Claims
- 1. A method for forming a thin film optical device including the steps of disposing an upper and lower boundary layers in optical contact with a thin film optical waveguide, imposing fixed perturbations onto one of said boundary layers in regions thereof which are interacted with upon propagation of light in said waveguide, and imposing variable perturbation in the other of said boundary layers for the purpose of varying the frequency response of said device.
- 2. A laser comprising an optical waveguide defining a guided wavelength for propagating wave of light at a predetermined frequency, said waveguide having a predetermined frequency, said waveguide having a predetermined optical index of refraction and made of a material transparent to light of said predetermined frequency, means defining at least one boundary layer adjacent to said waveguide and in such proximity that the propagating wave for light at said predetermined frequency extends both within said waveguide and into said boundary layer, said boundary layer having one or more indices of refraction at least a portion of which is less than the index of refraction of said waveguide, one of said waveguide or boundary layers being a laser active material which exhibits gain with respect to light at said predetermined frequency, first means associated with one of said boundary layers, said waveguide, or the interface between said boundary layer and said waveguide for forming a periodic variation of the index of refraction thereof in a first predetermined direction, said periodic variation being arranged for causing a spatial variation of said index of refraction between two values which repeat in a regular pattern of a first predetermined periodicity a.sub.y, second means associated with one of said boundary layer, said waveguide on the interface of said boundary layer and said waveguide for forming a periodic variation of the index of refraction thereof in a second predetermined direction, said second periodic variation of said index of refraction between two values which repeat in regular pattern of a second predetermined periodicity a.sub.z wherein said periodicities a.sub. y and a.sub.z are solutions to an equation of the general form ##EQU8## where .lambda..sub.g is the guided wavelength N.sub.y and N.sub.z are integers and the ratios ##EQU9## define an intersection in reciprocal lattice space for a given waveguide structure.
- 3. A thin film optical device comprising an optical waveguide having boundary surfaces and defining a guided wavelength for propagating wave of light at a predetermined frequency, said waveguide having a predetermined optical index of refraction and made of a material transparent to light of said predetermined frequency, means defining at least one boundary layer adjacent to said waveguide and in such proximity that the propagating wave for light at said predetermined frequency extends both within said waveguide and into said boundary layer, said boundary layer having one or more indices of refraction at least a portion of which is less than the index of refraction of said waveguide, perturbation means associated with said boundary layer, said waveguide or the interface between said boundary layer and said waveguide for forming a periodic variation of an optical parameter thereof in a first predetermined direction, said periodic variation being arranged for causing a spatial variation of said optical parameter between two values which repeat in a regular pattern of a first predetermined periodicity a.sub.y, said perturbation means further forming a second periodic variation of an optical parameter thereof in a second predetermined direction, said second periodic variation of said optical parameter between two values which repeat in regular pattern of a second predetermined periodicity a.sub.z, one of said boundary layers and said waveguide being made of laser active material, and means for pumping said laser active material.
Parent Case Info
This is a division of application Ser. No. 355,454 filed Apr. 30, 1973, now U.S. Pat. No. 3,884,549.
Government Interests
The invention herein described was made in the course of research sponsored in part by the United States Army Research Office.
Non-Patent Literature Citations (2)
Entry |
kogelnik et al., Stimulated Emission in a Periodic Structure, Appl. Phys. Lett., vol. 18, No. 4 (Feb. 15, 1971) pp. 152-154. |
Shank et al., Tunable Distributed-Feedback Dye Laser, Appl. Phys. Lett., vol. 18, No. 9 (May 1, 1971), pp. 395-396. |
Divisions (1)
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Number |
Date |
Country |
Parent |
355454 |
Apr 1973 |
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