Integrated optical givens rotation device
First Claim
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1. An elementary Givens rotation matrix device comprising a monolithic integrated optical circuit including crossed waveguides, interdigitated-electrode voltage-induced cosinusoidal grating associated with the crossed waveguides at their crossing point such that light from a first of the crossed waveguides is incident at a first Bragg angle and light from a second of the crossed waveguides is incident at another first Bragg angle, the interdigitated-electrode voltage-induced cosinusoidal grating transmitting and diffracting coherent light energy traveling simultaneously through the respective waveguides, a means for applying a constant voltage to the interdigitated-electrode voltage-induced cosinusoidal grating, and electro-optic phase shifter means lying upstream and downstream of the interdigitated-electrode voltage-induced cosinusoidal grating with respect to one of the waveguides for effecting the respective phase shifts therein by applying voltages to said phase shifter means which are equal but of opposite sign.
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Abstract
An elementary optical Givens rotation device is disclosed comprising a monolithic integrated optical circuit including crossed waveguides, interdigitated electrode means associated with the crossed waveguides at their crossing point, and electro-optic phase shifter means lying upstream and downstream of the interdigitated electrode means with respect to one of the waveguides. Two mutually coherent, transverse magnetic input light signals are guided simultaneously into each waveguide. A voltage applied to the interdigitated electrode means induces a diffraction grating thereby forming transmitted and diffracted light waves in output sections of the respective waveguides. Phase shifter means include means for applying voltages to each phase shifter which are equal in magnitude but opposite in sign so that the transmitted and diffracted waves combine in phase in one waveguide and combine 180° out of phase in the other waveguide. The device is useful for matrix triangularization by arranging arrays of these devices in a parallel or pipelined architecture on a substrate.
18 Citations
16 Claims
- 1. An elementary Givens rotation matrix device comprising a monolithic integrated optical circuit including crossed waveguides, interdigitated-electrode voltage-induced cosinusoidal grating associated with the crossed waveguides at their crossing point such that light from a first of the crossed waveguides is incident at a first Bragg angle and light from a second of the crossed waveguides is incident at another first Bragg angle, the interdigitated-electrode voltage-induced cosinusoidal grating transmitting and diffracting coherent light energy traveling simultaneously through the respective waveguides, a means for applying a constant voltage to the interdigitated-electrode voltage-induced cosinusoidal grating, and electro-optic phase shifter means lying upstream and downstream of the interdigitated-electrode voltage-induced cosinusoidal grating with respect to one of the waveguides for effecting the respective phase shifts therein by applying voltages to said phase shifter means which are equal but of opposite sign.
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6. A method for performing the elementary Givens rotation operation with a monolithic integrated optical circuit including crossed waveguides each having an input section and an output section, interdigitated electrode means associated with the crossed waveguides at their crossing point and oriented so that the first Bragg condition is satisfied, and electro-optic phase shifter means lying upstream and downstream of the interdigitated electrode means with respect to one of the waveguides, comprising the steps of:
- guiding two mutually coherent, monochromatic transverse magnetic input light signals simultaneously through the input section in each of said crossed waveguides to said interdigitated electrode means;
inducing a diffraction grating at the interdigitated electrode means by applying a voltage to said electrode means with said diffraction grating then operating on each input light signal to form a transmitted and diffracted wave in the output section in each of said crossed waveguides; coherently combining the transmitted and diffracted waves formed in each output section of said crossed waveguides by applying voltages that are equal in magnitude but opposite in sign to said upstream and downstream phase shifter means and adjusting said voltages so that the transmitted and diffracted waves formed in the output section of one waveguide are combined in phase and the transmitted and diffracted waves formed in the output section of the other waveguide are combined 180°
out of phase; andvarying the voltage applied to said interdigitated electrode means until the amplitude of the coherently combined transmitted and diffracted waves formed in the output section of one waveguide is zero.
- guiding two mutually coherent, monochromatic transverse magnetic input light signals simultaneously through the input section in each of said crossed waveguides to said interdigitated electrode means;
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7. An array of elementary Givens rotation matrix devices arranged in a parallel architecture on a monolithic integrated optical circuit for performing triangularization of a nonsingular square matrix of rank N comprising:
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a plurality of crossed channel waveguides configured so that the optical amplitude corresponding to each input element in the matrix to be triangularized are entered simultaneously in each of said crossed waveguides, with each of said waveguides intersecting at least one other of said waveguides that are used to input elements in the same column vector of said matrix; a plurality of interdigitated electrode means associated with each pair of the crossed waveguides at their crossing point for transmitting and diffracting coherent light energy traveling simultaneously through the respective waveguides; electro-optic phase shifter means lying upstream and downstream of each of said interdigitated electrode means with respect to one of each pair of said associated crossed waveguides for effecting respective phase shifts therein by applying voltages to said phase shifter means which are equal but of opposite sign; a plurality of conductor means for electrically connecting in parallel a column of said interdigitated electrode means corresponding to crossed waveguides representing elements in the said pair of rows of said matrix; a plurality of detector means disposed at the end of each channel waveguide representing a matrix element to be nulled for detecting the output optical amplitude of said channel waveguide; and a plurality of voltage means for successively sweeping the voltage applied to each column of said electrically connected interdigitated electrode means until the corresponding detected output optical amplitude is nulled. - View Dependent Claims (8, 9, 10)
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11. An array of elementary Givens rotation matrix devices arranged in a pipeline architecture for performing triangularization of a nonsingular square matrix of rank N comprising:
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a plurality of crossed channel waveguides configured to enter successively the optical amplitudes corresponding to each column of the matrix with each input element in a single column of said matrix entered simultaneously in one of said crossed waveguides, with each of said waveguides intersecting each of said other waveguides; a plurality of interdigitated electrode means associated with each pair of the crossed transmitting and diffracting coherent light energy travelling simultaneously through the respective waveguides; electro-optic phase shifter means lying upstream and downstream of each of said interdigitated electrode means with respect to one of each pair of said associated crossed waveguides for effecting respective phase shifts therein by applying voltages to said phase shifter means which are equal but of opposite sign; a plurality of detector means disposed downstream of each of said interdigitated electrode means with respect to one of each pair of said associated crossed waveguides for detecting the output amplitude of the matrix element to be nulled; and a plurality of voltage means for applying a voltage to each of said interdigitated electrode means until the corresponding detected output optical amplitude is nulled. - View Dependent Claims (12, 13, 14)
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15. A method for performing matrix triangularization with a monolithic integrated optical circuit having components arranged in a parallel architecture including a plurality of crossed channel waveguides with each waveguide having an input section and an output section, a plurality of interdigitated electrode means associated with the crossed waveguides at their crossing point and oriented so that the first Bragg condition is satisfied, electo-optic phase shifter means lying upstream and downstream of each of said interdigitated electrode means with respect to one of each pair of said associated crossed waveguides, a plurality of conductor means for electrically connecting in parallel each column of interdigitated electrode means corresponding to crossed waveguides representing elements in the same pair of rows of said matrix, a plurality of detector means disposed at the end of each channel waveguide whose optical amplitude is to be nulled, and a plurality of voltage means, said method comprising:
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guiding mutually coherent, monochromatic transverse magnetic input light signals simultaneously through the input section in each of said pair of crossed waveguides to said associated interdigitated electrode means; inducing a diffraction grating at said interdigitated electrode means by applying a voltage to said electrode means with said diffraction grating then operating on each light signal to form a transmitted and a diffracted wave in the output section in each of said pair of crossed waveguides; coherently combining the transmitted and diffracted waves formed in the output section of each of said pair of crossed waveguides by applying voltages that are equal in magnitude but opposite in sign to said upstream and downstream phase shifter means associated with said crossed waveguides and adjusting said voltages so that the transmitted and diffracted waves formed in the output section of one wave guide are combined in phase and the transmitted and diffracted waves formed in the output section of the other waveguide are combined 180°
out of phase;sweeping the voltage applied to said electrically connected column of interdigitated electrode means until the amplitude of the coherently combined and transmitted and diffracted waves formed in the output section of one waveguide is zero; and repeating the steps of inducing a diffraction grating, coherently combining the transmitted and diffracted waves, and sweeping the voltage applied to said electrically connected column of interdigitated electrode means successively to each of said columns of electrically connected interdigitated electrode means.
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16. A method for performing matrix triangularization with a monolithic integrated optical circuit having components arranged in a pipeline architecture including a plurality of crossed waveguides with each of said waveguides having an input section and an output section and with each of said waveguides intersecting each of said other waveguides, a plurality of interdigitated electrode means associated with the crossed waveguides at their crossing point and oriented so that the first Bragg condition is satisfied, electro-optic phase shifter means lying upstream and downstream of each of said interdigitated electrode means with respect to one of each pair of crossed waveguides, a plurality of detector means disposed downstream of each of said interdigitated electrode means with respect to one of each pair of said associated crossed waveguides, and a plurality of voltage means, said method comprising:
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guiding mutually coherent, monochromatic transverse magnetic input light signals corresponding to one column of said matrix simultaneously through the input section in each of said pair of crossed waveguides to said associated interdigitated electrode means; inducing a diffraction grating at said interdigitated electrode means by applying a voltage to said electrode means with said diffraction grating then operating on each input light signal to form a transmitted and diffracted wave in the output section in each of said pair of crossed waveguides; coherently combining the transmitted and diffracted waves formed in the output section of each of said pair of crossed waveguides by applying voltages that are equal in magnitude but opposite in sign to each of said upstream and downstream phase shifter means associated with said crossed waveguides and adjusting said voltages so that the transmitted and diffracted waves formed in the output section in one waveguide are combined in phase and the transmitted and diffracted waves formed in the output section of the other waveguide are combined 180°
out of phase;sweeping the voltage applied to said interdigitated electrode means until the amplitude of the coherently combined transmitted and diffracted waves formed in the output section of one waveguide is zero; and repeating the above steps for each column of the matrix.
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Current AssigneeGeorgia Tech Research Corporation (University System of Georgia)
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Original AssigneeGeorgia Tech Research Corporation (University System of Georgia)
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InventorsVerriest, Erik I., Mirsalehi, Mir M., Gaylor, Thomas K.
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Primary Examiner(s)Lee, John D.
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Application NumberUS07/232,905Time in Patent Office735 DaysField of Search350/96.11, 350/96.12, 350/96.13, 350/96.14, 350/96.15US Class Current385/3CPC Class CodesG02F 1/2955 by controlled diffraction o...G06E 3/005 using electro-optical or op...
