File:Two polarizers animation.gif
Two_polarizers_animation.gif (500 × 500 pixels, file size: 3.56 MB, MIME type: image/gif, looped, 101 frames, 10 s)
Captions
Summary
[edit]DescriptionTwo polarizers animation.gif |
English: From the incoming circularly polarized light only its vertical component propagates through the first polarizer. When another polarizer is inserted after the first one, the polarization and intensity of the outgoing light depend on the rotation angle of the second polarizer. When the second polarizer is set to 90 degrees, no light makes it through. Čeština: Z kruhově polarizovaného světla je lineárním polarizátorem vyfiltrována vertikální polarizace. Další přidaný polarizátor tuto polarizaci již dále nezmění, je-li ve výchozí poloze. S natočením druhého polarizátoru je vyfiltrováno čím dál méně světla v závislosti na úhlu natočení. Pokud je úhel roven 90 stupňům, neprochází druhým polarizátorem již žádné světlo. |
Date | |
Source | Own work |
Author | JozumBjada |
Licensing
[edit]- You are free:
- to share – to copy, distribute and transmit the work
- to remix – to adapt the work
- Under the following conditions:
- attribution – You must give appropriate credit, provide a link to the license, and indicate if changes were made. You may do so in any reasonable manner, but not in any way that suggests the licensor endorses you or your use.
- share alike – If you remix, transform, or build upon the material, you must distribute your contributions under the same or compatible license as the original.
Source code
[edit]This animation was created using Wolfram language 12.0.0 for Microsoft Windows (64-bit) (April 6, 2019). The source code follows.
(* ::Package:: *)
(* ::Title:: *)
(*Two polarizers*)
(* ::Text:: *)
(*Version: "12.0.0 for Microsoft Windows (64-bit) (April 6, 2019)"*)
(* ::Section:: *)
(*Parameters*)
(* ::Input::Initialization:: *)
innerrad=0.8;
outerthick=.3;
innerthick=.2;
dist=2;
(* ::Input::Initialization:: *)
black=GrayLevel[0.3];
(* ::Input::Initialization:: *)
fontFamily="Times New Roman";
fontSize=25;
(* ::Input::Initialization:: *)
ang1=0.619;
ang2=0.772;
ang12=0.843;
(* ::Section:: *)
(*Polarizer*)
(* ::Input::Initialization:: *)
rim=ChartElementData["CylindricalSector3D"][{{0,2Pi},{innerrad,1},{-outerthick/2,outerthick/2}},1];
(*courtesy: suggestion by user 'kglr' at: https://mathematica.stackexchange.com/questions/153536/thick-annulus-ring-in-3d*)
(* ::Input::Initialization:: *)
coating=DensityPlot[y ,{x,-1,1},{y,-1,1},RegionFunction->(#1^2+#2^2<=1&),ColorFunction->(ColorData["Rainbow"][Mod[2#1,1]]&),PlotStyle->Opacity[.5],Frame->False];
coating=First@Cases[InputForm[coating],_GraphicsComplex,Infinity];
coating=Rasterize[Graphics@coating,ImageResolution->50,Background->None];
coating={Texture[coating],EdgeForm[None],Polygon[{{-1,-1,0},{1,-1,0},{1,1,0},{-1,1,0}},VertexTextureCoordinates->{{0,0},{1,0},{1,1},{0,1}}]};
(* ::Input::Initialization:: *)
filter={EdgeForm[None],
{Opacity[.5],LightBlue,Cylinder[{{0,0,-innerthick/2},{0,0,innerthick/2}},innerrad-.001]},
{coating},
{Gray,rim,Scale[rim,{1.03,1.03,.6}]},
{Darker[black],Cuboid[{innerrad,-0.02,0},{1.01,0.02,1.3outerthick/2}],Cuboid[{-innerrad,-0.02,0},{-1.01,0.02,1.3outerthick/2}]}
};
(* ::Input::Initialization:: *)
arc[ang_]:=Module[{c=1,ampl=1.5,aux},
If[ang==0,Return[{}]];
aux=ParametricPlot3D[{ampl Cos[c t],ampl Sin[c t],0},{t,0,-ang}];
aux=First@Cases[InputForm[aux],_Line,Infinity];
If[ang>25Degree,Arrow[Tube[Reverse@First@aux,.02]],Tube[aux,.02]]
];
(* ::Input::Initialization:: *)
reticule[ang_]:=With[{len=1.8},
{black,
Tube[Line[{{1,0,0},{len,0,0}}],.03],
Tube[Line[{{Cos[ang],-Sin[ang],0},len{Cos[ang],-Sin[ang],0}}],.03],
Arrowheads[.04],arc[ang],
Text[Style[ToString[NumberForm[N@ang/Degree,{3,1}]]<>"\[Degree]",fontSize,Black,Background->GrayLevel[1,.8],FontFamily->fontFamily],1.7{Cos[ang/2],-Sin[ang/2],0},{-.5,-.5}]
}
];
(* ::Section:: *)
(*Waves*)
(* ::Input::Initialization:: *)
waveCircular[ampl_,phase_,length_:dist]:=Module[{c=2\[Pi] /dist 5,aux},
aux=ParametricPlot3D[{ampl Sin[c t-phase],ampl Cos[c t-phase],t},{t,0,length}];
aux=First@Cases[InputForm[aux],_Line,Infinity];
{Red,Tube[aux,.05]}
];
(* ::Input::Initialization:: *)
wave[ampl_,phase_,length_:dist]:=Module[{c=2\[Pi] /dist 5,aux},
aux=ParametricPlot3D[{ampl Sin[c t-phase],0,t},{t,0,length}];
aux=First@Cases[InputForm[aux],_Line,Infinity];
{Red,Tube[aux,.05]}
];
(* ::Section:: *)
(*Time evolution*)
(* ::Input::Initialization:: *)
evolAngleRezoom=Interpolation[{{0,ang1},{.5,ang12},{1,ang2}},InterpolationOrder->2];
(* ::Input:: *)
(*(*Plot[evolAngleRezoom[x],{x,0,1}]*)*)
(* ::Input::Initialization:: *)
timeEvolution[t_]:=Module[{ang,pt,ctr,len,ypos,rot,lena,
t1=0.1,t2=0.3,t3=0.5,t4=0.7,t5=0.9,ypos1=-2.1,ypos2=0,rot1=0,rot2=90Degree,pt1={2,4,4},pt2={2,2,4}+{0.18,0,2dist},ctr1={0,0,0.3},ctr2={0.18,0,2dist},len1=dist,len2=2dist-outerthick,len3=3dist,len4=2dist-innerthick-0.01,lena1=0,lena2=dist
},
Which[
t<t1,{ang1,pt1,ctr1,len1,ypos1,rot1,lena1},
t1<=t<t2,{
evolAngleRezoom[Rescale[t,{t1,t2},{0,1}]],
pt1+Rescale[t,{t1,t2},{0,1}](pt2-pt1),
ctr1+Rescale[t,{t1,t2},{0,1}](ctr2-ctr1),
Rescale[t,{t1,t2},{len1,len2}],
ypos1,
rot1,
lena1
},
t2<=t<t3,{ang2,pt2,ctr2,len2,Rescale[t,{t2,t3},{ypos1,ypos2}],rot1,lena1},
t3<=t<t4,{ang2,pt2,ctr2,Rescale[t,{t3,t4},{len2,len3}],ypos2,rot1,lena1},
t4<=t<t5,{ang2,pt2,ctr2,len4,ypos2,Rescale[t,{t4,t5},{rot1,rot2}],lena2},
t5<=t,{ang2,pt2,ctr2,len4,ypos2,rot2,lena2}
]
]
(* ::Section:: *)
(*Scene*)
(* ::Input::Initialization:: *)
scene[t_]:=Module[{ang,pt,ctr,len,ypos,rot,lena},
{ang,pt,ctr,len,ypos,rot,lena}=timeEvolution[t];
Graphics3D[{
{
filter,
{Red,EdgeForm[None],
{Opacity[.5],Cylinder[{{0,0,-dist},{0,0,-1.01innerthick/2}},.6innerrad]},
{Opacity[0.25],Cylinder[{{0,0,1.01innerthick/2},{0,0,len}},.6innerrad]}
},
Translate[waveCircular[.55innerrad ,-5t],{0,0,-dist}],
Translate[wave[1/Sqrt[2] .55innerrad ,-5t,len],{0,0,0}]
},
{
Translate[reticule[rot],{0,ypos,2dist}],
Translate[Rotate[filter,-rot,{0,0,1}],{0,ypos,2dist}],
If[lena!=0,{Red,EdgeForm[None],
Opacity[0.25Cos[rot]^2],Cylinder[{{0,0,2dist+1.01innerthick/2},{0,0,2dist+lena}},.6innerrad],
Opacity[Cos[rot]],Translate[Rotate[wave[1/Sqrt[2] .55innerrad Cos[rot],-5t,len/2],-rot,{0,0,1}],{0,0,2dist}]
},{}]
}
},
Boxed->False,Lighting->"Neutral",
PlotRange->{2.1{-.6,1},2{-2,0.6},1.05dist{-1,4}},
ViewVector->{pt,ctr},ViewAngle->ang,ViewVertical->{1,0,0}
]]
(* ::Section:: *)
(*Export*)
(* ::Input:: *)
(*(*Manipulate[scene[t],{{t,.878},0,1,Appearance\[Rule]"Open"}]*)*)
(* ::Input:: *)
(*{time,frames}=AbsoluteTiming[ParallelTable[Rasterize[scene[t],RasterSize->500],{t,0,1,.01}]];*)
(*time*)
(* ::Input:: *)
(*SetDirectory[NotebookDirectory[]]*)
(*Export["scene.gif",frames,AnimationRepetitions->Infinity,"DisplayDurations"->.1]*)
(* ::Input:: *)
(*SystemOpen[%]*)
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Date/Time | Thumbnail | Dimensions | User | Comment | |
---|---|---|---|---|---|
current | 12:54, 29 August 2021 | 500 × 500 (3.56 MB) | JozumBjada (talk | contribs) | Cross-wiki upload from cs.wikipedia.org |
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