Difference between revisions of "Star magnitude"

Revision as of 19:59, July 28, 2020

Star magnitude refers to the apparent brightness of stars.^[1] More generally, the term "apparent magnitude" is a measure of how bright any astronomical object is as seen from Earth. The absolute magnitude of an object is the magnitude of the object as seen from 10 parsecs from the object. Somewhat confusingly, lower magnitudes correspond to brighter objects.

History

Stars were first classified by brightness by Hipparchus in 129 BC. He produced the first well known catalog of stars in which the brightest stars were listed as "first magnitude" and the second grouping was "second magnitude". This division went up to sixth magnitude.^[2] The observation of different brightness of stars is mentioned also in the New Testament: "The sun has one kind of splendor, the moon another and the stars another; and star differs from star in splendor."^[3]

In 140 AD, Claudius Ptolemy added "greater" and "smaller" within the magnitude to separate them further.

With Galileo and the telescope, it was possible to make out stars that were much dimmer than sixth magnitude.

Modern definition

In the 1800s, Norman R. Pogson proposed and codified magnitude to be a logarithmic scale where the difference between the first and fifth magnitude is one hundred times brighter. The ratio of one number to the next is the fifth root of one hundred, or about 2.512 - known as the Pogson ratio.^[1] For example, this means a magnitude +5.0 star is about 2.512 times brighter than a magnitude +6.0 star.

The apparent magnitude of a star, m_* can be computed using,^[4]

\text{[math]}

where m_c is the apparent magnitude of a comparison star and b_* and b_c are the brightness of the star and comparison star as seen on Earth. The $\text{[math]}$ refers to a base 10 logarithm.

The apparent magnitude of an object depends not only on how much light the object emits, but also on how far away the object is. To compare the instrinsic brightness of objects, the absolute magnitude is often used. It is defined as the magnitude of an object as seen from 10 parsecs (32.6156 light years). The absolute magnitude, M, can be calculated using,^[5]

\text{[math]}

where m is the apparent magnitude and d is the distance to the object from Earth. d must be measured in parsecs for this equation to work.

Examples

Naked eye limit with a dark sky: +6
Visual limit of a 12" telescope: +14
Visual limit of a 200" telescope: +20
Sirius: –1.5
Venus: –4.4
Full moon: –12.5
The Sun: –26.7

References

↑ ^1.0 ^1.1 Magnitude. britannica. Retrieved on July 28, 2020.
↑ http://skytonight.com/howto/basics/3304516.html
↑ Bible, 1 Corinthians 15:41 (New International Version). Bible Gateway. “Credit:Holy Bible, New International Version®, NIV® Copyright © 1973, 1978, 1984, 2011 by Biblica, Inc.®”
↑ Formulas - Magnitudes. astronomyonline.org. Retrieved on July 28, 2020.
↑ Absolute Magnitude. astronomy.swin.edu.au. Retrieved on July 28, 2020.

[britannica-1] 1.0 ^1.1 Magnitude. britannica. Retrieved on July 28, 2020.

[2] ttp://skytonight.com/howto/basics/3304516.html

[3] Bible, 1 Corinthians 15:41 (New International Version). Bible Gateway. “Credit:Holy Bible, New International Version®, NIV® Copyright © 1973, 1978, 1984, 2011 by Biblica, Inc.®”

[4] Formulas - Magnitudes. astronomyonline.org. Retrieved on July 28, 2020.

[5] Absolute Magnitude. astronomy.swin.edu.au. Retrieved on July 28, 2020.

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@@ Line 10: / Line 10: @@
 == Modern definition ==
-In the 1800s, Norman R. Pogson proposed and codified magnitude to be a logarithmic scale where the difference between the first and fifth magnitude is one hundred times brighter.  The ratio of one number to the next is the fifth root of one hundred, or about 2.512 - known as the Pogson ratio.<ref name=britannica/> For example, this means a magnitude +5.0 star is about 2.512 times brighter than a magnitude 6.0 star.
+In the 1800s, Norman R. Pogson proposed and codified magnitude to be a logarithmic scale where the difference between the first and fifth magnitude is one hundred times brighter.  The ratio of one number to the next is the fifth root of one hundred, or about 2.512 - known as the Pogson ratio.<ref name=britannica/> For example, this means a magnitude +5.0 star is about 2.512 times brighter than a magnitude +6.0 star.
 The apparent magnitude of a star, ''m''<sub>*</sub> can be computed using,<ref>{{cite web|url=http://astronomyonline.org/Science/Magnitude.asp#:~:text=A%20Magnitude%20is%20the%20measure,of%20Magnitude%3A%20apparent%20and%20absolute.|title=Formulas - Magnitudes|accessdate=July 28, 2020|publisher=astronomyonline.org}}</ref>
 ::<math>m_* - m_c = -2.5 \log_{10}  \frac{b_*}{b_c}</math>
-where ''m''<sub>c</sub> is the apparent magnitude of a comparison star and ''b''<sub>*</sub> and ''b''<sub>c</sub> are the brightness of the star and comparison star as seen on Earth. The <math>\log_10</math> refers to a base 10 [[logarithm]].
+where ''m''<sub>c</sub> is the apparent magnitude of a comparison star and ''b''<sub>*</sub> and ''b''<sub>c</sub> are the brightness of the star and comparison star as seen on Earth. The <math>\log_{10}</math> refers to a base 10 [[logarithm]].
 The apparent magnitude of an object depends not only on how much light the object emits, but also on how far away the object is. To compare the instrinsic brightness of objects, the absolute magnitude is often used. It is defined as the magnitude of an object as seen from 10 [[parsec]]s (32.6156 [[light year]]s). The absolute magnitude, ''M'', can be calculated using,<ref>{{cite web|url=https://astronomy.swin.edu.au/cosmos/A/Absolute+Magnitude|title=Absolute Magnitude|accessdate=July 28, 2020|publisher=astronomy.swin.edu.au}}</ref>

Difference between revisions of "Star magnitude"

Revision as of 19:59, July 28, 2020

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