Patents Assigned to Gemfire Corporation
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Patent number: 9494735Abstract: Roughly described, an AWG has two or more inputs and multiple outputs. By selecting the angular spacing among the inputs, and by designing the different inputs to address different orders of the waveguide array, the device can be designed such that the inputs will carry frequency bands having any desired center frequency spacing and any desired same or different channel spacing. For example a dual input device can be designed such that one input carries C-band channels and the other input carries L-band channels, and both have channel spacings that match or substantially match the ITU grid.Type: GrantFiled: October 12, 2011Date of Patent: November 15, 2016Assignee: GEMFIRE CORPORATIONInventor: Hindrik Freerk Bulthuis
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Patent number: 8873910Abstract: In one aspect of the invention, roughly stated, Applicants have discovered that a compensation material within slot elongated in a direction parallel to a segment of waveguide in an arrayed waveguide grating apparatus can compensate for both first and second order change in refractive index of the base waveguide material over temperature. Unlike the transverse slots of conventional linear athermalization techniques, the elongated slot generally parallel to the base material defines a composite waveguide section having a second order effective index of refraction temperature dependency which can be utilized to accurately minimize the temperature dependence of the overall optical path length to both the first and second order. The techniques described herein are also generalizeable to neutralization of the optical path length temperature dependence to any order.Type: GrantFiled: March 18, 2011Date of Patent: October 28, 2014Assignee: Gemfire CorporationInventors: Hindrik Freerk Bulthuis, Paula McDade, Gunter B. Beelen
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Patent number: 8824056Abstract: Roughly described, an optical device has first and second waveguide segments which are constructed such that irradiation changes both average refractive index and also birefringence in the respective segment. The change in birefringence as a function of the change in average refractive index, is different for the two segments. Predetermined lengths of each of the two segments are irradiated. In an MZI, the technique can be used to adjust simultaneously for one or more of differential path length phase delays, coupler-induced phase errors, and frequency errors.Type: GrantFiled: March 28, 2012Date of Patent: September 2, 2014Assignee: Gemfire CorporationInventors: Hindrik Freerk Bulthuis, Gunter B. Beelen
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Publication number: 20120250160Abstract: Roughly described, an optical device has first and second waveguide segments which are constructed such that irradiation changes both average refractive index and also birefringence in the respective segment. The change in birefringence as a function of the change in average refractive index, is different for the two segments. Predetermined lengths of each of the two segments are irradiated. In an MZI, the technique can be used to adjust simultaneously for one or more of differential path length phase delays, coupler-induced phase errors, and frequency errors.Type: ApplicationFiled: March 28, 2012Publication date: October 4, 2012Applicant: GEMFIRE CORPORATIONInventors: Hindrik Freerk Bulthuis, Gunter B. Beelen
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Publication number: 20110229080Abstract: In one aspect of the invention, roughly stated, Applicants have discovered that a compensation material within slot elongated in a direction parallel to a segment of waveguide in an arrayed waveguide grating apparatus can compensate for both first and second order change in refractive index of the base waveguide material over temperature. Unlike the transverse slots of conventional linear athermalization techniques, the elongated slot generally parallel to the base material defines a composite waveguide section having a second order effective index of refraction temperature dependency which can be utilized to accurately minimize the temperature dependence of the overall optical path length to both the first and second order. The techniques described herein are also generalizeable to neutralization of the optical path length temperature dependence to any order.Type: ApplicationFiled: March 18, 2011Publication date: September 22, 2011Applicant: GEMFIRE CORPORATIONInventors: Hindrik Freerk Bulthuis, Paula Mc Dade, Gunter B. Beelen
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Patent number: 7711222Abstract: A colorless tunable optical dispersion compensator (TODC) comprising a silica arrayed-waveguide grating (AWG) directly coupled to a polymer thermo-optic lens. As a result of its inventive construction, the device exhibits low loss, large tuning range, low electrical consumption and is readily manufactured using standard processes. Additionally, the TODC is fully solid-state and scales to a large figure-of-merit (dispersion range times bandwidth squared).Type: GrantFiled: March 3, 2006Date of Patent: May 4, 2010Assignees: Alcatel-Lucent USA Inc., Gemfire CorporationInventors: Robert Blum, Hindrik Bulthius, Christopher Doerr
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Patent number: 7689072Abstract: Optical apparatus with improved center wavelength temperature stability. In an embodiment, an AWG has a plurality of slots inserted along the optical paths. The slots contain one or more compensation materials which collectively correct for an order Q temperature dependency of the AWG base material. Q>=2 or the number of compensation materials is at least 2 or both.Type: GrantFiled: May 30, 2008Date of Patent: March 30, 2010Assignee: Gemfire CorporationInventors: Hindrick Freerk Bulthuis, Tony C. Kowalczyk, Michael G. Jubber
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Patent number: 7653109Abstract: An optical assembly, such as a multiple output diode laser pump source for EDFAs, is formed by pressing an optical array emitter chip against a standoff structure protruding from a submount such that the emitter chip deforms to match the curvature of the standoff structure. An IO chip is also juxtaposed against the standoff structure such that its optical receivers can receive optical energy from the emitter chip. The IO chip can provide various optical functions, and then provide an optical array output for coupling into an optical fiber array. The standoff structure preferably contacts the emitter chip over an aggregate contact area much smaller than the area by which the emitter chip overlaps the submount. The materials used for bonding the emitter chip and the IO chip to the submount are disposed in the recesses between standoffs and not on the contact surfaces of the standoff structure.Type: GrantFiled: June 25, 2007Date of Patent: January 26, 2010Assignee: Gemfire CorporationInventors: William K. Bischel, David K. Wagner, Harald Guenther, Simon J. Field, Markus P. Hehlen, Richard B. Tompane, Andrew T. Ryan, C. Geoffrey Fanning, Jim W. Li, Nina D. Morozova
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Patent number: 7492991Abstract: Roughly described, arrayed waveguide grating apparatus includes one or more input and/or output waveguides which are shaped and oriented such that optical energy communicated with the waveguide array is, within a distance of no more than 1 mm into the mouth of the waveguide, directed substantially in-line with the optical centerline of the waveguide. In one embodiment, the waveguides are shaped and oriented such that the optical energy enters or exits the waveguide substantially-line with the optical centerline of each waveguide. In another embodiment the waveguides are shaped and oriented such that optical energy is, at the mouth of each waveguide, directed off-axis, and the waveguide includes mode conversion means such that optical energy is directed substantially in-line with the optical centerline within a distance of no more than 1 mm into the mouth of the waveguide. The mode conversion means may, for example, include a non-adiabatic lateral optical centerline shift.Type: GrantFiled: April 19, 2007Date of Patent: February 17, 2009Assignee: Gemfire CorporationInventors: Gunter B. L. Beelen, Hindrick F. Bulthuis
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Patent number: 7471856Abstract: An optical link includes a polymer waveguide having a top cladding layer, a core polymer layer, and a bottom cladding layer, supported by a substrate, with mirrors and optical vias. The core polymer layer includes a polymer material having a nanoparticle filler with a particle size of less than one tenth the shortest wavelength of interest for the optical link. The optical links comprise individual, multiple or massively parallel channels in single or multilayer networks.Type: GrantFiled: July 8, 2005Date of Patent: December 30, 2008Assignees: Dow Corning Corporation, Gemfire CorporationInventors: Jon Degroot, Jr., Shedric Glover, William K. Bischel, Mark J. Dyer
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Publication number: 20080226232Abstract: Optical apparatus with improved center wavelength temperature stability. In an embodiment, an AWG has a plurality of slots inserted along the optical paths. The slots contain one or more compensation materials which collectively correct for an order Q temperature dependency of the AWG base material. Q>=2 or the number of compensation materials is at least 2 or both.Type: ApplicationFiled: May 30, 2008Publication date: September 18, 2008Applicant: GEMFIRE CORPORATIONInventors: Hindrick Freerk Bulthuis, Tony C. Kowalczyk, Michael G. Jubber
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Patent number: 7397986Abstract: Optical apparatus with improved center wavelength temperature stability. In an embodiment, an AWG has a plurality of slots inserted along the optical paths. The slots contain one or more compensation materials which collectively correct for an order Q temperature dependency of the AWG base material. Q>=2 or the number of compensation materials is at least 2 or both.Type: GrantFiled: March 4, 2005Date of Patent: July 8, 2008Assignee: Gemfire CorporationInventors: Hindrick Freerk Bulthuis, Tony C. Kowalczyk, Michael G. Jubber
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Patent number: 7382953Abstract: Roughly described, an AWG has a waveguide array and a region of vertical-only confinement that is shared for both input and output beams of the waveguide array. The AWG layout is such that the input and output beams to and from the waveguide array cross each other within the region of vertical-only confinement.Type: GrantFiled: February 9, 2007Date of Patent: June 3, 2008Assignee: Gemfire CorporationInventors: Hindrick F. Bulthuis, Gunter B. L. Beelen
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Publication number: 20080044133Abstract: An optical link includes a polymer waveguide having a top cladding layer, a core polymer layer, and a bottom cladding layer, supported by a substrate, with mirrors and optical vias. The core polymer layer includes a polymer material having a nanoparticle filler with a particle size of less than one tenth the shortest wavelength of interest for the optical link. The optical links comprise individual, multiple or massively parallel channels in single or multilayer networks.Type: ApplicationFiled: July 8, 2005Publication date: February 21, 2008Applicants: Dow Corning Corporation, Gemfire CorporationInventors: Jon Degroot, Shedric Glover, William Bischel, Mark Dyer
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Publication number: 20070274632Abstract: Roughly described, arrayed waveguide grating apparatus includes one or more input and/or output waveguides which are shaped and oriented such that optical energy communicated with the waveguide array is, within a distance of no more than 1 mm into the mouth of the waveguide, directed substantially in-line with the optical centerline of the waveguide. In one embodiment, the waveguides are shaped and oriented such that the optical energy enters or exits the waveguide substantially-line with the optical centerline of each waveguide. In another embodiment the waveguides are shaped and oriented such that optical energy is, at the mouth of each waveguide, directed off-axis, and the waveguide includes mode conversion means such that optical energy is directed substantially in-line with the optical centerline within a distance of no more than 1 mm into the mouth of the waveguide. The mode conversion means may, for example, include a non-adiabatic lateral optical centerline shift.Type: ApplicationFiled: April 19, 2007Publication date: November 29, 2007Applicant: Gemfire CorporationInventors: GUNTER B.L. BEELEN, Hindrik F. Bulthuis
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Publication number: 20070248139Abstract: An optical assembly, such as a multiple output diode laser pump source for EDFAs, is formed by pressing an optical array emitter chip against a standoff structure protruding from a submount such that the emitter chip deforms to match the curvature of the standoff structure. An IO chip is also juxtaposed against the standoff structure such that its optical receivers can receive optical energy from the emitter chip. The IO chip can provide various optical functions, and then provide an optical array output for coupling into an optical fiber array. The standoff structure preferably contacts the emitter chip over an aggregate contact area much smaller than the area by which the emitter chip overlaps the submount. The materials used for bonding the emitter chip and the IO chip to the submount are disposed in the recesses between standoffs and not on the contact surfaces of the standoff structure.Type: ApplicationFiled: June 25, 2007Publication date: October 25, 2007Applicant: Gemfire CorporationInventors: William Bischel, David Wagner, Harald Guenther, Simon Field, Markus Hehlen, Richard Tompane, Andrew Ryan, C. Fanning, Jim Li, Nina Morozova
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Publication number: 20070206896Abstract: A colorless tunable optical dispersion compensator (TODC) comprising a silica arrayed-waveguide grating (AWG) directly coupled to a polymer thermo-optic lens. As a result of its inventive construction, the device exhibits low loss, large tuning range, low electrical consumption and is readily manufactured using standard processes. Additionally, the TODC is fully solid-state and scales to a large figure-of-merit (dispersion range times bandwidth squared).Type: ApplicationFiled: March 3, 2006Publication date: September 6, 2007Applicants: LUCENT TECHNOLOGIES INC., GEMFIRE CORPORATIONInventors: ROBERT BLUM, HINDRIK BULTHIUS, CHRISTOPHER DOERR
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Patent number: 7263247Abstract: An integrated isolator array is provided having a plurality of waveguides fabricated in a planar optical substrate, each waveguide having input and output sections. An isolator subassembly is received within a transverse trench formed in the substrate between the input and output sections such that it intersects the optical paths of the waveguides. The isolator subassembly, which may consist of layers of Faraday rotator material sandwiched between layers of birefringent crystal material, permits the forward passage of light from the input sections to the output sections of the waveguides while preventing the backward passage of light from the output to the input sections. Each waveguide input section is preferably adapted with a mode-expanding input taper to collimate light propagating through the waveguide.Type: GrantFiled: February 11, 2002Date of Patent: August 28, 2007Assignee: Gemfire CorporationInventors: Markus P. Hehlen, William K. Bischel
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Patent number: 7235150Abstract: An optical assembly, such as a multiple output diode laser pump source for EDFAs, is formed by pressing an optical array emitter chip against a standoff structure protruding from a submount such that the emitter chip deforms to match the curvature of the standoff structure. An IO chip is also juxtaposed against the standoff structure such that its optical receivers can receive optical energy from the emitter chip. The IO chip can provide various optical functions, and then provide an optical array output for coupling into an optical fiber array. The standoff structure preferably contacts the emitter chip over an aggregate contact area much smaller than the area by which the emitter chip overlaps the submount. The materials used for bonding the emitter chip and the IO chip to the submount are disposed in the recesses between standoffs and not on the contact surfaces of the standoff structure.Type: GrantFiled: July 23, 2004Date of Patent: June 26, 2007Assignee: Gemfire CorporationInventors: William K. Bischel, David K. Wagner, Harald Guenther, Simon J. Field, Markus P. Hehlen, Richard B. Tompane, Andrew T. Ryan, C. Geoffrey Fanning, Jim W. Li, Nina D. Morozova
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Patent number: 7215854Abstract: An improved low-loss waveguide crossover uses an out-of-plane, such as vertical, waveguide to bridge over any number of waveguides with very low, or essentially no, optical loss or crosstalk. Optical signals transmitted in a waveguide system having the improved waveguide crossover can cross over one or multiple transverse waveguides with a greatly reduced loss of signal intensity by using a second waveguide (such as a bridge) positioned in a second plane different from the plane containing the transverse waveguides. An optical signal from the input waveguide is coupled efficiently through directional coupling to the bridge waveguide and optionally from the bridge waveguide to the output waveguide. Methods for fabricating the improved waveguide crossover are described.Type: GrantFiled: August 12, 2005Date of Patent: May 8, 2007Assignee: Gemfire CorporationInventors: Arthur Telkamp, Randy Bindrup