Alternative theories being tested by Gravity probe B

In summary: SCC predicts a small value for the cosmological constant due to the non-linear behavior of the metric in curved spacetime.3. SCC predicts a universe that is unstable and will eventually collapse in on itself.In summary, the Gravity Probe B satellite has placed four (over redundant) gyroscopes in low polar Earth orbit to primarily test two predictions of General Relativity. The first effect being tested is (for the GP-B polar orbit) a N-S geodetic precession, caused by the amount a gyro 'leans' over into the slope of curved space. The second effect being tested is the
  • #316
Garth said:
The aberration of starlight is clearly observed as predicted and provides the natural system calibration, over both orbital (the satelite's) and annual (the Earth's) orbits.

Garth – It is true that the steady signal from the ~5” aberration of light from the spacecraft ’s 91 minute orbit around the Earth served as a useful calibration tool. The less frequent ~20” aberration (due to the earth’s orbit around the sun) was hardly helpful at all because the periodicity during the allotted time for the experiment was less than 2x and because the incoming GP-B data was broken up so many times (with stops and starts and recalibrations along the way).

But perhaps the biggest blunder of the experiment was failure to account for the moving frame of the solar system. The aberration of light from this effect is large (larger than the diurnal or annual figures and larger than the relativity effects) but looks like drift and is still unquantified because there is still large uncertainty about the exact speed and exact motions of the SS (it may have several). I do not blame the current program scientists for this problem as it was unforeseen by the original designers of the experiment (note the complete absence of any mention of this effect in the literature).

Garth said:
Having come this far it would be madness not to complete the data reduction, which is being done through private funding, and the published raw data could provide a mine for others to dig into for years to come - that is if anybody else will be bothered to do so!


I agree it would be great to thoughtfully take apart and quantify every single signal recorded by GP-B. However, the current team is so focused on finding the relativity effects I believe they are missing the discovery of some very important science about the motion of the solar system. Unintentional bias is hard to get away from in an experiment of this type.

Polhode motion is an extremely tricky thing to quantify and predict (no paper supports its prediction with this many variables). In their attempts to cancel it out the GP-B team is probably throwing out vital information about the moving solar system (all in an effort to find the relativity effects). Personally, I doubt if there was any meaningful polhode motion (think about it - those gyros were pretty darn perfect – and polhode is exactly the sort of thing they were designed to avoid!). Most of the “noise” is likely motion of the frame of the SS, and possibly, motion of our local star group relative to the guide star.

GP-B is a unique experiment. No doubt some day someone will look at the data with a completely virgin mind and reveal key information about the moving solar system. Until then I hope the data is well preserved for future generations.

Walter
 
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  • #317
Polestar101 said:
But perhaps the biggest blunder of the experiment was failure to account for the moving frame of the solar system.

I don't think that can be right. The motion of the solar system and of the guide star IM Pegasi was considered and taken into account in the analysis. Not only that, the accuracy of motions was carefully measured and determined to have only a small effect on the uncertainty of the final result.

See: Bartel et. al. (2007) VLBI astrometry for the NASA/Stanford gyroscope relativity mission Gravity Probe B, in Proceedings of the International Astronomical Union, 3, pp 190-191; doi:10.1017/S1743921308019005.

Cheers -- sylas
 
  • #318
However the problem is that, given the noise has to be modeled and extracted from the data to find the relativistic signal, should the final signal deviate from GR then few would find the result convincing.
Garth, no matter what the outcome is: it is not convincing.
I understand that the published result does not support scc (correct me if I'm wrong), but I wouldn't see it as confirmation or rejection of anything. It is not reproducible, nobody will go down that road again in the foreseeable future, and nobody can follow their corrections without doubt.
It's sad, but I'd say: the experiment failed in this aspect. That's ok, it is bound to happen every now and then.
 
  • #319
Walter, would not motion of the Solar System frame be subsumed into the guide star IM Pegasus' proper motion? This was measured independently by the astrometry team at the VLBI and a report found here: Proper Motion of the GP-B Guide Star.

I was at the 2007 APS meeting in Jacksonville to hear the first results of the experiment and asked the question of Francis Everitt specifically about the desire to find the GR effects affecting the modelling of the noise and hence not finding new physics. Francis emphatically stated that that was what they were not doing but modelling the errors in an independent (actually two independent) ways.

The annual aberration of light effect is described here:The Annual Aberration Signal. It seemed to confirm the orbital aberration effect.

As far as the difficulty of modelling polhode motion, and no real sphere is ever perfect and free from such effect, they have spent four years now on the problem and so they would probably agree with your statement
Polhode motion is an extremely tricky thing to quantify and predict !

I actually have a vested interest in the GP-B team getting it wrong (see SCC earlier in this thread, which is falsified by the results), so I am playing Devil's Advocate in supporting their results, and I find no reason at present to think otherwise, but if you have a serious alternative solution to their data analysis I shall be very interested!

Edit: Crossed post with both sylas and Ich.

Garth
 
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  • #320
Garth said:
Walter, would not motion of the Solar System frame be subsumed into the guide star IM Pegasus' proper motion? This was measured independently by the astrometry team at the VLBI and a report found here: Proper Motion of the GP-B Guide Star.

It is certainly useful to exactly define the proper motion of the guide star but remember the reference point has nothing to do with the motion of the instrument that is doing the measuring. The spacecraft that is doing the measuring moves in its regular orbit, and it moves with the Earth in its orbit around the sun, and it moves with the Earth and solar system as the solar system moves through space – thereby changing orientation relative to the guide star independent of any proper motion of that reference point.

Garth said:
The annual aberration of light effect is described here:The Annual Aberration Signal. It seemed to confirm the orbital aberration effect.

The GP-B team properly describes the orbital aberration and the annual aberration but notice there is no mention of the little known aberration that results from the motion of the solar system. I doubt that it was considered when the experiment was conceived. Even today neither the speed nor exact motion of the SS is known for certain. The Voyager 1 and 2 data suggest the SS is moving at a high rate of speed in a general southwesterly direction. But we need more than two data points before we can match it to the GP-B data.

Garth said:
I actually have a vested interest in the GP-B team getting it wrong (see SCC earlier in this thread, which is falsified by the results), so I am playing Devil's Advocate in supporting their results, and I find no reason at present to think otherwise, but if you have a serious alternative solution to their data analysis I shall be very interested!

Hopefully the GP-B data when juxtaposed against the data from other experiments will be useful to several generations to come – even if not to test Einstein. I will be presenting a poster at the upcoming AGU meeting in SF that looks at how much the SS might be moving and why it may be artificially constrained by current lunisolar precession theory. This could have a bearing on the interpretation of the GP-B data but I freely admit I cannot make full sense of the GP-B data at this point.
 
  • #321
Polestar101 said:
The GP-B team properly describes the orbital aberration and the annual aberration but notice there is no mention of the little known aberration that results from the motion of the solar system. I doubt that it was considered when the experiment was conceived.

It is known and it is tiny. No offense, but at this point it is clear that you have no empirical basis for your interesting personal suppositions, and claims about what the team is ignoring are pure speculation; and not actually based on any understanding of the analysis.

[strike]The Sun is not part of a binary star system.[/strike] Analysis of GP-B does not give you the data you would like to support this hypothesis (of a stellar companion to the Sun). Speculations based on pure supposition that they've somehow failed to notice this are not really acceptable by forum guidelines.

Cheers -- sylas
 
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  • #322
If it is known - please tell me how it is known.

The fact is the motion of the solar system is not known - it is assumed. The major assumption is that its only motion is around the galactic center in a period of about 240 million years resulting in a change in orientation of about .005" p/y (within the precession observable), but no one really knows if this is correct. In fact, this assumption itself lies on the assumption that all changes in Earth orientation are local in nature and there is no accounting for the motion of the frame of the solar system relative to the VLBI reference points. This has nothing to do with a possible stellar companion. Good science simply requires that we not make too many unfounded assumptions. Unfounded assumptions is what got GP-B into its current mess.
 
  • #323
The experiment measured the angular displacement of the four gyros against a distant quasar, the core of 3C 454.3. Which, being at z=0.859 was seen to be a 'fixed direction in space'.

The satellite itself measured the angles between the gyros and the guide star IM Pegasi, a VLBI team independently measured the Proper Motion of the guide star, relative to the quasar. Both IM Pegasi and the quasar are radio objects.

The actual data being measured were the angles between an gryos' axes and the distant quasar. The Earth is orbiting the Sun, the Sun is orbiting the Milky Way and the Milky Way is moving through intergalactic space. The total velocity of these motions is approximately 10 -3c.

Using ball-park OOM estimates z = 0.859 converts into a distance of about 1010 light yrs and the galaxy moved about 10 -3 lgt yrs in the ~year data were collected, similarly with the quasar, so the proper motion of the quasar would be OOM 10 -13 rad i.e. ~ 10 -5 milliarcsecs. They hope to measure the displacement angles to an accuracy of about 1 milliarcsec, they have achieved an accuracy of about 10 milliarcsecs so far, so as the proper motion of the quasar relative to the Earth is 5 or 6 OOM smaller than this it can be disregarded.

Garth
 
  • #324
Garth said:
Using ball-park OOM estimates z = 0.859 converts into a distance of about 1010 light yrs and the galaxy moved about 10 -3 lgt yrs in the ~year data were collected, similarly with the quasar, so the proper motion of the quasar would be OOM 10 -13 rad i.e. ~ 10 -5 milliarcsecs. They hope to measure the displacement angles to an accuracy of about 1 milliarcsec, they have achieved an accuracy of about 10 milliarcsecs so far, so as the proper motion of the quasar relative to the Earth is 5 or 6 OOM smaller than this it can be disregarded.

Garth

Or put it another way: 1 milli arc second is about 5 * 10-9 radians. To let actual lateral movement of the solar system distort directions by this amount would require movement of the order of 50 light years over the year or so that data was collected.

Cheers -- sylas
 
  • #325
If the solar system changes "orientation" we are not just talking parallax.

VLBI does not account for changes in the solar system’s orientation to reference points outside the moving frame. Quote from NASA VLBI website:

“Changes in the Earth’s orientation in inertial space have two causes: the gravitational forces of the Sun and Moon and the redistribution of the total angular momentum among the solid Earth, ocean and atmosphere. VLBI makes a direct measurement of the Earth’s orientation in space from which geoscientists then model such phenomena as atmospheric angular momentum, ocean tides and currents, and the elastic response of the solid Earth.”

Please note the present methodology is only concerned with local changes - within the frame of the solar system – thereby effectively employing a static solar system model. Yet measurements are made to points far outside the moving frame – without accounting for any motion of the frame relative to the reference points. If the solar system curves through space we would never know it under current methodology because all changes in Earth orientation are attributed to local causes.

If the total precession observable includes some component of solar system motion then even though GP-B is be far above the precessing Earth it would still pick up some component of precession (due to SS motion) but think it was noise.

A careful reading of the press releases suggests this is exactly the type of “noise” that GP-B has been bothered with since inception.

http://www.space.com/businesstechnology/technology/gravity_probe_b_031231.html
 
  • #326
Polestar, as the measurement is that of the change of angle between the axis of a gyro and the distant quasar, are you claiming the changes in the solar system orientation also changes to orientation of the gyro?

The changes in the Earth's orientation you mention, its change of axis, would not affect the satellite.

The early Space.com site you linked to does accurately predict
Several members of the review at the time voiced a minority skepticism about the large extrapolations required from ground testing to GP-B's performance in space. Furthermore, this same minority thought it likely that some "as yet unknown disturbance" may prevent the spacecraft from performing as required.

Why does the build up of electrostatic patches not seem to you to be "exactly the type of “noise” that GP-B has been bothered with since inception."?

Garth
 
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  • #327
As the SS curves through space the spacecraft , in orbit around the earth, must move with it. Just as GP-B will detect a change in orientation due to the spacecraft s orbit around the Earth (seen as a 97 minute wave), and due to the earth’s orbit around the sun (a longer waveform), so too will it detect a change due to the solar system’s change in angular velocity relative to the guide star. I don’t see how it could be any other way. Of course, the later signal probably looks like noise (thought to be polhode or something else) because the short period of the experiment relative to the long wave makes that form difficult to see. All I’m saying is don’t throw out the baby with the bathwater until we know what is hiding in that bathwater.

Re: electrostatic patches. I don't know enough about this to offer an opinion. But I would start with the assumption that those $800 million gyros have done their job and probably picked up real signals far more subtle than we can imagine. EOP is still a science in progress.
 
  • #328
Polestar101 said:
As the SS curves through space the spacecraft , in orbit around the earth, must move with it. Just as GP-B will detect a change in orientation due to the spacecraft s orbit around the Earth (seen as a 97 minute wave), and due to the earth’s orbit around the sun (a longer waveform), so too will it detect a change due to the solar system’s change in angular velocity relative to the guide star.

The "solar system’s change in angular velocity relative to the guide star" will be caused by its motion around the galaxy, I have dealt with the motion of the galaxy itself above (it is negligible).

Orbiting the galaxy would cause a geodetic precession of

[tex](\frac{M_G}{M_E})^\frac{3}{2}(\frac{R_E}{R_G})^\frac{5}{2} \times 8 \text{arcsecs/yr }[/tex]

(See MTW 'Gravitation' page 1119 eq 40.35)

i.e. about 10-8 arcsecs per year.

I think this can also be safely ignored!

Garth
 
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  • #329
The is a general point here that is being overwhelmed by the discussion of a hypothetical solar companion star.

To save further confusion and time wasting I will re-iterate it.

It is this. If other effects such as poholde and perturbing forces are eliminated then gyros 'point in a constant direction' in space. The curvature of the space-time around the Earth cause two effects on that 'constant direction' that was measured by GP-B, the geodetic and frame-dragging precessions.

The direction of the GP-B gyros axes was referenced to a distant quasar.

All motions of the Earth around the Sun, the Sun around a possible companion, the Sun around the galaxy and the galaxy through space would add up to around 10-3c, as that guide quasar is approximately 1010 light years away then all motions create a parallax of no more than OOM 10-13 rad i.e. ~ 10 -5 milliarcsecs, far smaller than those caused by the curvature of the Earth and Sun's gravitational field that were measured by the experiment.

They can be safely ignored as negligible.

Garth
 
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  • #330
Garth said:
It is this. If other effects such as poholde and perturbing forces are eliminated then gyros 'point in a constant direction' in space. The curvature of the space-time around the Earth cause two effects on that 'constant direction' that was measured by GP-B, the geodetic and frame-dragging precessions.
So, the direction at which the gyroscopes point is not constant, but subjected to, at least, two effects: geodetic and frame-dragging precessions.

Now, imagine for a moment that the movement of the solar system towards the solar apex has an actually unknown characteristic that causes precession in the same way as either geodetic or frame-dragging. I'm not saying that these are geodetic/frame-dragging effects, just that they behave similarly, affecting the orientation of the gyroscopes, that of the earth, and that of the rest of the solar system.
Suppose that this precession is a small component of what we consider to be the known axial precession due to lunisolar causes, as Polestar101 suggested.
Now, when you send a probe to the space to measure small precession effects predicted by GR, your gyroscopes start behaving in an unexpected way.
That's what Polestar101 is saying, if I understood correctly. And I think that that's a possibility that clearly deserves a closer scrutiny.

All motions of the Earth around the Sun, the Sun around a possible companion, the Sun around the galaxy and the galaxy through space would add up to around 10-3c, as that guide quasar is approximately 1010 light years away then all motions create a parallax of no more than OOM 10-13 rad i.e. ~ 10 -5 milliarcsecs, far smaller than those caused by the curvature of the Earth and Sun's gravitational field that were measured by the experiment.
Those are the known, small effects, predicted by GR. Imagine for a moment that there actually are unknown effects, whose causes are being mistaken in the GP-B experiment.

Mauro
 
  • #331
Polestar101 said:
You can't simply eliminate polhode and other perturbing forces to save the experiment without first being able to exactly quantify these effects. And to try and measure them by eliminating anything that does not get to the GR goal is circular reasoning and bad science.

This doesn't make any sense at all. They DO quantify the podhole effect. It was quantified and understood and taken into account from the start. There is an additional effect which was stronger than anticipated; from a tiny residual change on the gyroscopes, which gives an additional effect on the motions. There is no doubt at all that this effect exists. Most of the work of the extended data analysis phase HAS been to quantify this effect -- and not by assumption. When quantified, it can be extracted to reveal any underlying signal.

This is an extra factor influencing the gyroscopes which was larger than anticipated, and has been at the root of the limited accuracy to which results could be given.

The description by Polestar101 is very misleading. It's not bad science at all -- it is precisely what science should do to test GR as well as they can without making assumptions. They quantify all influences and obtain the residual signal, which stands then as a test of the predictions from the frame-dragging effect. There is no assumption of GR involved in that process. Without the proper quantification of the electromagnetic forces, the accuracy of the test is very weak. With proper quantification, the test will improve, though it is unlikely to get to the level of 1% which had originally been hoped.

There's a nice summary of the issues in The Gravity Probe B Bailout, IEEE Spectrum, Oct 2008. This report is describing how the team was able to secure additional funding; and their own project page gives more on the existing funding. (Gravity Probe B -- current status -- updated November 12, 2009. The work is ongoing, and primarily this is focused upon quantifying the effects of the electromagnetic influences, so that they can be properly take into account -- without just making assumption -- and so improving the accuracy of the true independent test of GR.
 
  • #332
maurol2 said:
Garth said:
It is this. If other effects such as poholde and perturbing forces are eliminated then gyros 'point in a constant direction' in space. The curvature of the space-time around the Earth cause two effects on that 'constant direction' that was measured by GP-B, the geodetic and frame-dragging precessions.
So, the direction at which the gyroscopes point is not constant, but subjected to, at least, two effects: geodetic and frame-dragging precessions.

You have not understood the experiment. If other effects are eliminated then the gyro's do 'point in a constant direction' in space. It is space itself that is curved by the presence of the Earth's, and to a lesser degree, the Sun's gravitational fields. There is a further effect caused by the dilation (or 'curvature') of time.

It is this curvature of space-time that cause the geodetic precession and frame-dragging effects that GP-B measured.

Please start another thread about whether the Sun has a companion or not, it is irrelevant to this experiment.

Garth
 
  • #333
Offtopic posts have been removed, mostly to [thread=383916]here[/thread]. Please keep this thread on the topic of comparing published theories that have made proper predictions for the Gravity Probe B experiment.
 
  • #334
cristo said:
Offtopic posts have been removed, mostly to [thread=383916]here[/thread]. Please keep this thread on the topic of comparing published theories that have made proper predictions for the Gravity Probe B experiment.

I've noticed that you've deleted my last reply to Garth, in the name of "topicness". Do as you please. I couldn't care less, except to mention that I don't see why you didn't removed Garth's last comment too. He was the one which initiated that avenue towards "offtopicness", so to speak, presuming about the geometrical migth of GR.
 
  • #335
Hello Garth and all,

I just want to point out that strictly because of the very nature of this thread Garth you're not in a position to say "It is this curvature of space-time that cause the geodetic precession and frame-dragging effects that GP-B measured."

There may be other theories apart from mine, on the list of theories that are still viable in the light of the results, that give conceptual interpretations other than curvature for the measured effects.

But whether or not others do it, PSG certainly does. Equation 3 of the second paper on PSG published in a peer reviewed journal, here
http://journalgp.awardspace.com/journal/0202/020203.pdf [Broken]

generates the curvature component of the geodetic effect from flat space, simply from assuming that an effect like a refractive medium slows matter in the same way as it slows light. That's 2/3 of the effect potentially explained, and because the other 1/3 doesn't require curvature, the equation works as a proof that curvature doesn't necessarily have to be the cause. (Wikipedia, nevertheless, still defines the geodetic effect as a direct result of curvature.)

You checked the equation, found it gives the right numbers, and then put PSG back on the list of viable theories, after more than a year off it. The reason it deserved to go back on the list was that the only premiss that went into the equation was the original starting premiss of PSG, ie that light and matter are slowed by sqrt(1 - [2GM/rc^2]) in a gravity field. (So the equation vindicated the theory, and showed that in the earlier prediction I was wrong, but PSG wasn't.)

Sorry to restate this, but it seems directly relevant to what you've said about the interpretation of the results. (BTW, have been hoping to get back in touch anyway.)

Best wishes, Jonathan Kerr
 
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  • #336
JonathanK said:
But whether or not others do it, PSG certainly does. Equation 3 of the second paper on PSG published in a peer reviewed journal, here
http://journalgp.awardspace.com/journal/0202/020203.pdf [Broken]

generates the curvature component of the geodetic effect from flat space, simply from assuming that an effect like a refractive medium slows matter in the same way as it slows light. That's 2/3 of the effect potentially explained, and because the other 1/3 doesn't require curvature, the equation works as a proof that curvature doesn't necessarily have to be the cause. (Wikipedia, nevertheless, still defines the geodetic effect as a direct result of curvature.)

Very interesting. Are you suggesting that this is related also to the origin of the rotation of the planets, or I misunderstood/read too much?

Talking about the likely effect of refractive mediums, you might be interested in this 2003 paper by Consoli & Constanzo:
http://arxiv.org/abs/astro-ph/0311576" [Broken]

They re-analize the Michelson-Morley, Miller and other interferometry experiments, and show that in all cases a fringe shift is in fact detected, only its value is less than expected. They provide an excellent explanation for the differences, based on previous work by Kitto and Cahill, which goes back to Fresnel and the Fresnel drag coefficient.

I mention all this in this context due to a number of reasons:
- Consoli & Constanzo show that ether drag is dependant on the refractive index of the medium, and that this is the explanantion for the diverging results of the various interferometry experiments.
- They talk about a small similar effect caused by gravity, which resembles Fresnel drag, that will be equivalent to what you're proposing in your paper for 2/3 of the geodetic effect.

You might be interested also in this http://en.wikipedia.org/wiki/Aether_drag_hypothesis" [Broken]
and the linked references and papers. In particular those by D. Gezari.

Regards,
Mauro
 
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  • #337
Hello,

Thanks for the references, if we discuss it in detail it should be elsewhere (or we'll find ourselves there anyway!). But to make something clear - I don't believe in an ether, that was disproved. The original ether was thought to behave rather like matter behaves - unconventional 'ethers' have carried on, but they're so different they shouldn't be called that. The electromagnetic field is an example.

PSG is a gravity theory that comes out of a theory of time, and has a conceptual basis that's different from others I've seen. The visual picture that led to both is in a book 'Motion through time: the missing piece of the puzzle'. Initially it looks at the question of whether the future is decided or undecided, and points out that relativity and quantum theory tell us opposite things on that. My solution does overlap with some other theories, including refractive medium theories, which according to mine are incomplete. Incidentally, my view has special relativity entirely right, except in the interpretation, which is incomplete anyway.

To answer your question about the axial rotation of the planets - although most of them rotate in the right direction, I doubt if either version of the geodetic effect could slowly spin up the planets. But if mine could then it's likely the GR version could as well, so the question lands comfortably within standard physics, and the best thing is probably to ask Garth..

Jonathan
 
  • #338
JonathanK said:
Hello,

Thanks for the references, if we discuss it in detail it should be elsewhere (or we'll find ourselves there anyway!). But to make something clear - I don't believe in an ether, that was disproved. The original ether was thought to behave rather like matter behaves - unconventional 'ethers' have carried on, but they're so different they shouldn't be called that. The electromagnetic field is an example.

Oh, I don't believe either in a mechanical and material ether.
But in fact, I certainly do believe that reality is composed by more than matter. Particularly, I believe that there are fields and "forces" that have no material cause, but that interact with and affect matter.
Moreover: matter is just a manifestation of these fields and forces(a kind of condensation), under the right circumstances.
We may not know and observe these fields and forces today in a direct way, but we can start to know them by their effects. And the day will come when we'll be able to observe them directly again, in all their magnificence and harmony.
I also firmly believe that Science, in the great name and tradition that represents, must (and certainly will) study and incorporate these fields and forces into its subjects of study. And when I say Science I mean all the sciencies, from Physics to Biology, from the study of the mineral to the study of the living. Also the social sciences; and the most important study of all: the clear and real understanding of the human being and its true nature.
 
  • #339
Just a point: the geodetic effect is tiny unless you are dealing with an intense gravitational field, when the frame dragging effects would overwhelm it in the case of a rotating black hole, for example.

It is not responsible for the spinning up of the planets; that is due to the simply the conservation of angular momentum.

Unless a theory makes a specific prediction that is being tested by the GP-B experiment please post elsewhere.

Garth
 
  • #340
Garth said:
Just a point: the geodetic effect is tiny unless you are dealing with an intense gravitational field, when the frame dragging effects would overwhelm it in the case of a rotating black hole, for example.

It is not responsible for the spinning up of the planets; that is due to the simply the conservation of angular momentum.

That can't be so simple, or it is incomplete, considering by example that Venus is slowly spinning in the opposite direction.
Electromagnetic effects will have to be taken into account, sooner or later, to explain this solar system anomaly, and also others.
 
  • #341
Not at all, Venus could easily have been 'flipped' as the result of a past collision. The rotational axis of Uranus is similarly goofy, it points almost directly at the sun [re: http://www.windows2universe.org/our_solar_system/planets_table.html] and also has a slightly retrograde rotation. The former planet Pluto also suffers from this condition. Their current axial orientation is unrelated to how the planets acquired spin.
 
  • #342
Chronos said:
Not at all, Venus could easily have been 'flipped' as the result of a past collision. The rotational axis of Uranus is similarly goofy, it points almost directly at the sun [re: http://www.windows2universe.org/our_solar_system/planets_table.html] and also has a slightly retrograde rotation. The former planet Pluto also suffers from this condition. Their current axial orientation is unrelated to how the planets acquired spin.

"Simply". "Easily". I'm dismayed by your fondness for "easy" explanations. "Easy" meaning, of course, that you can explain things (independently of how improbable these explanations really are) using standard physics and models.

Venus has a super-rotating atmosphere. That atmosphere circles the planet in around 4 (earth) days in a westward (Earth's west) direction. That is, most likely, the cause of the planet anomalous spin. The westward(Earth) spinning atmosphere gradually slowed down, and eventually reversed, the spin of the underlying solid planet, due to friction based momentum transfer.

Now, (and this independently if it is the cause of Venus's actual spin or not), we have to explain the reason for the atmosphere's super rotation. And to explain that it will be unavoidable to reckon with and take into account electromagnetic effects.

References:
http://en.wikipedia.org/wiki/Atmosphere_of_Venus
http://www.esa.int/SPECIALS/Venus_Express/SEMYGQEFWOE_0.html
http://www.physorg.com/news194504586.html
 
  • #343
You can always blame it on polhode motion : )
 
  • #344
'Simple' explanations are usually more reliable than 'amazing' explanations, maurol2. Avoiding the issue I raised by injecting unrelated 'facts' does not rescue your 'amazing' model.
 
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  • #345
Chronos said:
'Simple' explanations are usually more reliable than 'amazing' explanations, maurol2. Avoiding the issue I raised by injecting unrelated 'facts' does not rescue your 'amazing' model.

What issue do you raised? The fact that the standard model of solar system formation has a potential explanation for the anomalous rotation of some planets, involving one or multiple collisions, does not mean that other cause can be the one responsible.

Uranus, by example, could be a former extrasolar planet, acquired with that particular spin angle.
Or it could have been inclined by the combined tidal effects of Saturn and Jupiter, when they crossed their 1:2 resonance, like this paper suggests:
http://www.planetary.org/blog/article/00000553/[/URL]
[url]http://www.nature.com/nature/journal/v440/n7088/abs/nature04577.html[/url]
That would explain the migration of its satellites, by the way.

With regard to Venus, what I find amazing (without the quotes) is that Venus atmosphere is super rotating with westwards winds of around 200 m/s. Excuse me, but what's the "standard" explanation for that?

And with those continuous and extremely strong winds I find plausible(if not obvious), they can be the real cause for Venus's actual spin.

The right thing to do would be to do the calculations, assuming an initial spin in accordance with Venus's position in its orbit, and testing for various atmospheric densities, velocity gradients, Venus's estimated age, etc. etc.

I don't have the time to do that, but maybe some other guy can do it. The hypothesis deserves some serious consideration and research. By the way, I don't think it is an amazing explanation, but a simple, elegant, and pretty obvious(if you think outside the standard box) one.

Finally: As far as I know, Venus's atmospheric super-rotation should be caused by the interaction between Venus's atmosphere and the solar wind. Here are some additional papers, which show a correlation between Earth's atmospheric Angular Momentum (AAM) and Solar Activity (SA). Interestingly, Earth's AAM is also retrograde in its general tendency, and of course, variations on Earth's AAM affect Length of Day (Length of Day) due to conservation of Angular Momentum:
[url]http://adsabs.harvard.edu/abs/2004cosp...35.4731A[/url]
[url]http://www.cgd.ucar.edu/cas/adai/papers/Abarca_delRio_etal_JGeodyn03.pdf[/url]


Mauro Lacy
 
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  • #346
maurol2 said:
What issue do you raised? The fact that the standard model of solar system formation has a potential explanation for the anomalous rotation of some planets, involving one or multiple collisions, does not mean that other cause can be the one responsible.
I meant: can't.

The right thing to do would be to do the calculations, assuming an initial spin in accordance with Venus's position in its orbit, and testing for various atmospheric densities, velocity gradients, Venus's estimated age, etc. etc.
I meant: Venus's position in the solar system (distance to the Sun)

Incidentally, a similar process can probably explain Mercury comparatively slow rotation rate.
 
  • #347
It is nearly a year since the last update of Mission Status on the GP-B website and while waiting for a final statement we note the existing published results are homing in on the GR prediction.

The gross GR prediction, including Solar GR effects and guide star motion is:
Geodetic (N-S) –6571 +/- 1 mas/yr and
Frame dragging (E-W) -75 +/1 1 mas /yr.

The average results over the 4 gyros is Geodetic = –6565 mas /yr i.e. within 0.1%,
and Frame dragging = -81 mas /yr i.e. within 8 % of the GR predictions.
These are consistent with GR to within the present experimental error bars.

Several of the alternative theories on the list I have compiled predict the same results as GR, therefore they fall into a different category to those that can be tested against GR by this experiment.

My news is that I have reviewed my theory (self-creation cosmology) and republished. The field equation can be cast in three forms, as explained in my paper, the Einstein conformal frame, the effective Jordan conformal frame and the true Jordan frame. The standard Brans Dicke theory is cast in the effective Jordan frame as was my 2002 version with its heterodox prediction for GP-B. Cast in the true Jordan frame (JF) it makes the same GP-B prediction as GR and therefore has not been falsified by the experiment. [Note of explanation: In SCC as I now understand it the true JF is to be used for the behaviour of massive particles, i.e. the gyros of GP-B and the effective JF for massless particles, i.e. the behaviour of light.]

  1. Einstein's General Relativity(GR)
  2. Brans-Dicke theory (BD)
  3. Moffat's Nonsymmetric Gravitational theory (NGT)
  4. Stanley Robertson's Newtonian Gravity theory (NG),
  5. F. Henry-Couannier's Dark Gravity theory (DG).
  6. Alexander and Yunes' prediction for the Chern-Simons gravity theory (CS).
  7. Kris Krogh's Wave Gravity theory (WG)
  8. Hongya Liu & J. M. Overduin prediction of the http://www.journals.uchicago.edu/ApJ/journal/issues/ApJ/v538n1/50681/50681.text.html?erFrom=5252751197746712308Guest#sc8 [Broken] gravity theory (KK).
  9. Kerr's Planck Scale Gravity: Predictions of Experimental Results from a Gravity Theory (PSG)
  10. My Self Creation Cosmology (SCC),
The predictions are now:

GP-B Geodetic gross precession (North-South).

  1. GR = -6606 mas/yr.
  2. BD = -[itex](3\omega + 4)/(3\omega + 6)[/itex] 6.606 arcsec/yr. where now [itex]\omega[/itex] >60.
  3. NGT = -(6606 - a small [itex]\sigma[/itex] correction) mas/yr.
  4. SCC = -6606 mas/yr.
  5. NG = -6606 mas/yr.
  6. DG = -6606 mas/yr.
  7. CS = -6606 mas/yr.
  8. WG = -6606 mas/yr.
  9. KK = -(1 + b/6 - 3b2 + ...) 6606 mas/yr. where 0 < b < 0.07.
  10. PSG = -6606 mas/yr.

GPB gravitomagnetic frame dragging gross precession (East-West).

  1. GR = -39 mas/yr.
  2. BD = -[itex](2\omega + 3)/(2\omega + 4)[/itex] 39 mas/yr.
  3. SCC = -39 mas/yr.
  4. NGT = -39 mas/yr.
  5. NG = -39 mas/yr.
  6. DG = 0 mas/yr.
  7. CS = -39 mas/yr. + CS correction
  8. WG = 0 mas/yr.
  9. KK = -39 mas/yr.
  10. PSG = -39 mas/yr.

Those theories being tested against GR by this experiment are:
BD – Brans Dicke theory; with [itex]\omega[/itex] > 660.
KK - Kaluza-Klein gravity theory; with b < 1.5 x 10-4.
NGT – Nonsymmetric Gravitational theory; it depends on how ‘small’ the [itex]\sigma[/itex] correction is!

The ones falsified by the present results are:
DG - Dark Gravity theory.
WG - Wave Gravity theory.

And the ones not tested against GR by this experiment, and are still consistent with GP-B are:
SCC - Self Creation Cosmology theory.
NG - Newtonian Gravity theory.
CS - Chern-Simons gravity theory.
PSG - Planck Scale Gravity theory.

Garth
 
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  • #348
Thanks Garth,

Just to point out that the link you posted with PSG theory was the wrong one, it should be
http://journalgp.awardspace.com/journal/0202/020203.pdf [Broken]

That's the paper (in a peer reviewed journal), "A derivation of the geodetic effect without space curvature", with the equation that shows a 'geodetic' effect with the same value as that of the GR curvature component - but being generated from flat space and using only the simple starting premiss of PSG theory. So that's the relevant link, as it shows why PSG theory is on the 'still consistent with GP-B' list, and gives the same result as GR.

Incidentally, the paper may be a first, in that it may be the first time an alternative interpretation for the geodetic effect (to the GR one) has been put forward on a mathematical basis. The generalised equation is for a single orbit around any mass.

thanks, Jonathan
 
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  • #349
Wish I shared your faith in the GP-B results. With so much unexpected noise (all of which needed to be properly accounted for and canceled out to have any chance of getting meaningful results) GP-B became more of an engineering project than a science experiment. Fortunately an objective panel of 15 scientists at NASA recognized the difference, pulled the funding and stated the truth; GP-B “failed to reach its goals”.

While subsequent attempts to engineer a solution were and are commendable they are highly suspect. Any methodology that relies on canceling out unanticipated “noise” by categorizing such unwanted effects as impossible to predict polhode motion (or anything else that is inherently unpredictable) negates the validity of the original science experiment. Good science relies on making and meeting predictions. Getting close to those predictions by “engineering” a preferred result is hardly science.

The only alternative theories that should be taken seriously are those that predicted the unwanted results without need to rely on cancellation of unpredictable signals.
 
  • #350
Polestar101 said:
Wish I shared your faith in the GP-B results. With so much unexpected noise (all of which needed to be properly accounted for and canceled out to have any chance of getting meaningful results) GP-B became more of an engineering project than a science experiment. Fortunately an objective panel of 15 scientists at NASA recognized the difference, pulled the funding and stated the truth; GP-B “failed to reach its goals”.

While subsequent attempts to engineer a solution were and are commendable they are highly suspect. Any methodology that relies on canceling out unanticipated “noise” by categorizing such unwanted effects as impossible to predict polhode motion (or anything else that is inherently unpredictable) negates the validity of the original science experiment. Good science relies on making and meeting predictions. Getting close to those predictions by “engineering” a preferred result is hardly science.

The only alternative theories that should be taken seriously are those that predicted the unwanted results without need to rely on cancellation of unpredictable signals.

Although I share your reservations and asked a question along similar lines to Francis Everitt about the error reduction at the April 2007 APS meeting, I have no doubt the signal did trace the GR prediction as can be seen here.

Francis Everitt's reply was that the one thing they mustn't do was perform the analysis with the answer (GR) in mind but try and make it as 'double blind' as possible. The procedure was to carry out the analysis in two teams using two different methods, an algebraic one and a geometric one, with both teams not knowing the proper motion of the guide star until they both came up with their answers. These were then compared for consistency and the proper motion then allowed for to get the result. Also the four gyros are analysed independently to help remove experimental errors by averaging.

Obviously then they have had to refine the process several times over the years to get to the latest published results so the further refinements would not have been 'double blind'.

They intended to complete all possible error reduction by this year and get a +/- 1 mas/yr accuracy ( an order of magnitude larger than originally hoped for), and unlesss they have succeeded in their aims and publish finally before the end of the year it may be that the present state of play is all they have been able to achieve, i.e. a ~ +/- 10 mas/yr (from the diagram of 50% error ellipses).

The level 2 data after preliminary processing is available here but does not mean much until "considerable further processing to calibrate the instrument, remove the effects of vehicle dynamics, aberration, guide star proper motion, small classical torques, and other systematic effects before any results about gyro orientation history can be determined".

"This refined processing of the data, which will result in a Level 3 data archive, is precisely what the GP-B team has been working on since October 2005" and they say will also be publicly available. I don't think I'll have the energy to sort through it to check it though! You might!

Garth
 
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<h2>1. What is Gravity Probe B and what is its purpose?</h2><p>Gravity Probe B is a satellite launched by NASA in 2004 to test Einstein's theory of general relativity. Its purpose is to measure the effects of Earth's gravity on the space-time around it, and to provide evidence for or against alternative theories of gravity.</p><h2>2. How does Gravity Probe B work?</h2><p>Gravity Probe B uses four gyroscopes, which are spinning spheres made of fused quartz, to measure tiny changes in their orientation caused by the warping of space and time around Earth. These changes are then compared to predictions made by Einstein's theory of general relativity.</p><h2>3. What alternative theories of gravity is Gravity Probe B testing?</h2><p>Gravity Probe B is primarily testing the theory of general relativity, but it is also looking for evidence of other theories that attempt to explain gravity, such as string theory and loop quantum gravity.</p><h2>4. What have been the results of Gravity Probe B's experiments so far?</h2><p>After nearly a decade of collecting data, Gravity Probe B has confirmed Einstein's theory of general relativity to a high degree of accuracy. However, the data is still being analyzed and there may be potential for new discoveries or insights into alternative theories of gravity.</p><h2>5. How does the Gravity Probe B mission impact our understanding of the universe?</h2><p>The Gravity Probe B mission has provided strong evidence for the validity of Einstein's theory of general relativity, which has been the basis for our understanding of gravity for over a century. It also opens up new possibilities for exploring alternative theories of gravity and expanding our understanding of the universe and its fundamental laws.</p>

1. What is Gravity Probe B and what is its purpose?

Gravity Probe B is a satellite launched by NASA in 2004 to test Einstein's theory of general relativity. Its purpose is to measure the effects of Earth's gravity on the space-time around it, and to provide evidence for or against alternative theories of gravity.

2. How does Gravity Probe B work?

Gravity Probe B uses four gyroscopes, which are spinning spheres made of fused quartz, to measure tiny changes in their orientation caused by the warping of space and time around Earth. These changes are then compared to predictions made by Einstein's theory of general relativity.

3. What alternative theories of gravity is Gravity Probe B testing?

Gravity Probe B is primarily testing the theory of general relativity, but it is also looking for evidence of other theories that attempt to explain gravity, such as string theory and loop quantum gravity.

4. What have been the results of Gravity Probe B's experiments so far?

After nearly a decade of collecting data, Gravity Probe B has confirmed Einstein's theory of general relativity to a high degree of accuracy. However, the data is still being analyzed and there may be potential for new discoveries or insights into alternative theories of gravity.

5. How does the Gravity Probe B mission impact our understanding of the universe?

The Gravity Probe B mission has provided strong evidence for the validity of Einstein's theory of general relativity, which has been the basis for our understanding of gravity for over a century. It also opens up new possibilities for exploring alternative theories of gravity and expanding our understanding of the universe and its fundamental laws.

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