Patents by Inventor Benjamin J. Eggleton
Benjamin J. Eggleton 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: 7440664Abstract: A microstructured optical waveguide is formed to include a periodic sequence of “plugs” of optically active material within the inner cladding air tunnels. The plugs are utilized as a grating structure for generating resonant and periodic structures. The waveguide (in one embodiment, an optical fiber) is tunable by changing the spacing of the plugs (e.g., heating the structure, changing the pressure within the structure, etc.), or by modifying the initial spacing of the plugs during the formation of the microstructured optical waveguide (i.e., by modifying the “dipping frequency” of the waveguide into a reservoir of optically active material). In general, any number of different types of optically active material may be used to form the plugs, where two or more different materials may be used in the same structure, and introduced in an alternating fashion.Type: GrantFiled: April 8, 2003Date of Patent: October 21, 2008Assignee: Fitel USA Corp.Inventors: Benjamin J. Eggleton, Justin D. Ging, Arturo Hale, Charles Kerbage
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Patent number: 7139478Abstract: Embodiments of the invention include system for monitoring the effectiveness of pulse shaping in a nonlinear optical fiber (40). The spectral content of the pulse, after passing through the nonlinear fiber (40), provides an indication of how effectively the pulse was regenerated. A portion of the pulse exiting the nonlinear fiber is tapped off and its pulse energy is measured in at least one selected spectral region. The selected spectral region is one in which the pulse tends to gain energy when effective regeneration is taking place. The information concerning the effectiveness of pulse shaping in a nonlinear optical fiber is fed back to dynamically change the residual dispersion at the regenerator input. The spectral measurement leads to a control signal (48) to indicate a level of performance of the system, or to improve the performance of the system by adjusting an operational parameter.Type: GrantFiled: March 13, 2002Date of Patent: November 21, 2006Assignee: Fitel USA Corp.Inventors: Benjamin J. Eggleton, Tsing Hua Her, Stefan Hunsche, Gregory Raybon, John A. Rogers, Paul S. Westbrook
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Patent number: 7081323Abstract: In accordance with the invention, the fabrication of a grating phase mask is improved by providing a multiple-scan exposure which can provide an accumulated exposure that is effectively phase modulated or modulated rapidly in amplitude. Applicants have determined that exposure scans can be chosen so that each is modulated in amplitude and without modulation in phase, but the accumulated exposure of the multiple scans is modulated in phase and/or modulated in amplitude. The improved method can be used to make phase masks for fabrication of sophisticated fiber gratings such as superstructure gratings.Type: GrantFiled: November 5, 2003Date of Patent: July 25, 2006Assignee: Fitel USA CorpInventors: Benjamin J. Eggleton, Misha Sumetsky, Paul S. Westbrook
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Patent number: 6996317Abstract: A microstructured optical component is formed from an optical preform fabricated to include one ore more internal regions of differing refractive index. The preform is drawn into a fiber and sliced into relatively long individual fiber segments, each segment thus forming a microstructured optical component. An optical signal may then be coupled through a sidewall of the component in a direction parallel to the endfaces of the segment. A more complex structure can be formed by grouping together a plurality of fiber segments and performing an additional drawing and slicing process.Type: GrantFiled: October 23, 2003Date of Patent: February 7, 2006Assignee: Fitel U.S.A. Corp.Inventors: Benjamin J. Eggleton, Mikio Ogai, Mikhail Sumetsky
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Patent number: 6885792Abstract: The specification describes a wavelength monitoring system for multiple wavelength communications systems, such as WDM systems, based on the recognition that the mechanism for spatially separating the individual wavelength bands can be achieved within the optical fiber itself. Individual wavelength bands are separated using a series of discrete gratings spaced longitudinally along the fiber core. The wavelength bands are extracted from the fiber core by converting the energy in the selected band from a core-guided mode to a radiation mode. By using a tilted grating, the light in the radiation mode is directed through the cladding and out of the fiber. Spatial resolution of the selected bands can be any desired physical length. An important implication of this is that detection can be made in the near field using inexpensive detecting apparatus.Type: GrantFiled: September 24, 2002Date of Patent: April 26, 2005Assignee: Furukawa Electric North America Inc.Inventors: Benjamin J. Eggleton, Kenneth S. Feder, Paul S. Westbrook
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Patent number: 6847763Abstract: A colorless tunable dispersion compensator (TDC) comprises a plurality of N separate dispersion compensation elements, each centered at a different wavelength used in the communication system. A single tuning element is coupled to the plurality of separate dispersion compensation elements. A 1-out-of-N selector (such as a 1×N optical switch) is used to select the particular tunable dispersion compensation element to be implemented for an associated channel in the system. Advantageously, the same TDC can then be used in association with each channel in the communication system, as controlled by the 1-out-of-N selector to chose the particular compensation element for a specific channel wavelength.Type: GrantFiled: December 17, 2002Date of Patent: January 25, 2005Assignee: Fitel U.S.A. CorpInventors: Benjamin J. Eggleton, Richard J. Ramsay, Paul Steinvurzel
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Publication number: 20040208609Abstract: Embodiments of the invention include system for monitoring the effectiveness of pulse shaping in a nonlinear optical fiber (40). The spectral content of the pulse, after passing through the nonlinear fiber (40), provides an indication of how effectively the pulse was regenerated. A portion of the pulse exiting the nonlinear fiber is tapped off and its pulse energy is measured in at least one selected spectral region. The selected spectral region is one in which the pulse tends to gain energy when effective regeneration is taking place. The information concerning the effectiveness of pulse shaping in a nonlinear optical fiber is fed back to dynamically change the residual dispersion at the regenerator input. The spectral measurement leads to a control signal (48) to indicate a level of performance of the system, or to improve the performance of the system by adjusting an operational parameter.Type: ApplicationFiled: November 1, 2002Publication date: October 21, 2004Inventors: Benjamin J Eggleton, Tsing Hua Her, Stefan Hunsche, Gregory Raybon, John A Rogers, Paul S Westbrook
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Publication number: 20040202438Abstract: A microstructured optical waveguide is formed to include a periodic sequence of “plugs” of optically active material within the inner cladding air tunnels. The plugs are utilized as a grating structure for generating resonant and periodic structures. The waveguide (in one embodiment, an optical fiber) is tunable by changing the spacing of the plugs (e.g., heating the structure, changing the pressure within the structure, etc.), or by modifying the initial spacing of the plugs during the formation of the microstructured optical waveguide (i.e., by modifying the “dipping frequency” of the waveguide into a reservoir of optically active material). In general, any number of different types of optically active material may be used to form the plugs, where two or more different materials may be used in the same structure, and introduced in an alternating fashion.Type: ApplicationFiled: April 8, 2003Publication date: October 14, 2004Inventors: Benjamin J. Eggleton, Justin D. Ging, Arturo Hale, Charles Kerbage
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Patent number: 6768577Abstract: A tunable multimode wavelength division multiplex Raman pump and amplifier, and a system, method, and computer program product for controlling a tunable Raman pump and amplifier. The tunability of the pump source is accomplished by either straining or heating an external fiber grating, thereby causing a different wavelength of light to be emitted by the pump source. The system includes a microprocessor-based controller that monitors an amplifier's performance and adjusts the drive current and/or wavelength of the tunable pumps of an amplifier to achieve a target performance.Type: GrantFiled: March 15, 2002Date of Patent: July 27, 2004Assignee: Fitel USA Corp.Inventors: Benjamin J. Eggleton, Paul Steinvurzel, Yoshihiro Emori, Shu Namiki, Akira Fujisaki, Toshio Kimura
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Patent number: 6753118Abstract: A grating fabrication process utilizes real-time measurement of a grating characteristic (such as, for example, grating period chirp, reflectivity, group delay) as a feedback error signal to modify the writing process and improve the characteristics of the finished grating. A test beam is launched through the optical medium during the writing process (or at the end of an initial writing process) and a particular characteristic is measured and used to generate a “corrective” apodization refractive index profile that can be incorporated with the grating to improve its characteristics. The improvements may be applied to a phase (or amplitude) mask used to write the grating (etching, local deformation, coating changes, for example), or the grating itself may be corrected using additional UV exposure, non-uniform annealing, non-uniform heating, and/or non-uniform tension—these techniques applied separately or in an intermittent sequence.Type: GrantFiled: March 27, 2002Date of Patent: June 22, 2004Assignee: Fitel USA Corp.Inventors: Rajan D. Deshmukh, Benjamin J. Eggleton, Pavel Ivanoff Reyes, Carl Soccolich, Michael Sumetsky, Paul S. Westbrook
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Publication number: 20040114863Abstract: A colorless tunable dispersion compensator (TDC) comprises a plurality of N separate dispersion compensation elements, each centered at a different wavelength used in the communication system. A single tuning element is coupled to the plurality of separate dispersion compensation elements. A 1-out-of-N selector (such as a 1×N optical switch) is used to select the particular tunable dispersion compensation element to be implemented for an associated channel in the system. Advantageously, the same TDC can then be used in association with each channel in the communication system, as controlled by the 1-out-of-N selector to chose the particular compensation element for a specific channel wavelength.Type: ApplicationFiled: December 17, 2002Publication date: June 17, 2004Inventors: Benjamin J. Eggleton, Richard J. Ramsay, Paul Steinvurzel
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Publication number: 20040106050Abstract: In accordance with the invention, the fabrication of a grating phase mask is improved by providing a multiple-scan exposure which can provide an accumulated exposure that is effectively phase modulated or modulated rapidly in amplitude. Applicants have determined that exposure scans can be chosen so that each is modulated in amplitude and without modulation in phase, but the accumulated exposure of the multiple scans is modulated in phase and/or modulated in amplitude. The improved method can be used to make phase masks for fabrication of sophisticated fiber gratings such as superstructure gratings.Type: ApplicationFiled: November 5, 2003Publication date: June 3, 2004Applicant: OFS FITELInventors: Benjamin J. Eggleton, Misha Sumetsky, Paul S. Westbrook
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Publication number: 20040056183Abstract: The specification describes a wavelength monitoring system for multiple wavelength communications systems, such as WDM systems, based on the recognition that the mechanism for spatially separating the individual wavelength bands can be achieved within the optical fiber itself. Individual wavelength bands are separated using a series of discrete gratings spaced longitudinally along the fiber core. The wavelength bands are extracted from the fiber core by converting the energy in the selected band from a core-guided mode to a radiation mode. By using a tilted grating, the light in the radiation mode is directed through the cladding and out of the fiber. Spatial resolution of the selected bands can be any desired physical length. An important implication of this is that detection can be made in the near field using inexpensive detecting apparatus.Type: ApplicationFiled: September 24, 2002Publication date: March 25, 2004Inventors: Benjamin J. Eggleton, Kenneth S. Feder, Paul S. Westbrook
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Publication number: 20030186142Abstract: A grating fabrication process utilizes real-time measurement of a grating characteristic (such as, for example, grating period chirp, reflectivity, group delay) as a feedback error signal to modify the writing process and improve the characteristics of the finished grating. A test beam is launched through the optical medium during the writing process (or at the end of an initial writing process) and a particular characteristic is measured and used to generate a “corrective” apodization refractive index profile that can be incorporated with the grating to improve its characteristics. The improvements may be applied to a phase (or amplitude) mask used to write the grating (etching, local deformation, coating changes, for example), or the grating itself may be corrected using additional UV exposure, non-uniform annealing, non-uniform heating, and/or non-uniform tension—these techniques applied separately or in an intermittent sequence.Type: ApplicationFiled: March 27, 2002Publication date: October 2, 2003Inventors: Rajan D. Deshmukh, Benjamin J. Eggleton, Pavel Ivanoff Reyes, Carl Soccolich, Michael Sumetsky, Paul S. Westbrook
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Publication number: 20030174387Abstract: A tunable multimode wavelength division multiplex Raman pump and amplifier, and a system, method, and computer program product for controlling a tunable Raman pump and amplifier. The tunability of the pump source is accomplished by either straining or heating an external fiber grating, thereby causing a different wavelength of light to be emitted by the pump source. The system includes a microprocessor-based controller that monitors an amplifier's performance and adjusts the drive current and/or wavelength of the tunable pumps of an amplifier to achieve a target performance.Type: ApplicationFiled: March 15, 2002Publication date: September 18, 2003Applicant: FITEL USA CORPORATIONInventors: Benjamin J. Eggleton, Paul Steinvurzel, Yoshihiro Emori, Shu Namiki, Akira Fujisaki, Toshio Kimura
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Patent number: 6415079Abstract: The present invention is predicated on applicants' discovery that an appropriately spaced and dimensioned internal gap cladding can substantially reduce short wavelength cladding mode loss in a fiber Bragg grating. A fiber Bragg grating is provided with a ring of closely spaced, longitudinally extending gap regions in the glass peripherally surrounding the core. The gaps are spaced apart by thin glass webs having a thickness less than a wavelength of the light being transmitted and are disposed peripherally about the core at a distance of 2-10 wavelengths from the core center. The thin webs limit the passage of the light between the gaps. The combination of webs and gaps acts as an internal thin cladding which supports fewer cladding modes than conventional glass cladding and, significantly, provides increased wavelength spacing between the Bragg resonance and the first cladding mode resonance.Type: GrantFiled: March 3, 2000Date of Patent: July 2, 2002Assignee: Fitel USA Corp.Inventors: Geoffrey L. Burdge, Benjamin J. Eggleton, Thomas A. Strasser, Paul S. Westbrook, Robert S. Windeler
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Patent number: 6386714Abstract: A reflecting apparatus includes a flexible mirror and at least one rocker arm coupling an applied force to a plurality of spaced-apart locations on the mirror to adjust the shape of the mirror. The reflecting apparatus may be used in an interferometer in the path of one of the interfering beams, and adjustments of the shape of the mirror may be used to control the interference pattern generated. The interference pattern created by the apparatus may be used to create fiber Bragg gratings and phase masks, including chirped gratings and masks. An interferometer may use such a reflecting apparatus in the path of each interfering beam.Type: GrantFiled: May 4, 2001Date of Patent: May 14, 2002Assignee: Lucent Technolgies Inc.Inventors: Benjamin J. Eggleton, Kenneth S. Feder, Mikhail Sumetskiy