Abstract: A light source system for fiberoptic networks is presented. The system has a laser light source, an optical circulator, an optical fiber section having at least one fiber Bragg grating, and an output port. The optical circulator receives light through its first port and passes the light to the circulator's second port and light received through the second port is passed to the circulator's third port. The first port is connected to the light source. The optical fiber section is connected to the second port and the fiber Bragg grating has a reflectivity centered about a predetermined wavelength. The third port, which is unconnected to the light source, is connected to the output port of the system. Light from the output port has the predetermined wavelength with significantly reduced ASE.

Abstract: A compact, high-performance WDM coupler which couples at least three optical fibers is presented. The coupler has the ends of first, second and third optical fibers near a first face of a collimating lens. A wavelength-dependent filter, such as a long-pass filter, a short-pass filter or a band-pass filter, is located near the opposite face of the collimating lens. The wavelength-dependent filter and the ends of the first and second optical fibers are arranged with respect to each other so that light from the first optical fiber and reflected by the wavelength-dependent filter passes into the second optical fiber. Light which passes through the wavelength-dependent filter remains collimated by the collimated lens. Reflecting elements or a second collimating lens in focus with the end(s) of one or more optical fibers can placed next to the wavelength-dependent filter and on the other side of the collimating lens to create variations of the WDM coupler for many applications.

Abstract: The present invention provides fiber optic couplers for use with at least three optic fibers. The optic fibers arranged in a linear array, that is, the optic fibers are coupled side by side. The fibers along either end of the linear-array are coupled only to a single fiber, while the remaining fibers are generally coupled between only two adjacent fibers. Generally, at least one of the fibers has a propagation constant different than the other fibers. Such variations in the propagation constant are used to vary the coupling coefficients among the fibers of the linear-array, thereby providing a repeatable mechanism, to vary coupled power ratios among the fibers of the coupler. Theoretical calculations and empirical experience have shown that varying the propagation constant of fibers among a linear-array, generally by pre-pulling the fibers by varying amounts, allows repeatable manufacturing of 1.times.3, 3.times.3, 1.times.4, 4.times.4, 1.times.N and even N.times.

Abstract: The present invention provides for a fiberoptic connector device which has low back reflection with little increase in insertion loss. The connector device includes an end section of the optical fiber, a ferrule holding the end section, an optical fiber section in the ferrule, and a housing holding the ferrule. The end of the optical fiber terminates in the ferrule and the optical fiber section is coaxially aligned with the end section in the ferrule between the end of the optical fiber and an end of the ferrule. The optical fiber section has one end in close proximity to the end of the optical fiber and its other end terminates with the end of the ferrule. The end of the optical fiber is slanted and covered with antireflection material. The proximate end of the optical fiber section is slanted reciprocally and also covered with antireflection material.

Abstract: Multiplexer and demultiplexer devices for Dense WDM networks are described. The devices use an optical circulator, a plurality of bandpass wavelength division units and fiber Bragg gratings arranged in the optical fibers interconnecting the optical circulator and the bandpass wavelength division units. The optical circulator is connected to a network optical fiber and the bandpass wavelength division units are connected to a plurality of input/output optical fibers. Each fiber Bragg grating has a narrow wavelength reflection band about a predetermined wavelength and is arranged so that optical signals at wavelengths differing from predetermined wavelengths of the first optical fibers connected to a bandpass wavelength division unit are blocked and reflected. Depending upon the direction of the optical circulator, the device may be a multiplexer or a demultiplexer. Alternatively, a 3dB optical coupler may be used in place of the optical circulator with a corresponding rearrangement of the fiber Bragg gratings.

Abstract: The present invention provides improved optic switches in which the optic fibers and optical pathways need not move. Advantageously, the switches of the present invention generally rely on a combination of a moveable reflective element and at least one fixed collimating lens. The collimating lens typically expands the light signal from a single mode fiber to a substantially larger optic path. When the reflective element is disposed out of this large optic path, the light signals continue on to a first output fiber, often through another collimating lens. However, when the reflective element is disposed within the expanded optic path from the collimating lens, the signal is reflected back through that same collimating lens into an alternative output fiber which is parallel and in close proximity to the input fiber. Conveniently, the reflective element can move across the optic path without changing the position of the input or output fibers relative to each other.

Abstract: Collimated light from two input fibers are directed against the interface of a beam splitter cube formed by two right-angle prisms. Light transmitted through, or reflected by, depends upon the polarization of the incoming light. A collimator subassembly for an output fiber receives light from the beam splitter cube. Polarization of the incoming light is controlled by orientation of the optical axes of one or two liquid crystal cells placed between each input fiber and beam splitter cube. By controlling the optical axes of the liquid crystal cells light from the two input fibers can be sent to the output fiber in any desired ratio. By rearranging the optical fibers, right-angle prisms and liquid crystal cells, a variable polarization beam combiner can be formed.

Abstract: The present invention provides for an improved package for a laser diode. The package has portions of its inner surfaces covered with a non-reflecting material, such as simple black paint, non-reflective metals or specific anti-reflection coatings. Such non-reflecting materials surprisingly enhances the performance of packaged laser diodes used as pumping lasers for fiber amplifiers, for example.

Abstract: The present invention provides for a reduced isolator assembly having only two elements for a linearly polarized light source. The first element may be a birefringent crystal or a linear polarizer, such as a linear polarizer sheet, a laminated thin-film polarizer, or a polarizing beam splitter. The second element is a quarter-wave plate. The isolator blocks the light reflected back toward the polarized light source.

Abstract: An improved optical attenuator minimizes polarization mode dispersion in optical signals carried by optical fiber systems. The optical signals are expanded and refocussed by GRIN lenses, and the attenuator makes use of a liquid crystal cell disposed between birefringent polarizers for polarization-independent attenuation or switching. A birefringent plate compensates for dispersion of the ordinary and extra-ordinary rays within the attenuator. The plate will often be disposed at an oblique angle to minimize walk-off between these rays.

Abstract: A laser diode package assembly is described. Besides a laser diode, the package assembly has an optical fiber section having an end located to receive the light output from the laser diode. The optical fiber section also has a fiber grating designed to operate as a bandpass filter. The fiber grating inside the package assembly not only narrows the output wavelength from the laser diode, but also increases the lifetime of the laser diode.

Abstract: An optical isolator array is presented. The array has a substrate with parallel grooves and a groove perpendicular to the parallel grooves to separate them. First sleeves each holding an end section of a first optical fiber and a first collimating element are fixed in the parallel grooves on one side of the perpendicular groove. Second sleeves each holding an end section of a second optical fiber and a second collimating element are fixed in the parallel grooves on the other side of the perpendicular groove. An optical isolator core subassembly having first and second strips of birefringent polarizer material, and a strip of Faraday rotator material between the first and second strips of birefringent polarizer materials is fixed in the perpendicular groove.

Abstract: A semiconductor laser source having a laser diode and a fiber Bragg grating is described. The laser diode has first and second facets from which output light is emitted. A first end of the fiber Bragg grating is located near the second facet to receive output light from the laser diode. The fiber Bragg grating has a very narrow linewidth about a selected wavelength and reflects output light in the selected narrow linewidth back into the laser diode through its second facet. The output light emitted from the first facet has a very narrow linewidth about the selected linewidth.

Abstract: An improved polarization beam splitter formed by a collimator and two similarly shaped, birefringent crystal prisms is provided. The light from the collimator is incident upon the first face of the first birefringent crystal prism which also has second and third faces. The collimated light is incident upon the second face at an angle .phi. with respect to a line normal to the second face so that light polarized perpendicular to a plane of incidence upon the second face is reflected toward the third face and light polarized in the plane of incidence is refracted at the second face. The second birefringent crystal prism has a second face parallel to, and in close proximity with, the second face of the first birefringent prism so that light refracted at the second face of said first prism is refracted at the second face of the second prism and into the second prism.

Abstract: Assemblies having a first optical circulator, a pumping laser, a rare-earth doped fiber and a first coupler are described. The first coupler has a first fiber connected to the optical circulator, a second fiber connected to said pumping laser, and a third fiber connected to one end of the rare-earth doped fiber which is operated as a fiber amplifier. The coupler blocks the pumping laser light from the first fiber and reflects the light into the third fiber. The coupler further transmits the input signals from the first fiber into the third fiber. This arrangement allows the rare-earth doped fiber to amplify the input signals from the energy of the pumping laser light. By changing the elements connected to the second end of the rare-earth doped fiber, optical fiber amplifier assemblies in which the message signals are amplified by passing through the rare-earth doped fiber twice, by pumping the rare-earth doped fiber with two pumping lasers, or both, are provided for.

Abstract: A compact optical circulator which can be expanded into a large number of optical ports is provided. For each port, the circulator has an optical port assembly which has an end of an optical fiber, a collimator subassembly and a birefringent crystal. The collimator subassembly collimates light from the optical fiber end into a beam of collimated light and focusses a beam of collimated light to the optical fiber end in a reverse direction. The birefringent crystal is dimensioned and arranged with respect to the collimator subassembly to split the collimated light beam from the collimator subassembly into two parallel beams of light linearly polarized perpendicularly to each other, and to combine parallel beams of light linearly polarized perpendicularly to each other in the reverse direction into a beam of collimated light toward the collimator subassembly.

Abstract: A high performance optical circulator is formed by a polarization beam splitter and optical port assemblies. The polarization beam splitter is formed by two prisms with an interface between the prisms. The interface transmits linearly polarized light directed at the interface in directions responsive to a polarization orientation of linearly polarized light. The optical port assemblies are arranged with respect to the polarization beam splitter so that light from one port assembly is transmitted by the polarization beam splitter interface to another optical port assembly and light from this optical port assembly is transmitted by the beam splitter interface to still another optical port assembly.

Abstract: A fiberoptic coupler capable of many functions is presented. The basic fiberoptic coupler has a first sleeve, a second sleeve, a first collimating GRIN or conventional lens, and a second collimating GRIN or conventional lens. The first sleeve holds end sections of two or more input optical fibers along the longitudinal axis of the sleeve. The second sleeve holds an end section of at least one output optical fiber. The end face of the second sleeve faces the first sleeve end face. The first collimating GRIN or conventional lens in front of the first sleeve end face collimates light signals from the input optical fibers and the second collimating GRIN or conventional lens in front of the second sleeve end face focusses light signals from at least one of the input optical fibers into the single output fiber, or at least one of the output optical fibers. With only one output fiber the coupler operates as a combiner.

Abstract: A fiberoptic network transmission system combines the output signals of several laser sources into a single optical fiber. The transmission system has integrated optical isolator couplers which each have at least two input optical fibers and an output optical fiber. Each input optical fiber is connected to a laser source and the output optical fiber is connected to an input terminal of a combiner which has its output terminal connected to the single optical fiber. The integrated optical isolator couplers block light from the single optical fiber from reaching any of the laser sources.

Abstract: An improved optical isolator of the type having an input optical fiber, a first GRIN lens, a first polarizer, a optical rotator, a second polarizer, a second GRIN lens and an output optical fiber. Lithium niobate birefringent crystals are used for lowered costs and high performance. Improvements also include polishing the end of the input optical fiber at a slant and covering the end with a window coated with antireflection material. The surface of the GRIN lens facing the end of the input optical fiber is slant-polished reciprocally and spaced apart with gap which avoids Fabry-Perot interference.