Patents by Inventor Simit Mayank Patel
Simit Mayank Patel 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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Publication number: 20240151609Abstract: A method of selecting a group of multimode optical fibers, includes comparing a first effective modal bandwidth at a first wavelength of a multimode optical fiber with a first effective modal bandwidth threshold at the first wavelength, the multimode optical fiber being in a group of multimode optical fibers meeting a first OM standard, wherein the first wavelength is from 844 nm to 863 nm; and categorizing the multimode optical fiber as passing a transmission distance requirement if the first effective modal bandwidth of the first multimode optical fiber is greater than or equal to the first effective modal bandwidth threshold; wherein the transmission distance is defined in a transceiver specification, wherein the transceiver specification is one or more of: (a) an 800G bidirectional (BiDi) transceiver specification, or (b) a 100G/lane based MM VCSEL transceiver specification, or (c) a 25Gbaud based transceiver specification, or (d) 50G PAM4 based transceiver specification.Type: ApplicationFiled: October 20, 2023Publication date: May 9, 2024Inventors: Zoren Dene Bullock, Xin Chen, Hao Dong, Ming-Jun Li, Simit Mayank Patel
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Publication number: 20230314276Abstract: A method of categorizing single mode optical fibers, the method including determining one or more fiber properties of an optical fiber, the optical fiber being a single mode optical fiber at an operating wavelength of about 1310 nm. The method further including calculating a peak bandwidth wavelength of the optical fiber based on the one or more fiber properties, comparing the calculated peak bandwidth wavelength with a target peak bandwidth wavelength and based on the comparison, determining if the optical fiber meets a target modal bandwidth.Type: ApplicationFiled: March 30, 2023Publication date: October 5, 2023Inventors: Xin Chen, Kangmei Li, Ming-Jun Li, Snigdharaj Kumar Mishra, Simit Mayank Patel
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Patent number: 11698485Abstract: A method of manufacturing a multimode optical fiber includes specifying a peak wavelength ?P for the multimode optical fiber. The peak wavelength ?P corresponds to a wavelength at which the multimode optical fiber has a maximum bandwidth. The multimode optical fiber comprises a core and a cladding surrounding and directly adjacent to the core. The core has a radius r1 and a maximum relative refractive index ?1,MAX>0. The cladding comprises a depressed-index region having a minimum relative refractive index ?3,MIN<0 and a volume v. A draw tension T for the multimode optical fiber is selected based on a correlation relating peak wavelength ?P to draw tension T, the correlation comprising a correlation constant. The correlation constant K is a function of at least one of ?1,MAX, r1, v, ?3,MIN, and ?P. The multimode optical fiber is drawn from a preform at the draw tension T.Type: GrantFiled: December 14, 2020Date of Patent: July 11, 2023Assignee: Corning IncorporatedInventors: Xin Chen, Ming-Jun Li, Simit Mayank Patel
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Publication number: 20230110293Abstract: A method of categorizing a group of multimode optical fibers, the method including comparing an effective modal bandwidth of a first multimode optical fiber with a first threshold, the first multimode optical fiber being in a group of multimode optical fibers meeting a first OM-standard and the first threshold being an effective modal bandwidth of the first multimode optical fiber. The method further including categorizing the first multimode optical fiber as meeting OM functional requirements of a second OM-standard if the effective modal bandwidth of the first multimode optical fiber is equal to or above the first threshold, wherein the second OM-standard is higher than the first OM-standard.Type: ApplicationFiled: September 15, 2022Publication date: April 13, 2023Inventors: Xin Chen, Kangmei Li, Ming-Jun Li, Simit Mayank Patel
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Publication number: 20230094509Abstract: Methods for classifying a core cane of an multimode optical fiber are disclosed. In embodiments, the method includes determining a relative refractive index profile ?(r) of the core cane; fitting the relative refractive index profile ?(r) to an alpha profile ?fit(r) defined by: ? fit ( r ) = ? o , fit ( 1 - ( r a fit ) ? fit ) where ?o,fit is a relative refractive index at a longitudinal centerline of the core cane, ?fit is a core shape parameter, and afit is an outer radius of the core cane; generating a non-alpha residual profile ?diff(r)=?(r)??fit(r) for the core cane; computing one or more metrics from ?diff(r), and using the one or metrics in a classification of the core cane, the classification comprising a prediction of whether a bandwidth at a pre-determined wavelength of an optical fiber drawn from a preform comprising the core cane exceeds a pre-determined bandwidth at the pre-determined wavelength.Type: ApplicationFiled: September 23, 2022Publication date: March 30, 2023Inventors: John Steele Abbott, III, Scott Robertson Bickham, Amanda Lee Billings, Ian David Cook, Simit Mayank Patel
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Patent number: 11530157Abstract: A method of manufacturing a tuned optical fiber includes providing a first preform from a set of like preforms each having substantially the same refractive index profile, including amount of axial variation relative to a target refractive index profile. The method includes drawing a reference optical fiber from the first preform and measuring a variation in an optical or physical property as a function of axial position. The method also includes drawing from a second preform from the set of like preforms the tuned optical fiber. The drawing includes using a time-varying tension that reduces the amount of variation of the optical or physical property of interest. The time-varying tension is defined by an amount of axial stress imparted to the tuned fiber needed to alter the refractive index profile and the at least one optical or physical property based on a stress-optic effect.Type: GrantFiled: May 11, 2020Date of Patent: December 20, 2022Assignee: Corning IncorporatedInventors: Sean Nicole DeMass, Simit Mayank Patel, Pushkar Tandon
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Patent number: 11327223Abstract: A multimode optical fiber having a core region. The core region includes silica, has an outer radius r1, and has a maximum relative refractive index of about 1.5% or less. Additionally, the multimode optical fiber is configured to have an effective bandwidth of about 4.7 GHz-Km or greater for an excited portion of the core region that has a diameter greater than 50 microns, the effective bandwidth being at a wavelength that is within a range of between about 800 and about 1370 nm.Type: GrantFiled: March 29, 2021Date of Patent: May 10, 2022Assignee: Corning IncorporatedInventors: Xin Chen, Kangmei Li, Ming-Jun Li, Anping Liu, Simit Mayank Patel, Jeffery Scott Stone
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Publication number: 20210325599Abstract: A multimode optical fiber having a core region. The core region includes silica, has an outer radius r1, and has a maximum relative refractive index of about 1.5% or less. Additionally, the multimode optical fiber is configured to have an effective bandwidth of about 4.7 GHz-Km or greater for an excited portion of the core region that has a diameter greater than 50 microns, the effective bandwidth being at a wavelength that is within a range of between about 800 and about 1370 nm.Type: ApplicationFiled: March 29, 2021Publication date: October 21, 2021Inventors: Xin Chen, Kangmei Li, Ming-Jun Li, Anping Liu, Simit Mayank Patel, Jeffery Scott Stone
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Publication number: 20210208332Abstract: A method of manufacturing a multimode optical fiber includes specifying a peak wavelength ?P for the multimode optical fiber. The peak wavelength ?P corresponds to a wavelength at which the multimode optical fiber has a maximum bandwidth. The multimode optical fiber comprises a core and a cladding surrounding and directly adjacent to the core. The core has a radius r1 and a maximum relative refractive index ?1,MAX>0. The cladding comprises a depressed-index region having a minimum relative refractive index ?3,MIN<0 and a volume v. A draw tension T for the multimode optical fiber is selected based on a correlation relating peak wavelength ?P to draw tension T, the correlation comprising a correlation constant. The correlation constant K is a function of at least one of ?1,MAX, r1, v, ?3,MIN, and ?P. The multimode optical fiber is drawn from a preform at the draw tension T.Type: ApplicationFiled: December 14, 2020Publication date: July 8, 2021Inventors: Xin Chen, Ming-Jun Li, Simit Mayank Patel
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Publication number: 20200361809Abstract: A method of manufacturing a tuned optical fiber includes providing a first preform from a set of like preforms each having substantially the same refractive index profile, including amount of axial variation relative to a target refractive index profile. The method includes drawing a reference optical fiber from the first preform and measuring a variation in an optical or physical property as a function of axial position. The method also includes drawing from a second preform from the set of like preforms the tuned optical fiber. The drawing includes using a time-varying tension that reduces the amount of variation of the optical or physical property of interest. The time-varying tension is defined by an amount of axial stress imparted to the tuned fiber needed to alter the refractive index profile and the at least one optical or physical property based on a stress-optic effect.Type: ApplicationFiled: May 11, 2020Publication date: November 19, 2020Inventors: Sean Nicole DeMass, Simit Mayank Patel, Pushkar Tandon
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Patent number: 9841559Abstract: An optical fiber including a multimode core having a radius, R1, and a maximum relative refractive index, ?1MAX, at a wavelength ?0, an inner clad layer surrounding the core and having a radial thickness, T2, and a minimum relative refractive index, ?2MIN, of about 0.0% at a wavelength of ?0, an intermediate clad layer surrounding the inner clad layer and having a radial thickness, T3, and a maximum relative refractive index ?3MAX and an outer clad layer surrounding the inner clad layer and having a radial thickness, T4, and a maximum relative refractive index, ?4MIN, at a wavelength of ?0. The optical fiber satisfies the following relationship: ?1MAX>?3MAX>?2MIN, and the optical fiber exhibits an overfilled bandwidth of greater than or equal to about 1.5 GHz-km at ?0.Type: GrantFiled: February 10, 2017Date of Patent: December 12, 2017Assignee: Corning IncorporatedInventors: Snigdharaj Kumar Mishra, Oleksandr Kogan, Simit Mayank Patel, Elios Klemo, Daniel J Halvorson
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Publication number: 20170242186Abstract: An optical fiber including a multimode core having a radius, R1, and a maximum relative refractive index, ?1MAX, at a wavelength ?0, an inner clad layer surrounding the core and having a radial thickness, T2, and a minimum relative refractive index, ?2MIN, of about 0.0% at a wavelength of ?0, an intermediate clad layer surrounding the inner clad layer and having a radial thickness, T3, and a maximum relative refractive index ?3MAX and an outer clad layer surrounding the inner clad layer and having a radial thickness, T4, and a maximum relative refractive index, ?4MIN, at a wavelength of ?0. The optical fiber satisfies the following relationship: ?1MAX>?3MAX>?2MIN, and the optical fiber exhibits an overfilled bandwidth of greater than or equal to about 1.5 GHz-km at ?0.Type: ApplicationFiled: February 10, 2017Publication date: August 24, 2017Inventors: Snigdharaj Kumar Mishra, Oleksandr Kogan, Simit Mayank Patel, Elios Klemo, Daniel J. Halvorson