Apparatus and method for optical add/drop multiplexing

US 7,136,588 B1
Filed: 12/22/2000
Issued: 11/14/2006
Est. Priority Date: 12/22/2000
Status: Expired due to Fees

First Claim

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1. An apparatus operable to facilitate add/drop multiplexing of optical signals, the apparatus comprising:

an input operable to receive an input optical signal and an added optical signal, and to generate a first and a second copy of the input signal and a first and a second copy of the added signal;

a plurality of at least substantially reflective surfaces, each operable to receive either the first signal copies or the second signal copies and to reflect the copies for ultimate combination at an output to form an output signal for transmission, at least one of the at least substantially reflective surfaces comprising a micro-electro-optic system (MEMS) device, the MEMS device comprising;

a moveable mirror operable to change its position relative to the input to create a phase shift between the first and second signal copies so that either the input optical signal or the added optical signal is communicated as the output signal depending on the position of the at least one moveable mirror; and

an inner conductive layer disposed inwardly from the moveable mirror and forming a space between the moveable mirror and the inner conductive layer, wherein the moveable mirror comprises an at least substantially conductive layer operable to move relative to the inner conductive layer in response to a voltage difference between the moveable mirror and the inner conductive layer.

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Abstract

In one aspect of the invention, an apparatus operable to facilitate add/drop multiplexing of optical signals includes an input operable to receive an input optical signal and an added optical signal, the input operable to generate a first and a second copy of the input signal and a first and a second copy of the added signal. The apparatus further includes a plurality of at least substantially reflective surfaces, each operable to receive either the first signal copies or the second signal copies and to reflect the copies for ultimate combination at an output to form an output signal for transmission. At least one of the at least substantially reflective surfaces comprises a moveable mirror operable to change its position relative to the input to create a phase shift between the first and second signal copies so that either the input optical signal or the added optical signal is communicated as the output signal depending on the position of the at least one moveable mirror.

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27 Claims

1. An apparatus operable to facilitate add/drop multiplexing of optical signals, the apparatus comprising:
- an input operable to receive an input optical signal and an added optical signal, and to generate a first and a second copy of the input signal and a first and a second copy of the added signal;
  
  a plurality of at least substantially reflective surfaces, each operable to receive either the first signal copies or the second signal copies and to reflect the copies for ultimate combination at an output to form an output signal for transmission, at least one of the at least substantially reflective surfaces comprising a micro-electro-optic system (MEMS) device, the MEMS device comprising;
  
  a moveable mirror operable to change its position relative to the input to create a phase shift between the first and second signal copies so that either the input optical signal or the added optical signal is communicated as the output signal depending on the position of the at least one moveable mirror; and
  
  an inner conductive layer disposed inwardly from the moveable mirror and forming a space between the moveable mirror and the inner conductive layer, wherein the moveable mirror comprises an at least substantially conductive layer operable to move relative to the inner conductive layer in response to a voltage difference between the moveable mirror and the inner conductive layer.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12)
- - 2. The apparatus of claim 1, wherein the MEMS device is operable to undergo a substantially piston-like motion to change its position relative to the input.
  - 3. The apparatus of claim 1, wherein the inner conductive layer comprises a doped semiconductor substrate.
  - 4. The apparatus of claim 1, wherein the inner conductive layer comprises a layer of at least substantially conductive material formed outwardly from a semiconductor substrate.
  - 5. The apparatus of claim 1, wherein the moveable mirror comprises a plurality of adjacent mirror strips, at least some of the plurality of adjacent mirror strips separated by air gaps operable to relieve air damping when the mirror strips move relative to the inner conductive layer.
  - 6. The apparatus of claim 5, wherein all of the moveable mirror strips move at least substantially in unison in response to the voltage difference.
  - 7. The apparatus of claim 6, wherein either the inner conductive layer or each of the moveable mirror strips is coupled to a ground, and wherein the other is operable to receive a control voltage signal.
  - 8. The apparatus of claim 1, wherein a grazing angle between the moveable mirror and the signal copy reflected by the moveable mirror comprises an angle that is less than forty-five degrees.
  - 9. The apparatus of claim 1, further comprising a second MEMS device disposed between the MEMS device and the output, the second MEMS device comprising a moveable mirror layer operable to receive a phase shifted signal copy from the MEMS device and to change its position relative to the MEMS device to introduce a further phase shift to the signal copy.
  - 10. The apparatus of claim 1, wherein the input comprises a first beam splitter and wherein the output comprises a second beam splitter.
  - 11. The apparatus of claim 10, further comprising at least one additional reflective surface between the first beam splitter and the MEMS device, the at least one additional reflective surface operable to receive a signal copy from the first beam splitter and to reflect the signal copy for ultimate reception at the output.
  - 12. The apparatus of claim 1, wherein the input and the output comprise a single beam splitting device.

13. A wave division add/drop multiplexer, comprising:
- a wavelength division demultiplexer operable to separate an optical input signal into a plurality of wavelengths;
  
  an array of optical add/drop multiplexers coupled to the demultiplexer, at least one of the add/drop mutiplexers comprising;
  
  an input operable to receive an input wavelength signal and an added wavelength signal, and to generate a first and a second copy of the input signal and a first and a second copy of the added signal;
  
  a plurality of at least substantially reflective surfaces, each operable to receive either the first signal copies or the second signal copies and to reflect the copies for ultimate combination at an output to form an output signal for transmission, at least one of the at least substantially reflective surfaces comprising a micro-electro-optic system (MEMS) device, the MEMS device comprising;
  
  a moveable mirror operable to change its position relative to the input to create a phase shift between the first and second signal copies so that either the input optical signal or the added optical signal is communicated as the output signal depending on the position of the at least one moveable mirror; and
  
  an inner conductive layer disposed inwardly from the moveable mirror and forming a space between the moveable mirror and the inner conductive layer, wherein the moveable mirror comprises an at least substantially conductive layer operable to move relative to the inner conductive layer in response to a voltage difference between the moveable mirror and the inner conductive layer; and
  
  a wavelength division multiplexer operable to receive a plurality of output signals from the array of add/drop multiplexers and to multiplex at least some of the output wavelengths into an optical output signal.

14. A wave division add/drop multiplexer, comprising:
- a wavelength division demultiplexer operable to separate an optical input signal into a plurality of input wavelengths;
  
  an array of optical add/drop multiplexers coupled to the demultiplexer, at least one of the add/drop mutiplexers comprising a beam splitter operable to receive at least a portion of the optical input signal and split the at least a portion of the optical input signal into a first copy and a second copy, wherein the first copy and the second copy of the optical input signal comprise unequal amplitudes, and a micro-electro-optic system (MEMS) device, the MEMS device comprising;
  
  a moveable mirror operable to change its position, the position of the moveable mirror affecting whether one or more of the input wavelengths are passed through or dropped from the array; and
  
  an inner conductive layer disposed inwardly from the moveable mirror and forming a space between the moveable mirror and the inner conductive layer, wherein the moveable mirror comprises an at least substantially conductive layer operable to move relative to the inner conductive layer in response to a voltage difference between the moveable mirror and the inner conductive layer; and
  
  a wavelength division multiplexer operable to receive a plurality of output wavelengths from the array and to multiplex at least some of the output wavelengths into an optical output signal.
- View Dependent Claims (15, 16, 17, 18)
- - 15. The wave division add/drop multiplexer of claim 14, wherein the moveable mirror is operable to undergo a substantially piston-like motion to create a phase difference between a wavelength reflected from the moveable mirror and a substantial copy of the wavelength.
  - 16. The wave division add/drop multiplexer system of claim 14, wherein the first copy and the second copy of the at least a portion of the optical input signal are combined at a second beam splitter.
  - 17. The wave division add/drop multiplexer system of claim 14, wherein the wavelength division demultiplexer is operable to communicate at least some of the plurality of input wavelengths to a bypass channel that bypasses the array of optical add/drop multiplexers.
  - 18. The wave division add/drop multiplexer system of claim 17, wherein the bypass channel and the plurality of output wavelengths are combined at the wavelength division multiplexer.

19. A method of facilitating optical add/drop multiplexing, comprising:
- receiving an input optical signal and an added optical signal;
  
  generating a first and a second copy of the input signal;
  
  generating a first and a second copy of the added signal;
  
  communicating the first signal copies toward a first mirror and the second signal copies toward a second mirror;
  
  changing the position of the first mirror to create a phase shift between the first and second copy when combined at an output; and
  
  communicating either the added signal or the input signal as an output signal depending at least in part on the position of the first mirror;
  
  wherein at least the first mirror comprises a micro-electro-optic system (MEMS) device, the MEMS device comprisinga moveable mirror layer; and
  
  an inner conductive layer disposed inwardly from the moveable mirror layer and forming a space between the moveable mirror layer and the inner conductive layer, wherein changing the position of the moveable mirror layer comprises displacing the moveable mirror layer relative to the inner conductive layer in response to a voltage difference between the moveable mirror layer and the inner conductive layer.
- View Dependent Claims (20, 21, 22, 23, 24)
- - 20. The method of claim 19, wherein the MEMS is operable to experience a substantially piston-like motion in response to a control signal.
  - 21. The method of claim 19, wherein the moveable mirror layer comprises a plurality of adjacent mirror strips, at least some of the plurality of adjacent mirror strips separated by air gaps operable to relieve air damping when the mirror strips move relative to the inner conductive layer.
  - 22. The method of claim 21, wherein changing the position of the moveable mirror layer comprises displacing all of the moveable mirror strips relative to the inner conductive layer substantially in unison in response to the voltage difference.
  - 23. The method of claim 21, wherein changing the position of the moveable mirror layer comprises:
    - coupling either the inner conductive layer or each of the moveable mirror strips to a ground; and
      
      applying to the other a control voltage signal.
  - 24. The method of claim 19, wherein changing the position of the moveable mirror layer comprises selectively displacing the moveable mirror layer relative to the inner conductive layer, wherein the distance increases as the voltage difference between the moveable mirror layer and the inner conductive layer increases.

25. A method of facilitating wave division add/drop multiplexing, comprising:
- receiving an optical input signal comprising a plurality of wavelengths;
  
  separating the optical signal into a plurality of wavelength signals;
  
  communicating at least some of the wavelength signals to an array of optical add/drop multiplexers;
  
  at least one of the add/drop multiplexers;
  
  receiving an input optical signal and an added optical signal;
  
  generating a first and a second copy of the input signal;
  
  generating a first and a second copy of the added signal;
  
  communicating the first signal copies toward a first mirror and the second signal copies toward a second mirror;
  
  changing the position of the first mirror to create a phase shift between the first and second copy when combined at an output; and
  
  communicating either the added signal or the input signal as an output signal depending at least in part on the position of the first mirror, wherein at least the first mirror comprises a micro-electro-optic system (MEMS) device, the MEMS device comprising;
  
  a moveable mirror layer; and
  
  an inner conductive layer disposed inwardly from the moveable mirror layer and forming a space between the moveable mirror layer and the inner conductive layer, wherein changing the position of the moveable mirror layer comprises displacing the moveable mirror layer relative to the inner conductive layer in response to a voltage difference between the moveable mirror layer and the inner conductive layer.

26. An apparatus operable to facilitate add/drop multiplexing of optical signals, the apparatus comprising:
- an input operable to receive an input optical signal and an added optical signal, and to generate a first and a second copy of the input signal and a first and a second copy of the added signal;
  
  a plurality of at least substantially reflective surfaces, each operable to receive either the first signal copies or the second signal copies and to reflect the copies for ultimate combination at an output to form an output signal for transmission, at least one of the at least substantially reflective surfaces comprising a Micro-electro-optic system (MEMS) device, wherein the MEMS device comprises;
  
  a plurality of adjacent mirror strips, the mirror strips operable to change their position relative to the input to create a phase shift between the first and second signal copies so that either the input optical signal or the added optical signal is communicated as the output signal depending on the position of the moveable mirror strips; and
  
  an inner conductive layer disposed inwardly from the moveable mirror strips and forming a space between the moveable mirror strips and the inner conductive layer, wherein the moveable mirror strips comprise an at least substantially conductive layer operable to move relative to the inner conductive layer in response to a voltage difference between the moveable mirror strips and the inner conductive layer.

27. A method of facilitating optical add/drop multiplexing, comprising:
- receiving an input optical signal and an added optical signal;
  
  generating a first and a second copy of the input signal;
  
  generating a first and a second copy of the added signal;
  
  communicating the first signal copies toward a first mirror and the second signal copies toward a second mirror, the first mirror comprising a Micro-electro-optic system (MEMS) device, the MEMS device comprising;
  
  a plurality of adjacent mirror strips, the mirror strips operable to change their position relative to the input; and
  
  an inner conductive layer disposed inwardly from the moveable mirror strips and forming a space between the moveable mirror strips and the inner conductive layer, wherein changing the position of the moveable mirror strips comprises displacing the moveable mirror strips relative to the inner conductive layer in response to a voltage difference between the moveable mirror strips and the inner conductive layer; and
  
  displacing adjacent mirror strips to create a phase shift between the first and second copy when combined at an output; and
  
  communicating either the added signal or the input signal as an output signal depending at least in part on the position of the adjacent mirror strips.

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Current Assignee
Cheetah Omni LLC
Original Assignee
Cheetah Omni LLC
Inventors
Islam, Mohammed N., Kuditcher, Amos
Primary Examiner(s)
Phan, Hanh

Application Number

US09/746,822
Time in Patent Office

2,153 Days
Field of Search

398/83, 398/82, 398/86, 398/79, 398/45, 398/48, 385/16, 385/17, 385/18, 385/24, 385/31, 385/37, 385/140
US Class Current

398/83
CPC Class Codes

G02B 6/3514   the reflective optical elem...

G02B 6/356   in an optical cross-connect...

G02B 6/3584   constructional details of a...

H04J 14/0212   using optical switches or w...

H04J 14/06   Polarisation multiplex systems

Apparatus and method for optical add/drop multiplexing

First Claim

5 Assignments

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Abstract

42 Citations

27 Claims

Specification

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Apparatus and method for optical add/drop multiplexing

First Claim

5 Assignments

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0 Petitions

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Accused Products

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Abstract

42 Citations

27 Claims

Specification

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Solutions

Use Cases

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