Apparent magnitude: Difference between revisions

The scale now used to indicate magnitude originates in the Hellenistic practice of dividing stars visible to the naked eye into six magnitudes. The brightest stars in the night sky were said to be of first magnitude (m = 1), whereas the faintest were of sixth magnitude (m = 6), the limit of human visual perception (without the aid of a telescope). Each grade of magnitude was considered twice the brightness of the following grade (a logarithmic scale). This somewhat crude method of indicating the brightness of stars was popularized by Ptolemy in his Almagest, and is generally believed to originate with Hipparchus. This original system did not measure the magnitude of the Sun.

In 1856, Norman Robert Pogson formalized the system by defining a typical first magnitude star as a star that is 100 times as bright as a typical sixth magnitude star; thus, a first magnitude star is about 2.512 times as bright as a second magnitude star. The fifth root of 100 is known as Pogson's Ratio.^[4] Pogson's scale was originally fixed by assigning Polaris a magnitude of 2. Astronomers later discovered that Polaris is slightly variable, so they first switched to Vega as the standard reference star, and then switched to using tabulated zero pointsTemplate:Clarify for the measured fluxes.^[5] The magnitude depends on the wavelength band (see below).

The modern system is no longer limited to 6 magnitudes or only to visible light. Very bright objects have negative magnitudes. For example, Sirius, the brightest star of the celestial sphere, has an apparent magnitude of –1.4. The modern scale includes the Moon and the Sun. The full Moon has a mean apparent magnitude of –12.74^[6] and the Sun has an apparent magnitude of –26.74.^[7] The Hubble Space Telescope has located stars with magnitudes of 30 at visible wavelengths and the Keck telescopes have located similarly faint stars in the infrared.

Calculations

As the amount of light received actually depends on the thickness of the Earth's atmosphere in the line of sight to the object, the apparent magnitudes are adjusted to the value they would have in the absence of the atmosphere. The dimmer an object appears, the higher the numerical value given to its apparent magnitude. Note that brightness varies with distance; an extremely bright object may appear quite dim, if it is far away. Brightness varies inversely with the square of the distance. The absolute magnitude, M, of a celestial body (outside the Solar System) is the apparent magnitude it would have if it were at 10 parsecs (~32.6 light years); that of a planet (or other Solar System body) is the apparent magnitude it would have if it were 1 astronomical unit from both the Sun and Earth. The absolute magnitude of the Sun is 4.83 in the V band (yellow) and 5.48 in the B band (blue).^[8]

The apparent magnitude, m, in the band, x, can be defined as,

${\displaystyle m_{x}-m_{x,0}=-2.5\log _{10}\left({\frac {F_{x}}{F_{x,0}}}\right)\,}$,

where ${\displaystyle F_{x}\!\,}$ is the observed flux in the band x, and ${\displaystyle m_{x,0}}$ and ${\displaystyle F_{x,0}}$ are a reference magnitude, and reference flux in the same band x, such as that of Vega. An increase of 1 in the magnitude scale corresponds to a decrease in brightness by a factor of ${\displaystyle \approx 2.512}$. Based on the properties of logarithms, a difference in magnitudes, ${\displaystyle m_{1}-m_{2}=\Delta m}$, can be converted to a variation in brightness as ${\displaystyle F_{2}/F_{1}\approx 2.512^{\Delta m}}$.

Example: Sun and Moon

What is the ratio in brightness between the Sun and the full moon?

The apparent magnitude of the Sun is -26.74 (brighter), and the mean apparent magnitude of the full moon is -12.74 (dimmer).

Difference in magnitude : ${\displaystyle x=m_{1}-m_{2}=(-12.74)-(-26.74)=14.00}$

Variation in Brightness : ${\displaystyle v_{b}=2.512^{x}=2.512^{14.00}\approx 400,000}$

The Sun appears about 400,000 times brighter than the full moon.

Magnitude addition

Sometimes, it might be useful to add magnitudes, for example, to determine the combined magnitude of a double star when the magnitude of the individual components are known. This can be done by setting an equation using the brightness (in linear units) of each magnitude.^[9]

${\displaystyle 2.512^{-m_{f}}=2.512^{-m_{1}}+2.512^{-m_{2}}\!\ }$

Solving for ${\displaystyle m_{f}}$ yields

${\displaystyle m_{f}=-log_{2.512}\left(2.512^{-m_{1}}+2.512^{-m_{2}}\right)\!\ }$

where ${\displaystyle m_{f}}$ is the resulting magnitude after adding ${\displaystyle m_{1}}$ and ${\displaystyle m_{2}}$. Note that the negative of each magnitude is used because greater intensities equate to lower magnitudes.

Standard reference values

Standard apparent magnitudes and fluxes for typical bands^[10]

Band	${\displaystyle \lambda }$ (${\displaystyle \mu m}$)	${\displaystyle \Delta \lambda /\lambda }$Template:Clarify	Flux at m = 0, ${\displaystyle F_{x,0}}$ (Jy)	Flux at m = 0, ${\displaystyle F_{x,0}}$ ${\displaystyle (10^{-20}{\text{ erg/s/cm}}^{2}{\text{/Hz}})}$
U	0.36	0.15	1810	1.81
B	0.44	0.22	4260	4.26
V	0.55	0.16	3640	3.64
R	0.64	0.23	3080	3.08
I	0.79	0.19	2550	2.55
J	1.26	0.16	1600	1.6
H	1.60	0.23	1080	1.08
K	2.22	0.23	670	6.7
L	3.50
g	0.52	0.14	3730	3.73
r	0.67	0.14	4490	4.49
i	0.79	0.16	4760	4.76
z	0.91	0.13	4810	4.81

It is important to note that the scale is logarithmic: the relative brightness of two objects is determined by the difference of their magnitudes. For example, a difference of 3.2 means that one object is about 19 times as bright as the other, because Pogson's Ratio raised to the power 3.2 is approximately 19.05. A common misconception is that the logarithmic nature of the scale is because the human eye itself has a logarithmic response. In Pogson's time this was thought to be true (see Weber-Fechner law), but it is now believed that the response is a power law (see Stevens' power law).^[11]

Magnitude is complicated by the fact that light is not monochromatic. The sensitivity of a light detector varies according to the wavelength of the light, and the way it varies depends on the type of light detector. For this reason, it is necessary to specify how the magnitude is measured for the value to be meaningful. For this purpose the UBV system is widely used, in which the magnitude is measured in three different wavelength bands: U (centred at about 350 nm, in the near ultraviolet), B (about 435 nm, in the blue region) and V (about 555 nm, in the middle of the human visual range in daylight). The V band was chosen for spectral purposes and gives magnitudes closely corresponding to those seen by the light-adapted human eye, and when an apparent magnitude is given without any further qualification, it is usually the V magnitude that is meant, more or less the same as visual magnitude.

Because cooler stars, such as red giants and red dwarfs, emit little energy in the blue and UV regions of the spectrum their power is often under-represented by the UBV scale. Indeed, some L and T class stars have an estimated magnitude of well over 100, because they emit extremely little visible light, but are strongest in infrared.

Measures of magnitude need cautious treatment and it is extremely important to measure like with like. On early 20th century and older orthochromatic (blue-sensitive) photographic film, the relative brightnesses of the blue supergiant Rigel and the red supergiant Betelgeuse irregular variable star (at maximum) are reversed compared to what human eyes perceive, because this archaic film is more sensitive to blue light than it is to red light. Magnitudes obtained from this method are known as photographic magnitudes, and are now considered obsolete.

For objects within our Galaxy with a given absolute magnitude, 5 is added to the apparent magnitude for every tenfold increase in the distance to the object. This relationship does not apply for objects at very great distances (far beyond our galaxy), because a correction for general relativity must then be taken into account due to the non-Euclidean nature of space.

For planets and other Solar System bodies the apparent magnitude is derived from its phase curve and the distances to the Sun and observer. 50 year old Petroleum Engineer Kull from Dawson Creek, spends time with interests such as house brewing, property developers in singapore condo launch and camping. Discovers the beauty in planing a trip to places around the entire world, recently only coming back from .

Table of notable celestial objects

Some of the above magnitudes are only approximate. Telescope sensitivity also depends on observing time, optical bandpass, and interfering light from scattering and airglow.

See also

Template:Colbegin

• Absolute Magnitude
• Magnitude (astronomy)
• Photographic magnitude
• Luminosity in astronomy
• List of brightest stars
• List of nearest bright stars
• List of nearest stars
• Lux
• Surface brightness
• Distance modulus

Template:Colend

References

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External links

• The astronomical magnitude scale (International Comet Quarterly)

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