michelson_1879: A.A. Michelson's 1879 Determinations of the Speed of Light
In loon.data: Data Used to Illustrate 'Loon' Functionality
Description
Format
Details
Author(s)
References
See Also
Description
In 1879, Albert Abraham Michelson conducted an experimental study to
determine the speed of light using a rotating mirror apparatus at the
U.S. Naval Academy in Annapolis, Maryland in 1879.
Details on the apparatus, the optical theory, and the conduct of the experiment are
given in the reference. An abbreviated summary of these follows the variable descriptions.
Format
A data frame with 100 rows and 15 variables
- Speed
The determined speed of light in air in kilometres per second.
- Beat
Number of beats per second between tuning forks.
- Correction
Correction for temperature to a standard fork in beats per second.
- Day
Day of experiment in progress (June 5 is day 1) on which these measurements were taken.
- Difference
Difference betweeen the greatest and least values of revolutions.
- Quality
Subjective measure of the quality of the image 'I'; the more distinct
was the image the higher the quality (1 = poor, 3 = good).
- Displacement
Displacement of image 'I' from slit 'S' in divisions of the micrometer.
- Image
Micrometer position of the deflected image.
- Radius
Radius of measurement in feet.
- Revolutions
Number of times the mirror revolved per second.
- Screw
Measure of one screw turn in millimetres.
- Slit
Micrometer position of the slit providing the light source 'S'.
- Temperature
Air temperature measured in degrees Fahrenheit.
- Time.of.day
Time of day at which the observation was recorded.
'AM' means one hour after sunrise and 'PM' one hour before sunset.
- Remarks
Unusual remarks recorded for that observation.
Details
The experiment is conducted within a closed and darkened small building at the U.S. Naval Academy.
Light enters the building from one corner passing through a slit 'S' whose location is
precisely determined using a micrometer.
The light then proceeds to hit a rotating mirror
at the other end of the building's interior from whence it is reflected out of the
building through an opening in a corner different from that of the source.
The light
beam travels outside to strike another (stationary) mirror which reflects it back into the
building through the same corner it exited whereupon it then strikes the rotating mirror.
Depending on the position of the rotating mirror, the returning light will be reflected off
it to land at some position 'I' near the original source given by the slit 'S'.
The speed of the rotating mirror is controlled using an adjustable pump to blow air across a surface to
rotate it.
If the speed of rotation is just right, a crisp image 'I' of the reflected slit will appear near
the original source 'S'. The speed is adjusted until this is the case.
The speed of rotation is determined using an electric tuning fork connected to the
rotating mirror and whose frequency was measured by comparing it to a second standard tunig
fork of known frequency. The electronic fork frequency was compared to the standard fork
by determining the number of beats per second difference the two (by counting over 60 seconds).
With a speed of revolution and the displacement measured between 'S' and its returned image 'I',
a measurement of the speed of light could be had.
See reference for more details.
Author(s)
R.W. Oldford
References
R.J. MacKay and R.W. Oldford 2000,
'Scientific Method, Statistical Method, and the Speed of Light',
Statistical Science, Volume 15, No. 3, pp. 254-278. <doi:10.1214/ss/1009212817>
See Also
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Description Format Details Author(s) References See Also
Description
In 1879, Albert Abraham Michelson conducted an experimental study to determine the speed of light using a rotating mirror apparatus at the U.S. Naval Academy in Annapolis, Maryland in 1879.
Details on the apparatus, the optical theory, and the conduct of the experiment are given in the reference. An abbreviated summary of these follows the variable descriptions.
Format
A data frame with 100 rows and 15 variables
- Speed
The determined speed of light in air in kilometres per second.
- Beat
Number of beats per second between tuning forks.
- Correction
Correction for temperature to a standard fork in beats per second.
- Day
Day of experiment in progress (June 5 is day 1) on which these measurements were taken.
- Difference
Difference betweeen the greatest and least values of revolutions.
- Quality
Subjective measure of the quality of the image 'I'; the more distinct was the image the higher the quality (1 = poor, 3 = good).
- Displacement
Displacement of image 'I' from slit 'S' in divisions of the micrometer.
- Image
Micrometer position of the deflected image.
- Radius
Radius of measurement in feet.
- Revolutions
Number of times the mirror revolved per second.
- Screw
Measure of one screw turn in millimetres.
- Slit
Micrometer position of the slit providing the light source 'S'.
- Temperature
Air temperature measured in degrees Fahrenheit.
- Time.of.day
Time of day at which the observation was recorded. 'AM' means one hour after sunrise and 'PM' one hour before sunset.
- Remarks
Unusual remarks recorded for that observation.
Details
The experiment is conducted within a closed and darkened small building at the U.S. Naval Academy. Light enters the building from one corner passing through a slit 'S' whose location is precisely determined using a micrometer.
The light then proceeds to hit a rotating mirror at the other end of the building's interior from whence it is reflected out of the building through an opening in a corner different from that of the source.
The light beam travels outside to strike another (stationary) mirror which reflects it back into the building through the same corner it exited whereupon it then strikes the rotating mirror.
Depending on the position of the rotating mirror, the returning light will be reflected off it to land at some position 'I' near the original source given by the slit 'S'.
The speed of the rotating mirror is controlled using an adjustable pump to blow air across a surface to rotate it. If the speed of rotation is just right, a crisp image 'I' of the reflected slit will appear near the original source 'S'. The speed is adjusted until this is the case.
The speed of rotation is determined using an electric tuning fork connected to the rotating mirror and whose frequency was measured by comparing it to a second standard tunig fork of known frequency. The electronic fork frequency was compared to the standard fork by determining the number of beats per second difference the two (by counting over 60 seconds).
With a speed of revolution and the displacement measured between 'S' and its returned image 'I', a measurement of the speed of light could be had.
See reference for more details.
Author(s)
R.W. Oldford
References
R.J. MacKay and R.W. Oldford 2000, 'Scientific Method, Statistical Method, and the Speed of Light', Statistical Science, Volume 15, No. 3, pp. 254-278. <doi:10.1214/ss/1009212817>
See Also
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