Method and apparatus for wavelength conversion and switching
First Claim
1. Apparatus for simultaneous wavelength interchange of two optical signals of selected carrier frequencies ω
-
1 and ω
2 comprising;
(a) a lattice body comprising sensitized regions arranged in a two-dimensional array in a matrix material, the sensitized regions differing from the matrix material in the sign of the second order susceptibility, the spacing and pattern of the sensitized regions in the array selected to provide wavelength interchange for two optical signals at frequencies ω
1 and ω
2;
(b) at least one input optical waveguide coupled to the lattice body by which the input signals at the frequencies ω
1 and ω
2 and a pump signal at a frequency ω
p may be coupled into the lattice body; and
(c) at least one output waveguide coupled to the lattice body in position to receive from the lattice body wavelength interchanged components of the input signals at least one of the frequencies ω
1 and ω
2.
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Abstract
A two-dimensional second order nonlinear lattice formed in a lattice body is utilized for performing a one-step optical carrier wavelength interchange between pairs of input optical signals. The lattice body includes sensitized regions arranged in a two-dimensional array in a matrix material with the sensitized regions differing from the matrix material in the sign of the second order susceptibility. When an optical pump signal is coupled to the lattice body at a frequency corresponding to the sum of the frequencies of the two input signals, nonlinear interactions in the lattice body produce wavelength interchange between the input signals, resulting in angularly deflected optical signals exiting the lattice body in which the signal information on the input signals is interchanged between the carrier frequencies of the two input signals. The apparatus can be utilized to provide switching of optical signals and wavelength interchange for applications such as in wavelength division multiplexed communication systems.
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Citations
20 Claims
-
1. Apparatus for simultaneous wavelength interchange of two optical signals of selected carrier frequencies ω
-
1 and ω
2 comprising;(a) a lattice body comprising sensitized regions arranged in a two-dimensional array in a matrix material, the sensitized regions differing from the matrix material in the sign of the second order susceptibility, the spacing and pattern of the sensitized regions in the array selected to provide wavelength interchange for two optical signals at frequencies ω
1 and ω
2;
(b) at least one input optical waveguide coupled to the lattice body by which the input signals at the frequencies ω
1 and ω
2 and a pump signal at a frequency ω
p may be coupled into the lattice body; and
(c) at least one output waveguide coupled to the lattice body in position to receive from the lattice body wavelength interchanged components of the input signals at least one of the frequencies ω
1 and ω
2.- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12)
where φ
is the exterior angle subtended by the reciprocal lattice vectors GA and GB as well as the interior angle subtended by rA and rB and where |GA| and |GB| are the magnitudes of the reciprocal lattice vectors.
-
1 and ω
-
10. The apparatus of claim 1 wherein the sensitized regions and the matrix material have the same first order susceptibility.
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11. The apparatus of claim 1 wherein the pairs of input optical signals have carrier wavelengths in the 1.0 to 1.6 μ
- m wavelength range and the spacing between centers of sensitized regions in the lattice in the lattice body are in the range of about 5 to 10 μ
m.
- m wavelength range and the spacing between centers of sensitized regions in the lattice in the lattice body are in the range of about 5 to 10 μ
-
12. The apparatus of claim 1 wherein a single input optical waveguide is coupled to the lattice body by which the input signals at the frequencies ω
-
1 and ω
2 and the pump signal may be coupled into the lattice body collinear with one another.
-
1 and ω
-
13. A method for carrying out simultaneous wavelength interchange between two modulated optical signals at different carrier wavelengths comprising:
-
(a) providing a lattice body comprising sensitized regions arranged in a two-dimensional array in a matrix material, the sensitized regions differing from the matrix material in the sign of the second order susceptibility, the spacing and pattern of the sensitized regions in the array selected to provide wavelength interchange for two optical signals at frequencies ω
1 and ω
2;
(b) coupling two input optical signals at the carrier frequencies ω
1 and ω
2 into the lattice body and coupling a third pump optical signal into the lattice body, the pump optical signal having a frequency ω
p selected to cause wavelength interchange in the lattice body between the two input optical signals;
(c) receiving an output optical signal exiting from the lattice body angularly displaced from the direction of propagation of the input optical signals that comprises an optical signal at a carrier frequency ω
2 that carries the information on the input signal at the carrier frequency ω
1, and receiving an output optical signal exiting from the lattice body angularly displaced from the direction of propagation of the input signals that comprises an optical signal at a carrier frequency ω
1 that carries the information on the input signal at the carrier frequency ω
2.- View Dependent Claims (14, 15, 16, 17)
-
-
18. Apparatus for simultaneous wavelength interchange of two optical signals of selected carrier frequencies ω
-
1 and ω
2 comprising;(a) a lattice body comprising sensitized regions arranged in a two-dimensional array in a matrix material, the sensitized regions differing from the matrix material in the sign of the second order susceptibility and having the same first order susceptibility, the spacing and pattern of the sensitized regions in the array selected to provide wavelength interchange for two optical signals at frequencies ω
1 and ω
2 and wavelengths λ
A and λ
B, respectively;
(b) at least one input optical waveguide coupled to the lattice body by which the input signals at the frequencies ω
1 and ω
2 and a pump signal at a frequency ω
p=ω
1+ω
2 and wavelength λ
p may be coupled into the lattice body collinear with one another;
(c) at least one output waveguide coupled to the lattice body in position to receive from the lattice body wavelength interchanged components of the input signals at least one of the frequencies ω
1 and ω
2; and
(d) wherein the centers of the sensitized regions in the lattice body have spacings rA and rB in the two dimensions of the lattice given by the relation;
where φ
is the interior angle subtended by the vectors rA and rB and where |GA| and |GB| are the magnitudes of the reciprocal lattice vectors and are determined in accordance with;
where np is the refractive index in the lattice body for the pump signal, nA is the refractive index in the lattice body for the signal at the wavelength λ
A,nB is the refractive index in the lattice body for the signal at the wavelength λ
B,θ
A is a selected desired half exit angle with respect to a normal to an output face of the lattice body for the output signal at the wavelength λ
A,θ
B is a selected desired half exit angle with respect to a normal to the output face of the lattice body for the output signal at the wavelength λ
B,- View Dependent Claims (19, 20)
-
1 and ω
Specification