Patents by Inventor Nikolai Platonov
Nikolai Platonov 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: 20240136783Abstract: A laser system is configured with at least one light amplifying device sequentially outputting a light signal at first and at least one additional operating wavelengths over respective time intervals. Each time interval is shorter than the predetermined lifespan of the light amplifying device. The total useful life of the light amplifying device, operating at a plurality of wavelengths, is 3-10 times longer than the predetermined lifespan.Type: ApplicationFiled: June 7, 2022Publication date: April 25, 2024Applicant: IPG PHOTONICS CORPORATIONInventors: Alexey Avdokhin, Nikolai Platonov, Pankaj Kadwani, Jimyung Kim
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Patent number: 8781272Abstract: A monolithic fiber has a double bottleneck-shaped core configured with opposite uniformly configured end regions, frustoconical transformer regions which run inwards from the respective end regions, and a central uniformly-dimensioned region which bridges the transformer regions. The core is configured as a multimode core or single-mode core and capable of guiding a single transverse mode between the end regions without splice losses.Type: GrantFiled: August 24, 2012Date of Patent: July 15, 2014Assignee: IPG Photonics CorporationInventors: Valentin P. Gapontsev, Valentin Fomin, Nikolai Platonov, Mikhall Vyatkin
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Patent number: 8655121Abstract: A high power single mode fiber laser system has a monolithic active fiber configured with a double bottleneck-shaped multimode (MM) core which is capable of supporting substantially only a fundamental mode at a given wavelength. The core has opposite uniformly configured end regions, frustoconical transformer regions running inwards from the respective end regions, and a central uniformly-dimensioned region which bridges the transformer regions. The MM core is configured with a refractive step-index profile which includes a continuous dip configured to shape an intensity field of the fundamental mode from a Gaussian or dome-shaped field profile to a two-peak-shaped profile and back to the Gaussian filed profile.Type: GrantFiled: October 20, 2011Date of Patent: February 18, 2014Assignee: IPG Photonics CorporationInventors: Valentin P Gapontsev, Nikolai Platonov, Valentin Fomin, Michael Vyatkin
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Publication number: 20130034326Abstract: A monolithic fiber has a double bottleneck-shaped core configured with opposite uniformly configured end regions, frustoconical transformer regions which run inwards from the respective end regions, and a central uniformly-dimensioned region which bridges the transformer regions. The core is configured as a multimode core or single-mode core and capable of guiding a single transverse mode between the end regions without splice losses.Type: ApplicationFiled: August 24, 2012Publication date: February 7, 2013Inventors: Valentin P. Gapontsev, Valentin Fomin, Nikolai Platonov, Mikhall Vyatkin
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Publication number: 20120269209Abstract: A high power single mode fiber laser system has a monolithic active fiber configured with a double bottleneck-shaped multimode (MM) core which is capable of supporting substantially only a fundamental mode at a given wavelength. The core has opposite uniformly configured end regions, frustoconical transformer regions running inwards from the respective end regions, and a central uniformly-dimensioned region which bridges the transformer regions. The MM core is configured with a refractive step-index profile which includes a continuous dip configured to shape an intensity field of the fundamental mode from a Gaussian or dome-shaped field profile to a two-peak-shaped profile and back to the Gaussian filed profile.Type: ApplicationFiled: October 20, 2011Publication date: October 25, 2012Applicant: IPG Photonics CorporationInventors: Valentin P. Gapontsev, Valentin Fomin, Nikolai Platonov, Mikhail Vyatkin
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Patent number: 8285101Abstract: Optical fiber apparatus having a wavelength of operation, that comprises an optical fiber including a core comprising an active material for providing light having the operating wavelength responsive to the optical apparatus receiving pump optical energy having a pump wavelength; a cladding disposed about the core; at least one region spaced from the core; and wherein the optical fiber is configured and arranged such that at the wavelength of operation the optical fiber can propagate a plurality of modes and wherein the optical fiber comprises a fundamental mode that is primarily a mode of the core and at least one higher order mode (HOM) that is a mixed mode of a selected mode of the core and of a selected mode of the at least one region.Type: GrantFiled: October 15, 2009Date of Patent: October 9, 2012Assignee: IPG Photonics CorporationInventors: Valentin P Gapontsev, Nikolai Platonov, Roman Yagodkin, Volodia Sergueev
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Patent number: 8204349Abstract: Optical apparatus, comprising an optical fiber having a wavelength of operation, the optical fiber comprising an inner core, the inner core supporting a fundamental mode and at least first and second higher order modes (HOMs) at the wavelength of operation; a first ring-shaped core region spaced from and disposed about the inner core; a second ring-shaped core region spaced from and disposed about the ring-shaped core region; and wherein the optical fiber is configured and arranged such that the first HOM optically interacts with the first ring-shaped core region and the second HOM optically interacts with the second ring-shaped core region.Type: GrantFiled: October 28, 2009Date of Patent: June 19, 2012Assignee: IPG Photonics CorporationInventors: Valentin P Gapontsev, Nikolai Platonov, Roman Yagodkin, Volodia Sergueev
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Patent number: 8139912Abstract: An optical fiber apparatus having a wavelength of operation comprises an optical fiber comprising a core; a pump cladding disposed about the core for receiving pump optical energy having a pump wavelength; and a second cladding disposed about for tending to confine pump optical energy to the pump cladding. The core can comprise a rare earth material for providing optical energy having the wavelength of operation responsive to the optical fiber receiving the pump optical energy, and the fiber can further comprise at least one ring core spaced from the core, the ring core defined by inner and outer diameters and comprising the cross sectional area therebetween. The ring core can comprise an absorbing material for absorbing optical energy having the wavelength of operation.Type: GrantFiled: October 16, 2009Date of Patent: March 20, 2012Assignee: IPG Photonics CorporationInventors: Valentin P Gapontsev, Nikolai Platonov, Roman Yagodkin, Volodia Sergueev
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Patent number: 8081667Abstract: A high power single mode fiber laser system is configured with an active fiber including coextending multimode core (MM) and cladding around the MM core. The MM core is doped with one or more ions selected from rare earth and transitional metals and has a bottleneck cross in accordance with one aspect of the disclosure. The bottleneck cross-section includes a relatively small uniformly dimensioned input end region, a frustoconical region and a relatively large uniformly dimensioned amplifying region. The refractive step index of the MM core is configured with a central dip shaped and dimensioned along the input region so as not to disturb a Gaussian field profile of fundamental mode, gradually transform the Gaussian field profile into the ring profile of the fundamental mode and support the latter along the amplifying region.Type: GrantFiled: December 3, 2009Date of Patent: December 20, 2011Inventors: Valentin P. Gapontsev, Nikolai Platonov, Valentin Fomin, Michael Vyatkin
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Patent number: 8068705Abstract: A monolithic fiber is configured with a double bottleneck-shaped multimode (MM) core capable of supporting substantially only a fundamental mode at a given wavelength and having opposite end regions, frustoconically shaped transformer regions, which run inwards from the respective end regions, and a central uniformly dimensioned region, which bridges the transformer regions. The MM core has a refractive step-index profile which is configured with a centrally positioned dip having a variable width along the length of the fiber. The width of the dip is relatively small at the end regions of the MM core so as to support only the fundamental mode with a Gaussian profile. As the dip becomes larger along the input transformer region, it gradually shapes the Gaussian profile into the ring profile of the fundamental mode, which is guided along the central region of the MM core.Type: GrantFiled: September 14, 2009Date of Patent: November 29, 2011Inventors: Valentin P. Gapontsev, Valentin Fomin, Nikolai Platonov, Mikhall Vyatkin
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Publication number: 20110097049Abstract: Optical apparatus, comprising an optical fiber having a wavelength of operation, the optical fiber comprising an inner core, the inner core supporting a fundamental mode and at least first and second higher order modes (HOMs) at the wavelength of operation; a first ring-shaped core region spaced from and disposed about the inner core; a second ring-shaped core region spaced from and disposed about the ring-shaped core region; and wherein the optical fiber is configured and arranged such that the first HOM optically interacts with the first ring-shaped core region and the second HOM optically interacts with the second ring-shaped core region.Type: ApplicationFiled: October 28, 2009Publication date: April 28, 2011Applicant: IPG Photonics CorporationInventors: Valentin P. Gapontsev, Vladimir Sergueev, Nikolai Platonov, Roman Yagodkin
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Publication number: 20110091178Abstract: An optical fiber apparatus having a wavelength of operatic comprises an optical fiber comprising a core; a pump cladding disposed about the core for receiving pump optical energy having a pump wavelength; and a second cladding disposed about for tending to confine pump optical energy to the pump cladding. The core can comprise a rare earth material for providing optical energy having the wavelength of operation responsive to the optical fiber receiving the pump optical energy, and the fiber can further comprise at least one ring core spaced from the core, the ring core defined by inner and outer diameters and comprising the cross sectional area therebetween. The ring core can comprise an absorbing material for absorbing optical energy having the wavelength of operation.Type: ApplicationFiled: October 16, 2009Publication date: April 21, 2011Applicant: IPG Photonics CorporationInventors: Valentin P. Gapontsev, Vladimir Sergueev, Nikolai Platonov, Roman Yagodkin
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Publication number: 20110091177Abstract: Optical fiber apparatus having a wavelength of operation, that comprises an optical fiber including a core comprising an active material for providing light having the operating wavelength responsive to the optical apparatus receiving pump optical energy having a pump wavelength; a cladding disposed about the core; at least one region spaced from the core; and wherein the optical fiber is configured and arranged such that at the wavelength of operation the optical fiber can propagate a plurality of modes and wherein the optical fiber comprises a fundamental mode that is primarily a mode of the core and at least one higher order mode (HOM) that is a mixed mode of a selected mode of the core and of a selected mode of the at least one region.Type: ApplicationFiled: October 15, 2009Publication date: April 21, 2011Applicant: IPG Photonics CorporationInventors: Valentin P. Gapontsev, Vladimir Sergueev, Nikolai Platonov, Roman Yagodkin
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Publication number: 20110064097Abstract: A high power single mode fiber laser system is configured with an active fiber including coextending multimode core (MM) and cladding around the MM core. The MM core is doped with one or more ions selected from rare earth and transitional metals and has a bottleneck cross in accordance with one aspect of the disclosure. The bottleneck cross-section includes a relatively small uniformly dimensioned input end region, a frustoconical region and a relatively large uniformly dimensioned amplifying region. The refractive step index of the MM core is configured with a central dip shaped and dimensioned along the input region so as not to disturb a Gaussian field profile of fundamental mode, gradually transform the Gaussian field profile into the ring profile of the fundamental mode and support the latter along the amplifying region.Type: ApplicationFiled: December 3, 2009Publication date: March 17, 2011Applicant: IPG Photonics CorporationInventors: Valentin P. Gapontsev, Nikolai Platonov, Valentin Fomin, Michael Vyatkin
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Publication number: 20110064095Abstract: A monolithic fiber is configured with a double bottleneck-shaped multimode (MM) core capable of supporting substantially only a fundamental mode at a given wavelength and having opposite end regions, frustoconically shaped transformer regions, which run inwards from the respective end regions, and a central uniformly dimensioned region, which bridges the transformer regions. The MM core has a refractive step-index profile which is configured with a centrally positioned dip having a variable width along the length of the fiber. The width of the dip is relatively small at the end regions of the MM core so as to support only the fundamental mode with a Gaussian profile. As the dip becomes larger along the input transformer region, it gradually shapes the Gaussian profile into the ring profile of the fundamental mode, which is guided along the central region of the MM core.Type: ApplicationFiled: September 14, 2009Publication date: March 17, 2011Applicant: IPG Photonics CorporationInventors: Valentin P. Gapontsev, Valentin Fomin, Nikolai Platonov, Mikhall Vyatkin
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Publication number: 20100247912Abstract: A method of producing a large mode area optical preform includes selecting a preexisting rod and at least one preexisting outer tube. The rod and tube are selected so that a difference between respective indices of refraction is uniform and lies within the desired range, and a ratio between respective rod and tube diameters is within the desired range after the rod is inserted into the tube and both are thermally treated. The predetermined ranges are selected to provide mass production of a large mode area fiber with the desired physical and geometrical characteristics.Type: ApplicationFiled: March 24, 2009Publication date: September 30, 2010Inventors: Valentin P. Gapontsev, Volodia Sergueev, Nikolai Platonov
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Publication number: 20100061410Abstract: An optical system includes a launching component radiating a beam of light at a fixed power, a specialty component, which receives the beam and is configured with a transverse mode field diameter different from that one of the launching component, and a focusing component substantially losslessly coupled to the launching and receiving components. The focusing component is configured so that the effective area of mode at the input of the receiving component determines the intensity of light inducing at least one nonlinear effect at the desired threshold.Type: ApplicationFiled: September 11, 2008Publication date: March 11, 2010Inventors: Nikolai Platonov, Alex Yusim, Oleg Shkurikhin, Anton Drozhzhin
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Patent number: 7593435Abstract: A powerful fiber laser system is configured with at least one large-area multi-clad rare-earth doped fiber, which is configured with a MM core capable of propagating a single mode laser emission at a first wavelength, and with at least one pumping assembly capable of generating an optical pump output at a wavelength shorter than the first wavelength of the rare-earth doped fiber. The pumping assembly has a plurality SM fiber lasers coupled to a SM-MM combiner which is operative to lunch the pump output into the cladding of the rare-earth doped fiber so that the powerful fiber laser system is operative to deliver a power of up to 20 kW.Type: GrantFiled: October 9, 2007Date of Patent: September 22, 2009Assignee: IPG Photonics CorporationInventors: Valentin P. Gapontsev, Valentin Fomin, Nikolai Platonov