W.RonG said:Been reading about aberration and two explanations that diverge - classical and relativistic. at speeds much slower than c the angle is very small for either formulation. the stellar aberration that led Bradley to the explanation 300 years ago is less than a minute of arc. Has there been any observation of aberration angles such that it can be definitely ascribed to relativistic effects?
Thanks.
rg
W.RonG said:Been reading about aberration and two explanations that diverge - classical and relativistic. at speeds much slower than c the angle is very small for either formulation. the stellar aberration that led Bradley to the explanation 300 years ago is less than a minute of arc. Has there been any observation of aberration angles such that it can be definitely ascribed to relativistic effects?
Thanks.
rg
W.RonG said:Been reading about aberration and two explanations that diverge - classical and relativistic. at speeds much slower than c the angle is very small for either formulation. the stellar aberration that led Bradley to the explanation 300 years ago is less than a minute of arc. Has there been any observation of aberration angles such that it can be definitely ascribed to relativistic effects?
Thanks.
rg
Relativistic Aberration is a phenomenon in which the apparent direction of light or other electromagnetic radiation is altered due to the relative motion between the source of the radiation and the observer.
Relativistic Aberration causes celestial objects to appear to be in slightly different positions than they actually are. This effect is most noticeable for objects that are moving at high speeds, such as stars or galaxies.
The equation for calculating Relativistic Aberration is tan θ' = (v/c)/(1+(v/c)cosθ), where θ' is the apparent angle of the radiation, v is the relative velocity between the source and observer, and c is the speed of light.
Classical Aberration is based on the assumption that light travels instantaneously, while Relativistic Aberration takes into account the finite speed of light and the effects of time dilation. This makes Relativistic Aberration more accurate for high-speed objects.
Yes, Relativistic Aberration can be observed in everyday life, although the effects are usually very small. For example, the apparent position of the stars in the night sky is slightly altered due to the Earth's rotation and orbit around the sun.