Patents by Inventor Rudolf F. Kazarinov
Rudolf F. Kazarinov has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Patent number: 5448585Abstract: The quantum well lasers according to the invention comprise an electron stopper layer that provides a barrier for the flow of electrons from the active region to the p-side waveguide and cladding layers and in preferred embodiments also comprise a hole stopper layer that provides a barrier for the flow of holes from the active region to the n-side waveguide and cladding layers. An exemplary InP-based laser according to the invention comprises AlInGaAs quantum well layers and barrier layers, and an AlInAs electron stopper layer and an InP hole stopper layer. Lasers according to the invention can have relatively low temperature dependence of, e.g., threshold current and/or external quantum efficiency, and may be advantageously incorporated in, e.g., optical fiber communication systems.Type: GrantFiled: June 29, 1994Date of Patent: September 5, 1995Assignee: AT&T IPM Corp.Inventors: Grigory Belenky, Rudolf F. Kazarinov
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Patent number: 5440416Abstract: An optical communication network includes a novel, passive optical component. This component combines the function of a splitter with the function of a wavelength-division multiplexer. These functions are performed in distinct wavelength bands. In one embodiment, the inventive component is made using silicon optical bench technology.Type: GrantFiled: February 24, 1993Date of Patent: August 8, 1995Assignee: AT&T Corp.Inventors: Leonard G. Cohen, Charles H. Henry, Rudolf F. Kazarinov, Henry H. Yaffe
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Patent number: 5418868Abstract: An optically switches relatively low power requirements and a relatively broad operating bandwidth. This switch includes a Mach-Zehnder interferometer (MZI) optically coupled at respective ends to an input coupler and an output coupler. One arm of the MZI includes a thermo-optic phase shifter. The output coupler is an adiabatic 3-dB coupler. In one embodiment, the input coupler is a Y-branch coupler having one input port. In a second embodiment, the input coupler is an adiabatic 3-dB coupler having two input ports.Type: GrantFiled: November 17, 1993Date of Patent: May 23, 1995Assignee: AT&T Corp.Inventors: Leonard G. Cohen, Charles H. Henry, Rudolf F. Kazarinov, Yiu-Huen Wong
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Patent number: 5309534Abstract: We describe an interferometric, channel-dropping, optical filter that includes a pair of planar waveguides. The two waveguides are spaced apart by a distance which is periodically varied along the longitudinal axis of the filter in order to effect a periodic optical coupling between them. There are at least three coupling locations, each associated with a coupling constant. The two waveguides have nominally equal effective refractive indices. In preferred embodiments of the invention, the coupling constants decrease symmetrically from the center of the filter toward the ends.Type: GrantFiled: February 24, 1993Date of Patent: May 3, 1994Assignee: AT&T Bell LaboratoriesInventors: Leonard G. Cohen, Charles H. Henry, Rudolf F. Kazarinov, Mark E. Kuznetsov
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Patent number: 5278812Abstract: In optical apparatus for reading, writing or erasing optical disks, the optical head is implemented in integrated form. Silicon optical bench technology, including integrated optical waveguides, Y-splitters and directional couplers, is used in the design of the tracking, lens focussing, and read/write/erase functions.Type: GrantFiled: February 18, 1992Date of Patent: January 11, 1994Assignee: AT&T Bell LaboratoriesInventors: Renen Adar, Rudolf F. Kazarinov
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Patent number: 5276746Abstract: In accordance with the invention an integrated optic device useful as a low level polarization independent optical tap comprises a pair of optical waveguides intersecting at an angle of 10.degree.-25.degree. to provide a tap signal in the range minus 20 dB to minus 60 dB. In a preferred embodiment for use in a passive repeater for undersea cable, the device comprises fiber-matching waveguides of phosphorus silicate glass on an oxide covered silicon substrate with a boron and phosphorus silicate cladding. The waveguides preferably intersect at an angle of 13.degree.-16.degree.. The preferred repeater further comprises a 3 dB coupler for averaging the power provided by two external pumping sources and a pair of wavelength division multiplexers for applying the pumping power to the outputs of the tap.Type: GrantFiled: June 24, 1992Date of Patent: January 4, 1994Assignee: AT&T Bell LaboratoriesInventors: Renen Adar, Charles H. Henry, Rudolf F. Kazarinov, Michele A. Milbrodt
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Patent number: 5195161Abstract: Disclosed are planar waveguides comprising substantially polarization-independent Bragg gratings. A preferred embodiment of the invention comprises a Si body with a silica lower cladding layer thereon, and a phosphorus P-doped silica core on the lower cladding. Appropriate periodic recessed features are etched into the core, and phophorus P- and B-doped silica upper cladding is deposited over the core. The dopant concentrations are adjusted such that the refractive index difference between core and upper cladding is small (0.35-1.45.times.10.sup.-2), and such that the flow temperature of the upper cladding material is lower than that of the core material. In another preferred embodiment a thin layer of Si.sub.3 N.sub.x (x.about.4) is conformally deposited over the core after the grating etch, and the upper cladding material is deposited onto the Si.sub.3 N.sub.x layer. Bragg devices according to the invention are advantageously used in Integrated Optical Circuits (IOCs), e.g.Type: GrantFiled: December 11, 1991Date of Patent: March 16, 1993Assignee: AT&T Bell LaboratoriesInventors: Renen Adar, Charles H. Henry, Rudolf F. Kazarinov, Rodney C. Kistler
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Patent number: 5093876Abstract: A wavelength selective structure is coupled to an adiabatic Y-coupler via a multimode section which supports both symmetric and antisymmetric modes. One single mode branch of the coupler converts guided light to a symmetric mode, whereas the other single mode branch converts guided light to an anti-symmetric mode. The structure, which includes a pair of single mode waveguide arms coupled to the common section and a reflection device (such as a grating or ROR) located in each arm, converts reflected light from a symmetric mode to an anti-symmetric mode and conversely. Applications described include a channel dropping filter and channel balancing apparatus for WDM systems, and a dispersion compensator for fiber optic systems.Type: GrantFiled: May 31, 1991Date of Patent: March 3, 1992Assignee: AT&T Bell LaboratoriesInventors: Charles H. Henry, Rudolf F. Kazarinov, Yosi Shani
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Patent number: 5048909Abstract: A wavelength selective structure is coupled to an adiabatic Y-coupler via a multimode section which supports both symmetric and antisymmetric modes. One single mode branch of the coupler converts guided light to a symmetric mode, whereas the other single mode branch converts guided light to an anti-symmetric mode. The structure, which includes a pair of single mode waveguide arms coupled to the common section and a reflection device (such as a grating or ROR) located in each arm, converts reflected light from a symmetric mode to an anti-symmetric mode and conversely. Applications described include a channel dropping filter and channel balancing apparatus for WDM systems, and a dispersion compensator for fiber optic systems.Type: GrantFiled: July 27, 1990Date of Patent: September 17, 1991Assignee: AT&T Bell LaboratoriesInventors: Charles H. Henry, Rudolf F. Kazarinov, Yosi Shani
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Patent number: 4998793Abstract: A TE-TM polarization manipulating (i.e., splitting, combining or filtering) device is constructed from substrate-supported dielectric thin film waveguides. In a 3-port device, two waveguides have cores of different materials and different effective refractive indices. The waveguide cores overlap in a first transition section and one waveguide core has an adiabatic taper; in this section they also separate adiabatically in and are coupled to a second (e.g., output) section where the waveguides are physically separate and optically decoupled. In a 4-port device, two additional waveguides are coupled in a second adiabatic transition section to the first transition section to enable TE or TM modes to be coupled straight through the device from one input port to a directly opposite output port or to be crossed-over from one input port to a diagonally opposite output port.Type: GrantFiled: November 14, 1989Date of Patent: March 12, 1991Assignee: AT&T Bell LaboratoriesInventors: Charles H. Henry, Rudolf F. Kazarinov, Yosi Shani
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Patent number: 4978189Abstract: An optical circulator/isolator is implemented in a semiconductor package formed by a semiconductor substrate, which supports integral thin film waveguide polarization splitters and combiners, and a semiconductor lid, which supports four spherical lenses and a polarization rotator. The latter is a composite of at least two adjacent slabs of optically active material, one slab serving as a nonreciprocal 45.degree. rotator (e.g., a Faraday rotator) and the other as a reciprocal 45.degree. rotator (e.g., half-wave device). The lenses, serving both as beam expanders/condensers and as collimators, are positioned between the waveguide ends and major surfaces of the composite slab. When used with means for reversing the direction of the magnetic field in the nonreciprocal rotator, the device functions also as a switch. Also described are system architectures made possible by these devices; e.g.Type: GrantFiled: November 14, 1989Date of Patent: December 18, 1990Assignee: AT&T Bell LaboratoriesInventors: Greg E. Blonder, Charles H. Henry, Rudolf F. Kazarinov, Raymond Wolfe
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Patent number: 4952017Abstract: In a fiber-optic communication system, a polarization independent semiconductor optical amplifier structure is achieved by tailoring the height-width aspect ratio of its active region to a value at least close to unity and at the same time using a laser cavity structure in which the end mirrors are buried in the semiconductor body in which the optical amplifier structure is built.Type: GrantFiled: March 14, 1989Date of Patent: August 28, 1990Assignee: AT&T Bell LaboratoriesInventors: Charles H. Henry, Rudolf F. Kazarinov, Nils A. Olsson
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Patent number: 4923271Abstract: An optical device is disclosed which provides wavelength multiplexing/demultiplexing utilizing a plurality of focusing Bragg reflectors. Each Bragg reflector includes a plurality of confocal (i.e., common foci) elliptical grating lines, with the exit/entrance ports of the input/output waveguides located at the foci of the ellipse. By virtue of the elliptical design, the signal propagating outward from the exit port of the input waveguide will be reflected by the appropriate Bragg reflector and focused into the entrance port of the appropriate output waveguide. When each Bragg reflector exhibits a different ellipticity, but shares one common focal point, optical multiplexing/demultiplexing may be achieved. Optical filtering may be achieved when all Bragg reflectors are designed to have common foci.Type: GrantFiled: March 28, 1989Date of Patent: May 8, 1990Assignee: American Telephone and Telegraph CompanyInventors: Charles H. Henry, Rudolf F. Kazarinov, Rodney C. Kistler, Kenneth J. Orlowsky, Yosi Shani, Aasmund S. Sudbo
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Patent number: 4914667Abstract: In the interest of ease of manufacture, hybrid lasers of distributed-Bragg-reflector type are preferred for use as light sources in optical communications. Such lasers are made to operate away from mode instabilities by adjusting a laser parameter such as, e.g., laser temperature, thereby assuring highly error-free transmission. Alternatively, by suitable design of the Bragg reflector it is possible to render mode instability of negligible influence on error rate.Type: GrantFiled: May 30, 1989Date of Patent: April 3, 1990Assignee: American Telephone and Telegraph Company, AT&T Bell LaboratoriesInventors: Greg E. Blonder, Charles H. Henry, Rudolf F. Kazarinov, Nils A. Olsson, Kenneth J. Orlowsky
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Patent number: 4852960Abstract: Highly frequency-selective reflectivity is realized in an optical device including a waveguide and an evanescent-field coupled grating resonator cavity. The device may include a light source and serve as a low-chirp, narrow-linewidth communications laser for use, e.g., for transmission over a fiber having non-negligible dispersion and also in wavelength-multiplexed coherent systems.Type: GrantFiled: September 23, 1988Date of Patent: August 1, 1989Assignee: American Telephone and Telegraph Company, AT&T Bell LaboratoriesInventors: Rodney C. Alferness, Charles H. Henry, Rudolf F. Kazarinov, Nils A. Olsson, Kenneth J. Orlowsky
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Patent number: 4488164Abstract: A switching element (e.g., 30) is furnished by an inversion layer (e.g., 55) in a zero resistance state under the influence of a quantizing magnetic field, the inversion layer having a ring geometry. Voltage (e.g., V.sub.o) applied across a pair of localized spaced apart terminals (e.g., 37, 38)--one on a portion of the inner edge of the ring, the other on the outer edge--produces a percolating current in the inversion layer, that is, a current circulating around the ring in a zero resistance state. This percolating current suddenly vanishes when a control voltage is applied to an auxiliary (gate) electrode (e.g., 51), whereby an output voltage (e.g., V.sub.out) previously developed across another pair of localized spaced apart terminals (e.g., 47, 48) on either edge of the ring suddenly also vanishes.Type: GrantFiled: June 10, 1982Date of Patent: December 11, 1984Assignee: AT&T Bell LaboratoriesInventors: Rudolf F. Kazarinov, Sergey Luryi
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Patent number: RE35516Abstract: A wavelength selective structure is coupled to an adiabatic Y-coupler via a multimode section which supports both symmetric and antisymmetric modes. One single mode branch of the coupler converts guided light to a symmetric mode, whereas the other single mode branch converts guided light to an anti-symmetric mode. The structure, which includes a pair of single mode waveguide arms coupled to the common section and a reflection device (such as a grating or ROR) located in each arm, converts reflected light from a symmetric mode to an anti-symmetric mode and conversely. Applications described include a channel dropping fiber and channel balancing apparatus for WDM systems, and a dispersion compensator for fiber optic systems.Type: GrantFiled: May 30, 1995Date of Patent: May 20, 1997Assignee: Lucent Technologies Inc.Inventors: Charles H. Henry, Rudolf F. Kazarinov, Yosi Shani