Flatness (systems theory): Difference between revisions
en>Togo59 mNo edit summary |
en>Larry Cox 2 Added flat pseudospectral method link |
||
Line 1: | Line 1: | ||
{{about|precession of orbiting bodies|observing binary stars|de Sitter double star experiment}} | |||
[[File:Geodetic effekt.jpg|thumb|A representation of the geodetic effect.]] | |||
The '''geodetic effect''' (also known as '''geodetic precession''', '''de Sitter precession''' or '''de Sitter effect''') represents the effect of the curvature of [[spacetime]], predicted by [[general relativity]], on a vector carried along with an orbiting body. For example, the vector could be the angular momentum of a gyroscope orbiting the Earth, as carried out by the [[Gravity Probe B]] experiment. The geodetic effect was first predicted by [[Willem de Sitter]] in 1916, who provided relativistic corrections to the Earth–Moon system's motion. De Sitter's work was extended in 1918 by [[Jan Schouten]] and in 1920 by [[Adriaan Fokker]].<ref name=Eisenstaedt>{{cite book |title=Studies in the History of General Relativity |author=Jean Eisenstaedt, Anne J. Kox |url=http://books.google.com/?id=vDHCF_3vIhUC&pg=PA42 |page = 42 |isbn=0-8176-3479-7 |publisher=Birkhäuser |year=1988}}</ref> | |||
It can also be applied to a particular secular [[precession]] of astronomical orbits, equivalent to the rotation of the [[Laplace–Runge–Lenz vector]].<ref>{{cite journal | last = de Sitter | first = W | year = 1916 | title = On Einstein's Theory of Gravitation and its Astronomical Consequences | journal = Mon. Not. Roy. Astron. Soc. | volume = 77 | pages = 155–184|bibcode = 1916MNRAS..77..155D }}</ref> | |||
The term '''geodetic effect''' has two slightly different meanings as the moving body may be spinning or non-spinning. Non-spinning bodies move in [[geodesic]]s, whereas spinning bodies move in slightly different orbits.<ref>Rindler Page 254</ref> | |||
The difference between de Sitter precession and [[Lense–Thirring precession]] (frame dragging) is that the de Sitter effect is due simply to the presence of a central mass, whereas Lense–Thirring precession is due to the rotation of the central mass. The total precession is calculated by combining the de Sitter precession with the Lense–Thirring precession. | |||
==Experimental confirmation== | |||
The geodetic effect was verified to a precision of better than 0.5% percent by [[Gravity Probe B]], an experiment which measures the tilting of the spin axis of [[gyroscope]]s in orbit about the Earth.<ref> | |||
{{cite web | |||
|author=Everitt, C.W.F.; Parkinson, B.W. | |||
|url=http://einstein.stanford.edu/content/final_report/GPB_Final_NASA_Report-020509-web.pdf | |||
|title=Gravity Probe B Science Results—NASA Final Report | |||
|format=PDF | |||
|year=2009 | |||
|accessdate=2009-05-02 | |||
}}</ref> The first results were announced on April 14, 2007 at the meeting of the [[American Physical Society]].<ref>http://einstein.stanford.edu/content/press_releases/SU/pr-aps-041807.pdf</ref> | |||
==Formulae== | |||
{{General relativity|cTopic=Phenomena}} | |||
To derive the precession, assume the system is in a rotating [[Schwarzschild metric]]. The nonrotating metric is | |||
:<math>ds^2 = dt^2 \left(1-\frac{2m}{r}\right) - dr^2 \left(1 - \frac{2m}{r}\right)^{-1} - r^2 (d\theta^2 + \sin^2 \theta \, d\phi'^2) , | |||
</math> | |||
where ''c'' = ''G'' = 1. | |||
We introduce a rotating coordinate system, with an angular velocity <math>\omega</math>, such that a satellite in a circular orbit in the θ = π/2 plane remains at rest. This gives us | |||
:<math>d\phi = d\phi' - \omega \, dt.</math> | |||
In this coordinate system, an observer at radial position ''r'' sees a vector positioned at ''r'' as rotating with angular frequency ω. This observer, however, sees a vector positioned at some other value of ''r'' as rotating at a different rate, due to relativistic time dilation. Transforming the Schwarzschild metric into the rotating frame, and assuming that <math>\theta</math> is a constant, we find | |||
:<math> | |||
ds^2 = \left(1-\frac{2m}{r}-r^2 \beta\omega^2 \right)\left(dt-\frac{r^2 \beta\omega}{1-2m/r-r^2 \beta\omega^2} \, d\phi\right)^2 | |||
- dr^2 \left(1-\frac{2m}{r}\right)^{-1} - \frac{r^2 \beta - 2mr\beta}{1-2m/r - r^2 \beta\omega^2} \, d\phi^2 | |||
</math> | |||
with <math>\beta = \sin^2(\theta)</math>. For a body orbiting in the θ = π/2 plane, we will have β = 1, and the body's world-line will maintain constant spatial coordinates for all time. Now, the metric is in the [[canonical form]] | |||
:<math>ds^2 = e^{2\Phi}\left(dt - w_i \, dx^i \right)^2 - k_{ij} \, dx^i \, dx^j.</math> | |||
From this canonical form, we can easily determine the rotational rate of a gyroscope in proper time | |||
:<math> | |||
\Omega = \frac{\sqrt{2}}{4} e^\Phi [k^{ik}k^{jl}(\omega_{i,j}-\omega_{j,i})(\omega_{k,l} - \omega_{l,k})]^{1/2} = | |||
\frac{ \sqrt{\beta} \omega (r -3 m) }{ r- 2 m - \beta \omega^2 r^3 } | |||
=\sqrt{\beta}\omega. | |||
</math> | |||
where the last equality is true only for free falling observers for which | |||
there is no acceleration, and thus <math> \Phi,_{i} = 0</math>. This leads to | |||
:<math> | |||
\Phi,_i = \frac{2m/r^2 - 2r\beta\omega^2}{2(1-2m/r-r^2 \beta\omega^2)} = 0. | |||
</math> | |||
Solving this equation for ω yields | |||
:<math> | |||
\omega^2 = \frac{m}{r^3 \beta}. | |||
</math> | |||
This is essentially [[Kepler's laws|Kepler's law of periods]], which happens to be relativistically exact when expressed in terms of the time coordinate ''t'' of this particular rotating coordinate system. In the rotating frame, the satellite remains at rest, but an observer aboard the satellite sees the gyroscope's angular momentum vector precessing at the rate ω. This observer also sees the distant stars as rotating, but they rotate at a slightly different rate due to time dilation. Let τ be the gyroscope's [[proper time]]. Then | |||
:<math> | |||
\Delta \tau = \left(1-\frac{2m}{r} - r^2 \beta\omega^2 \right)^{1/2} \, dt = \left(1-\frac{3m}{r}\right)^{1/2} \, dt. | |||
</math> | |||
The −2''m''/''r'' term is interpreted as the gravitational time dilation, while the additional −''m''/''r'' is due to the rotation of this frame of reference. Let α' be the accumulated precession in the rotating frame. Since <math>\alpha' = \Omega \Delta \tau</math>, the precession over the course of one orbit, relative to the distant stars, is given by: | |||
:<math> | |||
\alpha = \alpha' + 2\pi = -2 \pi \sqrt{\beta}\Bigg( \left(1-\frac{3m}{r} \right)^{1/2} - 1 \Bigg). | |||
</math> | |||
With a first-order [[Taylor series]] we find | |||
:<math> | |||
\alpha \approx \frac{3\pi m}{r}\sqrt{\beta} = \frac{3\pi m}{r}\sin(\theta). | |||
</math> | |||
==Thomas precession== | |||
One can attempt to break down the de Sitter precession into a [[kinematic]] effect called [[Thomas precession]] combined with a geometric effect caused by gravitationally curved spacetime. At least one author<ref>Rindler, Page 234</ref> does describe it this way, but others state that "The Thomas precession comes into play for a gyroscope on the surface of the Earth ..., but not for a gyroscope in a freely moving satellite."<ref>Misner, Thorne, and Wheeler, Gravitation, p. 1118</ref> An objection to the former interpretation is that the Thomas precession required has the wrong sign. | |||
==See also== | |||
* [[Frame-dragging]] | |||
* [[Timeline of gravitational physics and relativity]] | |||
==Notes== | |||
<references/> | |||
==References== | |||
*[[Wolfgang Rindler]] (2006) Relativity: special, general, and cosmological (2nd Ed.), Oxford University Press, ISBN 978-0-19-856731-8 | |||
==External links== | |||
* Gravity Probe B web site at [http://www.nasa.gov/mission_pages/gpb/index.html NASA] and [http://einstein.stanford.edu/ Stanford University] | |||
* [http://science.nasa.gov/headlines/y2000/geodetic.htm Precession in Curved Space "The Geodetic Effect"] | |||
*[http://sciencepal.blogspot.com/2008_05_12_archive.html Geodetic Effect] | |||
{{Relativity}} | |||
[[Category:General relativity]] |
Latest revision as of 04:37, 20 June 2013
29 yr old Orthopaedic Surgeon Grippo from Saint-Paul, spends time with interests including model railways, top property developers in singapore developers in singapore and dolls. Finished a cruise ship experience that included passing by Runic Stones and Church.
The geodetic effect (also known as geodetic precession, de Sitter precession or de Sitter effect) represents the effect of the curvature of spacetime, predicted by general relativity, on a vector carried along with an orbiting body. For example, the vector could be the angular momentum of a gyroscope orbiting the Earth, as carried out by the Gravity Probe B experiment. The geodetic effect was first predicted by Willem de Sitter in 1916, who provided relativistic corrections to the Earth–Moon system's motion. De Sitter's work was extended in 1918 by Jan Schouten and in 1920 by Adriaan Fokker.[1]
It can also be applied to a particular secular precession of astronomical orbits, equivalent to the rotation of the Laplace–Runge–Lenz vector.[2]
The term geodetic effect has two slightly different meanings as the moving body may be spinning or non-spinning. Non-spinning bodies move in geodesics, whereas spinning bodies move in slightly different orbits.[3]
The difference between de Sitter precession and Lense–Thirring precession (frame dragging) is that the de Sitter effect is due simply to the presence of a central mass, whereas Lense–Thirring precession is due to the rotation of the central mass. The total precession is calculated by combining the de Sitter precession with the Lense–Thirring precession.
Experimental confirmation
The geodetic effect was verified to a precision of better than 0.5% percent by Gravity Probe B, an experiment which measures the tilting of the spin axis of gyroscopes in orbit about the Earth.[4] The first results were announced on April 14, 2007 at the meeting of the American Physical Society.[5]
Formulae
Diving Coach (Open water ) Dominic from Kindersley, loves to spend some time classic cars, property developers in singapore house for rent (Source Webpage) and greeting card collecting. Finds the world an interesting place having spent 8 days at Cidade Velha.
To derive the precession, assume the system is in a rotating Schwarzschild metric. The nonrotating metric is
where c = G = 1.
We introduce a rotating coordinate system, with an angular velocity , such that a satellite in a circular orbit in the θ = π/2 plane remains at rest. This gives us
In this coordinate system, an observer at radial position r sees a vector positioned at r as rotating with angular frequency ω. This observer, however, sees a vector positioned at some other value of r as rotating at a different rate, due to relativistic time dilation. Transforming the Schwarzschild metric into the rotating frame, and assuming that is a constant, we find
with . For a body orbiting in the θ = π/2 plane, we will have β = 1, and the body's world-line will maintain constant spatial coordinates for all time. Now, the metric is in the canonical form
From this canonical form, we can easily determine the rotational rate of a gyroscope in proper time
where the last equality is true only for free falling observers for which there is no acceleration, and thus . This leads to
Solving this equation for ω yields
This is essentially Kepler's law of periods, which happens to be relativistically exact when expressed in terms of the time coordinate t of this particular rotating coordinate system. In the rotating frame, the satellite remains at rest, but an observer aboard the satellite sees the gyroscope's angular momentum vector precessing at the rate ω. This observer also sees the distant stars as rotating, but they rotate at a slightly different rate due to time dilation. Let τ be the gyroscope's proper time. Then
The −2m/r term is interpreted as the gravitational time dilation, while the additional −m/r is due to the rotation of this frame of reference. Let α' be the accumulated precession in the rotating frame. Since , the precession over the course of one orbit, relative to the distant stars, is given by:
With a first-order Taylor series we find
Thomas precession
One can attempt to break down the de Sitter precession into a kinematic effect called Thomas precession combined with a geometric effect caused by gravitationally curved spacetime. At least one author[6] does describe it this way, but others state that "The Thomas precession comes into play for a gyroscope on the surface of the Earth ..., but not for a gyroscope in a freely moving satellite."[7] An objection to the former interpretation is that the Thomas precession required has the wrong sign.
See also
Notes
- ↑ 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.
My blog: http://www.primaboinca.com/view_profile.php?userid=5889534 - ↑ One of the biggest reasons investing in a Singapore new launch is an effective things is as a result of it is doable to be lent massive quantities of money at very low interest rates that you should utilize to purchase it. Then, if property values continue to go up, then you'll get a really high return on funding (ROI). Simply make sure you purchase one of the higher properties, reminiscent of the ones at Fernvale the Riverbank or any Singapore landed property Get Earnings by means of Renting
In its statement, the singapore property listing - website link, government claimed that the majority citizens buying their first residence won't be hurt by the new measures. Some concessions can even be prolonged to chose teams of consumers, similar to married couples with a minimum of one Singaporean partner who are purchasing their second property so long as they intend to promote their first residential property. Lower the LTV limit on housing loans granted by monetary establishments regulated by MAS from 70% to 60% for property purchasers who are individuals with a number of outstanding housing loans on the time of the brand new housing purchase. Singapore Property Measures - 30 August 2010 The most popular seek for the number of bedrooms in Singapore is 4, followed by 2 and three. Lush Acres EC @ Sengkang
Discover out more about real estate funding in the area, together with info on international funding incentives and property possession. Many Singaporeans have been investing in property across the causeway in recent years, attracted by comparatively low prices. However, those who need to exit their investments quickly are likely to face significant challenges when trying to sell their property – and could finally be stuck with a property they can't sell. Career improvement programmes, in-house valuation, auctions and administrative help, venture advertising and marketing, skilled talks and traisning are continuously planned for the sales associates to help them obtain better outcomes for his or her shoppers while at Knight Frank Singapore. No change Present Rules
Extending the tax exemption would help. The exemption, which may be as a lot as $2 million per family, covers individuals who negotiate a principal reduction on their existing mortgage, sell their house short (i.e., for lower than the excellent loans), or take part in a foreclosure course of. An extension of theexemption would seem like a common-sense means to assist stabilize the housing market, but the political turmoil around the fiscal-cliff negotiations means widespread sense could not win out. Home Minority Chief Nancy Pelosi (D-Calif.) believes that the mortgage relief provision will be on the table during the grand-cut price talks, in response to communications director Nadeam Elshami. Buying or promoting of blue mild bulbs is unlawful.
A vendor's stamp duty has been launched on industrial property for the primary time, at rates ranging from 5 per cent to 15 per cent. The Authorities might be trying to reassure the market that they aren't in opposition to foreigners and PRs investing in Singapore's property market. They imposed these measures because of extenuating components available in the market." The sale of new dual-key EC models will even be restricted to multi-generational households only. The models have two separate entrances, permitting grandparents, for example, to dwell separately. The vendor's stamp obligation takes effect right this moment and applies to industrial property and plots which might be offered inside three years of the date of buy. JLL named Best Performing Property Brand for second year running
The data offered is for normal info purposes only and isn't supposed to be personalised investment or monetary advice. Motley Fool Singapore contributor Stanley Lim would not personal shares in any corporations talked about. Singapore private home costs increased by 1.eight% within the fourth quarter of 2012, up from 0.6% within the earlier quarter. Resale prices of government-built HDB residences which are usually bought by Singaporeans, elevated by 2.5%, quarter on quarter, the quickest acquire in five quarters. And industrial property, prices are actually double the levels of three years ago. No withholding tax in the event you sell your property. All your local information regarding vital HDB policies, condominium launches, land growth, commercial property and more
There are various methods to go about discovering the precise property. Some local newspapers (together with the Straits Instances ) have categorised property sections and many local property brokers have websites. Now there are some specifics to consider when buying a 'new launch' rental. Intended use of the unit Every sale begins with 10 p.c low cost for finish of season sale; changes to 20 % discount storewide; follows by additional reduction of fiftyand ends with last discount of 70 % or extra. Typically there is even a warehouse sale or transferring out sale with huge mark-down of costs for stock clearance. Deborah Regulation from Expat Realtor shares her property market update, plus prime rental residences and houses at the moment available to lease Esparina EC @ Sengkang - ↑ Rindler Page 254
- ↑ Template:Cite web
- ↑ http://einstein.stanford.edu/content/press_releases/SU/pr-aps-041807.pdf
- ↑ Rindler, Page 234
- ↑ Misner, Thorne, and Wheeler, Gravitation, p. 1118
References
- Wolfgang Rindler (2006) Relativity: special, general, and cosmological (2nd Ed.), Oxford University Press, ISBN 978-0-19-856731-8
External links
- Gravity Probe B web site at NASA and Stanford University
- Precession in Curved Space "The Geodetic Effect"
- Geodetic Effect