User:AbiLtoCen/Sandbox

In the year 1926 the astrophysicist Robert Emden has published the article Aberration und Relativitätstheorie in the journal Die Naturwissenschaften.^[2] In this article he states, that the direction of a light ray isn't influenced by the motion of the star and neither by the motion of the earth.^[3] At that time, the opponents of the special theory of relativity reasoned that the theory must be flawed, because it would state that the stellar aberration would depend on the relative velocity of the star — which would be in contradiction to observation — and R. Emden's article explains that the special theory of relativity does not predict this. Today, the special theory of relativity isn't contested anymore but there are still articles that suggest that the aberration would depend on the relative velocity of the star.^[4]

The explanation in the main article is a good and a mathematically compact one, which uses the (relativistic) w:en:velocity-addition formula. In this article only the Lorentz transformation of the star's coordinates is used. This derivation is similar but since it only uses the star's coordinates at the time of emission, it has the additional formal advantage there is no place for the relative velocity of the star towards the astronomer and therefore it's evident that the observed position position doesn't depend on the star's velocity — provided that the resultant change of position is much smaller than the distance between star and earth.^[5] The observed position of the star wouldn't depend on the earth's motion either, if the astronomer could use the same inertial frame of reference all the time. But of course that is technically impossible,^[6] the astronomer uses his current rest frame and these current rest frames are different at different times as the earth orbits around the sun. It is mathematically convenient to declare the position of star in a rest frame of the sun (more exactly: the center of mass of the solar system) as the "real" position and that the difference to this "real" position derives form the "aberration".^[7]

Sample calculation edit

S and S' are (quasi-)inertial frames of reference and the reference frame S' is in uniform motion with v_x = 0,5c relative to S, such that in the future the star comes nearer to the origin of the coordinate system (and consequently further afar in the past). The x-,y- and z-axes of both systems ought to be parallel and at time t=t'=0 the origins of both systems ought to coincide. Therefore one gets according to Lorentz transformation: ${\displaystyle \scriptstyle \beta =v/c}$ , ${\displaystyle \scriptstyle \gamma =1/{\sqrt {1-\beta ^{2}}}}$ : y'=y ; z=z'; ${\displaystyle \scriptstyle x'=\gamma \cdot (x-\beta \cdot ct)}$ 

Suppose now that the star emitted a light signal at time ${\displaystyle \scriptstyle c\,t_{1}=-5\,Ly}$  at location ${\displaystyle \scriptstyle x_{1}=4\,Ly\;,\;y_{1}=3\,Ly\;,\;z_{1}=0}$  (S coordinates) and that this light signal is received by an astronomer at time ${\displaystyle \scriptstyle c\,t_{2}=0}$  at location ${\displaystyle \scriptstyle x_{2}=0\;,\;y_{2}=0\;,\;z_{2}=0}$ .

In S the star's position and the x-axis form an angle ${\displaystyle \delta }$  with ${\displaystyle \scriptstyle \tan \delta =3/4\;\rightarrow \;\delta =36.87^{\circ }}$  But in S' ${\displaystyle \scriptstyle x_{1}'=\gamma \cdot (x_{1}-\beta \cdot c\,t_{1})=1,1547\cdot (4Lj-0,5\cdot (-5Lj))=7,50555Lj;\quad y_{1}'=y_{1}=3Lj}$  and therefore the angle ${\displaystyle \delta '}$  between the star's position and x'-axis^[8] is ${\displaystyle \scriptstyle \tan \delta '=y_{1}'/x_{1}'=3/7,50555\;\rightarrow \;\delta '=21,79^{\circ }}$ 

Calculation with help of the formula in w:en:aberration of light#Explanation gives the same result: ${\displaystyle \scriptstyle \tan(\delta '/2)=\tan(\delta /2)\cdot {\sqrt {(1-0,5)/(1+0,5)}}=\tan(36,87^{\circ }/2)\cdot {\sqrt {1/3}}=0,19245\;}$  ${\displaystyle \scriptstyle \;\rightarrow \;\delta '/2=10,89^{\circ }\;\rightarrow \;\delta '=21,79^{\circ }}$ .

For the derivation it is assumed, that the light signal only travels through space regions where the gravitation field is negligible. Hence is suffices to use special relativity and the path of the light signal is a straight line in any inertial frame of reference.

Observation in the rest frame S of the center of mass of our solar system

The rest frame of the center of mass (barycenter) is a very good^[9] quasi-inertial frame of reference for periods of time in the order of thousands of years, since our solar system needs about 230 million years (w:en:galactic year) to move completely around the center of the w:en;Milky Way. The space coordinates of this frame of reference form a w:en:Cartesian coordinate system.

In the reference frame S ${\displaystyle (x_{1}|y_{1}|0|c\,t_{1})}$  with ${\displaystyle c\,t_{1}<0}$  and ${\displaystyle (x_{1}|y_{1})\neq (0|0)}$  are the (space-time) coordinates at which the star emits a light signal and ${\displaystyle (0|0|0|0)}$  are the coordinates at which the astronomer receives the light signal.

In reference frame S the light signal starts at ${\displaystyle t_{1}<0}$  and stops at time ${\displaystyle t_{2}=0}$  and therefore the light signal did cover the distance ${\displaystyle d=c\cdot (0-t_{1})=-c\,t_{1}}$  .

In S the path of the light signal is a straight line and it forms an angle ${\displaystyle \delta }$  with the x-axis (in the x-y-plane) with: ${\displaystyle \sin \delta ={\frac {y_{1}}{d}}={\frac {y_{1}}{-c\,t_{1}}}}$   and ${\displaystyle \cos \delta ={\frac {x_{1}}{-c\,t_{1}}}}$ 

Observation in a reference frame S' whereby S' is moving in uniform motion (relative to S) along the x-axis

The origin of the reference frame S' is in uniform motion relative to S with ${\displaystyle (v|0|0)}$  , i.e. moves along the x-axis, and the x-,y- und z-axes of S' and S are parallel to each other and at time ${\displaystyle \scriptstyle t=t'=0}$  the origins of S and S' coincide. Let ${\displaystyle \beta ={\frac {v}{c}},\gamma ={\frac {1}{\sqrt {1-\beta ^{2}}}}}$ 

S' now is an equally good quasi-inertial frame of reference as S: the space coordinates form a w:en:Cartesian coordinate system and the path of the light signal is a straight line.

According to the Lorentz transformation one gets: ${\displaystyle x_{1}'=\gamma \cdot (x_{1}-\beta \cdot c\,t_{1}),y_{1}'=y_{1},z_{1}'=0,c\,t_{1}'=\gamma \cdot (c\,t_{1}-\beta \cdot x_{1})}$ 

In reference frame S' the light signal starts at ${\displaystyle t_{1}'<0}$  and stops at time ${\displaystyle t_{2}'=0}$  and therefore the light signal did cover the distance ${\displaystyle d\,'=c\cdot (0-t_{1}')=-c\,t_{1}'}$  .

In S' the path of the light signal is a straight line, too. It forms an angle ${\displaystyle \delta '}$  with the x'-axis and one gets:

${\displaystyle \sin \delta '={\frac {y_{1}'}{d\,'}}={\frac {y_{1}}{-c\,t_{1}'}}={\frac {y_{1}}{-\gamma \cdot (c\,t_{1}-\beta \cdot x_{1})}}={\frac {y_{1}}{-c\,t_{1}\cdot \gamma \cdot \left(1-\beta \cdot {\frac {x_{1}}{c\,t_{1}}}\right)}}={\frac {\frac {y_{1}}{-c\,t_{1}}}{\gamma \cdot \left(1+\beta \cdot {\frac {x_{1}}{-c\,t_{1}}}\right)}}={\frac {\sin \delta }{\gamma \cdot (1+\beta \cdot \cos \delta )}}}$ 

${\displaystyle \cos \delta '={\frac {x_{1}'}{-c\,t_{1}'}}={\frac {\gamma \cdot (x_{1}-\beta \cdot c\,t_{1})}{-\gamma \cdot (c\,t_{1}-\beta \cdot x_{1})}}={\frac {-c\,t_{1}\cdot \gamma \cdot \left({\frac {x_{1}}{-c\,t_{1}}}+\beta \right)}{-c\,t_{1}\cdot \gamma \cdot \left(1+\beta \cdot {\frac {x_{1}}{-c\,t_{1}}}\right)}}={\frac {{\frac {x_{1}}{-c\,t_{1}}}+\beta }{1+\beta \cdot {\frac {x_{1}}{-c\,t_{1}}}}}={\frac {\cos \delta +\beta }{1+\beta \cdot \cos \delta }}}$ 

Hence: ${\displaystyle \tan \delta '={\frac {\sin \delta '}{\cos \delta '}}={\frac {\sin \delta }{\gamma \cdot (\cos \delta +\beta )}}}$ 

These are the same formulas as in w:en:aberration of light#Explanation.

Approximate formula for motion along the x-axis in case of v/c <<1 edit

${\displaystyle \triangle \delta \;=\;\delta '-\delta \;}$  is the change of the angle δ. As β<<1 this change is also very small.

Case I: ${\displaystyle \;\delta \neq \pm 90^{\circ }\;\rightarrow \;\cos \delta \neq 0}$ 

As Δδ<<1 one gets: ${\displaystyle {\frac {\tan \delta '-\tan \delta }{\triangle \delta }}\approx {\frac {d}{d\delta }}\tan \delta ={\frac {1}{(\cos \delta )^{2}}}\;\rightarrow \;\triangle \delta \;=\;(\cos \delta )^{2}\cdot (\tan \delta '-\tan \delta )}$ 

As β<<1 one gets: ${\displaystyle \tan \delta '={\frac {\sin \delta }{\gamma (\cos \delta +\beta )}}\approx {\frac {\sin \delta }{\cos \delta +\beta }}={\frac {\sin \delta }{\cos \delta \cdot \left(1+{\frac {\beta }{\cos \delta }}\right)}}\approx \tan \delta \cdot \left(1-{\frac {\beta }{\cos \delta }}\right)}$ 

Therefore ${\displaystyle \triangle \delta \;=\;(\cos \delta )^{2}\cdot (\tan \delta '-\tan \delta )=(\cos \delta )^{2}\cdot \tan \delta \left(1-{\frac {\beta }{\cos \delta }}\;-1\right)=-\cos \delta \cdot \tan \delta \cdot \beta =-\beta \cdot \sin \delta }$ 

Case IIa: ${\displaystyle \;\delta \;=90^{\circ }\;}$ , hence: ${\displaystyle \tan \delta '={\frac {\sin 90^{\circ }}{\gamma \cdot (\cos 90^{\circ }+\beta )}}={\frac {1}{\gamma \cdot \beta }}\;\approx {\frac {1}{\beta }}\quad \rightarrow \quad \cot \delta '=\beta \quad \rightarrow \quad \delta '=\operatorname {arccot} \beta \approx {\frac {\pi }{2}}-\beta }$ 

and therefore: ${\displaystyle \triangle \delta =\delta '-\delta =-\beta \quad \left(=-\beta \cdot \sin(90^{\circ })\right)}$ 

Case IIb: ${\displaystyle \;\delta \;=-90^{\circ }\;}$ , and hence: ${\displaystyle \tan \delta '={\frac {-1}{\gamma \cdot \beta }}\;\approx -{\frac {1}{\beta }}\quad \rightarrow \quad \cot \delta '=-\beta \quad \rightarrow \quad \delta '=\operatorname {arccot} \beta \approx -{\frac {\pi }{2}}+\beta \quad }$     ^[10]

Hence: ${\displaystyle \triangle \delta =\delta '-\delta =+\beta \quad \left(=-\beta \cdot \sin(-90^{\circ })\right)}$ 

Conclusion:The change of the angle Δδ = δ'-δ in the case of β = v/c << 1 can be described by the approximate formula ${\displaystyle \triangle \delta =-{\frac {v}{c}}\cdot \sin \delta \;}$  resp. in the degree measure ${\displaystyle \triangle \delta =-{\frac {v}{c}}\cdot \sin \delta \cdot {\frac {180^{\circ }}{\pi }}}$ 

Symmetric form of the (exact) formula for motion along the x-axis edit

With help of tangent half-angle formula ${\displaystyle \scriptstyle \tan(\alpha /2)=\sin \alpha /(1+\cos \alpha )}$   one can prove the symmetric form: ${\displaystyle \tan {\frac {\delta '}{2}}={\sqrt {\frac {1-\beta }{1+\beta }}}\cdot \tan {\frac {\delta }{2}}}$    (derivation found in a SR-textbook^[11])

${\displaystyle \tan {\frac {\delta '}{2}}={\frac {\sin \delta '}{1+\cos \delta '}}={\frac {\frac {\sin \delta }{\gamma \cdot (1+\beta \cdot \cos \delta )}}{{\frac {1+\beta \cdot \cos \delta }{1+\beta \cdot \cos \delta }}+{\frac {\cos \delta +\beta }{1+\beta \cdot \cos \delta }}}}={\frac {\sin \delta }{\gamma \cdot (1+\beta \cdot \cos \delta +\cos \delta +\beta )}}={\frac {\sin \delta }{\gamma \cdot (1+\beta )\cdot (1+\cos \delta )}}={\frac {\tan {\frac {\delta }{2}}}{\gamma \cdot (1+\beta )}}}$ 

And as ${\displaystyle {\frac {1}{\gamma \cdot (1+\beta )}}={\frac {\sqrt {1-\beta ^{2}}}{1+\beta }}={\frac {\sqrt {(1+\beta )(1-\beta )}}{1+\beta }}={\sqrt {\frac {1-\beta }{1+\beta }}}}$  the symmetric form follows.

Formula for motion along the y-axis edit

Let ${\displaystyle \theta }$  be the angle between the light ray (=path of the light signal which is a straight line) and the y-axis whereby θ is positive if the y-axis would have to rotate counter-clockwise to coincide with the light ray. Then the derivation of the formula of angle θ' for the motion along the x-axis is the same as the derivation of the formula of angle δ' for the motion along the x-axis.

Hence: ${\displaystyle \tan \theta \,'={\frac {\sin \theta }{\gamma \cdot (\cos \theta +\beta )}}}$ 

The symmetric form is: ${\displaystyle \tan {\frac {\theta \,'}{2}}={\sqrt {\frac {1-\beta }{1+\beta }}}\cdot \tan {\frac {\theta }{2}}}$  and the approximate formula is: ${\displaystyle \triangle \theta =-\beta \cdot \sin \theta }$ 

As ${\displaystyle \theta =\delta -90^{\circ }}$  and as ${\displaystyle \scriptstyle \sin(\delta -90^{\circ })=-\sin(90^{\circ }-\delta )=-\cos \delta \;,\;\cos(\delta -90^{\circ })=\cos(90^{\circ }-\delta )=\sin \delta }$  and ${\displaystyle \scriptstyle \tan(\delta -90^{\circ })=-\tan(90^{\circ }-\delta )=-\cot \delta }$   one gets:

${\displaystyle \tan(\delta '-90^{\circ })={\frac {\sin(\delta -90^{\circ })}{\gamma \cdot \left(\cos(\delta -90^{\circ })+\beta \right)}}}$  and therefore:  ${\displaystyle -\cot \delta '={\frac {-\cos \delta }{\gamma \cdot (\sin \delta +\beta )}}}$  and hence ${\displaystyle \cot \delta '={\frac {\cos \delta }{\gamma \cdot (\sin \delta +\beta )}}}$ 

Since ${\displaystyle \cot \delta '={\frac {1}{\tan \delta '}}}$   one also gets: ${\displaystyle \tan \delta '={\frac {\gamma \cdot (\sin \delta +\beta )}{\cos \delta }}}$ 

And the symmetric form is: ${\displaystyle \tan {\frac {\delta '-90^{\circ }}{2}}={\sqrt {\frac {1-\beta }{1+\beta }}}\cdot \tan {\frac {\delta -90^{\circ }}{2}}}$ 

And as ${\displaystyle \scriptstyle \triangle \theta =(\delta '-90^{\circ })-(\delta -90^{\circ })=\triangle \delta }$   the approximate formula is: ${\displaystyle \triangle \delta =\triangle \theta =-\beta \cdot \sin(\delta -90^{\circ })=+\beta \cdot \cos \delta }$    

Formula for motion along a ray lying in the x-y-plane with direction vector (cos α | sin α) edit

With the same reasoning as above one gets the formula: ${\displaystyle \tan(\delta '-\alpha )={\frac {\sin(\delta -\alpha )}{\gamma \cdot \left(\cos(\delta -\alpha )+\beta \right)}}}$ 

The symmetric form is ${\displaystyle \tan {\frac {\delta '-\alpha }{2}}={\sqrt {\frac {1-\beta }{1+\beta }}}\cdot \tan {\frac {\delta -\alpha }{2}}}$  and the approximate formula is ${\displaystyle \triangle \delta =-\beta \cdot \sin(\delta -\alpha )}$ 

Three-dimensional problem edit

If the motion is along an arbitary ray, one needs two angles to characterize the direction of the light ray (and both do change) and therefore one needs a new proper definition of the angles like for spherical coordinates.

--Remains to be done.--

The stellar aberration is only an effect of the change of the reference frame. The astronomer orbits (with the earth) around the sun in one year and furthermore rotates around the axis of the earth in one day. His current rest frame S' therefore has different velocities relative to the rest frame S of the barycenter of the solar system at different times. Hence the astronomer observes, that the position of the star changes. The formula is derived under the condition that the change of the position of the star and of the earth is negligible in the period of observation ^[12] That is correct for almost all stars: The amplitude of the parallax of a star in a distance of ≥ n parsec is ≤ 1/n ".

Stellar aberration due to the orbit of the earth (around the sun) edit

The mean orbital speed of the earth is ${\displaystyle v_{e}={\frac {2\cdot \pi \cdot 1\,AE}{365,25\,d}}=29,78\,km/s}$ , and therefore ${\displaystyle {\frac {v_{e}}{c}}=0,00009935}$ .

-> ${\displaystyle {\frac {v}{c}}\cdot {\frac {180^{\circ }}{\pi }}=20,5^{\prime \prime }}$ .

${\displaystyle k_{A}=20,5^{\prime \prime }}$  is dubbed constant of aberration for the annual aberration.^[13]

Stellar aberration due to the earth's rotation edit

An astronomer at the w:en:latitude ${\displaystyle \varphi }$  rotates in 24 hours around the axis of the earth. His speed of rotation is therefore ${\displaystyle v_{r}={\frac {\cos \varphi \cdot 40000\,km}{1\,d}}=\cos \varphi \cdot 463\,m/s}$ . Hence ${\displaystyle {\frac {v_{r}}{c}}=\cos \varphi \cdot 1,54\cdot 10^{-6}}$ . Form this so called diurnal aberration one gets an additional contribution of (at max.) ${\displaystyle \cos \varphi \cdot 0,32^{\prime \prime }}$ .

Stellar aberration due the orbit of our solar system around the center of the Milky Way edit

The rest frame of the center of mass of our solar system isn't a perfect inertial frame of reference since our solar system orbits around the center of the Milky Way. An estimation for the time of period of circulation is 230 million years (estimations vary between 225 and 250 million years).^[14][15] As the estimation for the distance between our solar system and the center of the Milky Way is about 28000 Ly, the assumed w:en:orbital speed of our solar system is ${\displaystyle \scriptstyle v={\frac {2\pi \cdot 280000\cdot 9,461\cdot 10^{15}\,m}{230\cdot 10^{6}\cdot 365,25\cdot 24\cdot 3600}}\approx \,230\,km/s}$ . This would cause an aberration ellipse with a major semiaxis of 2,6' (arcminutes ). Therefore, in one year the aberration angle could change (at max.) ${\displaystyle \scriptstyle 2,6^{\prime }\cdot {\frac {2\pi \cdot 1\,a}{230000000\,a}}}$  = 4,3 µas (microarcseconds). This very small value isn't detectable now, perhaps it's possible with the planned mission of the Gaia spacecraft.^[16]

• w:en:Aberration of light
• Parallax in astronomy

1. ↑ See Herschel, John Frederick William (1844). "Schreiben des Herrn Baronets Herschel an den Herausgeber". Astronomische Nachrichten. 22 (520): 249–254.
2. ↑ Emden, R. (1926). "Aberration und Relativitätstheorie". Die Naturwissenschaften. 14 (16): 329–335. doi:10.1007/BF01506966. (14. Jahrgang, Heft 16)
3. ↑ R. Emden's (rhetorical) question "Wie wird die Richtung des einfallenden Strahles durch die momentane Bewegung der Erde und die Bewegung (nicht den Ort) des Sternes zur Zeit der Aussendung des Strahles beeinflußt?" is answered by him with "Gar nicht."(Not at all)
4. ↑ See for example equation (4) in Klaus Kassner (2002). "Why the Bradley aberration cannot be used to measure absolute speeds. A comment". arΧiv:astro-ph/0203056 [astro-ph]. 
5. ↑ i.e. the stars can rotate very fast like eclipsing binary stars as long as the change in position is << distance star-earth
6. ↑ It's easy to (technically) compensate the deviation of the direction of the axes due to the earth's rotation and earth's orbit but it almost impossible to (technically) compensate a velocity in the order of several 1000 m/s. This can only be achieved with help of mathematics.
7. ↑ Of course every inertial frame of reference is physically equal, but the rest system of the barycenter has the mathematical advantage, that it's the mean frame of reference and since the time of Galileo Galilei it's the preferred frame of reference
8. ↑ The lines of x-axis and x'-axis lie on top of each other
9. ↑ An even better quasi-inertial frame of reference would be a frame of reference in which the center of mass of the Milky Way would rest or be in uniform motion.
10. ↑ Here the solution with cot 0 = -π/2 has to be used, see Plot of arccot (x)
11. ↑ Spezielle Realtivitätstheorie für Studenanfänger, Jürgen Freund, vdf-Verlag (Zürich), 2nd. Ed. (2005)
12. ↑ For the star this period lies in the past.
13. ↑ see e.g. The Constant of Aberration and the Solar Parallax
14. ↑ see hypertextbook.com
15. ↑ NASA - StarChild Question of the Month for February 2000
16. ↑ This is an hint from H.-H. Voigt: Abriss der Astronomie, 6. Auflage. Herausgegeben von H.-J. Röser und W. Tscharnuter. © 2012 Wiley-VCH Verlag GmbH & Co. KGaA., page 35 of extract