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{{About||the thermodynamic function "availability", in the sense of available useful work|exergy|availability as a form of cognitive bias|availability heuristic}}
[[Image:Brewsters-angle.svg|thumb|250px|An illustration of the polarization of light that is incident on an interface at Brewster's angle.]]
'''Brewster's angle''' (also known as the '''polarization angle''') is an [[angle of incidence]] at which [[light]] with a particular [[Polarization (waves)|polarization]] is perfectly transmitted through a transparent [[dielectric]] surface, with no [[Reflection (physics)|reflection]]. When ''unpolarized'' light is incident at this angle, the light that is reflected from the surface is therefore perfectly polarized. This special angle of incidence is named after the Scottish physicist [[David Brewster|Sir David Brewster]] (1781–1868).<ref>David Brewster (1815) [http://books.google.com/books?id=U-U_AAAAYAAJ&pg=PA125#v=onepage&q&f=false "On the laws which regulate the polarisation of light by reflection from transparent bodies,"] ''Philosophical Transactions of the Royal Society of London'', '''105''': 125-159.</ref>


In [[telecommunication]]s and [[reliability theory]], the term '''availability''' has the following meanings:
==Explanation==
When light encounters a boundary between two [[medium (optics)|media]] with different [[refractive index|refractive indices]], some of it is usually reflected as shown in the figure above. The fraction that is reflected is described by the [[Fresnel equations]], and is dependent upon the incoming light's polarization and angle of incidence.


* The degree to which a [[system]], [[subsystem]], or equipment is in a specified operable and committable state at the start of a mission, when the mission is called for at an unknown, ''i.e.,'' a random, time. Simply put, availability is the proportion of time a system is in a functioning condition.  This is often described as a '''mission capable rate'''.  Mathematically, this is expressed as 1 minus [[unavailability]].
The Fresnel equations predict that light with the ''p'' polarization ([[electric field]] polarized in the same [[Plane (mathematics)|plane]] as the [[incident ray]] and the [[surface normal]]) will not be reflected if the angle of incidence is
* The ratio of (a) the total time a [[functional unit]] is capable of being used during a given interval to (b) the length of the interval.


For example, a unit that is capable of being used 100 hours per week (168 hours) would have an availability of 100/168.  However, typical availability values are specified in [[decimal]] (such as 0.9998).  In [[high availability]] applications, a metric known as [[nines (engineering)|nines]], corresponding to the number of nines following the decimal point, is used.  In this system, "five nines" equals 0.99999 (or 99.999%) availability.
:<math>\theta_\mathrm B = \arctan \left( \frac{n_2}{n_1} \right), </math>


== Introduction ==
where ''n''<sub>1</sub> is the [[refractive index]] of the initial medium through which the light propagates (the "incident medium"), and ''n''<sub>2</sub> is the index of the other medium. This equation is known as '''Brewster's law''', and the angle defined by it is Brewster's angle.
Availability of a system is typically measured as a factor of its [[reliability (engineering)|reliability]] - as reliability increases, so does availability.  However, no system can guarantee 100.000% reliability;  and as such, no system can assure 100.000% availability.  Further, [[reliability engineering]] and [[maintainability]] involve processes designed to optimize availability under a set of constraints, such as time and cost-effectiveness.  Availability is the goal of most [[system]] users, and reliability engineering and maintainability provide the means to assure that availability performance [[requirements]] are achieved.


==Representation==
The physical mechanism for this can be qualitatively understood from the manner in which electric [[dipole]]s in the media respond to ''p''-polarized light. One can imagine that light incident on the surface is absorbed, and then reradiated by oscillating electric dipoles at the interface between the two media. The polarization of freely propagating light is always perpendicular to the direction in which the light is travelling. The dipoles that produce the transmitted (refracted) light oscillate in the polarization direction of that light. These same oscillating dipoles also generate the reflected light. However, dipoles do not radiate any energy in the direction of the [[Electric dipole moment|dipole moment]]. If the refracted light is p-polarized and propagates exactly perpendicular to the direction in which the light is predicted to be [[specular reflection|specularly reflected]], the dipoles point along the specular reflection direction and therefore no light can be reflected. (See diagram, above)
The most simple representation for '''availability''' is as a ratio of the expected value of the uptime of a system to the aggregate of the expected values of up and down time, or


: <math>A = \frac{E[\mathrm{Uptime}]}{E[\mathrm{Uptime}]+E[\mathrm{Downtime}]}</math>
With simple geometry this condition can be expressed as
:<math> \theta_1 + \theta_2 = 90^\circ,</math>
where θ<sub>1</sub> is the angle of reflection (or incidence) and θ<sub>2</sub> is the angle of refraction.


If we define the status function <math>X(t)</math> as
Using [[Snell's law]],


: <math>X(t)=
:<math>n_1 \sin \left( \theta_1 \right) =n_2 \sin \left( \theta_2 \right),</math>
  \begin{cases}
  1, & \mbox{sys functions at time } t\\
  0, &  \mbox{otherwise}
  \end{cases}
</math>


therefore, the availability ''A''(''t'') at time ''t''>0 is represented by
one can calculate the incident angle θ<sub>1</sub>&nbsp;=&nbsp;θ<sub>B</sub> at which no light is reflected:


: <math>
:<math>n_1 \sin \left( \theta_\mathrm B \right) =n_2 \sin \left( 90^\circ - \theta_\mathrm B \right)=n_2 \cos \left( \theta_\mathrm B \right).</math>
    A(t)=\Pr[X(t)=1]=E[X(t)].</math>


Average availability must be defined on an interval of the real line. If we consider an arbitrary constant <math>c>0</math>, then average availability is represented as
Solving for θ<sub>B</sub> gives


: <math>
:<math>\theta_\mathrm B = \arctan \left( \frac{n_2}{n_1} \right) .</math>
    A_c = \frac{1}{c}\int_0^c A(t)\,dt.
</math>


Limiting (or steady-state) availability is represented by{{Citation needed|date=August 2010}}
For a glass medium (''n''<sub>2</sub>&nbsp;≈&nbsp;1.5) in air (''n''<sub>1</sub>&nbsp;≈&nbsp;1), Brewster's angle for visible light is approximately 56°, while for an air-water interface (''n''<sub>2</sub>&nbsp;≈&nbsp;1.33), it is approximately 53°. Since the refractive index for a given medium changes depending on the wavelength of light, Brewster's angle will also vary with wavelength.


: <math>
The phenomenon of light being polarized by reflection from a surface at a particular angle was first observed by [[Étienne-Louis Malus]] in 1808.<ref>See:
    A = \lim_{c \rightarrow \infty} A_c.
*  Malus (1809) [http://books.google.com/books?id=hnJKAAAAYAAJ&pg=PA143#v=onepage&q&f=false "Sur une propriété de la lumière réfléchie"] (On a property of reflected light), ''Mémoires de physique et de chimie de la Société d'Arcueil'', '''2''' :  143-158.
</math>
*  Malus, E.L. (1809) "Sur une propriété de la lumière réfléchie par les corps diaphanes" (On a property of light reflected by translucent substances), ''Nouveau Bulletin des Sciences'' [par la Societé Philomatique de Paris], '''1''' : 266-270.
*  Etienne Louis Malus, ''Théorie de la double réfraction de la lumière dans les substances christallisées'' [Theory of the double refraction of light in crystallized substances] (Paris, France:  Garnery, 1810).</ref> He attempted to relate the polarizing angle to the refractive index of the material, but was frustrated by the inconsistent quality of glasses available at that time. In 1815, Brewster experimented with higher-quality materials and showed that this angle was a function of the refractive index, defining Brewster's law.


Limiting average availability is also defined on an interval <math>(0,c]</math> as,
Brewster's angle is often referred to as the "polarizing angle", because light that reflects from a surface at this angle is entirely polarized perpendicular to the incident plane ("''s''-polarized") A glass plate or a stack of plates placed at Brewster's angle in a light beam can, thus, be used as a [[polarizer]]. The concept of a polarizing angle can be extended to the concept of a Brewster wavenumber to cover planar interfaces between two linear [[bianisotropic material]]s. In the case of reflection at Brewster's angle, the reflected and refracted rays are mutually perpendicular.


: <math>
== Applications ==
    A_{\infty}=\lim_{c \rightarrow \infty} A_c = \lim_{c \rightarrow \infty}\frac{1}{c}\int_0^c A(t)\,dt,\quad c > 0.
</math>


===Example===
Polarized [[sunglasses]] use the principle of Brewster's angle to reduce glare from the sun reflecting off horizontal surfaces such as water or road. In a large range of angles around Brewster's angle, the reflection of ''p''-polarized light is lower than ''s''-polarized light. Thus, if the sun is low in the sky, reflected light is mostly ''s''-polarized. Polarizing sunglasses use a polarizing material such as [[Polaroid (polarizer)|Polaroid]] sheets to block horizontally-polarized light, preferentially blocking reflections from horizontal surfaces. The effect is strongest with smooth surfaces such as water, but reflections from roads and the ground are also reduced.
If we are using equipment which has [[mean time to failure]] (MTTF) of 81.5 years and [[mean time to repair]] (MTTR) of 1 hour:


MTTF in hours = 81.5*365*24=713940
Photographers use the same principle to remove reflections from water so that they can photograph objects beneath the surface. In this case, the [[Polarizing filter (photography)|polarizing filter]] camera attachment can be rotated to be at the correct angle (see figure).


Availability= MTTF/(MTTF+MTTR) = 713940/713941 =99.999859%
[[Image:Poloriser-demo.jpg|center|frame|Photograph taken of a window with a camera polarizer filter rotated to two different angles. In the picture at left, the polarizer is aligned with the polarization angle of the window reflection. In the picture at right, the polarizer has been rotated 90° eliminating the heavily polarized reflected sunlight.]]


Unavailability = 0.000141%
===Brewster windows=== <!--Brewster window redirects here.-->
[[Image:Brewster window.svg|thumb|right|A Brewster window]]
[[Gas laser]]s typically use a window tilted at Brewster's angle to allow the beam to leave the laser tube. Since the window reflects some ''s''-polarized light but no ''p''-polarized light, the round trip loss for the ''s'' polarization is higher than that of the ''p'' polarization. This causes the laser's output to be ''p'' polarized due to competition between the two modes.<ref name=Hecht>''Optics'', 3rd edition, Hecht, ISBN 0-201-30425-2</ref>


Outage due to equipment in hours per year
== See also ==
* [[Brewster angle microscope]]


U=0.01235 hours per year.
==Notes==
<!-- article does not discuss 1+0
<references/>
That was the case if we are using 1+0 link.. if we are using 1+1 we would use below formula to calculate availability
 
A= Under root  of MTBFa/MTBFa+20ms * MTBFb/MTBFb+20ms
-->
 
==Literature==
'''Availability''' is well established in the literature of [[stochastic modeling]] and [[optimal maintenance]]. Barlow and Proschan [1975] define availability of a repairable system as "the probability that the system is operating at a specified time t." While Blanchard [1998] gives a qualitative definition of availability as "a measure of the degree of a system which is in the operable and committable state at the start of mission when the mission is called for at an unknown random point in time." This definition comes from the MIL-STD-721. Lie, Hwang, and Tillman [1977] developed a complete survey along with a systematic classification of availability.
 
Availability measures are classified by either the time interval of interest or the mechanisms for the system [[downtime]]. If the time interval of interest is the primary concern, we consider instantaneous, limiting, average, and limiting average availability. The aforementioned definitions are developed in Barlow and Proschan [1975], Lie, Hwang, and Tillman [1977], and Nachlas [1998]. The second primary classification for availilability is contingent on the various mechanisms for downtime such as the inherent availability, achieved availability, and operational availability. (Blanchard [1998], Lie, Hwang, and Tillman [1977]). Mi [1998] gives some comparison results of availability considering inherent availability.
 
Availability considered in maintenance modeling can be found in Barlow and Proschan [1975] for replacement models, Fawzi and Hawkes [1991] for an R-out-of-N system with [[spare part|spare]]s and repairs, Fawzi and Hawkes [1990] for a series system with replacement and repair, Iyer [1992] for imperfect repair models, Murdock [1995] for age replacement preventive maintenance models, Nachlas [1998, 1989] for preventive maintenance models, and Wang and Pham [1996] for imperfect maintenance models.
 
==See also==
* [[High availability]]
* [[List of system quality attributes]]
* [[Spurious trip level]]
* [[Condition-based maintenance]]
* [[Fault reporting]]


==References==
==References==
{{FS1037C MS188}}
*A. Lakhtakia, "Would Brewster recognize today's Brewster angle?" ''OSA Optics News'', Vol. 15, No. 6,  pp.&nbsp;14–18 (1989).
*A. Lakhtakia, "General schema for the Brewster conditions," ''Optik'', Vol. 90, pp.&nbsp;184–186 (1992).


==External links==
==External links==
* [http://www.eventhelix.com/RealtimeMantra/FaultHandling/reliability_availability_basics.htm Reliability and Availability Basics]
*[http://scienceworld.wolfram.com/physics/BrewstersAngle.html Brewster's Angle Extraction] from Wolfram Research
* [http://www.eventhelix.com/RealtimeMantra/FaultHandling/system_reliability_availability.htm System Reliability and Availability]
*[http://www.rp-photonics.com/brewster_windows.html Brewster window at RP-photonics.com]
 
[[Category:Applied probability]]
[[Category:Telecommunication theory]]


[[ar:التواجدية]]
{{DEFAULTSORT:Brewster's Angle}}
[[cs:Dostupnost]]
[[Category:Geometrical optics]]
[[de:Verfügbarkeit]]
[[Category:Physical optics]]
[[es:Factor de disponibilidad]]
[[Category:Angle]]
[[eo:Havebleco]]
[[Category:Polarization (waves)]]
[[fr:Disponibilité]]
[[it:Disponibilità]]
[[hu:Rendelkezésre állás]]
[[nl:Beschikbaarheid]]
[[ja:可用性]]
[[pl:Dostępność (informatyka)]]
[[ru:Доступность информации]]
[[fi:Saatavuus]]
[[sv:Driftsäkerhet]]
[[uk:Доступність інформаційна]]
[[zh:可用性]]

Revision as of 09:20, 9 August 2014

An illustration of the polarization of light that is incident on an interface at Brewster's angle.

Brewster's angle (also known as the polarization angle) is an angle of incidence at which light with a particular polarization is perfectly transmitted through a transparent dielectric surface, with no reflection. When unpolarized light is incident at this angle, the light that is reflected from the surface is therefore perfectly polarized. This special angle of incidence is named after the Scottish physicist Sir David Brewster (1781–1868).[1]

Explanation

When light encounters a boundary between two media with different refractive indices, some of it is usually reflected as shown in the figure above. The fraction that is reflected is described by the Fresnel equations, and is dependent upon the incoming light's polarization and angle of incidence.

The Fresnel equations predict that light with the p polarization (electric field polarized in the same plane as the incident ray and the surface normal) will not be reflected if the angle of incidence is

where n1 is the refractive index of the initial medium through which the light propagates (the "incident medium"), and n2 is the index of the other medium. This equation is known as Brewster's law, and the angle defined by it is Brewster's angle.

The physical mechanism for this can be qualitatively understood from the manner in which electric dipoles in the media respond to p-polarized light. One can imagine that light incident on the surface is absorbed, and then reradiated by oscillating electric dipoles at the interface between the two media. The polarization of freely propagating light is always perpendicular to the direction in which the light is travelling. The dipoles that produce the transmitted (refracted) light oscillate in the polarization direction of that light. These same oscillating dipoles also generate the reflected light. However, dipoles do not radiate any energy in the direction of the dipole moment. If the refracted light is p-polarized and propagates exactly perpendicular to the direction in which the light is predicted to be specularly reflected, the dipoles point along the specular reflection direction and therefore no light can be reflected. (See diagram, above)

With simple geometry this condition can be expressed as

where θ1 is the angle of reflection (or incidence) and θ2 is the angle of refraction.

Using Snell's law,

one can calculate the incident angle θ1 = θB at which no light is reflected:

Solving for θB gives

For a glass medium (n2 ≈ 1.5) in air (n1 ≈ 1), Brewster's angle for visible light is approximately 56°, while for an air-water interface (n2 ≈ 1.33), it is approximately 53°. Since the refractive index for a given medium changes depending on the wavelength of light, Brewster's angle will also vary with wavelength.

The phenomenon of light being polarized by reflection from a surface at a particular angle was first observed by Étienne-Louis Malus in 1808.[2] He attempted to relate the polarizing angle to the refractive index of the material, but was frustrated by the inconsistent quality of glasses available at that time. In 1815, Brewster experimented with higher-quality materials and showed that this angle was a function of the refractive index, defining Brewster's law.

Brewster's angle is often referred to as the "polarizing angle", because light that reflects from a surface at this angle is entirely polarized perpendicular to the incident plane ("s-polarized") A glass plate or a stack of plates placed at Brewster's angle in a light beam can, thus, be used as a polarizer. The concept of a polarizing angle can be extended to the concept of a Brewster wavenumber to cover planar interfaces between two linear bianisotropic materials. In the case of reflection at Brewster's angle, the reflected and refracted rays are mutually perpendicular.

Applications

Polarized sunglasses use the principle of Brewster's angle to reduce glare from the sun reflecting off horizontal surfaces such as water or road. In a large range of angles around Brewster's angle, the reflection of p-polarized light is lower than s-polarized light. Thus, if the sun is low in the sky, reflected light is mostly s-polarized. Polarizing sunglasses use a polarizing material such as Polaroid sheets to block horizontally-polarized light, preferentially blocking reflections from horizontal surfaces. The effect is strongest with smooth surfaces such as water, but reflections from roads and the ground are also reduced.

Photographers use the same principle to remove reflections from water so that they can photograph objects beneath the surface. In this case, the polarizing filter camera attachment can be rotated to be at the correct angle (see figure).

Photograph taken of a window with a camera polarizer filter rotated to two different angles. In the picture at left, the polarizer is aligned with the polarization angle of the window reflection. In the picture at right, the polarizer has been rotated 90° eliminating the heavily polarized reflected sunlight.

Brewster windows

A Brewster window

Gas lasers typically use a window tilted at Brewster's angle to allow the beam to leave the laser tube. Since the window reflects some s-polarized light but no p-polarized light, the round trip loss for the s polarization is higher than that of the p polarization. This causes the laser's output to be p polarized due to competition between the two modes.[3]

See also

Notes

  1. David Brewster (1815) "On the laws which regulate the polarisation of light by reflection from transparent bodies," Philosophical Transactions of the Royal Society of London, 105: 125-159.
  2. See:
    • Malus (1809) "Sur une propriété de la lumière réfléchie" (On a property of reflected light), Mémoires de physique et de chimie de la Société d'Arcueil, 2 : 143-158.
    • Malus, E.L. (1809) "Sur une propriété de la lumière réfléchie par les corps diaphanes" (On a property of light reflected by translucent substances), Nouveau Bulletin des Sciences [par la Societé Philomatique de Paris], 1 : 266-270.
    • Etienne Louis Malus, Théorie de la double réfraction de la lumière dans les substances christallisées [Theory of the double refraction of light in crystallized substances] (Paris, France: Garnery, 1810).
  3. Optics, 3rd edition, Hecht, ISBN 0-201-30425-2

References

  • A. Lakhtakia, "Would Brewster recognize today's Brewster angle?" OSA Optics News, Vol. 15, No. 6, pp. 14–18 (1989).
  • A. Lakhtakia, "General schema for the Brewster conditions," Optik, Vol. 90, pp. 184–186 (1992).

External links

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