cern gps frame of reference shift error of 20 meters faster than the speed of light
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8/3/2019 CERN GPS frame of reference shift error of 20 meters faster than the speed of light
http://slidepdf.com/reader/full/cern-gps-frame-of-reference-shift-error-of-20-meters-faster-than-the-speed 1/5
Nahhas' "Faster than the speed of light" Puzzle solution I
Joe Nahhas Alfred Nobel Wrong
Arab American real time first physicist Joe Nahhas explains CERN Geneva - San
Grasso Opera experiment Dr Dario Autiero 2011 error of "faster than the speed of light"
Abstract: frame of reference shift from San Grasso to GPS satellite amounts to
an error of 20 meters and is not counted for in Opera experiment and Dr Dario
Autiero 20 meters "faster than the speed of light" calculations are all wrong
Proof:
1 = 1 is self evident; 2 = 2 is self evident
And r0= r 0 is self evident; add and subtract r
Then r 0 = r + (r 0 - r); divide by r
Then (r 0 /r) = 1 + (r 0 - r)/ r; multiply by f
Then (r 0 /r) f = f + [(r - r 0)/ r] f --------------------Eq-1
Also, f 0= f 0; add and subtract f 0
Then f 0 = f + (f 0- f) --------------------------------Eq-2
Comparing Eq-1to Eq-2
Then f 0 = (r0 /r) f; or f 0 /f = r0 /r; subtract 1 from both sides
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8/3/2019 CERN GPS frame of reference shift error of 20 meters faster than the speed of light
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Then (f 0 /f) - 1= (r0 /r) -; or, (f 0 - f) /f = (r 0 - r)/ r
Or, - d f/f = - d r /r; and d f/f = d r /r -------------------Eq-3
Solving Eq-3 using separation of variables
Then d f/f = d r /r = λ+ í ω = translation + rotation
Or, f = f 0 e (λ+ í ω) t and r = r0 e (λ+ í ω) t
With r = r x + í r y = r0 e λ t (cosine ω t + í sine ω t)
Then r x = r0 e λ t cosine ω t; and r y = r0 e λ t sine ω t
And (r y / r x) = tan ω t; and ω t = tan-1 (r y / r x)
With r x = r0 e λ t cosine ω t = r0 e λ t cosine tan-1 (r y / r x)
Then (r x / r0) = e λ t cosine tan-1 (r y / r x); e λ t = (r x / r0)/cosine tan-1 (r y / r x)
And λ t = L n [(r x / r0)/cosine tan-1 (r y / r x)]
= L n [cosine tan-1 (r y / r x)/cosine tan-1 (r y / r x)] = L n 1 = 0
With r y = r0 e λ t sine ω t = r0 e λ t sine tan-1 (r y / r x)
Then (r y / r0) = e λ t sine tan-1 (r y / r x)
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r0 r y
r x
8/3/2019 CERN GPS frame of reference shift error of 20 meters faster than the speed of light
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And λ t = L n [(r y / r0)/sine tan-1 (r y / r x)]
= L n [sine tan-1 (r y / r x)/sine tan-1 (r y / r x)] = L n 1 = 0
This means decay or birth factor λ = 0 or the decay or birth factor e λ t = 1
And r = r0 e í ω t = r x + í r y = r0 (cosine ω t + í sine ω t)
What this math means?
If a car is at a distance r0; its visual is r = r0 e (λ+ í ω) t
If r0 is the same not shopped or welded e λ t = 1; then r0 visual is r = r0 e í ω t
With r = r0 e í ω t; divide by time t
Then velocity v = v 0 e í ω t
And (r. v) = (r0. v 0) e2 í ω t
Then (r. v) = (r0. v 0) (cosine 2ω t + í sine 2ω t)
Or (r. v) = (r. v) x + í (r. v) y = (r0. v 0) (cosine 2ω t + í sine 2ω t)
Along the line of sight (r. v) x= (r0. v 0) cosine 2ω t
For an elliptical motion (r0. v 0) = 2 π a b/T
With a = semi major axis a and semi minor axis b and orbital period T
And r0 = a (1 - ε2)/ (1 + ε cosine θ); b = a √ (1 - ε2); ε = eccentricity
Then (r0. v 0) = 2 π a b/T = 2 π a2 [√ (1 - ε2)]/T
At perihelion θ = 0 and r0 (perihelion) = a (1 - ε2)/ (1 + ε cosine 0°)
And r0 (perihelion) = a (1 - ε
2
)/ (1 + ε) = a (1 - ε)
Angular velocity at perihelion is θ' (perihelion) = (r. v) x / [r0 (perihelion)] 2
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And θ' (perihelion) = (r0. v 0) cosine 2ω t/ [r0 (perihelion)] 2
= {2 π a2 [√ (1 - ε2)]/ a2 (1 - ε) 2 T} cosine 2ω t
= {2 π [√ (1 - ε2)]/ (1 - ε) 2 T} cosine 2ω t
= {2 π [√ (1 - ε2)]/ (1 - ε) 2 T} (1 - 2 sine2 ω t)
= {2 π [√ (1 - ε2)]/ (1 - ε) 2 T} (1 - 2 sine2 ω t)
And θ' (perihelion) - {2 π [√ (1 - ε2)]/ (1 - ε) 2 T}
= - 4 π {[√ (1 - ε2)]/ (1 - ε) 2 T} sine2 ω t in radians per period - seconds
Angle per second multiply by T
Angle (θ perihelion) = - 4 π {[√ (1 - ε2)]/ (1 - ε) 2} sine2 ω t radians
In degree per second multiply by 180/ π
= - 720 {[√ (1 - ε2)]/ (1 - ε) 2} sine2 ω t
In arc second multiply by 3600
Angle (θ perihelion) = (- 720 x 3600) {[√ (1 - ε2)]/ (1 - ε) 2} sine2 ω t
Per century multiply by (t0 /T) = century/period; θ perihelion = θ p
Angle (θ perihelion) = (- 720 x 3600) (t/T) {[√ (1 - ε2)]/ (1 - ε) 2} sine2 ω t
With t = 36526; T = 88; ε = 0.206; ω t = tan-1 (v/c) = aberration angle
And v = orbital velocity - spin velocity = 47.9
And c = 300,000; {[√ (1 - ε2)]/ (1 - ε) 2} = 1.552
Finally θ p = (- 720 x 3600) (t0 /T) {[√ (1 - ε2)]/ (1 - ε) 2} sine2 ω t
= (- 720 x 3600) (36526/88) (1.552) sine
2
[tan
-1
(47.9/300,000)]= 43 arc second per century Google 50 solutions of Mercury's Perihelion
Same as measured and same as Einstein validating this formula validity
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GPS satellite has a velocity of 14000 km/hr and a period T = ½ day
and eccentricity of ε = 0
The velocity of the GPS satellite is 14,000,000/0.5 x 24 x 3600 = 3.8888889
Earth Spin = 0.4651 and ω t = tan-1
[(3.89 - 0.4651)/300,000]
With θ p = (- 720 x 3600) (t0 /T) {[√ (1 - ε2)]/ (1 - ε) 2} sine2 ω t
With ε = 0; θ p = (- 720 x 3600) (t0 /T) sine2 ω t
With t0 = 1 day and T = 0.5 days
With 24 hours = 360°; or 1 second = 15 arc second
Then T d = [(- 720 x 3600)/15] (t0 /T) sine2 ω t seconds
Then T= [(- 720 x 3600)/15] (1/0.5) sine2 tan -1 [(3.89 - 0.4651)/300,000]
seconds = 0.000045043 seconds per day or per Earth revolution
Same as measured to justify this method
In radial distance: 0.000045043 x 300,000/2 π = 13.51289/2 π = 2.15 km
With San Grasso moving with respect to the satellite the orbit aberration is
With θ p = (- 720 x 3600) (t0 /T) {[√ (1 - ε2)]/ (1 - ε) 2} sine2 ω t
With ε = 0; θ p = (- 720 x 3600) (t0 /T) sine2 ω t
With 24 hours = 360°; or 1 second = 15 arc second
Then T error = [(- 720 x 3600)/15] (t0 /T) sine2 ω t seconds
With ω t = tan -1 [(3.89 - 0.4651)/300,000]
And (t0 /T) = (2.15/730)
T error = [(- 720 x 3600)/15] (2.15/730) sine2 tan -1 [(3.89 - 0.4651)/300,000]
= 0.00000006635 seconds and 0.00000006635 x 300,000,000 = 19.9 meters
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