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Perihelion of Mercury with classical mechanics ?



 
 
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  #1  
Old January 27th 05, 02:45 PM
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Default Perihelion of Mercury with classical mechanics ?

1. Does anyone know if the classical calculation of the perihelion of
Mercury accounts for the attraction of the sun by Mercury?

I stumbled on an interesting article that discusses flaws in Newton's
theory, and which suggests that the sun's motion is neglected even for
the most accurate calculations.
It would be surprising if that were true!

2. It also suggests that when taking it into account, the correct
answer may be found. Any ideas if htat could be right?
http://www.journaloftheoretics.com/L...pers/gravi.pdf
Regretfully I know nothing about astronomy.

Harald

  #2  
Old January 28th 05, 02:35 AM
Greg Neill
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wrote in message
oups.com...
1. Does anyone know if the classical calculation of the perihelion of
Mercury accounts for the attraction of the sun by Mercury?

I stumbled on an interesting article that discusses flaws in Newton's
theory, and which suggests that the sun's motion is neglected even for
the most accurate calculations.
It would be surprising if that were true!

2. It also suggests that when taking it into account, the correct
answer may be found. Any ideas if htat could be right?
http://www.journaloftheoretics.com/L...pers/gravi.pdf
Regretfully I know nothing about astronomy.

Harald


Attempts to calculate the precession of the perihelion of
Mercury by purely classical means have taken into account any
number of influences, including of course the motion of the
Sun. Newton's theory is completely symmetric when expressed
as differential equations to solve the problem.

Amongst the other factors included in "heavy duty" analyses
include the influences of other solar system bodies, and
the oblateness of the Sun due to its rotation.

No amount of fiddling around with classical mechanics can
produce the correct result.


  #3  
Old January 28th 05, 02:30 PM
Nicolaas Vroom
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"Greg Neill" schreef in bericht
. ..
wrote in message
oups.com...
1. Does anyone know if the classical calculation of the perihelion of
Mercury accounts for the attraction of the sun by Mercury?

I stumbled on an interesting article that discusses flaws in Newton's
theory, and which suggests that the sun's motion is neglected even for
the most accurate calculations.
It would be surprising if that were true!

2. It also suggests that when taking it into account, the correct
answer may be found. Any ideas if htat could be right?
http://www.journaloftheoretics.com/L...pers/gravi.pdf
Regretfully I know nothing about astronomy.

Harald


Attempts to calculate the precession of the perihelion of
Mercury by purely classical means have taken into account any
number of influences, including of course the motion of the
Sun. Newton's theory is completely symmetric when expressed
as differential equations to solve the problem.


100 % Correct.

Newton's theory assumes that gravity act instantaneous.
However if you take into acount that the speed of gravity is
not infinite but equal to 300*c you can correctly simulate
the perihelion precession of Mercury.
For details go to my home page:
http://users.pandora.be/nicvroom/
and study the e-book:
The Reality Now and Understanding.
http://users.pandora.be/nicvroom/now.htm


Amongst the other factors included in "heavy duty" analyses
include the influences of other solar system bodies, and
the oblateness of the Sun due to its rotation.

No amount of fiddling around with classical mechanics can
produce the correct result.


There is no fiddling involved.
To be even more precise:
Within our solair system there is no dark matter.
You do not need MOND.

Nicolaas Vroom



  #4  
Old January 28th 05, 02:59 PM
Greg Neill
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"Nicolaas Vroom" wrote in message
...

"Greg Neill" schreef in bericht
. ..
wrote in message
oups.com...
1. Does anyone know if the classical calculation of the perihelion of
Mercury accounts for the attraction of the sun by Mercury?

I stumbled on an interesting article that discusses flaws in Newton's
theory, and which suggests that the sun's motion is neglected even for
the most accurate calculations.
It would be surprising if that were true!

2. It also suggests that when taking it into account, the correct
answer may be found. Any ideas if htat could be right?
http://www.journaloftheoretics.com/L...pers/gravi.pdf
Regretfully I know nothing about astronomy.

Harald


Attempts to calculate the precession of the perihelion of
Mercury by purely classical means have taken into account any
number of influences, including of course the motion of the
Sun. Newton's theory is completely symmetric when expressed
as differential equations to solve the problem.


100 % Correct.

Newton's theory assumes that gravity act instantaneous.
However if you take into acount that the speed of gravity is
not infinite but equal to 300*c you can correctly simulate
the perihelion precession of Mercury.


Unfortunately, this leads to the problem of the
energy of the orbit changing due to the non-central
nature of the resulting force. The magnitude of the
effect is such that it would lead to obvious changes
in the semi-major axes of the planets over relatively
short periods of time.


For details go to my home page:
http://users.pandora.be/nicvroom/
and study the e-book:
The Reality Now and Understanding.
http://users.pandora.be/nicvroom/now.htm


Amongst the other factors included in "heavy duty" analyses
include the influences of other solar system bodies, and
the oblateness of the Sun due to its rotation.

No amount of fiddling around with classical mechanics can
produce the correct result.


There is no fiddling involved.
To be even more precise:
Within our solair system there is no dark matter.
You do not need MOND.

Nicolaas Vroom





  #5  
Old January 28th 05, 03:41 PM
Nicolaas Vroom
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Default


"Greg Neill" schreef in bericht
. ..
"Nicolaas Vroom" wrote in message
...

"Greg Neill" schreef in bericht
. ..
wrote in message
oups.com...
1. Does anyone know if the classical calculation of the perihelion

of
Mercury accounts for the attraction of the sun by Mercury?

I stumbled on an interesting article that discusses flaws in

Newton's
theory, and which suggests that the sun's motion is neglected even

for
the most accurate calculations.
It would be surprising if that were true!

2. It also suggests that when taking it into account, the correct
answer may be found. Any ideas if htat could be right?
http://www.journaloftheoretics.com/L...pers/gravi.pdf
Regretfully I know nothing about astronomy.

Harald


Attempts to calculate the precession of the perihelion of
Mercury by purely classical means have taken into account any
number of influences, including of course the motion of the
Sun. Newton's theory is completely symmetric when expressed
as differential equations to solve the problem.


100 % Correct.

Newton's theory assumes that gravity act instantaneous.
However if you take into acount that the speed of gravity is
not infinite but equal to 300*c you can correctly simulate
the perihelion precession of Mercury.


Unfortunately, this leads to the problem of the
energy of the orbit changing due to the non-central
nature of the resulting force.


Can you be more spefic what you mean.
Does this mean that the distance (to the Sun) increases ?
What is magtitude of this effect ?
Any way what is wrong with the assumption
that for example the distance of Mars is not constant ?
I have seen studies that if you assume that the distance
of our Earth is not constant you can explain
the ice ages.

(Anyway how do you compare your reply with an
expanding Universe ?)

The magnitude of the
effect is such that it would lead to obvious changes
in the semi-major axes of the planets over relatively
short periods of time.


I expect you mean the semi-major axis of the orbits
of the planets ?
What is wrong with that ?
What are the time periods involved ?

Any way what I have also done is to simulate the perihelion
advance for one complete revolution.
The results are quite interesting and ofcourse I would like
to compare them with observations.
Have you done, such a simulation, using GR ?

For details go to my home page:
http://users.pandora.be/nicvroom/
and study the e-book:
The Reality Now and Understanding.
http://users.pandora.be/nicvroom/now.htm

Nicolaas Vroom




  #6  
Old January 28th 05, 04:50 PM
Bjoern Feuerbacher
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Nicolaas Vroom wrote:
[snip]


I have seen studies that if you assume that the distance
of our Earth is not constant you can explain
the ice ages.


Reference, please.



(Anyway how do you compare your reply with an
expanding Universe ?)


Why do you think that is in any way relevant?



[snip]

Bye,
Bjoern
  #7  
Old January 28th 05, 07:36 PM
Paul Schlyter
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Nicolaas Vroom wrote:

"Greg Neill" schreef in bericht
. ..
"Nicolaas Vroom" wrote in message
...

................
Newton's theory assumes that gravity act instantaneous.
However if you take into acount that the speed of gravity is
not infinite but equal to 300*c you can correctly simulate
the perihelion precession of Mercury.


Unfortunately, this leads to the problem of the
energy of the orbit changing due to the non-central
nature of the resulting force.


Can you be more spefic what you mean.


In Newtonian physics, any force with a finite propagation speed
would be subjected to aberration as seen from a moving object.
In the case of a planet orbiting the Sun, that would imply
a small component of the force in the direction of motion
which would slowly increase the speed of the planet, moving it
into a larger orbit. And that would violate the principle of
conservation of energy.

Does this mean that the distance (to the Sun) increases ?


It would - and quite measurably so. But that does not happen.

What is magtitude of this effect ?


For your proposed speed of gravity of 300*c, Mercury's energy would
increase by some 10% in less than a year, which in turn would increase
the mean distance of Mercury from the Sun by a comparable amount.
Now, we've carefully observed the positions of the planets during
several centuries, and less carefully over a few millennia. And
these observations are very clear about this: such a rapid change
of Mercury's distance to the Sun just does not happen. And it
does not happen for the Earth, or any other planet, either.

Any way what is wrong with the assumption
that for example the distance of Mars is not constant ?


This distance has periodic variations, sure. But the long
term average is, as far as we can measure, constant over
time. And we can measure this to some 8-10 digits of accuracy.

I have seen studies that if you assume that the distance
of our Earth is not constant you can explain the ice ages.


Are you referring to the Milakovitch theory? Well, Milankovitch
talks about periodic variations in the eccentricity of the
Earth's orbit, and of the inclination and orientation of the
axis of the Earth. But he does not assume a long term change
of the mean distance Earth-Sun.

(Anyway how do you compare your reply with an
expanding Universe ?)


That's a completely different subject.

The magnitude of the
effect is such that it would lead to obvious changes
in the semi-major axes of the planets over relatively
short periods of time.


I expect you mean the semi-major axis of the orbits
of the planets ?
What is wrong with that ?


It is contradicted by observations.

What are the time periods involved ?


For your proposed speed of gravity = 300*c, the mean distance
would increase some 10% over a time scale of just a few years.
Observations show very clearly that it does not happen.

Any way what I have also done is to simulate the perihelion
advance for one complete revolution.
The results are quite interesting and ofcourse I would like
to compare them with observations.
Have you done, such a simulation, using GR ?


GR also shows the perihelion advance -- AND it predicts that
the mean distance of the planets from the Sun does not
change over the long term. A good fundamental textbook in
celestial mechanics will show you how.

For details go to my home page:
http://users.pandora.be/nicvroom/
and study the e-book:
The Reality Now and Understanding.
http://users.pandora.be/nicvroom/now.htm

Nicolaas Vroom



--
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Paul Schlyter, Grev Turegatan 40, SE-114 38 Stockholm, SWEDEN
e-mail: pausch at stockholm dot bostream dot se
WWW: http://www.stjarnhimlen.se/
http://home.tiscali.se/pausch/
  #8  
Old January 29th 05, 03:46 AM
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Greg Neil wrote:
No amount of fiddling around with classical mechanics can
produce the correct result.

Now that's for sure at least an exaggeration, as I know for fact that
in 1898 Paul Gerber derived from Newtonian mechanics the same equation
as Einstein for the perihelion, and that he calculated c from it with
high accuracy. But I don't have his paper so I don't know the details
of how he did it. I only have a copy of the original end part as
printed in the book Einstein plus two, and Gerber found c = 305500
km/sec.

Harald

  #9  
Old January 29th 05, 03:49 AM
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Newton's theory assumes that gravity act instantaneous.
However if you take into acount that the speed of gravity is
not infinite but equal to 300*c you can correctly simulate
the perihelion precession of Mercury.
For details go to my home page:
http://users.pandora.be/nicvroom/

See my reply to Greg Neil; thus I must assume that you made an error
somewhere.
But I doubt that I am qualified to find it. If I get the paper of
Gerber then I can send the PDF on to you.

Harald

  #10  
Old January 29th 05, 03:56 AM
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Paul Schlyter wrote:
Unfortunately, this leads to the problem of the
energy of the orbit changing due to the non-central
nature of the resulting force.

In Newtonian physics, any force with a finite propagation sp=ADeed
would be subjected to aberration as seen from a moving objec=ADt.
In the case of a planet orbiting the Sun, that would imply
a small component of the force in the direction of motion
which would slowly increase the speed of the planet, moving =ADit
into a larger orbit. And that would violate the principle o=ADf
conservation of energy.

I suppose an upgrade to SRT would take care of that, right?
Thanks,
Harald

 




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