Optical fiber light tap
First Claim
1. A light tap for use in an optical communications system including a source of an optical signal and a first optical fiber to transmit said signal, said light tap comprising:
- (a) a segment of said first optical fiber having a first planar endface intersecting the longitudinal axis of said first fiber at an angle of α
;
(b) a second optical fiber in substantially coaxial alignment with said segment and having a second planar endface intersecting the longitudinal axis of said second fiber at an angle of (180 degrees -α
), said first and second endfaces being adjacent to each other and forming a gap therebetween;
(c) a dielectric film filling said gap which has a different refractive index than said first and second fibers; and
(d) means disposed between said source and said first endface for exciting a steady-state mode distribution of said signal.
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Accused Products
Abstract
An optical fiber tap is described which comprises a beamsplitter formed by positioning bevelled, parallel endfaces of two segments of optical fiber in coaxial alignment and in close proximity to each other. A suitable dielectric film, such as air, fills the gap between the endfaces. Light propagating into the tap from the first fiber segment is partially reflected and partially refracted at the bevelled endfaces. The refracted portion enters the second fiber segment and the reflected portion leaves the tap and is detected by a photodetector. By choice of the proper angle for the bevelled endfaces, the tap can be made substantially mode independent. A greater degree of mode independence can be obtained by interposing a steady-state mode exciter between the light source and the beamsplitter. The tap is particularly useful for semiconductor junction laser stabilization by the feedback arrangement described herein since the ratio of the intensity of the reflected portion to that of the refracted portion is substantially constant. A package assembly for use in the feedback arrangement is also described.
116 Citations
10 Claims
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1. A light tap for use in an optical communications system including a source of an optical signal and a first optical fiber to transmit said signal, said light tap comprising:
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(a) a segment of said first optical fiber having a first planar endface intersecting the longitudinal axis of said first fiber at an angle of α
;(b) a second optical fiber in substantially coaxial alignment with said segment and having a second planar endface intersecting the longitudinal axis of said second fiber at an angle of (180 degrees -α
), said first and second endfaces being adjacent to each other and forming a gap therebetween;(c) a dielectric film filling said gap which has a different refractive index than said first and second fibers; and (d) means disposed between said source and said first endface for exciting a steady-state mode distribution of said signal. - View Dependent Claims (2, 3, 4)
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5. In an optical communications system including a semiconductor junction laser as a source of an optical signal and a first optical fiber to transmit said signal, an arrangement for feedback stabilization of said laser so that the intensity of the optical signal propagating through said system remains substantially constant in time, said arrangement comprising:
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(a) a segment of said first optical fiber having a first planar endface intersecting the longitudinal axis of said first fiber at an angle of α
;(b) a second optical fiber in substantial coaxial alignment with said segment and having a second planar endface intersecting the longitudinal axis of said second fiber at an angle of (180 degrees -α
), said first and second endfaces being adjacent to each other and forming a gap therebetween;(c) a dielectric film disposed in said gap which has a difference in refractive index relative to said first and second fibers such that said optical signal is split into a portion which is refracted into said second optical fiber and another portion which is reflected in a direction transverse to the axis of said first and second fibers; (d) means for detecting the intensity of said reflected portion and converting said intensity into an electrical signal; and (e) means for controlling said laser in response to said electrical signal. - View Dependent Claims (6, 7, 8, 9, 10)
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Specification