Variable optical power limiter
First Claim
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1. An apparatus, comprising:
- an optical waveguide including a slab region and a rib region formed from a layer of substrate semiconductor material, wherein the rib region includes intrinsic silicon, an optical beam to be directed through the optical waveguide such that the optical beam propagates through the intrinsic silicon of the rib region, the optical beam to generate free carriers in the optical waveguide via two-photon absorption in response to an input power level of the optical beam; and
a reversed-biased PIN diode structure disposed in the optical waveguide, the reverse-biased PIN diode structure including an electric field between a P region and an N region of the reverse-biased PIN diode structure to sweep out free carriers from the optical waveguide to control free carrier lifetimes of the free carriers in the optical waveguide to limit an output power of the optical beam to a clamped output power level in response to the electric field of the reverse biased diode structure such that substantially all of the optical beam propagates through the optical waveguide when the input power level of the optical beam is substantially less than the clamped output power level and such that the output power of the optical beam is clamped to the clamped output power level when the input power level is greater than the clamped output power level, wherein the intrinsic silicon of rib region is disposed directly on intrinsic silicon of the slab region without a layer of dielectric material intervening between the intrinsic silicon of the rib region and the intrinsic silicon of the slab region.
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Abstract
A variable optical power limiter is disclosed. An apparatus according to aspects of the present invention includes an optical waveguide disposed in semiconductor material. An optical beam is to be directed through the optical waveguide. The optical beam is to generate free carriers in the optical waveguide via two-photon absorption in response to an input power level of the optical beam. A diode structure is disposed in the optical waveguide. The diode structure is coupled to be biased to control free carrier lifetimes of the free carriers in the optical waveguide to set an output power of the optical beam to a clamped output power level in response to the bias of the diode structure.
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Citations
13 Claims
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1. An apparatus, comprising:
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an optical waveguide including a slab region and a rib region formed from a layer of substrate semiconductor material, wherein the rib region includes intrinsic silicon, an optical beam to be directed through the optical waveguide such that the optical beam propagates through the intrinsic silicon of the rib region, the optical beam to generate free carriers in the optical waveguide via two-photon absorption in response to an input power level of the optical beam; and a reversed-biased PIN diode structure disposed in the optical waveguide, the reverse-biased PIN diode structure including an electric field between a P region and an N region of the reverse-biased PIN diode structure to sweep out free carriers from the optical waveguide to control free carrier lifetimes of the free carriers in the optical waveguide to limit an output power of the optical beam to a clamped output power level in response to the electric field of the reverse biased diode structure such that substantially all of the optical beam propagates through the optical waveguide when the input power level of the optical beam is substantially less than the clamped output power level and such that the output power of the optical beam is clamped to the clamped output power level when the input power level is greater than the clamped output power level, wherein the intrinsic silicon of rib region is disposed directly on intrinsic silicon of the slab region without a layer of dielectric material intervening between the intrinsic silicon of the rib region and the intrinsic silicon of the slab region. - View Dependent Claims (2, 3, 4, 5, 6, 7)
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8. A system, comprising:
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optical waveguide including a slab region and a rib region formed from a layer of substrate semiconductor material, wherein the rib region includes intrinsic silicon, an optical beam to be directed through the optical waveguide such that the optical beam propagates through the intrinsic silicon of the rib region, the optical beam to generate free carriers in the optical waveguide via two-photon absorption in response to an input power level of the optical beam; a reverse-biased PIN diode structure disposed in the optical waveguide, the reverse-biased PIN diode structure including an electric field between a P region and an N region of the reverse-biased diode structure to sweep out free carriers from the optical waveguide to control free carrier lifetimes of the free carriers in the optical waveguide to limit an output power of the optical beam to a clamped output power level in response to the electric field of the reverse biased PIN diode structure such that substantially all of the optical beam propagates through the optical waveguide when the input power level of the optical beam is substantially less than the clamped output power level and such that the output power of the optical beam is clamped to the clamped output power level when the input power level is greater than the clamped output power level, wherein the intrinsic silicon of rib region is disposed directly on intrinsic silicon of the slab region without a layer of dielectric material intervening between the intrinsic silicon of the rib region and the intrinsic silicon of the slab region; an optical fiber optically coupled to receive the optical beam from the optical waveguide; and an optical receiver optically coupled to receive the optical beam from the optical waveguide through the optical fiber. - View Dependent Claims (9, 10, 11)
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12. An optical power limiter, comprising:
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a layer of substrate semiconductor material; an optical waveguide including a slab region and a rib region formed from the layer of substrate semiconductor material, wherein the rib region and the slab region each include intrinsic silicon, wherein the optical waveguide is configured such that an optical beam is to be directed through the intrinsic silicon of the rib region and through the intrinsic silicon of the slab region to generate free carriers in the optical waveguide via two-photon absorption in response to an input power level of the optical beam; and a PIN diode structure coupled to be reverse-biased and disposed in the optical waveguide, the PIN diode structure including a P region, an N region, and the intrinsic silicon of the slab region, wherein the P region and the N region are disposed at opposite lateral sides of the slab region and on opposite lateral sides of the intrinsic silicon of the slab region, wherein an electric field is to be created between a P region and an N region to sweep out free carriers from the optical waveguide to control free carrier lifetimes of the free carriers in the optical waveguide to limit an output power of the optical beam to a clamped output power level in response to the electric field of the PIN diode structure when reverse-biased, wherein the intrinsic silicon of rib region is disposed directly on the intrinsic silicon of the slab region without a layer of dielectric material intervening between the intrinsic silicon of the rib region and the intrinsic silicon of the slab region. - View Dependent Claims (13)
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Specification