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		<title>Lenticular lens</title>
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		<summary type="html">&lt;p&gt;74.92.216.121: /* Corrective lenses */&lt;/p&gt;
&lt;hr /&gt;
&lt;div&gt;A &#039;&#039;&#039;distributed Bragg reflector&#039;&#039;&#039; (&#039;&#039;&#039;DBR&#039;&#039;&#039;) is a [[reflection (physics)|reflector]] used in [[Waveguide (optics)|waveguides]], such as [[optical fiber]]s. It is a structure formed from multiple layers of alternating materials with varying [[refractive index]], or by periodic variation of some characteristic (such as height) of a dielectric waveguide, resulting in periodic variation in the effective refractive index in the guide. Each layer boundary causes a partial reflection of an optical wave. For waves whose [[wavelength]] is close to four times the [[optical path length|optical thickness]] of the layers, the many reflections combine with [[constructive interference]], and the layers act as a high-quality reflector.  The range of wavelengths that are reflected is called the photonic [[stopband]]. Within this range of wavelengths, light is &amp;quot;forbidden&amp;quot; to propagate in the structure.&lt;br /&gt;
&lt;br /&gt;
==Reflectivity==&lt;br /&gt;
[[Image:DBRREFL.JPG|thumb|right|Calculated reflectivity of a schematic DBR structure]]&lt;br /&gt;
The DBR&#039;s [[reflectivity]], &amp;lt;math&amp;gt;R&amp;lt;/math&amp;gt;, for [[intensity (physics)|intensity]] is approximately given by &amp;lt;ref&amp;gt;{{cite journal | first=C.J.R. |last=Sheppard |authorlink=Colin Sheppard |title=Approximate calculation of the reflection coefficient from a stratified medium |year=1995 |journal=Pure and Applied Optics: Journal of the European Optical Society Part A |volume=4 |issue=5|page=665 |doi=10.1088/0963-9659/4/5/018|bibcode = 1995PApOp...4..665S }}&amp;lt;/ref&amp;gt;&amp;lt;!--The source calculates amplitudes or reflection coefficient r. The formular given in the source is the squareroot of the formular here, which is correct because here is the intensity of the reflection meant. The source expresses the reflection coefficient r with characteristic impedances Z so there is no doubt, that electo-magnetic amplitudes are meant.--&amp;gt;&lt;br /&gt;
&lt;br /&gt;
:&amp;lt;math&amp;gt;R= \left[\frac{n_o (n_2)^{2N} - n_s&lt;br /&gt;
(n_1)^{2N}}{n_o (n_2)^{2N} + n_s (n_1)^{2N}}\right]^2,&amp;lt;/math&amp;gt;&lt;br /&gt;
&lt;br /&gt;
where &amp;lt;math&amp;gt;n_o,\ n_1,\ n_2&amp;lt;/math&amp;gt; and &amp;lt;math&amp;gt;n_s\,&amp;lt;/math&amp;gt; are the respective refractive indices of the originating medium, the two alternating materials, and the terminating medium (i.e. backing or substrate); and &amp;lt;math&amp;gt;N&amp;lt;/math&amp;gt; is the number of repeated pairs of low/high refractive index material.&lt;br /&gt;
&lt;br /&gt;
The [[Bandwidth (signal processing)|bandwidth]] &amp;lt;math&amp;gt;\Delta\lambda_0&amp;lt;/math&amp;gt; of the photonic stopband can be calculated by&lt;br /&gt;
&lt;br /&gt;
:&amp;lt;math&amp;gt;\Delta\lambda_0 =&lt;br /&gt;
\frac{4\lambda_o}{\pi}\arcsin\left(\frac{n_2 - n_1}{n_2 + n_1}\right),&amp;lt;/math&amp;gt;&lt;br /&gt;
&amp;lt;!--Is this still correct?--&amp;gt;&lt;br /&gt;
where &amp;lt;math&amp;gt;\lambda_o&amp;lt;/math&amp;gt; is the central wavelength of the band.  &lt;br /&gt;
&lt;br /&gt;
Increasing the number of pairs in a DBR increases the mirror reflectivity and increasing the refractive index contrast between the materials in the Bragg pairs increases both the reflectivity and the bandwidth.  A common choice of materials for the stack is [[titanium dioxide]] (&#039;&#039;n&#039;&#039;≈2.5) and [[silica]] (&#039;&#039;n&#039;&#039;≈1.5).&amp;lt;ref&amp;gt;{{cite web |url=http://www.rp-photonics.com/bragg_mirrors.html |title=Bragg Mirrors |work=Encyclopedia of Laser Physics and Technology |publisher=RP Photonics |first=Rüdiger |last=Paschotta|accessdate=May 1, 2009}}&amp;lt;/ref&amp;gt; Substituting into the formula above gives a bandwidth of about 200&amp;amp;nbsp;nm for 630&amp;amp;nbsp;nm light.&lt;br /&gt;
&lt;br /&gt;
Distributed Bragg reflectors are critical components in [[vertical cavity surface emitting laser]]s and other types of narrow-linewidth [[laser diode]]s such as [[distributed feedback laser]]s. They are also used to form the [[cavity resonator]] (or [[optical cavity]]) in [[fiber laser]]s and [[free electron laser]]s.&lt;br /&gt;
&lt;br /&gt;
=== TE and TM mode reflectivity ===&lt;br /&gt;
[[Image:DBR TE MODE.PNG|thumb|left|Calculated reflectivity for TE mode light at various incidence angles, and wavelengths. Red regions correspond to R=1, while blue regions correspond to R=0, and other colors 0 &amp;lt; R &amp;lt; 1.]]&lt;br /&gt;
[[Image:DBR TM MODE.PNG|thumb|right|Calculated reflectivity for TM mode light at various incidence angles, and wavelengths. Orange regions correspond to R=1, while blue regions correspond to R=0, and other colors 0 &amp;lt; R &amp;lt; 1.]]&lt;br /&gt;
&lt;br /&gt;
This section discusses the interaction of [[Polarization (waves)|transverse electric]] (TE)&lt;br /&gt;
and [[Polarization (waves)|transverse magnetic]] (TM) polarized light with the DBR structure, over several&lt;br /&gt;
wavelengths and incidence angles. This reflectivity of the DBR structure (described below)&lt;br /&gt;
was calculated using the [[Transfer-matrix method (optics)|transfer-matrix method]] (TMM), where&lt;br /&gt;
the TE mode alone is highly reflected by this stack, while the TM modes are passed &lt;br /&gt;
through. This also shows the DBR acting as a [[polarizer]].&lt;br /&gt;
&lt;br /&gt;
For TE and TM incidence we have the reflection spectra of a DBR stack, corresponding&lt;br /&gt;
to a 6 layer stack of dielectric contrast of 11.5, between an air and dielectric layers.&lt;br /&gt;
The thicknesses of the air and dielectric layers are 0.8 and 0.2 of the period, respectively.&lt;br /&gt;
The wavelength in the figures below, corresponds to multiples of the cell period.&lt;br /&gt;
&lt;br /&gt;
This DBR is also a simple example of a 1D [[photonic crystal]].  It has a complete TE band gap, but only a pseudo TM band gap.&lt;br /&gt;
&lt;br /&gt;
==See also==&lt;br /&gt;
* [[Bragg&#039;s law]]&lt;br /&gt;
* [[Bragg diffraction]]&lt;br /&gt;
* [[Diffraction]]&lt;br /&gt;
** [[Diffraction grating]]&lt;br /&gt;
* [[Dielectric mirror]]&lt;br /&gt;
* [[Fabry–Pérot interferometer]]&lt;br /&gt;
* [[Fiber Bragg grating]]&lt;br /&gt;
* [[Photonic crystal fiber]]&lt;br /&gt;
* [[VCSEL]]&lt;br /&gt;
&lt;br /&gt;
==References==&lt;br /&gt;
{{Reflist}}&lt;br /&gt;
&lt;br /&gt;
[[Category:Optical devices]]&lt;br /&gt;
[[Category:Fiber optics]]&lt;/div&gt;</summary>
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