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... Vector The Stokes vector is the quadractic form of a spinor. It is a bi-spinor, or also a 4-vector 4-vectors live in a Minkowsky space with metric ... – PowerPoint PPT presentation

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Title: Outline


1
Outline
  • Stokes Vectors, Jones Calculus and Mueller
    Calculus
  • Optics of Crystals Birefringence
  • Common polarization devices for the laboratory
    and for astronomical instruments
  • Principles of Polarimetry Modulation and
    Analysis. Absolute and Relative Polarimetry
  • Principles of Polarimetry Spatial modulation,
    Temporal modulation, Spectral modulation
  • Principles of Polarimetry Noise and errors
  • Spurious sources of polarization

2
Stokes Vector, Jones Calculus,Mueller Calculus
playing around with matrices
  • A. López Ariste

3
  • Assumptions
  • A plane transverse electromagnetic wave
  • Quasi-monochromatic
  • Propagating in a well defined direction z

4
Jones Vector
5
Jones Vector It is actually a complex vector
with 3 free parameters It transforms under the
Pauli matrices. It is a spinor
6
The Jones matrix of an optical device
In group theory SL(2,C)
7
From the quantum-mechanical point of view, the
wave function cannot be measured
directly. Observables are made of quadratic
forms of the wave function
J is a density matrix The coherence matrix
8
Like Jones matrices, J also belongs to the
SL(2,C) group, and can be decomposed in the basis
of the Pauli matrices.
Is the Stokes Vector
9
The Stokes vector is the quadractic form of a
spinor. It is a bi-spinor, or also a 4-vector
10
4-vectors live in a Minkowsky space with metric
(,-,-,-)
11
The Minkowski space
I
Partially polarized light
Cone of (fully polarized) light
Fully polarized light
V
Q
12
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13
M is the Mueller matrix of the transformation
14
From group theory, the Mueller matrix belongs to
a group of transformations which is the square of
SL(2,C) Actually a subgroup of this general
group called O(3,1) or Lorentz group
15
The cone of (fully polarized) light
I
Lorentz boost de/polarizer, attenuators,
dichroism
V
Q
16
The cone of (fully polarized) light
I
3-d rotation retardance, optical rotation
V
Q
17
Mueller Calculus
  • Any macroscopic optical device that transforms
    one input Stokes vector to an output Stokes
    vector can be written as a Mueller matrix
  • Lorentz group is a group under matrix
    multiplication A sequence of optical devices has
    as Mueller matrix the product of the individual
    matrices

18
Mueller Calculus 3 basic operations
  • Absorption of one component
  • Retardance of one component respect to the other
  • Rotation of the reference system

19
Mueller Calculus 3 basic operations
  • Absorption of one component

20
Mueller Calculus 3 basic operations
  • Absorption of one component
  • Retardance of one component respect to the other

21
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22
Mueller Calculus 3 basic operations
  • Absorption of one component
  • Retardance of one component respect to the other
  • Rotation of the reference system

23
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24
Optics of Crystals Birefringence
  • A. López Ariste

25
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26
Chapter XIV, Born Wolf
27
!!
28
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31
Ellipsoïd
32
Ellipsoïd
33
Three types of crystals
A spherical wavefront
34
Three types of crystals
  • Two apparent waves propagating at different
    speeds
  • An ordinary wave, with a spherical wavefront
    propagating
  • at ordinary speed vo
  • An extraordinary wave with an elliptical
    wavefront, its speed
  • depends on direction with characteristic values
    vo and ve

35
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37
Three types of crystals
38
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40
z
s
The ellipsoïd of D in uniaxial crystals
De
The two propagating waves are linearly polarized
and orthogonal one to each other
Do
41
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42
  • Typical birefringences
  • Quartz 0.009
  • Calcite -0.172
  • Rutile 0.287
  • Lithium Niobate -0.085

43
Common polarization devices for the laboratory
and for astronomical instruments
  • A. López Ariste

44
Linear Polarizer
45
Retarder
46
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47
Savart Plate
48
Glan-Taylor Polarizer
  • Glan-Taylor.jpg

49
Glan-Thompson Polarizing Beam-Splitter
50
Rochon Polarizing Beamsplitter
51
Polaroid
52
Dunn Solar Tower. New Mexico
53
  • Typical birefringences
  • Quartz 0.009
  • Calcite -0.172
  • Rutile 0.287
  • Lithium Niobate -0.085

Zero-order waveplates
Multiple-order waveplates
54
Waveplates
55
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Principles of PolarimetryModulation Absolute
and Relative Polarimetry
  • A. López Ariste

57
Measure 1 I Q Measure 2 I -
Q Subtraction 0.5 (M1 M2 ) Q Addition
0.5 (M1 M2 ) I
How to switch from Measure 1 to Measure 2?
MODULATION
58
Measure 1 I Q Measure 2 I -
Q Subtraction 0.5 (M1 M2 ) Q Addition
0.5 (M1 M2 ) I
Principle of Polarimetry Everything should be
the same EXCEPT for the sign
59
MODULATION
60
MODULATION
61
MODULATION
O is the Modulation Matrix
62
MODULATION
Conceptually, it is the easiest thing Is it so
instrumentally? Is it efficient respect to photon
collection, noise and errors?
63
MODULATION
Del Toro Iniesta Collados (2000) Asensio Ramos
Collados (2008)
64
MODULATION
Del Toro Iniesta Collados (2000)
Del Toro Iniesta Collados (2000) Asensio Ramos
Collados (2008)
65
MODULATION
66
Design of a Polarimeter
  • Specify an efficient modulation scheme The
    answer is constrained by our instrumental choices

67
Absolute vs. Relative Polarimetry
Efficiency in Q,U and V limited by efficiency in
I
What limits efficiency in I?
68
Absolute vs. Relative Polarimetry
What limits efficiency in I?
Measure 1 I Q Measure 2 I -
Q Subtraction 0.5 (M1 M2 ) Q Addition
0.5 (M1 M2 ) I
Principle of Polarimetry Everything should be
the same EXCEPT for the sign
69
Absolute vs. Relative Polarimetry
What limits efficiency in I?
Measure 1 I Q Measure 2 I -
Q Subtraction 0.5 (M1 M2 ) Q Addition
0.5 (M1 M2 ) I
Usual photometry of present astronomical
detectors is around 10-3
Principle of Polarimetry Everything should be
the same EXCEPT for the sign
70
Absolute vs. Relative Polarimetry
What limits efficiency in I?
Usual photometry of present astronomical
detectors is around 10-3
You cannot do polarimetry better than photometry
71
Absolute vs. Relative Polarimetry
What limits efficiency in I?
Usual photometry of present astronomical
detectors is around 10-3
You cannot do ABSOLUTE polarimetry better than
photometry
72
Absolute vs. Relative Polarimetry
Absolute error 10-3 I Relative error 10-3 Q
73
Absolute vs. Relative Polarimetry
Li 6708
Absolute error 10-3 I Relative error 10-3 Q
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75
D2
D1
D2
Phase de 45 deg
Phase de 102 deg
76
Design of a Polarimeter
  • Specify an efficient modulation scheme The
    answer is constrained by our instrumental choices
  • Define a measurement that depends on relative
    polarimetry, if a good sensitivity is required

77
Principles of Polarimetry Spatial modulation,
Temporal modulation, Spectral modulation
  • A. López Ariste

78
Measure 1 I Q Measure 2 I -
Q Subtraction 0.5 (M1 M2 ) Q Addition
0.5 (M1 M2 ) I
How to switch from Measure 1 to Measure 2?
MODULATION
79
How to switch from Measure 1 to Measure n?
80
Analyser Calcite beamsplitter
81
Analyser Rotating Polariser
82
Analyser Calcite beamsplitter
2 beams 2 images Spatial modulation
Analyser Rotating Polariser
2 angles 2 exposures Temporal modulation
83
Modulator
What about U and V?
84
Modulator
85
Modulator
86
Modulator Rotating ?/4
87
The basic Polarimeter
Analyzer
Modulator
88
Examples
2 Quarter-Waves Calcite Beamsplitter
QW1 QW2 Measure
T1 0 0 Q
T2 22.5 22.5 U
T3 0 -45 V
T4 0 45 -V
.
89
LCVR
Calcite
90
Examples
  1. Rotating Quarterwave plate Calcite Beamsplitter
  2. Photelastic Modulators (PEM) Linear Polariser

91
Spectral Modulation
Chromatic waveplate
Followed by an analyzer
92
Spectral Modulation
Chromatic waveplate
Followed by an analyzer
See Video from Frans Snik (Univ. Leiden)
93
Principles of Polarimetry Noise and errors
  • A. López Ariste

94
Sensitivity vs. Accuracy
SENSITIVITY Smallest detectable polarization
signal related to noise levels in Q/I, U/I,
V/I. RELATIVE POLARIMETRY
ACCURACY The magnitude of detected polarization
signal That can be quanti?ed Parametrized by
position of zero point for Q, U, V ABSOLUTE
POLARIMETRY
95
Sensitivity vs. Accuracy
SENSITIVITY Smallest detectable polarization
signal related to noise levels in Q/I, U/I,
V/I. RELATIVE POLARIMETRY
Gaussian Noise (e.g. Photon Noise, Camera Shot
Noise)
96
Correcting some unknown errorsSpatio-temporal
modulation
Goal to make the measurements symmetric respect
to unknown errors in space and time
IV
Detectin in different pixels
I-V
Exposure 1
97
Spatio-temporal modulation
Goal to make the measurements symmetric respect
to unknown errors in space and time
IV
I-V
Detection at different times
Detectin in different pixels
I-V
IV
Exposure 1
Exposure 2
98
Spatio-temporal modulation
IV
I-V
I-V
IV
Exposure 1
Exposure 2
99
Spatio-temporal modulation
Lets make it more general
100
Cross-Talk
This is our polarimeter
This is what comes from the outer universe
Is this true?
101
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103
CrossTalk
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105
Solutions to Crosstalk
  • Avoid it
  • Measure it

Mirrors with spherical symmetry (M1,M2) introduce
no polarization Cassegrain-focus are good places
for polarimeters THEMIS, CFHT-Espadons,
AAT-Sempol,TBL-Narval,HARPS-Pol,
Given find its inverse and apply
it to the measurements It may be dependent on
time and wavelength It forces you to observe the
full Stokes vector
106
Dunn Solar Tower. New Mexico
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108
Solutions to Crosstalk
  • Compensate it
  • Several procedures
  • Introduce elements that compensate the
    instrumental polarization
  • Measure the Stokes vector that carries the
    information
  • Project the Stokes vector into the Eigenvector of
    the matrix


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