Multi-wavelength cross-connect optical network
First Claim
1. An optical device that separates an input signal into a first output signal having a first spectral band and a second output signal having a second spectral band, wherein the first and second spectral bands are substantially complementary, the device comprising:
- a first element that spatially separates the input signal into a first beam and a second beam that have orthogonal polarizations;
a first polarization rotator that rotates the polarization of one of the first beam and the second beam to the polarization of the other of the first beam and the second beam;
a first wavelength filter having a polarization dependent optical transmission function such that the first beam is decomposed into a third beam and a fourth beam and the second beam is decomposed into a fifth beam and a sixth beam, wherein the third beam and the fifth beam carry the first spectral band at a first polarization and the fourth beam and the sixth beam carry the second spectral band at a second polarization that is orthogonal to the first polarization;
a second element that spatially separates the third and fourth beams and spatially separates the fifth and sixth beams;
a second wavelength filter having a polarization dependent optical transmission function such that the first and second spectral bands are purified, and the polarization of one of the third beam and the fourth beam is rotated to the polarization of the other of the third beam and the fourth beam, and the polarization of one of the fifth beam and the sixth beam is rotated to the polarization of the other of the fifth beam and the sixth beam;
a second polarization rotator that rotates the polarization of one of the third beam and the fifth beam to the polarization of the other of the third beam and the fifth beam, and rotates the polarization of one of the fourth beam and the sixth beam to the polarization of the other of the fourth beam and the sixth beam; and
a third element that combines the third beam and fifth beam to form the first output signal and combines the fourth beam and the sixth beam to form the second output signal.
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Abstract
An optical cross-connect network provides wavelength routing of optical channels between two arrays of optical fibers carrying WDM signals using interconnected arrays of optical wavelength switches based on combinations of a 1×2 wavelength switch architecture. For example, a cross-connect network can be made by interconnecting two arrays of 1×4 wavelength switches, each of which is made by combining three 1×2 wavelength switches. Each 1×2 optical wavelength switch has polarization separation element (e.g., a first birefringent element) that decomposes and spatially separates the input WDM signal into two orthogonally-polarized beams. A first polarization rotator selectably rotates the polarization of one of the beams to match the polarization of other beam, based on an external control signal. A wavelength filter (e.g., stacked waveplates) provides a polarization-dependent optical transmission function such that the first beam decomposes into third and fourth orthogonal beams, and the second beam decomposes into fifth and sixth orthogonal beams. The third and fifth beams carry a first spectral band at a first polarization and the fourth and sixth beams carry a second spectral band at an orthogonal polarization. A polarization-dependent routing element (e.g., a second birefringent element) spatially separates these four beams into four horizontally polarized and vertically polarized components. A second polarization rotator rotates the polarizations of the beams so that the third and fifth beams, and the fourth and sixth beams are orthogonally polarized. A polarization combining element recombines the third and fifth beams and the fourth and sixth beams based on control states of the switch.
85 Citations
58 Claims
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1. An optical device that separates an input signal into a first output signal having a first spectral band and a second output signal having a second spectral band, wherein the first and second spectral bands are substantially complementary, the device comprising:
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a first element that spatially separates the input signal into a first beam and a second beam that have orthogonal polarizations;
a first polarization rotator that rotates the polarization of one of the first beam and the second beam to the polarization of the other of the first beam and the second beam;
a first wavelength filter having a polarization dependent optical transmission function such that the first beam is decomposed into a third beam and a fourth beam and the second beam is decomposed into a fifth beam and a sixth beam, wherein the third beam and the fifth beam carry the first spectral band at a first polarization and the fourth beam and the sixth beam carry the second spectral band at a second polarization that is orthogonal to the first polarization;
a second element that spatially separates the third and fourth beams and spatially separates the fifth and sixth beams;
a second wavelength filter having a polarization dependent optical transmission function such that the first and second spectral bands are purified, and the polarization of one of the third beam and the fourth beam is rotated to the polarization of the other of the third beam and the fourth beam, and the polarization of one of the fifth beam and the sixth beam is rotated to the polarization of the other of the fifth beam and the sixth beam;
a second polarization rotator that rotates the polarization of one of the third beam and the fifth beam to the polarization of the other of the third beam and the fifth beam, and rotates the polarization of one of the fourth beam and the sixth beam to the polarization of the other of the fourth beam and the sixth beam; and
a third element that combines the third beam and fifth beam to form the first output signal and combines the fourth beam and the sixth beam to form the second output signal. - View Dependent Claims (2, 3, 4, 5, 6)
the first polarization rotator is a half wave plate; and
the second polarization rotator is a half wave plate.
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3. The device of claim 1 wherein each of the first and second wavelength filters comprises:
a plurality of birefringent components with each element oriented in a predetermined direction.
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4. The device of claim 3 wherein each of the birefringent components comprise a birefringent material selected from the group consisting of:
calcite, rutile, YVO4, and LiNbO3.
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5. The device of claim 1 wherein each of the first, second, and third elements are birefringent elements.
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6. The device of claim 5 wherein each birefringent element comprises a birefringent material selected from the group consisting of:
calcite, rutile, YVO4, and LiNbO3.
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7. A method for separating an input optical signal into a first output optical signal having a first spectral band and a second output optical signal having a second spectral band, wherein the first and second spectral bands are substantially complementary, the method comprising the steps of:
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(a) spatially separating the input optical signal into a first beam and a second beam that have orthogonal polarizations;
(b) decomposing, according to a polarization dependent optical transmission function, the first beam into a third beam and a fourth beam;
(c) decomposing, according to a polarization dependent optical transmission function, the second beam into a fifth beam and a sixth beam, wherein the third beam and the fifth beam carry the first spectral band at a first polarization and the fourth beam and the sixth beam carry the second spectral band at a second polarization that is orthogonal to the first polarization;
(d) purifying the first and second spectral bands, according to a polarization dependent optical transmission function;
(e) combining the third beam and fifth beam to form the first output optical signal; and
(f) combining the fourth beam and the sixth beam to form the second output optical signal. - View Dependent Claims (8, 9)
calcite, rutile, YVO4, and LiNbO3.
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10. A method for separating an input optical signal into a first output optical signal having a first spectral band and a second output optical signal having a second spectral band, wherein the first and second spectral bands are substantially complementary, the method comprising the steps of:
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(a) spatially separating the input optical signal into a first beam and a second beam that have orthogonal polarizations;
(b) rotating the polarization of one of the first beam and the second beam to the polarization of the other of the first beam and the second beam;
(c) decomposing, according to a polarization dependent optical transmission function, the first beam into a third beam and a fourth beam;
(d) decomposing, according to a polarization dependent optical transmission function, the second beam into a fifth beam and a sixth beam, wherein the third beam and the fifth beam carry the first spectral band at a first polarization and the fourth beam and the sixth beam carry the second spectral band at a second polarization that is orthogonal to the first polarization;
(e) spatially separating the third and fourth beams;
(f) spatially separating the fifth and sixth beams;
(g) purifying the first and second spectral bands, according to a polarization dependent optical transmission function;
(h) rotating the polarization of one of the third beam and the fourth beam to the polarization of the other of the third beam and the fourth beam;
(i) rotating the polarization of one of the fifth beam and the sixth beam to the polarization of the other of the fifth beam and the sixth beam;
(j) rotating the polarization of one of the third beam and the fifth beam to the polarization of the other of the third beam and the fifth beam;
(k) rotating the polarization of one of the fourth beam and the sixth beam to the polarization of the other of the fourth beam and the sixth beam;
(l) combining the third beam and fifth beam to form the first output optical signal; and
(m) combining the fourth beam and the sixth beam to form the second output optical signal. - View Dependent Claims (11, 12, 13, 14, 15, 16, 17)
calcite, rutile, YVO4, and LiNbO3.
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14. The method of claim 10 wherein the steps (g), (h) and (i) are performed via a plurality of birefringent components with each element oriented in a predetermined direction.
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15. The method of claim 14 wherein each of the birefringent components comprise a birefringent material selected from the group consisting of:
calcite, rutile, YVO4, and LiNbO3.
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16. The method of claim 10 wherein the steps (a), (e), (f), (l), and (m) are performed via a birefringent element.
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17. The method of claim 16 wherein the birefringent elements comprises a birefringent material selected from the group consisting of:
calcite, rutile, YVO4, and LiNbO3.
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18. An optical device that separates an input signal into a first output signal having a first spectral band and a second output signal having a second spectral band, wherein the first and second spectral bands are substantially complementary, the device comprising:
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means for spatially separating the input optical signal into a first beam and a second beam that have orthogonal polarizations;
first means for decomposing, according to a polarization dependent optical transmission function, the first beam into a third beam and a fourth beam;
second means for decomposing, according to a polarization dependent optical transmission function, the second beam into a fifth beam and a sixth beam, wherein the third beam and the fifth beam carry the first spectral band at a first polarization and the fourth beam and the sixth beam carry the second spectral band at a second polarization that is orthogonal to the first polarization;
means for purifying the first and second spectral bands, according to a polarization dependent optical transmission function;
first means for combining the third beam and fifth beam to form the first output optical signal; and
second means for combining the fourth beam and the sixth beam to form the second output optical signal. - View Dependent Claims (19, 20)
a plurality of birefringent components with each element oriented in a predetermined direction.
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20. The device of claim 19 wherein each of the birefringent components comprise a birefringent material selected from the group consisting of:
calcite, rutile, YVO4, and LiNbO3.
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21. An optical device that separates an input signal into a first output signal having a first spectral band and a second output signal having a second spectral band, wherein the first and second spectral bands are substantially complementary, the device comprising:
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a first element that spatially separates the input signal into a first beam and a second beam;
a wavelength filter having a polarization dependent optical transmission function such that the first beam is decomposed into a third beam and a fourth beam and the second beam is decomposed into a fifth beam and a sixth beam, wherein the third beam and the fifth beam carry the first spectral band at a first polarization and the fourth beam and the sixth beam carry the second spectral band at a second polarization that is orthogonal to the first polarization;
a second element that combines the third beam and fifth beam to form the first output signal and combines the fourth beam and the sixth beam to form the second output signal. - View Dependent Claims (22, 23)
a plurality of birefringent components with each element oriented in a predetermined direction.
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23. The device of claim 22 wherein each of the birefringent components comprise a birefringent material selected from the group consisting of:
calcite, rutile, YVO4, and LiNbO3.
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24. An optical device that separates an input signal into a first output signal having a first spectral band and a second output signal having a second spectral band, wherein the first and second spectral bands are substantially complementary, the device comprising:
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a first element that spatially separates the input signal into a first beam and a second beam that have orthogonal polarizations;
a first polarization rotator that rotates the polarization of one of the first beam and the second beam to the polarization of the other of the first beam and the second beam;
a wavelength filter having a polarization dependent optical transmission function such that the first beam is decomposed into a third beam and a fourth beam and the second beam is decomposed into a fifth beam and a sixth beam, wherein the third beam and the fifth beam carry the first spectral band at a first polarization and the fourth beam and the sixth beam carry the second spectral band at a second polarization that is orthogonal to the first polarization;
a second element that spatially separates the third and fourth beams and spatially separates the fifth and sixth beams;
a second polarization rotator that rotates the polarization of one of the third beam and the fifth beam to the polarization of the other of the third beam and the fifth beam, and rotates the polarization of one of the fourth beam and the sixth beam to the polarization of the other of the fourth beam and the sixth beam; and
a third element that combines the third beam and fifth beam to form the first output signal and combines the fourth beam and the sixth beam to form the second output signal. - View Dependent Claims (25, 26, 27, 28, 29)
the first polarization rotator is a half wave plate; and
the second polarization rotator is a half wave plate.
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26. The device of claim 24 wherein the wavelength filter comprises:
a plurality of birefringent components with each element oriented in a predetermined direction.
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27. The device of claim 26 wherein each of the birefringent components comprise a birefringent material selected from the group consisting of:
calcite, rutile, YVO4, and LiNbO3.
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28. The device of claim 24 wherein each of the first, second, and third elements are birefringent elements.
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29. The device of claim 28 wherein each birefringent element comprises a birefringent material selected from the group consisting of:
calcite, rutile, YVO4, and LiNbO3.
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30. A method for separating an input optical signal into a first output optical signal having a first spectral band and a second output optical signal having a second spectral band, wherein the first and second spectral bands are substantially complementary, the method comprising the steps of:
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spatially separating the input optical signal into a first beam and a second beam;
decomposing, according to a polarization dependent optical transmission function, the first beam into a third beam and a fourth beam;
decomposing, according to a polarization dependent optical transmission function, the second beam into a fifth beam and a sixth beam, wherein the third beam and the fifth beam carry the first spectral band at a first polarization and the fourth beam and the sixth beam carry the second spectral band at a second polarization that is orthogonal to the first polarization;
combining the third beam and fifth beam to form the first output optical signal; and
combining the fourth beam and the sixth beam to form the second output optical signal. - View Dependent Claims (31, 32)
calcite, rutile, YVO4, and LiNbO3.
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33. A method for separating an input optical signal into a first output optical signal having a first spectral band and a second output optical signal having a second spectral band, wherein the first and second spectral bands are substantially complementary, the method comprising the steps of:
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spatially separating the input optical signal into a first beam and a second beam that have orthogonal polarizations;
rotating the polarization of one of the first beam and the second beam to the polarization of the other of the first beam and the second beam;
decomposing, according to a polarization dependent optical transmission function, the first beam into a third beam and a fourth beam;
decomposing, according to a polarization dependent optical transmission function, the second beam into a fifth beam and a sixth beam, wherein the third beam and the fifth beam carry the first spectral band at a first polarization and the fourth beam and the sixth beam carry the second spectral band at a second polarization that is orthogonal to the first polarization;
spatially separating the third and fourth beams;
spatially separating the fifth and sixth beams;
rotating the polarization of one of the third beam and the fifth beam to the polarization of the other of the third beam and the fifth beam;
rotating the polarization of one of the fourth beam and the sixth beam to the polarization of the other of the fourth beam and the sixth beam;
combining the third beam and fifth beam to form the first output optical signal; and
combining the fourth beam and the sixth beam to form the second output optical signal. - View Dependent Claims (34, 35, 36, 37, 38)
calcite, rutile, YVO4, and LiNbO3.
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37. The method of claim 33 wherein the separating and combining steps are performed via a birefringent element.
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38. The method of claim 37 wherein the birefringent elements comprises a birefringent material selected from the group consisting of:
calcite, rutile, YVO4, and LiNbO3.
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39. An optical device that separates an input signal into a first output signal having a first spectral band and a second output signal having a second spectral band, wherein the first and second spectral bands are substantially complementary, the device comprising:
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means for spatially separating the input optical signal into a first beam and a second beam that have orthogonal polarizations;
first means for decomposing, according to a polarization dependent optical transmission function, the first beam into a third beam and a fourth beam;
second means for decomposing, according to a polarization dependent optical transmission function, the second beam into a fifth beam and a sixth beam, wherein the third beam and the fifth beam carry the first spectral band at a first polarization and the fourth beam and the sixth beam carry the second spectral band at a second polarization that is orthogonal to the first polarization;
first means for combining the third beam and fifth beam to form the first output optical signal; and
second means for combining the fourth beam and the sixth beam to form the second output optical signal. - View Dependent Claims (40, 41)
a plurality of birefringent components with each element oriented in a predetermined direction.
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41. The device of claim 40 wherein each of the birefringent components comprise a birefringent material selected from the group consisting of:
calcite, rutile, YVO4, and LiNbO3.
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42. An optical device that separates an input signal into a first output signal having a first spectral band and a second output signal having a second spectral band, wherein the first and second spectral bands are substantially complementary, the device comprising:
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first means for spatially separating the input optical signal into a first beam and a second beam that have orthogonal polarizations;
first means for rotating the polarization of one of the first beam and the second beam to the polarization of the other of the first beam and the second beam;
first means for decomposing, according to a polarization dependent optical transmission function, the first beam into a third beam and a fourth beam;
second means for decomposing, according to a polarization dependent optical transmission function, the second beam into a fifth beam and a sixth beam, wherein the third beam and the fifth beam carry the first spectral band at a first polarization and the fourth beam and the sixth beam carry the second spectral band at a second polarization that is orthogonal to the first polarization;
second means for spatially separating the third and fourth beams;
third means for spatially separating the fifth and sixth beams;
second means for rotating the polarization of one of the third beam and the fifth beam to the polarization of the other of the third beam and the fifth beam;
third means for rotating the polarization of one of the fourth beam and the sixth beam to the polarization of the other of the fourth beam and the sixth beam;
first means for combining the third beam and fifth beam to form the first output optical signal; and
second means for combining the fourth beam and the sixth beam to form the second output optical signal. - View Dependent Claims (43, 44, 45, 46, 47)
the first means for rotating operates using a half wave plate;
the second means for rotating operates using a half wave plate; and
the third means for rotating operates using a half wave plate.
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44. The device of claim 42 wherein the first and second means for decomposing comprise:
a plurality of birefringent components with each element oriented in a predetermined direction.
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45. The device of claim 44 wherein each of the birefringent components comprise a birefringent material selected from the group consisting of:
calcite, rutile, YVO4, and LiNbO3.
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46. The device of claim 43 wherein the first, second and third means for separating, and the first and second means for combining operate using a birefringent element.
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47. The device of claim 46 wherein the birefringent element comprises a birefringent material selected from the group consisting of:
calcite, rutile, YVO4, and LiNbO3.
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48. An optical device that separates an input signal into a first output signal having a first spectral band and a second output signal having a second spectral band, wherein the first and second spectral bands are substantially complementary, the device comprising:
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a first element that spatially separates the input signal into a first beam and a second beam that have orthogonal polarizations;
a first wavelength filter having a polarization dependent optical transmission function such that the first beam is decomposed into a third beam and a fourth beam and the second beam is decomposed into a fifth beam and a sixth beam, wherein the third beam and the fifth beam carry the first spectral band at a first polarization and the fourth beam and the sixth beam carry the second spectral band at a second polarization that is orthogonal to the first polarization;
a second wavelength filter having a polarization dependent optical transmission function such that the first and second spectral bands are purified, and the polarization of one of the third beam and the fourth beam is rotated to the polarization of the other of the third beam and the fourth beam, and the polarization of one of the fifth beam and the sixth beam is rotated to the polarization of the other of the fifth beam and the sixth beam;
a second element that combines the third beam and fifth beam to form the first output signal and combines the fourth beam and the sixth beam to form the second output signal. - View Dependent Claims (49, 50)
a plurality of birefringent components with each element oriented in a predetermined direction.
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50. The device of claim 48 wherein each of the birefringent components comprise a birefringent material selected from the group consisting of:
calcite, rutile, YVO4, and LiNbO3.
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51. An optical device that separates an input signal into a first output signal having a first spectral band and a second output signal having a second spectral band, wherein the first and second spectral bands are substantially complementary, the device comprising:
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first means for spatially separating the input optical signal into a first beam and a second beam that have orthogonal polarizations;
first means for rotating the polarization of one of the first beam and the second beam to the polarization of the other of the first beam and the second beam;
first means for decomposing, according to a polarization dependent optical transmission function, the first beam into a third beam and a fourth beam;
second means for decomposing, according to a polarization dependent optical transmission function, the second beam into a fifth beam and a sixth beam, wherein the third beam and the fifth beam carry the first spectral band at a first polarization and the fourth beam and the sixth beam carry the second spectral band at a second polarization that is orthogonal to the first polarization;
second means for spatially separating the third and fourth beams;
third means for spatially separating the fifth and sixth beams;
means for purifying the first and second spectral bands, according to a polarization dependent optical transmission function;
second means for rotating the polarization of one of the third beam and the fourth beam to the polarization of the other of the third beam and the fourth beam;
third means for rotating the polarization of one of the fifth beam and the sixth beam to the polarization of the other of the fifth beam and the sixth beam;
fourth means for rotating the polarization of one of the third beam and the fifth beam to the polarization of the other of the third beam and the fifth beam;
fifth means for rotating the polarization of one of the fourth beam and the sixth beam to the polarization of the other of the fourth beam and the sixth beam;
first means for combining the third beam and fifth beam to form the first output optical signal; and
second means for combining the fourth beam and the sixth beam to form the second output optical signal. - View Dependent Claims (52, 53, 54, 55, 56, 57, 58)
the first means for rotating operates using a half wave plate;
the fourth means for rotating operates using a half wave plate; and
the fifth means for rotating operates using a half wave plate.
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53. The device of claim 51 wherein the first and second means for decomposing comprise:
a plurality of birefringent components with each element oriented in a predetermined direction.
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54. The device of claim 53 wherein each of the birefringent components comprise a birefringent material selected from the group consisting of:
calcite, rutile, YVO4, and LiNbO3.
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55. The device of claim 51 wherein the means for purifying and the second and third means for rotating operates using a a plurality of birefringent components with each element oriented in a predetermined direction.
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56. The device of claim 55 wherein each of the birefringent components comprise a birefringent material selected from the group consisting of:
calcite, rutile, YVO4, and LiNbO3.
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57. The device of claim 51 wherein the first, second and third means for separating, and the first and second means for combining operate using a birefringent element.
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58. The device of claim 57 wherein the birefringent element comprises a birefringent material selected from the group consisting of:
calcite, rutile, YVO4, and LiNbO3.
Specification