a state of
affairs extending to the whole world indeed !
What are the reasons ? ...what are the causes ? ... what are the
remedies ?
It is not opportune to discuss this now .... indeed some good &
appropriate chastiment are required before that .
* Information or Geological teaching is made of 3 elements :
1) Sur-information of redundant material comforting official
beuuliefs ,
2) Dis-information especially by play on word like by ex: Erosion. Of
course there is erosion of carbonates, oxides by water, and as well
secondary erosion of unconsolidated sedimentations ... but the
Original erosion of intrusive or extrusive rocks structures by water
since Water does not dissolve silicates ....& certainly not under
current pressure & temperature systems, and the millionzzz of yearzzz
are no operative factors non obstant the affirmation of the
Universilities Intellectual beasts TIME DOES NOT ERODE.
3) Non-information on any things infirming the official blind fools '
established theories, like by ex. the Glaciations theories where the
mere PRESSURE POINT OF FUSION OF ICE prevents indeed any pretension of
having such alleged erosion of rock formation by such weak tools ! Why
not use wrenches make of butter & ice scream .... it would lead any
fitter or tradesman to laugh his head off at the jokes ... but nothing
of the kind would move the Oxford, Curtin or ANU sci000ntific beasts
from their certitudes indeed !
Nom de Dieu... mais c'est pas possible !!!
He means he doesn't know!
>On 9 fév, 03:47, effac...@hotmail.com wrote:
>> I asked a science prof if the moon will eventually move away or into
>> the earth.
>>
>> He said neither, it will remain revolving the earth for eternity.
>>
I'm told the moon moves further away from the Earth by 2 inches per
year, apparently due to the loss of energy due to the tides on Earth.
However, wouldn't it take an energy GAIN in order to move a body
further away? Ideas?
Stan
The Moon is gaining part of the energy that the Earth loses.
Bud
--
The night is just the shadow of the Earth.
Yes, as the radius increases, the kinetic energy actually
decreases but the gravitational potential energy increases
at twice the rate. The energy comes from the spin of the
Earth so the day gets slightly longer.
The answer to the original question is that the Moon
is slowly moving away but the Earth's rotation will
slow until it becomes tidally locked at which point
the Moon's orbit would cease to increase. However,
the Sun will swell into a giant before that happens.
George
Would I be wrong to say that the Earth would only slow down to the
point that it equals the moon's period around us?
Stan
> Thanks George. If we could figure out how much energy was in the
> Earth's spin, then would it be possible to figure out hypthetically
> how much further away the moon could go? Assuming circular orbit, no
> effects of other bodies, etc.
Roughly, yes.
> Would I be wrong to say that the Earth would only slow down to the
> point that it equals the moon's period around us?
Yes, that's what I meant by "tidally locked" in the second
paragraph (restored above).
There are three components to the total angular momentum of
the system, that of the Earth due to its spin, that of the
Moon around the Earth (by far the largest) and a small
contribution from the Moon which is rotating once a month
as it is already locked to the Earth.
Angular momentum is conserved and the final orbital period
can be determined by finding value when both bodies are
locked to each other. Once you know the period, the radius
follows and hence energy.
George
LOL The moon maybe round, but a giant beach ball .. only three bounces
to date?
Only 12000 years ago too!
Nothing to do with it.
The moon is moving further away from the earth, as the earth transfers
angular momentum (and energy) to the moon via tidal forces. The earth-moon
distance increases, as does the length of a day.
Its pretyy easy to work out exactly where it will end up - the final
position is where the earth and moon keep the same face to each other (ie
where a day equals a month). This is easy to calculate through conservation
of angular momentum, this allows the final distance from the earth to the
moon to be calculated, though working out how long it takes is way harder.
It's pretty easy to guess where it will end up, and your guess isn't
a good one.
http://antwrp.gsfc.nasa.gov/apod/ap051113.html
This is easy to calculate through conservation of angular momentum,
this allows the final distance from the earth to the moon to be
calculated, though working out the eccentricity of the orbit is
beyond your guess.
Ok let's say the moon breaks up first before it hits the earth. It
still hits.
What keeps the moon away from the earth other than centripital force?
Thanks,
Steve
>> The Roche Limit. The closest distance at which a natural satellite can
>> orbit a planet without being broken up by the planet's gravitational
>> field, i.e. tidal forces. Look it up on Google.
> Nothing to do with it.
Agree.
> The moon is moving further away from the earth, as the earth transfers
> angular momentum (and energy) to the moon via tidal forces.
We're back to tides again?
>The earth-moon distance increases, as does the length of a day.
>
> Its pretyy easy to work out exactly where it will end up - the final
> position is where the earth and moon keep the same face to each other (ie
> where a day equals a month). This is easy to calculate through conservation
> of angular momentum, this allows the final distance from the earth to the
> moon to be calculated, though working out how long it takes is way harder.
So the earth is rotating slower and slower and may eventually stop and
face the moon permanently. How does this lessen earth's gravitational
force? Gravity is a function of rotation? A gyro effect won't play a
role since the moon is not part of the earth's gyro equation.
So by this theory, if a huge star spins fast enough it loses most all
of its gravitational force acting on neighboring bodies. That doesn't
compute.
Thanks,
Steve
> It's pretty easy to guess where it will end up, and your guess isn't
> a good one.
> http://antwrp.gsfc.nasa.gov/apod/ap051113.html
Nice time lapse shots of the entire moon day cycle. Didn't know the
moon swayed like that. It's not as static as I thought. Interesting.
Thanks!
> This is easy to calculate through conservation of angular momentum,
> this allows the final distance from the earth to the moon to be
> calculated, though working out the eccentricity of the orbit is
> beyond your guess.- Hide quoted text -
>
> - Show quoted text -
And your guess is?
Thanks,
Steve
Actually, the force that stops the moon from flying away is gravity. If
gravity was to be suddenly abolished the moon would travel away from the
earth along a tangent to its orbit. It is only gravity pulling it
towards the earth that causes it to swing around in an orbit. There is
no force keeping the moon away from the earth.
Cheers,
Cliff
--
Have you ever noticed that if something is advertised as 'amusing' or
'hilarious', it usually isn't?
You can even measure the major/minor axis ratio and compute
eccentricity from that if you notice the change in apparent size.
>> This is easy to calculate through conservation of angular momentum,
>> this allows the final distance from the earth to the moon to be
>> calculated, though working out the eccentricity of the orbit is
>> beyond your guess.- Hide quoted text -
>>
>> - Show quoted text -
>
> And your guess is?
Sorry, I never guess. Anyway, who is going to be around long
enough to verify it?
But don't you find it curious that all planetary orbits are nearly
circular rather than highly elliptical as a comet's?
(Except Pluto/Charon of course, but that is probably a captured
comet anyway.)
The inference is the solar system as a whole has had enough time
to settle down, the most eccentric planet being Mercury and
that is advancing its longitude of perihelion as Jupiter, Venus
and the Earth drag it along. Mars is too small and too far away
to have as much effect as the other three.
http://faculty.ifmo.ru/butikov/Projects/Collection1.html
Example 5 gives a clear indication of the result, example 3
what could happen with a spacecraft in Lunar orbit, Example 9
gives you Shoemaker Levy.
Example 10 is fascinating because it appears at first to be stable.
Collection3 is mind boggling.
Ha ha. The wobbling you think you see is a result of the inclination of the
earth's axis affecting the time lapse photography. The effect is due to the
camera moving, not the earth.
>> This is easy to calculate through conservation of angular momentum,
>> this allows the final distance from the earth to the moon to be
>> calculated, though working out the eccentricity of the orbit is
>> beyond your guess.- Hide quoted text -
It won't be particularly eccentric. Its current very slight eccentricity
will be smoothed out as the earth-moon distance increases.
>>
>> - Show quoted text -
>
> And your guess is?
>
> Thanks,
> Steve
>
The moon is retreating from the earth at about 3.8 cms per year (see
http://en.wikipedia.org/wiki/Lunar_distance_%28astronomy%29
As I said, its easy to work out the distance it will eventually reach
through conservation of angular momentum. With the benefit of the LIDAR
experiments, the time frames can be estimated but not precisiely defined
(unlike the terminal distance, which can be easily calculated).
You have badly mangled some physics concepts.
Why don't you first satisfy yourself that the moon is actually retreating
from the earth, for example by Googling Earth-Moon distance or LIDAR?
Once we have established that it is an astronomical fact that the moon's
orbital distance is increasing (and has done so since it was formed), we can
discuss the physics of why it happens, which are reasonably straightforward.
I cited the Roche Limit in the sense that the moon can't notionally collide
with the Earth as a result of orbit decay; at least in 1 piece it can't. I'm
aware that it is, in reality, moving away.
Seeing more than 180 degrees of the Moon's surface is caused by
the Earth's axis?
>
>>> This is easy to calculate through conservation of angular momentum,
>>> this allows the final distance from the earth to the moon to be
>>> calculated, though working out the eccentricity of the orbit is
>>> beyond your guess.- Hide quoted text -
>
> It won't be particularly eccentric. Its current very slight eccentricity
> will be smoothed out as the earth-moon distance increases.
What is its current slight eccentricity?
>
>
>>>
>>> - Show quoted text -
>>
>> And your guess is?
>>
>> Thanks,
>> Steve
>>
>
> The moon is retreating from the earth at about 3.8 cms per year (see
> http://en.wikipedia.org/wiki/Lunar_distance_%28astronomy%29
>
> As I said, its easy to work out the distance it will eventually reach
> through conservation of angular momentum.
Well, it is so easy, what is it?
> With the benefit of the LIDAR
> experiments, the time frames can be estimated but not precisiely defined
> (unlike the terminal distance, which can be easily calculated).
>
Yeah yeah... what is this easy calculation you can do through conservation
of angular momentum, as you said you can?
<snip>
>
> So the earth is rotating slower and slower and may eventually stop and
> face the moon permanently. How does this lessen earth's gravitational
> force? Gravity is a function of rotation?
Not at all. According to Newton's theory, gravity is a function of mass
and distance only; the configuration and motions of a body have no
effect on its gravity. The only way to generally "lessen earth's
gravitational force" would be to reduce its mass.
--
Odysseus
Yeah yeah... what is this easy calculation you can do through conservation
of angular momentum, as you said you can?
**********************
Do you first agree that the moon is actually moving away from the earth?
And that there will be an orbit it asymptotically approaches? (Equivalently,
whatever it is that is causing its orbital distance to increase will not
impart enough energy for it to escape the earth entirely?).
If the answers to both of these are yes, then:
The Earth has some angular momentum that could be calculated. I won't, as
the density of the earth varies with depth, so its a tedious arithmetic
calculation. Lets call it E.
So has the moon; this is easier as the major contributor to its angular
mamoentum is its movement around the earth. Lets call it M. Again, easily
calculated.
So the current total angular momentum is M + E.
When the two are in lock step and showing the same face towards each other
at all times, the total angular momentum will still be M + E (as it is
conserved).
As they are showing the same faces to each other, the period of rotation of
each will be the same. Let the common point they rotate about be "d_e" from
the earth and "d_m" from the moon. Let m_e be the mass of the earth and m_m
the mass of the moon.
Then:
(d_e)^2 * m_e + (d_m)^2 * m_m + some components related to the individual
rotational speeds of the earth and the moon= E+M
You get a second equation linking the rotational speeds to the distance
apart using conservation of energy and Newtons law of gravity.
Two equations and two unknowns (d_e and d_m). The earth-moon distance will
simply be d_e + d_m.
You should be able to find a link where somebody has dones the calculation
... its absolutely straightforward, but tedious to compute accurately
without knowing the approximate density at different depths of the earth.
For the theory, see http://en.wikipedia.org/wiki/Angular_momentum or Google
"angular momentum".
Like many uses of Conservation theories, this tells you what will happen,
but not how long it will take - the whole point about conserved quantities
is that they don't vary over time ...
The rise and fall of the tides are a function of rotation (according to
Newton's theory).
Hey fuckhead! I neither agree nor disagree! Just prove you can do it.
Show us this easy calculation you can do through conservation of angular
momentum, as you said you can.
Suppose the Earth was one solid rock, and we had no oceans, and the
moon was in a circular orbit. I'm presuming that the distance from
the earth to the moon would remain the same, and we would continue to
have our 24 hour or so period.
Now we add oceans (and take away an equal amount of rock, and preserve
mass, angular momentum etc). Now we expect the moon to slowly move
away from earth. This must be due to a decrease in gravity, which has
to balance centripetal force for a circular orbit, right?
Yet the effect of the moon's gravity is to pull some water up toward
it, moving the Earth's center of gravity closer to the moon, and hence
making gravity stronger....
So how do we explain the reason the moon is slowly receding? I
understand it is due to the loss of energy from the decrease in the
Earth's rotation but I can't see the mechanics of it. Can anyone
help?
Stan
Mostly because your model of orbital mechanics is too simple, and
although the mechanisms have been explained to you, you ignored it
because you don't want to understand.
Ignorance can be cured. Stupidity is another matter.
--
Timberwoof <me at timberwoof dot com> http://www.timberwoof.com
"Like this cup," the master daid, "you are full of your own opinions and
speculations. How can I show you anything unless you first empty your cup?"
What you're both missing is that the moon's orbit gets larger not
through a lessening of the Earth's mass but a different mechanism. Pay
attention now!
As the moon orbits the Earth, it drags water around with it, causing
tides and slowing the Earth's rotation. So what happens to the energy of
that rotation? Some of it is converted to heat through viscous friction.
But most of it is transferred to the moon's orbit, which gets bigger as
a result.
That's what orbits do. Do you understand how orbits work?
> Steve wrote:
> >
> > What keeps the moon away from the earth other than centripital force?
> >
> A centripetal force acts *towards* the centre. A centrifugal force acts
> away from the centre.
>
> Actually, the force that stops the moon from flying away is gravity. If
> gravity was to be suddenly abolished the moon would travel away from the
> earth along a tangent to its orbit. It is only gravity pulling it
> towards the earth that causes it to swing around in an orbit. There is
> no force keeping the moon away from the earth.
Oh, boy, I can already see it coming: a failure to distinguish between
force and acceleration.
> "Steve" <philh...@aol.com> wrote in message
> news:1171185075.0...@j27g2000cwj.googlegroups.com...
> > On Feb 10, 11:11 pm, "Androcles" <Engin...@hogwarts.physics.co.uk>
> > wrote:
> >> "Peter Webb" <webbfamily-diespam...@optusnet.com.au> wrote in
> >> messagenews:45cea46c$0$16555$afc3...@news.optusnet.com.au...
> >
> >> It's pretty easy to guess where it will end up, and your guess isn't
> >> a good one.
> >> http://antwrp.gsfc.nasa.gov/apod/ap051113.html
> >
> > Nice time lapse shots of the entire moon day cycle. Didn't know the
> > moon swayed like that. It's not as static as I thought. Interesting.
> > Thanks!
> >
>
> Ha ha. The wobbling you think you see is a result of the inclination of the
> earth's axis affecting the time lapse photography. The effect is due to the
> camera moving, not the earth.
No, I don't think so. The wobble happens with lunar cycles, not with an
Earth annual cycle. It has more to do with the inclination of the moon's
orbit around the earth and, as the text says, with the moon's elliptical
orbit.
> >> This is easy to calculate through conservation of angular momentum,
> >> this allows the final distance from the earth to the moon to be
> >> calculated, though working out the eccentricity of the orbit is
> >> beyond your guess.- Hide quoted text -
>
> It won't be particularly eccentric. Its current very slight eccentricity
> will be smoothed out as the earth-moon distance increases.
>
>
> >>
> >> - Show quoted text -
> >
> > And your guess is?
> >
> > Thanks,
> > Steve
> >
>
> The moon is retreating from the earth at about 3.8 cms per year (see
> http://en.wikipedia.org/wiki/Lunar_distance_%28astronomy%29
>
> As I said, its easy to work out the distance it will eventually reach
> through conservation of angular momentum. With the benefit of the LIDAR
> experiments, the time frames can be estimated but not precisiely defined
> (unlike the terminal distance, which can be easily calculated).
--
I meant centrifugal force.
Steve
Not even a theory?
>Anyway, who is going to be around long
> enough to verify it?
No one, but we can still hypothesize with existing data .. at the very
least establishing the odds to some degree. And so far factors in this
discussion strongly favor my tendency to believe of an eventual single
lump .. namely the slowing of the moon's revolution around the earth.
> But don't you find it curious that all planetary orbits are nearly
> circular rather than highly elliptical as a comet's?
Depends. Has anyone determined the amount deviation from pure
circular? The ellipses will "wear off" in time. A near circular path
*suggests* that a great deal of time has ellapsed.
The moon demonstrates is definite "wobble" in its day cycle alone. I
bet there's more than one wobble If someone could go back hundreds of
thousands of years, they could point out more wobbles. I'm suggesting
the LATEST outward movement is merely one of these elliptical wobbles.
Nothing far fetched.
> (Except Pluto/Charon of course, but that is probably a captured
> comet anyway.)
Is Pluto Charon?
> The inference is the solar system as a whole has had enough time
> to settle down, the most eccentric planet being Mercury and
> that is advancing its longitude of perihelion as Jupiter, Venus
> and the Earth drag it along. Mars is too small and too far away
> to have as much effect as the other three.
> http://faculty.ifmo.ru/butikov/Projects/Collection1.html
> Example 5 gives a clear indication of the result, example 3
> what could happen with a spacecraft in Lunar orbit, Example 9
> gives you Shoemaker Levy.
> Example 10 is fascinating because it appears at first to be stable.
>
> Collection3 is mind boggling.
Interesting.
Steve
******************
I showed how in the bit that was snipped.
What part don't you understand?
The Conservation of angular momentum is explained here:
http://www.astronomynotes.com/angmom/s1.htm
(It uses the earth-moon system as an example).
The calculation has been done at:
http://users.zoominternet.net/~matto/M.C.A.S/notes_tides.htm
They provide an estimate of the stable, terminal orbit as 50% greater than
today, or a bit under 600,000 kms.
At http://arxiv.org/pdf/astro-ph/0107024
They use the equations for conservation of angular momentum to calculate:
"the resonant condition between the Earth and Moon is such that the length
of the month is 50.7 days, a distance of 581098 km"
http://www.astronomynotes.com/gravappl/s10.htm
Calculates much the same thing - a resonant orbit with a period of 47 days
(this can be used to calculate the distnce using Newton's Law of Gravity).
There are plenty of others.
The interesting (for me) part of this is that the rate of recession is very
hard to calculate (but easy to measure with lasers) because it depends upon
the degree of tidal coupling of the earth-moon system, which in turn depends
upon the ocean depth and continental topography. For example, if the earth
had no water, then the rate of recession would be less than half the present
value (a few centimetres a year), as the major component of the tidal lock
is ocean tides - deformation of the solid structure of the earth is less
than half the tidal effect. With lots more water, or re-arranged continents
such that tides were not disrupted by large land masses, the rate would
increase. The law of conservation of angular momentum can't be used to
directly calculate the time until resonance (a stable orbit) occurs, but it
can directly calculate the distance at which this occurs (581,098 kms) and
the final shared earth/moon day length (47 days). This is independent of any
topographic considerations, which only affect the time it takes for the
synchronisation to occur.
The behaviour of the earth-moon system is somewhat paradoxical until tidal
forces are introduced. You would expect the moon to "fall towards" the
earth; as the concept of tidal locking demonstrates (and the LIDAR
experiment measured) the exact opposite is occuring
I haven't googled for it, but doubtless tightly coupled binary star systems
would have similar tidal effects which would increase their period.
http://en.wikipedia.org/wiki/Tidal_acceleration
has a pretty good non-mathematical treatment; they state that the earth-moon
system will not achive the stable 580,000 kms orbit before the Sun turns
into a red giant. This is partially predicated on the oceans boiling off as
the Sun expands, decreasing tidal locking.
If you actually want to understand this a bit better - and my explanations
and links aren't enough - feel free to ask specific questions. I studied
this in either my Uni physics or astronomy classes (or maybe both), but as
long as you understand the Law of Conservation of Angular Momentum it is
really just high school maths (apart from calculating the current angular
momentum of the earth, which uses a tiny bit of calculus, but you can skip
that).
Not quite. Look closely. The moon is not just wobbling it is
"twisting" around it's center of gravity. It's not perfectly static as
I've read. Watch particularily the edges. The camera would have to
move tens of thousands of miles to make the moon move that much it
were completely frozen.
>
> >> This is easy to calculate through conservation of angular momentum,
> >> this allows the final distance from the earth to the moon to be
> >> calculated, though working out the eccentricity of the orbit is
> >> beyond your guess.- Hide quoted text -
>
> It won't be particularly eccentric. Its current very slight eccentricity
> will be smoothed out as the earth-moon distance increases.
>
>
>
> >> - Show quoted text -
>
> > And your guess is?
>
> > Thanks,
> > Steve
>
> The moon is retreating from the earth at about 3.8 cms per year (seehttp://en.wikipedia.org/wiki/Lunar_distance_%28astronomy%29
The moon is CURRENTLY retreating. You've left out an extremely key
word. You can't prove it will continue "retreating" anymore than I can
prove it is in some long term elliptical sway (which is my theory) so
this movement could be a very stale factor and not worthy of this
discussion, but at least you're on topic. Thanks.
>
> As I said, its easy to work out the distance it will eventually reach
> through conservation of angular momentum. With the benefit of the LIDAR
> experiments, the time frames can be estimated but not precisiely defined
> (unlike the terminal distance, which can be easily calculated).
Again I've asked what force(s) move the moon away other than
centrifugal? If there are none and the moon revolution is slowing,
this PROVES without a shadow of doubt my theory that the moon will
slam into the earth, barring of course something unforeseen.
Steve
Cite. Funny how you say this without one reference! Credibility hit or
what?
>
> Why don't you first satisfy yourself that the moon is actually retreating
> from the earth, for example by Googling Earth-Moon distance or LIDAR?
Cite where I said this was a lie? If this is the case fine. I said
this proves nothing because of the short time frame or did you
conveniently leave that out of your mind too?
>
> Once we have established that it is an astronomical fact that the moon's
> orbital distance is increasing (and has done so since it was formed), we can
> discuss the physics of why it happens, which are reasonably straightforward.- Hide quoted text -
I thought your entire premise was that indeed we've proven the moon is
currently moving away?!
Wow maybe your just really tired (been there done that myself).
Steve
> I cited the Roche Limit in the sense that the moon can't notionally collide
> with the Earth as a result of orbit decay; at least in 1 piece it can't. I'm
> aware that it is, in reality, moving away.- Hide quoted text -
The Roche Limit is not a force acting outwardly on the ENTIRE moon
right? It is only a force acting on objects as multiple gravity points
collide and shift.
This phonomenon exists, BUT (HUGE BUT) wonder how much of a factor it
is on the moon (and earth since the moon is so massive in comparison)
if/when the moon slams into the earth. Will the moon break up before
it hits?
Interesting as hell. Great chat. Thanks,
Steve
Doesn't help. Its the concept that's flawed, not your terminology.
The fact that the earth-moon distance is increasing (and will continue to
increase until a "phase-locked" or "resonant" orbit is achieved) has been
known theoretically for 200 years and has been measured for the last 35
years.
What astounds me is that the majority of the posters (except timberwolf)
seem unaware of basic physics that has been known for 200 years. A simple
google of "earth moon distance" shows dozens or hundreds of sites that use
the conservation of angular momentum and tidal coupling to explain the
increasing earth-moon distance, and calcluate the terminal orbit (I provided
some in another post). Why people would bother posting their own bullshit
theories about the moon falling into the earth when the physics behind this
is relatively simple and easily found on the net is a mystery to me. If you
don't know much about physics - and I suspect from your use of the term
"centrifugal force" that you don't - wouldn't it make a little sense to
Google the question before posting your own hypothesis?
You want a web reference that discusses the terminology in your post?
You said:
"So the earth is rotating slower and slower and may eventually stop and
face the moon permanently. How does this lessen earth's gravitational
force? Gravity is a function of rotation? A gyro effect won't play a
role since the moon is not part of the earth's gyro equation.
So by this theory, if a huge star spins fast enough it loses most all
of its gravitational force acting on neighboring bodies. That doesn't
compute."
What do you mean by "gravitational force"? You mean the earth's
gravitational force on the moon? Yes, this decreases because of Newton's law
of gravitation.
F = G*M*E/r^2
(where M and E are the masses of the earth and moon).
Yes, this decreases because r increases.
>>
>> Why don't you first satisfy yourself that the moon is actually retreating
>> from the earth, for example by Googling Earth-Moon distance or LIDAR?
>
> Cite where I said this was a lie? If this is the case fine. I said
> this proves nothing because of the short time frame or did you
> conveniently leave that out of your mind too?
>
>>
>> Once we have established that it is an astronomical fact that the moon's
>> orbital distance is increasing (and has done so since it was formed), we
>> can
>> discuss the physics of why it happens, which are reasonably
>> straightforward.- Hide quoted text -
>
> I thought your entire premise was that indeed we've proven the moon is
> currently moving away?!
Yes.
> Wow maybe your just really tired (been there done that myself).
Huh?
>
> Steve
Which conveniently also happens to be distance through which a camera would
have to move to photograph the moon when it is on opposite sides of the
earth.
>>
>> >> This is easy to calculate through conservation of angular momentum,
>> >> this allows the final distance from the earth to the moon to be
>> >> calculated, though working out the eccentricity of the orbit is
>> >> beyond your guess.- Hide quoted text -
>>
>> It won't be particularly eccentric. Its current very slight eccentricity
>> will be smoothed out as the earth-moon distance increases.
>>
>>
>>
>> >> - Show quoted text -
>>
>> > And your guess is?
>>
>> > Thanks,
>> > Steve
>>
>> The moon is retreating from the earth at about 3.8 cms per year
>> (seehttp://en.wikipedia.org/wiki/Lunar_distance_%28astronomy%29
>
> The moon is CURRENTLY retreating. You've left out an extremely key
> word. You can't prove it will continue "retreating" anymore than I can
> prove it is in some long term elliptical sway (which is my theory) so
> this movement could be a very stale factor and not worthy of this
> discussion, but at least you're on topic. Thanks.
>
And has done so for billions of years, and will continue to do so for
billions of years to come. As a simple google of "earth-moon distance" will
very quickly verify. Its very basic physics.
>>
>> As I said, its easy to work out the distance it will eventually reach
>> through conservation of angular momentum. With the benefit of the LIDAR
>> experiments, the time frames can be estimated but not precisiely defined
>> (unlike the terminal distance, which can be easily calculated).
>
> Again I've asked what force(s) move the moon away other than
> centrifugal?
Tidal coupling.
> If there are none
There are. Tidal coupling.
> and the moon revolution is slowing,
If its revoution aroud the earth is slowing, then its orbit must be
increasing. Low earth sattelites go round the earth in a couple of hours,
the moon (much farther away) takes 28 days or so. Is this a typo, or is it
what you actually believe?
> this PROVES without a shadow of doubt my theory that the moon will
> slam into the earth, barring of course something unforeseen.
It just proves that:
1. You know nothing about physics, and
2. You are too stupid or lazy to google for a basic astronomical explanation
of what will happen, and why, which is the exact opposite of what you claim.
> Steve
>
>
One last time:
1. The moon is moving farther from the earth, not closer. This is predicted
by theory and confirmed by experiment.
2. Therefore the moon will never come within the Roche limit or fall into
the earth (barring some huge astronomical event such as another planet
hitting the moon).
Bingo!
This is totally insane. On contrary, where have you been?! I'VE BEEN
THE ONE saying there's likely all kinds of orbital movements involved,
not just the one observed over the last 40 years that people here have
resorted to as a "PROJECTILE MOVMENT." Sheeeeeeeeesh!
Ignorance can be cured. Stupidity is another matter. And blindness a
third.
Steve
Sorry to sound trollish myself, but I've ran into this TW dude before
and frankly he ain't worth my time especially when it involves to
science. So sorry TW I didn't read past your first post .. and that
rule stands.
Steve
Or to increase the distance between the earth and moon, which is what has
been happening for billions of years.
Sorry to sound trollish myself, but I've ran into this TW dude before
and frankly he ain't worth my time especially when it involves
science. So sorry TW I didn't read past your first post .. and that
rule stands.
However, if someone else here finds TW's comments "on topic
stimulating" please point them out for me. Thanks.
Steve
>Hey fuckhead! bla bla bla
Petie here earns his position as troll. Fine accomplishment in a
usenet group.
Let me pass on a bit of advice to trolls like Pete, if you want others
to think highly of you and make a serious valid convincing point
stick, that's not a great start.
Someone who knows more about it than you could claculate it. What
happens when they get slowly close together depends on the mass,
density, and tensional strength of the Earth and Moon. Two marbles, for
instance, have a lot of tensional strength, and would not break up as
they approached each other. But binary stars can do that sort of thing,
and their breakup as they get too close has been obvserved and the
models have been refined to match the data. So it's not all that hard to
apply the model to the Earth and Moon.
> Interesting as hell. Great chat. Thanks,
> Steve
--
Interesting. This reply does not contain a single word that I posted, and
doesn't address any of the issues I raised.
Have you any problems with the explanantion I gave of the dynamics of the
earth-moon system, or any of the links I provided that explain it further?
Do you still believe that all astronomers and physicists who (universally)
accept that the moon is moving further away from the earth, has done so for
billions of years, and will continue to do so until the Sun goes red giant,
are all wrong, and you are right?
And you call me a troll?
THANKS !!
STEVE
PS now you trolls have the floor. Go on ripping each other new holes.
One guy you can count on that won't be here to read any of it out of
sheer boredom will be moi. So piss off. Touche! I get the last laugh.
Gravity is like a roulette without friction.
Just so long as the moon continues to go round that invisable boundary of
that track at a constant velocity, the earth is safe.
Its easy to apply. Tensional strength is orders of magnitude too small to
hold together a body more than a few tens of kilometers across.
Its also bullshit, because tidal forces have moved the moon into higher and
higher orbits over billions of years, and will continue to do so.
No problem. Glad the links and explanations helped.
The problem with your hypothesis is that there's neither evidence nor
rigorous math to back it up.
> > But don't you find it curious that all planetary orbits are nearly
> > circular rather than highly elliptical as a comet's?
>
> Depends. Has anyone determined the amount deviation from pure
> circular?
Yes. Eccentricity is one of the fundamental defining properties of an
ellipse.
> The ellipses will "wear off" in time. A near circular path
> *suggests* that a great deal of time has ellapsed.
>
> The moon demonstrates is definite "wobble" in its day cycle alone. I
> bet there's more than one wobble If someone could go back hundreds of
> thousands of years, they could point out more wobbles. I'm suggesting
> the LATEST outward movement is merely one of these elliptical wobbles.
> Nothing far fetched.
Indeed, people have. The orbital parameters of the Earth and Moon are
very well known, both from current measurements and from ancient ones.
It may surprise you to learn that this whole "Age of Aquarius" thing is
a real astronomical event.
> > (Except Pluto/Charon of course, but that is probably a captured
> > comet anyway.)
>
> Is Pluto Charon?
No.
> > The inference is the solar system as a whole has had enough time
> > to settle down, the most eccentric planet being Mercury and
> > that is advancing its longitude of perihelion as Jupiter, Venus
> > and the Earth drag it along. Mars is too small and too far away
> > to have as much effect as the other three.
> > http://faculty.ifmo.ru/butikov/Projects/Collection1.html
> > Example 5 gives a clear indication of the result, example 3
> > what could happen with a spacecraft in Lunar orbit, Example 9
> > gives you Shoemaker Levy.
> > Example 10 is fascinating because it appears at first to be stable.
> >
> > Collection3 is mind boggling.
>
> Interesting.
> Steve
--
Basically yes. There are some subtle effects like relativistic
frame dragging but these would be tiny.
> Now we add oceans (and take away an equal amount of rock, and preserve
> mass, angular momentum etc). Now we expect the moon to slowly move
> away from earth. This must be due to a decrease in gravity, which has
> to balance centripetal force for a circular orbit, right?
No, it is more subtle.
> Yet the effect of the moon's gravity is to pull some water up toward
> it, moving the Earth's center of gravity closer to the moon, and hence
> making gravity stronger....
No, it just redistributes the mass.
> So how do we explain the reason the moon is slowly receding? I
> understand it is due to the loss of energy from the decrease in the
> Earth's rotation but I can't see the mechanics of it. Can anyone
> help?
The key is that the bulge is not directly under the Moon,
it takes time for the ocean to respond so the Earth has
turned some distance before the tide peaks. That means the
bulge is ahead of the Moon and is pulling it forward in its
orbit. The slight increase in speed is what causes the Moon
to move outward. In fact, due to the orbital dynamics, the
increased radius results in a drop in speed and the extra
energy given to the Moon occurs in the gravitational
potential. See pages 19, 20 and 23 of this presentation:
http://www.abdn.ac.uk/physics/astro/astro3.pdf
HTH
George
There's a common flaw in people which is to underestimate the difficulty
of a task one has little familiarity with. I'm most familiar with this
in motorcycling, where many a newbie thinks, what's so hard about this,
and ends up steering straight for a tree.
And so, someone who knows a little bit about Newton and marbles, but not
what has actually been observed about the Earth and Moon (and Sun and so
forth) does not know what all may be involved and is astounded that
anyone might come up with answers different from his own.
People hate to be told they don't know something and they like to
believe that their ideas are on par with those of degreed scientists.
(Remember Lavoisier...)
The bit where you showed YOUR calculations and YOUR result.
I couldn't find it.
> They use
Never mind "they". Where are YOUR calculations?
What is this easy calculation you can do through conservation
of angular momentum, as you said you can?
[snip links]
> There are plenty of others.
Never mind "others". Where are YOUR calculations?
What is this easy calculation you can do through conservation
of angular momentum, as you said you can?
> The interesting (for me) part of this is that the rate of recession is very
> hard to calculate
You said it was easy. Make up your fuckheaded mind!
What is this easy calculation you can do through conservation
of angular momentum, as you said you can?
> If you actually want to understand this a bit better
I understand it very well, what I want to see is your easy calculations.
What is this easy calculation you can do through conservation
I should have added cohesive strength from self-gravity, for that is
what holds stars together until they get inside some other star's Roche
limit.
It turns out that all asteroids are clumps of rocks, not solid. If they
were solid, they would be able to rotate much faster than they do. There
appears to be an upper limit on the rotational speed of asteroids, and
this matches the speed (at each mass) for how fast one would fly apart.
> Its also bullshit, because tidal forces have moved the moon into higher and
> higher orbits over billions of years, and will continue to do so.
Well, there you go.
Oh. I've been discredited by a dufus. I can't tell you how much that
hurts.
> On Feb 11, 1:02 pm, Timberwoof <timberwoof.s...@infernosoft.com>
> wrote:
> > Mostly because your model of orbital mechanics is too simple, and
> > although the mechanisms have been explained to you, you ignored it
> > because you don't want to understand.
>
> This is totally insane. On contrary, where have you been?! I'VE BEEN
> THE ONE saying there's likely all kinds of orbital movements involved,
> not just the one observed over the last 40 years that people here have
> resorted to as a "PROJECTILE MOVMENT." Sheeeeeeeeesh!
You are, of course, perfectly free to list all those other movements,
and to explain in what relevant ways projectile movement is different
from orbital movement.
> Ignorance can be cured. Stupidity is another matter. And blindness a
> third.
>
> Steve
--
I won't bother to discredit you, fuckhead. You did that all by yourself.
*plonk*
>
>"Steve" <philh...@aol.com> wrote in message
>news:1171185075.0...@j27g2000cwj.googlegroups.com...
>> On Feb 10, 11:11 pm, "Androcles" <Engin...@hogwarts.physics.co.uk>
>> wrote:
>>> "Peter Webb" <webbfamily-diespam...@optusnet.com.au> wrote in
>>> messagenews:45cea46c$0$16555$afc3...@news.optusnet.com.au...
>>
>>> It's pretty easy to guess where it will end up, and your guess isn't
>>> a good one.
>>> http://antwrp.gsfc.nasa.gov/apod/ap051113.html
>>
>> Nice time lapse shots of the entire moon day cycle. Didn't know the
>> moon swayed like that. It's not as static as I thought. Interesting.
>> Thanks!
>>
>
>Ha ha. The wobbling you think you see is a result of the inclination of the
>earth's axis affecting the time lapse photography. The effect is due to the
>camera moving, not the earth.
Maybe, some of it is due to cropping the images at different sizes,
but that could be due to different distances between Earth and moon.
Hard to say
JT
Oh, ow. I'm going to cry now.
::rolleyes::
> On Sun, 11 Feb 2007 21:21:18 +1100, "Peter Webb"
> <webbfamily...@optusnet.com.au> wrote:
>
> >
> >"Steve" <philh...@aol.com> wrote in message
> >news:1171185075.0...@j27g2000cwj.googlegroups.com...
> >> On Feb 10, 11:11 pm, "Androcles" <Engin...@hogwarts.physics.co.uk>
> >> wrote:
> >>> "Peter Webb" <webbfamily-diespam...@optusnet.com.au> wrote in
> >>> messagenews:45cea46c$0$16555$afc3...@news.optusnet.com.au...
> >>
> >>> It's pretty easy to guess where it will end up, and your guess isn't
> >>> a good one.
> >>> http://antwrp.gsfc.nasa.gov/apod/ap051113.html
> >>
> >> Nice time lapse shots of the entire moon day cycle. Didn't know the
> >> moon swayed like that. It's not as static as I thought. Interesting.
> >> Thanks!
> >>
> >
> >Ha ha. The wobbling you think you see is a result of the inclination of the
> >earth's axis affecting the time lapse photography. The effect is due to the
> >camera moving, not the earth.
You mean the pictures were taken from different points on the Earth's
surface?
> Maybe, some of it is due to cropping the images at different sizes,
> but that could be due to different distances between Earth and moon.
>
> Hard to say
Easy to say! Trivial to calculate.
It is reasonable to assume that the photographs were taken with the moon
always at the same right ascension and to assume that the images were
always at the same magnification. Varying either parameter woudl defeat
the purpose of the animation. So I think the changes in the moon's size
in the animation result from the changing distance to the moon. This can
be easily verified:
Perigee/apogee distances to the moon:
363,258 km
405,542 km
Moon's diameter: 3,476 km
So at perigee, the moon subtends an angle of .548 degrees. At apogee,
.491 degrees. That's a difference of more than ten percent. And that's
what we see in the animation.
The Earth's diameter is 12,756.3 km.
This means that the biggest difference in the earth-moon distance during
those photographs can be 6,378 km. The difference between the earth-moon
distances at perigee and apogee is 42,284 km, about 6.6x as much. That
would cause an apparent difference in the size of the moon of at most
~1.7% between moon at the horizon and moon overhead.
Here's the web site of the author:
http://www.astrosurf.com/cidadao/moon_obs.htm
You could write him and ask.
There is little reason, in this case, to assume anything. It is
possible to find how it was done.
Any way, what you are doing is considered speculation.
JT
Actually, no. Rock on large scales is quite plastic. In
fact, there are tides in the crust of the Earth, too, just
as in the ocean. They're just a bit smaller.
>
> Now we add oceans (and take away an equal amount of rock, and preserve
> mass, angular momentum etc). Now we expect the moon to slowly move
> away from earth. This must be due to a decrease in gravity, which has
> to balance centripetal force for a circular orbit, right?
Nope. It's due to the Earth's rotation carrying the tidal
bulge along ahead of the Earth-Moon line. The bulge pulls
the Moon along gravitationally. This is the "coupling"
you're looking for.
>
> Yet the effect of the moon's gravity is to pull some water up toward
> it, moving the Earth's center of gravity closer to the moon, and hence
> making gravity stronger....
The bulge is rotating ahead of the Earth-Moon line, so it
pulls the Moon forward in its orbit.
>
> So how do we explain the reason the moon is slowly receding? I
> understand it is due to the loss of energy from the decrease in the
> Earth's rotation but I can't see the mechanics of it. Can anyone
> help?
The pull of the bulge is adding angular momentum to
the Moon's orbit. The source of the angular momentum
is the Earth's spin (which slows accordingly).
Why don't you guys just follow the link on the above
page which tells you the cause:
http://en.wikipedia.org/wiki/Libration
HTH
George
*****
I gave you links, which you snipped. I also gave you the equations, and a
sketch of how they would be solved. Calculating this out for myself
independently and posting it would take a couple of hours. Why bother when
there are plenty of web sites that already have done the calculation?
BTW, my exact words were:
"Its pretyy easy to work out exactly where it will end up - the final
position is where the earth and moon keep the same face to each other (ie
where a day equals a month). This is easy to calculate through conservation
of angular momentum, this allows the final distance from the earth to the
moon to be calculated, though working out how long it takes is way harder."
I have given web sites that use the conservation of angular momentum to work
out the final earth-moon distance, and you can see its a pretty simple
calculation - somebody with a reasonably good understanding of physics
should be able to do it in a couple of hours work, as first occurred over
100 years ago.
Exactly as I said, the final earth moon distance can be calculated using
conservation of angular momentum; the stable state is where a month equals a
day; and its a pretty easy to do (assuming you know the physical parameters
such as the density of the earth at different depths).
Its a bit like me saying that the speed of light is easy to calculate using
the timing of occultation of Jupiter's moons - it is - and then you
demanding that I redo a tedious calculation to calculate c is approximately
3x10^8 m/s that was first done over 100 years ago and has never been
challenged, except perhaps by idiots in newsgroups.
Here is my claim, again:
"Its pretyy easy to work out exactly where it will end up - the final
position is where the earth and moon keep the same face to each other (ie
where a day equals a month). This is easy to calculate through conservation
of angular momentum, this allows the final distance from the earth to the
moon to be calculated, though working out how long it takes is way harder."
What part of this do you think is wrong?
> The interesting (for me) part of this is that the rate of recession is
> very
> hard to calculate
You said it was easy. Make up your fuckheaded mind!
*****
No, calculating the stable orbit is straightforward. Calculating how long it
takes to achieve (the "rate of recession") is very hard. I gave plenty of
websites that calculated the stable orbit; only one of these (from memory)
hazarded a guess as to how long it would take to achieve - for which you
need to know the rate.
> If you actually want to understand this a bit better
I understand it very well.
**********
Really? Do you understand what a vector cross-product is? (This is how
angular momentum is defined). Do you have enough calculus to calculate the
moment of inertial rotation of a spherical shell? (The calculation of the
earths angular momentum requires this). To do this rigourously, you would
also need enough perturbation theory to prove this orbit is stable and not
pseudo-stable, as is done with Lagrangian points (although there is so much
experimental verification that this is an academic exercise only; I did this
at Uni as part of course in perturbation theory literally as an academic
exercise - but that was 30 years ago).
If you do understand the orbital mechanics of the earth-moon system "very
well", you would know all this stuff already. But then, if you did
understand this stuff very well, I can't see what on earth (or on the moon)
you would object to what I have written.
So now I am confused. Do you understand basic orbital dynamics "very well" -
eg conservation of angular momentum (ie vector cross-products), integration
over the interior of a sphere, and perturbation theory?
If so, we can definitely kick this conversation up a level or two. If not,
perhaps you should learn some, and get back to this newsgroup when you know
what you are talking about.
As I said before, if there is anything in any of the many links I provided
that you don't understand, feel free to post any questions you may have.
*** cough *** - that's 17%, not 1.7%.
But your argument is correct (well, 83% correct) and I accept that
apogee-perigee distance is a much bigger effect than the changing position
of the camera.
Cheers,
Cliff
--
Have you ever noticed that if something is advertised as 'amusing' or
'hilarious', it usually isn't?
No - it's ~1.7%. The difference in apparent size due to perigee-apogee was
given above as .548 - .491 = .057 degrees. Expressed as a percentage of
.491 degrees it is 11.6%. This has been shown above to be ~ 6.6 times the
difference due to observing overhead compared to on the horizon . Hence the
% difference in apparent size due to overhead-horizon is 11.6% divided 6.6
or ~1.7%
I accept that the difference in earth-moon distance arising from orbit
eccentricity is 405,542 - 363,258 or about 40,000 kms.
The difference due to the camera being in a diiferent position as the earth
rotates is a maximum of 12,000 kms and a minimum of 6,000 kms (6,000 kms if
you want to be able to see the moon at all, and 12,000 kms if you photograph
it when it close to overhead at all times), assuming an equatorial camera.
Therefore the MINIMUM percentage contribution from the earth's rotation is
6,000/40,000 kms, or about 15% of the observed change is size; the MAXIMUM
is 12,000/40,000, or about 30%.
Either way, not the dominant component.
Whilst I can't find the original film clip, I suspect that is also the cause
of the perceived libration of its rotational axis. As the earth's rotation
is tilted from the plane of rotation of the moon, the time of day of
observation has an effect on the perceived orientation of the moons axis -
it appears to be wobbling, but this is artefact of the camera being at
different distances from the plane of rotation (this is known as "diurnal
libration" and it really only affects our observations of the moon, as
everthing else is too far away for it to matter).
The previous poster wasn't calculating the proportion of the observed change
that the overhead-horizon difference contributed. He was calculating the
apparent difference in size that the overhead-horizon difference caused.
Links are not your calculations.
What is this easy calculation you can do through conservation
of angular momentum, as you said you can, FUCKHEAD troll?
That's very interesting, I didn't know that. I found only one reference (the
original paper, http://keith.aa.washington.edu/papers/spinlimits.pdf ). It
makes an excellent argument - as you summarised it - but the implications
are huge, which makes me wonder if it is now accepted fact. It makes the
"demolished planet" theory of the asteroids formation look far more likley
than the "failed to accrete into a planet because of Jupiter's gravity"
theory of asteroid formation.
OK. Do you know how to calculate a vector cross product, or should we start
with that?
It is because you are mistaking the image with the moon. You think it
is an accurate portrait of the moon.
First, if you bothered to look at the evidence, the a webpage and an
animated gif image, you would see neither are the moon, just pictures
of it.
http://antwrp.gsfc.nasa.gov/apod/ap051113.html
Now what do we know from the webpage
"A full lunation takes about 29.5 days, just under a month (moon-th)"
Would you say the gif animation is representative of a "full
lunation?"
If yes, then it should surprise you to find there are only 26 frames
in the animation, and of those one is information, two background.
Which means the animation has 23 frames. If each frame is a day, six
days are missing. Should not make a difference right? Don't know,
just know a full lunation and the gif image are not representative of
one.
Next, the images of the phases of the moon are within it, and each
image is within a frame and each frame has a different X-offsetting
and Y-offsetting, when adjusted removes the wobble, or exaggerates it.
This is because the images are relative to the frame. Do not know the
relation of each image to the other.
Libration maybe and the image maybe made to show it, but it cannot be
consider a source for knowing of it.
JT
Should read:
Next, the images of the phases of the moon are within frames
>and each frame has a different X-offsetting
>and Y-offsetting, when adjusted removes the wobble, or exaggerates it.
Should read:
and each image within a frame has a different X-offsetting
and Y-offsetting, when adjusted, removes the wobble, or exaggerates
Well I guess there may be a few missing when the Moon was new
and perhaps there were a few cloudy nights.
>>Next, the images of the phases of the moon are within it, and each
>>image is within a frame
>
> Should read:
> Next, the images of the phases of the moon are within frames
>
>>and each frame has a different X-offsetting
>>and Y-offsetting, when adjusted removes the wobble, or exaggerates it.
>
> Should read:
> and each image within a frame has a different X-offsetting
> and Y-offsetting, when adjusted, removes the wobble, or exaggerates
> it.
Have you tried that? The x and y offsets should simply align
the centre of the Moon in the centre of the frame, they
shouldn't change the angle of the axis, and certainly they
cannot change the location of landmarks (craters) within the
disc of the Moon which is the clearest indication. If you
look near the edges there are features which are sometimes
visible and sometimes over the horizon. That cannot be the
result of changing the gif offsets.
>>This is because the images are relative to the frame. Do not know the
>>relation of each image to the other.
>>
>>Libration maybe and the image maybe made to show it, but it cannot be
>>consider a source for knowing of it.
Obviously. Scientific results come from accurate measurements,
not just an animation like that. A quick search of the web
suggests radar measurements of the lunar poles and of course
the reflectors left by the Apollo missions provide some
of the more accurate values but I'm sure there is a long
history of measurements if you are interested.
Bottom line is that the effect called libration has been known
for a very long time, its cause is known and the animation
simply illustrates it. What are you guys arguing about?
George
> >
> > Perigee/apogee distances to the moon:
> > 363,258 km
> > 405,542 km
> >
> > Moon's diameter: 3,476 km
> >
> > So at perigee, the moon subtends an angle of .548 degrees. At apogee,
> > .491 degrees. That's a difference of more than ten percent. And that's
> > what we see in the animation.
> >
> > The Earth's diameter is 12,756.3 km.
> >
> > This means that the biggest difference in the earth-moon distance during
> > those photographs can be 6,378 km. The difference between the earth-moon
> > distances at perigee and apogee is 42,284 km, about 6.6x as much. That
> > would cause an apparent difference in the size of the moon of at most
> > ~1.7% between moon at the horizon and moon overhead.
>
> *** cough *** - that's 17%, not 1.7%.
No, hang on. The difference in the earth-moon distance from Earth's
rotation, 6,378 km, compared to the mean earth-moon distance, 384,400
km, is less than 1.7%.
> But your argument is correct (well, 83% correct) and I accept that
> apogee-perigee distance
delta is ~ 10%
> is a much bigger effect than the changing position
> of the camera.
delta is < 1.7%
> Whilst I can't find the original film clip
http://antwrp.gsfc.nasa.gov/apod/ap051113.html
And what you are doing is considered ignoring the math.
When the moon is at a small angle to the sun, it is difficult to
photograph. When the moon is new, all you get is a black frame.
> Next, the images of the phases of the moon are within it, and each
> image is within a frame and each frame has a different X-offsetting
> and Y-offsetting, when adjusted removes the wobble, or exaggerates it.
>
> This is because the images are relative to the frame. Do not know the
> relation of each image to the other.
>
> Libration maybe and the image maybe made to show it, but it cannot be
> consider a source for knowing of it.
You're speculating.
Has anyone besides me actually written the photographer?
It is irrelevant since what we are talking about is a picture.
You might want to make the moon and it one and the same in your mind,
but that is just you.
JT
So the solution to
"Its pretyy easy to work out exactly where it will end up - the final
position is where the earth and moon keep the same face to each other (ie
where a day equals a month). This is easy to calculate through conservation
of angular momentum, this allows the final distance from the earth to the
moon to be calculated, though working out how long it takes is way harder."
is:
a) "should we start with that"
b) "OK"
c) "Do you know how to calculate a vector cross product"
READ MY LIPS:
What
is
this
easy
calculation
you
can
do
through
conservation of
angular
momentum,
YOU FUCKING ILLITERATE IGNORANT ARROGANT TROLL?
>
>"Steve" <philh...@aol.com> wrote in message
>news:1171235814....@v45g2000cwv.googlegroups.com...
>> On Feb 11, 2:12 pm, "Peter Webb" <webbfamily-
>> diespam...@optusnet.com.au> wrote:
>>> "Androcles" <Engin...@hogwarts.physics.co.uk> wrote in message
>>
>>>Hey fuckhead! bla bla bla
>>
>> Petie here earns his position as troll. Fine accomplishment in a
>> usenet group.
>>
>> Let me pass on a bit of advice to trolls like Pete, if you want others
>> to think highly of you and make a serious valid convincing point
>> stick, that's not a great start.
>>
>>
>>
>
>Interesting. This reply does not contain a single word that I posted, and
>doesn't address any of the issues I raised.
>
>Have you any problems with the explanantion I gave of the dynamics of the
>earth-moon system, or any of the links I provided that explain it further?
>Do you still believe that all astronomers and physicists who (universally)
>accept that the moon is moving further away from the earth, has done so for
>billions of years, and will continue to do so until the Sun goes red giant,
>are all wrong, and you are right?
>
>And you call me a troll?
Steve's known for it. Check out sci.geo.earthquakes, where he's
swapped out nyms once or twice, and he's "the worlds greatest
predictor of earthquakes". He's getting a pasting there too.
--
Find out about Australia's most dangerous Doomsday Cult:
http://users.bigpond.net.au/wanglese/pebble.htm
"You can't fool me, it's turtles all the way down."
"Maths proves you know how to plug in some figures into a formula, that's
all"
"Even physics is based on wrong theories, so what's the use of maths"
Carole - demonstrating her mathematical abilities.
There is no such thing as 'centrifugal force', there is only inertia.
Sure, your bum moves towards the door while your car is cornering,
but that has nothing to do with 'centrifugal force', (which doesn't exist).
It is simply the fact that the car is changing direction and you are inside it.
> Actually, the force that stops the moon from flying away is gravity. If
> gravity was to be suddenly abolished the moon would travel away from the
> earth along a tangent to its orbit. It is only gravity pulling it
> towards the earth that causes it to swing around in an orbit. There is
> no force keeping the moon away from the earth.
>
> Enkidu wrote ..
> > Steve wrote:
> > >
> > > What keeps the moon away from the earth other than centripital force?
> > >
> > A centripetal force acts *towards* the centre. A centrifugal force acts
> > away from the centre.
>
> There is no such thing as 'centrifugal force', there is only inertia.
> Sure, your bum moves towards the door while your car is cornering,
> but that has nothing to do with 'centrifugal force', (which doesn't exist).
> It is simply the fact that the car is changing direction and you are inside
> it.
>
> > Actually, the force that stops the moon from flying away is gravity. If
> > gravity was to be suddenly abolished the moon would travel away from the
> > earth along a tangent to its orbit. It is only gravity pulling it
> > towards the earth that causes it to swing around in an orbit. There is
> > no force keeping the moon away from the earth.
It is my belief that the notion that "there is no such thing as
'centrifugal/centripetal force', there is only inertia" is mostly useful
from the standpoint of someone somewhat knowledgeable in dynamics who
wants a handy club to use on people who know less.
If people actually know about such dynamics and how to correctly
calculate the effects, they can talk about these accelerations and
resulting forces and actually get to useful results without getting all
hung up on the pedantic minutiae.
If I'm sitting in one of those red comfy chairs in lobby of the Hilton
on Stanley Kubrick's space station, I could say the force I feel on my
butt is the result of centripetal acceleration or that the tension felt
by those eight big radial columns is the result of centrifugal force,
and everyone would understand what I mean.
It is, in any case, important for people to know and understand the
equations involved and how to use them properly. This is a case where
you simply have to understand something in its own terms, with the math,
and analogy won't work very well.