DescriptionPolarisation (Linear).svg	Diagram of linear polarisation. The direction of the black line relative to the central axis represents the direction of the electric field of the linearly polarized light at each point in space. The blue and red lines are projections of the black onto two planes which are at right angles. There is an version which is identical to this original with the exception of phase indictors to make the phase relationship of its components clearer. Refer to Other Versions section below.
Date	12/02/07
Source	Own drawing down in Mathematica, edited in the Open Source program Inscape.  ThisW3C-unspecifiedvector image was created withInkscape .
Author	inductiveload
Permission (Reusing this file)	Public domainPublic domainfalsefalse I, the copyright holder of this work, release this work into thepublic domain. This applies worldwide. In some countries this may not be legally possible; if so: I grant anyone the right to use this workfor any purpose, without any conditions, unless such conditions are required by law.
Other versions	Derivative works of this file: Polarisation (Linear) With.Phase.Indicators.svgCircular polarisation Elliptical polarisation

This figure requires the use of Arrow3D, which is not included in the StandardPackages (as of Feb 2007). This can be obtained from Wolfram Research atthis location. The required packages are:

<< Graphics`<< Arrow3D`Arrow3D`

The code is:

wavefunction=ParametricPlot3D[{Sin[4t],-Sin[4t],t},{t,0,5},    BoxRatios\[Rule]{1,      1,4},ImageSize\[Rule]400,Boxed\[Rule]False,Axes\[Rule]False,      PlotPoints\[Rule]60,ViewPoint->{2,2, 2},PlotRange\[Rule]All]repsi=ParametricPlot3D[{Sin[4t],-1,t,RGBColor[1,0,0]},{t,0,5},      BoxRatios\[Rule]{4,1,1},ImageSize\[Rule]500,      Boxed\[Rule]False,Axes\[Rule]False,        PlotPoints\[Rule]60,PlotRange\[Rule]All]impsi=ParametricPlot3D[{-1,-Sin[4t],t,RGBColor[0,0,102/255]},{    t,0,5},BoxRatios\[Rule]{4,1,1},ImageSize\[Rule]500,Boxed\[Rule]False,      Axes\[Rule]False,PlotPoints\[Rule]60,PlotRange\[Rule]All]end=ParametricPlot3D[{Sin[t],-Sin[t],0},{t,0,2π},BoxRatios\[Rule]{4,1,1},    ImageSize\[Rule]500,Boxed\[Rule]False,Axes\[Rule]False,      PlotPoints\[Rule]10,PlotRange\[Rule]All]xaxis=Graphics3D[Arrow3D[{0,0,-1},{  0,0,6},HeadSize \[Rule] UniformSize[.5],HeadColor\[Rule]Black]]uaxis=Graphics3D[Arrow3D[{0,-1,0},{0,3,0},HeadSize \[Rule]     UniformSize[.5],HeadColor\[Rule]Black]]vaxis=Graphics3D[Arrow3D[{-1,0,0},{3,0,0},HeadSize \[Rule]       UniformSize[.5],HeadColor\[Rule]Black]]plane=Graphics3D[Polygon[{{1.2,1.2,0},{1.2,-1.2,0},{-1.2,-1.2,0},{-1.2,1.2,0}}\]]crate=WireFrame[Graphics3D[Cuboid[{1,1,0},{-1,-1,5}]]]Show[wavefunction,xaxis,uaxis,vaxis,plane,repsi,impsi,end,crate]