Nonlinear optical coupler using a doped optical waveguide

US 5,311,525 A
Filed: 03/31/1992
Issued: 05/10/1994
Est. Priority Date: 03/31/1992
Status: Expired due to Term

First Claim

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1. An apparatus for controlling an optical signal, comprising:

a source of light which produces said optical signal;

an optical waveguide comprising an active medium, said optical signal being coupled to said waveguide for propagation therein, said waveguide having first and second spatial propagation modes for said optical signal, said first and second modes having first and second indices of refraction, respectively; and

a pump source coupled to introduce a pump signal into at leas tone of said spatial modes to optically perturb at least one of said first and second indices of refraction, said optical signal having a spatial intensity distribution in said waveguide that varies as a function of the perturbation.

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Abstract

An optical mode coupling apparatus includes an Erbium-doped optical waveguide in which an optical signal at a signal wavelength propagates in a first spatial propagation mode and a second spatial propagation mode of the waveguide. The optical signal propagating in the waveguide has a beat length. The coupling apparatus includes a pump source of perturbational light signal at a perturbational wavelength that propagates in the waveguide in the first spatial propagation mode. The perturbational signal has a sufficient intensity distribution in the waveguide that it causes a perturbation of the effective refractive index of the first spatial propagation mode of the waveguide in accordance with the optical Kerr effect. The perturbation of the effective refractive index of the first spatial propagation mode of the optical waveguide causes a change in the differential phase delay in the optical signal propagating in the first and second spatial propagation modes. The change in the differential phase delay is detected as a change in the intensity distribution between two lobes of the optical intensity distribution pattern of an output signal. The perturbational light signal can be selectively enabled and disabled to selectively change the intensity distribution in the two lobes of the optical intensity distribution pattern.

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56 Claims

1. An apparatus for controlling an optical signal, comprising:
- a source of light which produces said optical signal;
  
  an optical waveguide comprising an active medium, said optical signal being coupled to said waveguide for propagation therein, said waveguide having first and second spatial propagation modes for said optical signal, said first and second modes having first and second indices of refraction, respectively; and
  
  a pump source coupled to introduce a pump signal into at leas tone of said spatial modes to optically perturb at least one of said first and second indices of refraction, said optical signal having a spatial intensity distribution in said waveguide that varies as a function of the perturbation.
- View Dependent Claims (2, 4, 5, 6, 10, 11, 12, 17, 18)
- - 2. The apparatus of claim 1, wherein said second spatial mode is a higher order than said first spatial mode.
  - 4. The apparatus of claim 1, wherein the perturbation of said at least one of the effective refractive indices phase shifts an optical signal component propagating in one of said first and second modes.
  - 5. The apparatus of claim 4, wherein said pump source has a power, said pump source varying the intensity of said pump signal to vary said phase shift.
  - 6. The apparatus of claim 4, wherein said phase shift is approximately π
    - .
  - 10. The apparatus of claim 1, wherein said active medium is a rare earth.
  - 11. The apparatus of claim 1, wherein said active medium is Erbium.
  - 12. The apparatus of claim 1, wherein said active medium is a semiconductor material.
  - 17. The apparatus of claim 1, wherein said optical waveguide comprises silica.
  - 18. The apparatus of claim 1, wherein said optical waveguide is an Erbium-doped silica optical fiber.

3. An apparatus for controlling an optical signal, comprising:
- an optical waveguide comprising an active medium, said waveguide having first and second spatial propagation modes, said first and second modes having first and second indices of refraction, respectively, said second spatial mode being of a higher order mode than said first spatial mode, the optical waveguide having a cross section taken perpendicular to a longitudinal axis of said waveguide which is non-circular in shape and which has cross-sectional dimensions selected such that the waveguide guides light in the higher order mode in only a single stable intensity pattern; and
  
  a pump source coupled to introduce a pump signal into at least one of said spatial modes to optically perturb at least one of said first and second indices of refraction, said optical signal having a spatial intensity distribution in said waveguide that varies as a function of the perturbation.

7. An apparatus for controlling an optical signal, comprising:
- an optical waveguide comprising an active medium, said waveguide having first and second spatial propagation modes, said first and second modes having first and second indices of refraction, respectively;
  
  a pump source coupled to introduce a pump signal into at least one of said spatial modes to optically perturb at least one of said first and second indices of refraction, the intensity of said pump signal being selected to produce a phase shift in a first optical signal component propagating in one of said modes such that said first component has a phase difference of approximately π
  
  radians with respect to a second optical signal component propagating in the other of said modes, said optical signal having a spatial intensity distribution in said waveguide that varies as a function of said phase difference; and
  
  wherein said pump signal phase switches the optical energy of said optical signal from said first mode to said second mode and reciprocally.

8. An apparatus for controlling an optical signal, comprising:
- an optical waveguide comprising an active medium, said waveguide having first and second spatial propagating modes, said first and second modes having first and second indices of refraction, respectively;
  
  a pump source coupled to introduce a pump signal into at least one of said spatial modes to optically perturb at least one of said first and second indices of refraction, the intensity of said pump signal being selected to produce a phase shift in a first optical signal component propagating in one of said modes such that said first component has a phase difference of approximately π
  
  radians with respect to a second optical signal component propagating in the other of said modes, said optical signal having a spatial intensity distribution in said waveguide that varies as a function of said phase difference; and
  
  wherein said pump signal has a pump power, said pump power being greater than P_abs /1-exp(σ
  
  _p N₀ L+P_abs /AI_p,sat), wherein P_abs is the total amount of pump power absorbed by the waveguide, σ
  
  _p is the absorption cross section for said pump source, N₀ is the total species population density for said active medium, L is the length of the optical waveguide, A is the area of the optical waveguide illuminated by the pump signal, and I_p,sat is the pump saturation intensity for said active medium.

9. An apparatus for controlling an optical signal, comprising:
- an optical waveguide comprising an active medium, said waveguide having first and second spatial propagation modes, said first and second modes having first and second indices of refraction, respectively; and
  
  a pump source coupled to introduce a pump signal into at least one of said spatial modes to optically perturb at least one of said first and second indices of refraction, said optical signal having an optical intensity distribution pattern that varies as a function of the phase relationship between light propagating in said first and second modes, said optical intensity distribution pattern having at least two lobes.

13. An apparatus for controlling an optical signal, comprising:
- an optical waveguide comprising an active medium, said waveguide having first and second spatial propagation modes, said first and second modes having first and second indices of refraction, respectively;
  
  a pump source coupled to introduce a pump signal into at least one of said spatial modes to optically perturb at least one of said first and second indices of refraction, said optical signal having a spatial intensity distribution in said waveguide that varies as a function of the perturbation; and
  
  wherein said optical signal has a first wavelength and said pump signal has a second wavelength, said second wavelength being proximate to an absorption transition of said active medium.
- View Dependent Claims (14, 15, 16)
- - 14. The apparatus of claim 13, wherein said first wavelength is proximate to a further absorption transition of the active medium, thereby reducing the power of said pump source and increasing the loss of said optical signal for a specified phase shift.
  - 15. The apparatus of claim 14, wherein said absorption transition and said further absorption transition are the same.
  - 16. The apparatus of claim 13, wherein said first wavelength is selected away from a further absorption transition of the active medium, thereby increasing the power of said pump source and reducing the loss of said optical signal for a specified phase shift.

19. An apparatus for controlling an optical signal, comprising:
- an optical waveguide comprising an active medium, said active medium having an oscillator strength, said oscillator strength being greater or equal to one, said waveguide having first and second spatial propagation modes, said first and second modes having first and second indices of refraction, respectively; and
  
  a pump source coupled to introduce a pump signal into at least one of said spatial modes to optically perturb at least one of said first and second indices of refraction, said optical signal having a spatial intensity distribution in said waveguide that varies as a function of the perturbation.

20. An apparatus for controlling an optical signal, comprising:
- an optical waveguide comprising an active medium comprising a light propagation medium that supports at least first and second spatial propagation modes, said optical waveguide having a first effective refractive index for light propagating in said first spatial propagation mode and a second effective refractive index, said second effective refractive index different from said first effective refractive index, for light propagating in said second spatial propagation mode so that light propagating in one of said modes propagates at a phase propagation velocity that is different from the phase propagation velocity of light propagating in the other of said modes;
  
  an optical signal source that supplies a first optical input signal to said optical waveguide at a first optical wavelength, said first optical wavelength selected so that said first optical input signal has a first spatial mode component that propagates in said optical waveguide in said first spatial propagation mode and a second spatial mode component that propagates in said second spatial propagation mode, said first spatial mode component being shifted in phase with respect to said second spatial mode component as said first optical input signal propagates in said optical waveguide; and
  
  a pump source that supplies a second optical input signal to said optical waveguide at a second optical wavelength, said second optical wavelength selected so that said second optical input signal propagates in said optical waveguide in at least said first spatial propagation mode, said second optical input signal having an intensity that can be selected to perturb said first effective refractive index relative to said second effective refractive index to change the amount by which said first spatial propagation mode component of said first optical input signal is shifted in phase with respect to said second spatial mode component of said first optical input signal as said first and second spatial propagation mode components propagate in said optical waveguide.
- View Dependent Claims (21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33)
- - 21. The apparatus of claim 20, wherein said active medium is a rare earth.
  - 22. The apparatus of claim 20, wherein said active medium is Erbium.
  - 23. The apparatus of claim 20, wherein said active medium is a semiconductor material.
  - 24. The apparatus of claim 20, wherein said first wavelength is less than said second wavelength.
  - 25. The apparatus of claim 20, wherein said first wavelength is proximate to a first absorption resonance of said active medium and wherein said second wavelength is proximate to a second absorption resonance of the active medium.
  - 26. The apparatus of claim 20, wherein said first wavelength is approximately 906 nm, and said second wavelength is approximately 1.48 μ
    - m.
  - 27. The apparatus of claim 20, wherein said first spatial propagation mode is the fundamental LP₀₁ propagation mode and wherein said second spatial propagation mode is the second-order LP₁₁ propagation mode.
  - 28. The apparatus of claim 20, wherein said optical waveguide is a two-mode optical fiber having an elliptical core.
  - 29. The apparatus of claim 20, wherein:
    - said optical waveguide is a two-mode optical fiber;
      
      said first spatial mode of said waveguide is the fundamental LP₀₁ spatial propagation mode of said optical fiber and said second spatial mode of said waveguide is the second-order LP₁₁ spatial propagation mode of said optical fiber;
      
      substantially all the light of said second optical input signal propagates in the fundamental LP₀₁ spatial propagation mode of said optical fiber; and
      
      the light of said first optical signal propagates substantially equally in said fundamental LP₀₁ spatial propagation mode and said second-order LP₁₁ propagation mode of said optical fiber.
  - 30. The apparatus of claim 20, wherein the phase relationship between the first spatial mode component and the second spatial mode component of said first optical input signal produces an intensity distribution pattern having at least first and second lobes, the intensity of the light in said first and second lobes at said first wavelength varying in accordance with the phase relationship between said first spatial mode component and said second spatial mode component, said apparatus further including means for detecting the intensity of the light in one of said first and second lobes at said first wavelength, said intensity varying in accordance with the intensity of said second optical input signal.
  - 31. The apparatus of claim 30, wherein said means for detecting light in said one of said first and second lobes at said first wavelength includes an optical detector.
  - 32. The apparatus of claim 20, wherein said optical waveguide has a length between an input end and an output end that is selected so that at said output end said first spatial mode component and said second spatial mode component of said first optical input signal have a relative phase difference of Nπ
    - , for N equal to an integer (0, 1, 2, 3, . . . ), such that substantially all of the light intensity at said first wavelength is concentrated in a first lobe of an optical intensity distribution pattern at said output end when said second input signal has a first low intensity and such that light intensity in said first lobe decreases when said intensity of said second input signal increases.
  - 33. The apparatus of claim 30, further including means for detecting the intensity of the light in a selected one of said first and second lobes.

34. A method of controlling an optical signal in an optical waveguide, comprising the steps of:
- providing an optical waveguide doped with an active medium having a geometry selected so that said optical waveguide supports at least first and second spatial propagation modes light propagating therein, said first and second spatial propagation modes having first and second effective refractive indices, respectively, such that light propagating in one of said first and second spatial propagation modes propagates at a phase velocity that is different from the phase propagation velocity of light propagating in the other of said first and second spatial propagation modes;
  
  inputting a first optical signal having a first wavelength into said optical waveguide so that said first optical signal propagates in said optical waveguide with substantially equal light intensities in said first and second spatial propagation modes in said waveguide, the light propagating in said first spatial propagation mode propagating at a phase velocity that is different from the phase propagation velocity of the light propagating in said second spatial propagation mode thereby causing an optical phase difference between the light propagating in said first spatial propagation mode and the light propagating in said second spatial propagation mode, said optical phase difference varying along the length of said optical waveguide;
  
  inputting a second optical signal having a second wavelength into said optical waveguide to control said first optical signal, said second optical signal propagating in said optical waveguide in said first spatial propagation-mode; and
  
  selectively adjusting the intensity of said second optical signal so that said second optical signal has an intensity sufficiently large to perturb said first effective refractive index with respect to said second effective refractive index to change the phase velocity of the light of said first optical signal propagating in said first spatial propagation mode, thereby introducing an additional optical phase difference between the light propagating in said first spatial propagation mode and the light propagating in said second spatial propagation mode, said additional optical phase difference causing a change in the intensities in first and second lobes of an optical intensity distribution pattern at the output of said optical waveguide.
- View Dependent Claims (35, 36, 37, 38)
- - 35. The method as defined in claim 34, further comprising the step of detecting said change in the intensities of said first and second lobes of said optical intensity distribution pattern in said output of said optical waveguide.
  - 36. The method as defined in claim 35, wherein said step of detecting said change in the intensity comprises the step of directing the light from said first and second lobes of said optical intensity distribution pattern toward an optical detector.
  - 37. The method as defined in claim 34, further comprising the step of adjusting the length of said optical waveguide prior to said step of inputting said second optical signal into said optical waveguide so that substantially all of said light intensity is initially in one of said first and second lobes of said optical intensity distribution pattern.
  - 38. The method as defined in claim 37, wherein said step of selectively adjusting the intensity of said second optical signal comprises the step of selecting an intensity of said second optical signal wherein substantially all of said light intensity at said first wavelength is in the other of said first and second lobes of said optical intensity distribution pattern.

39. An optical mode coupling apparatus comprising an optical waveguide doped with an active medium, said apparatus coupling an optical signal propagating in the optical waveguide between propagation modes of the waveguide, the optical signal having an optical signal beat length for the modes, the waveguide comprising a guiding structure formed of materials having dissimilar indices of refraction and having perturbations being spaced at intervals related to the beat length of the optical signal to cause cumulative coupling of said optical signal from one of the propagation modes to another.
- View Dependent Claims (40, 41, 42, 43, 44, 45, 46)
- - 40. The apparatus as defined in claim 39, wherein the optical waveguide has a non-circular cross section having cross-sectional dimensions selected such that the waveguide guides a portion of the perturbational signal in a fundamental spatial mode and another portion in a higher order spatial mode, the cross-sectional dimensions of the waveguide being further selected such that the perturbational signal guided by the waveguide in the higher mode propagates in only a single, stable intensity pattern.
  - 41. The apparatus as defined in claim 40, wherein the fundamental spatial mode includes two polarization modes, the cross-sectional dimensions of the core being further selected to cause the polarization modes of the fundamental mode to be non-degenerate.
  - 42. The apparatus as defined in claim 41, wherein the single intensity pattern of the higher order spatial mode includes two polarization modes, the cross-sectional dimensions of the core being further selected to cause these polarization modes to be non-degenerate.
  - 43. The apparatus as defined in claim 39, wherein the core of the waveguide has an elliptical cross section.
  - 44. The apparatus as defined in claim 39, wherein the refractive index perturbations of said waveguide are produced by the optical Kerr effect.
  - 45. The apparatus as defined in claim 39, wherein said propagation modes are first and second order spatial modes of the waveguide.
  - 46. The apparatus as defined in claim 39, wherein the waveguide has a non-circular cross section.

47. A method of controlling an optical signal in an optical waveguide, comprising the steps of:
- providing an optical waveguide doped with an active medium, said optical waveguide having at least first and second spatial propagation modes, said first and second spatial propagation modes having first and second refractive indices, respectively;
  
  inputting said optical signal having a first wavelength into said optical waveguide;
  
  inputting a pump signal having a second wavelength into said optical waveguide to optically perturb at least one of said first and second indices of refraction;
  
  selectively adjusting the intensity of said pump signal to controllably vary the spatial intensity distribution of said optical signal.
- View Dependent Claims (48, 49, 50, 51, 52, 53, 54, 55, 56)
- - 48. The method of claim 47, further comprising the step of selecting the active medium so that said active medium has a high oscillator strength.
  - 49. The method of claim 47, further comprising the step of selecting said second wavelength to be proximate to an absorption transition of said active medium.
  - 50. The method of claim 47, further comprising the step of selecting said first wavelength to be proximate to an absorption transition of said active medium.
  - 51. The method of claim 47, further comprising the step of selecting said first wavelength to be away from an absorption transition of said active medium.
  - 52. The method of claim 47, further comprising the step of selecting said first and second wavelength to be proximate to the same absorption transition of said active medium.
  - 53. The method of claim 47, further comprising the step of selecting said second wavelength to be proximate to an absorption transition of said active medium and further comprising the step of selecting said first wavelength to be away from said absorption transition.
  - 54. The method of claim 47, further comprising the step of phase shifting said optical signal component propagating in one of said first and second modes.
  - 55. The method of claim 47, wherein said optical signal experiences a loss during its propagation in said optical waveguide, and wherein said pump source has a power, the perturbation of said at least one of the refractive indices phase shifting a component of said optical signal in one of said first and second modes, said method further comprising the step of selecting said first wavelength so as to minimize the loss of said optical signal and so as to minimize the power of said pump source for a specified phase shift, said pump power being reduced and said signal loss being increased when said first wavelength is proximate to an absorption transition of said active medium and, reciprocally, said pump power being increased and said signal loss being reduced when said first wavelength is selected away from an absorption transition of said active medium.
  - 56. The method of claim 47, wherein said optical waveguide has a length and said pump source has a power, the perturbation of said at least one of the refractive indices phase shifting a component of said optical signal in one of said first and second modes, said method further comprising the step of selecting the length of said optical waveguide and the power of said pump source so as to minimize both the length of said optical waveguide and the power of said pump source for a specified phase shift, the minimum length verifying Equation (27) and the minimum power verifying Equation (26).

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Current Assignee
Board of Trustees of the Leland Stanford Junior University (Stanford Management Co.)
Original Assignee
Board of Trustees of the Leland Stanford Junior University (Stanford Management Co.)
Inventors
Sadowski, Robert W., Digonnet, Michel J. F., Pantell, Richard H., Shaw, Herbert J.
Primary Examiner(s)
Gonzalez, Frank

Application Number

US07/861,322
Time in Patent Office

770 Days
Field of Search

372/6, 372/19, 372/20, 372/21, 372/22, 372/102, 359/328, 385/28
US Class Current

372/6
CPC Class Codes

G02F 1/3521   using a directional coupler

G02F 1/365   in an optical waveguide str...

H01S 3/067   Fibre lasers

H01S 3/06783   Amplifying coupler

Nonlinear optical coupler using a doped optical waveguide

First Claim

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Nonlinear optical coupler using a doped optical waveguide

First Claim

2 Assignments

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Abstract

31 Citations

56 Claims

Specification

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