Abstract: The present invention pertains to an optical shutter comprising an photon-absorbing layer and a surface layer in a transparent state on at least one side of the photon-absorbing layer, wherein the optical shutter is characterized by the absorption of photons to change the photon-absorbing layer to an opaque state and to change the surface layer to a reflective state. The optical shutter is reversibly imageable between these transparent and reflective states. The optical shutter may comprise a metallized layer on at least one side of the photon-absorbing layer. Preferably, the optical shutter comprises an organic free radical compound, such as a salt of an aminium radical cation, in the photon-absorbing layer. Also provided are optical switch devices and optical buffers comprising such optical shutters and methods of switching an optical signal utilizing such optical shutters and switch devices.

Abstract: An optical switch having switch mirror arrays controlled by scanning beams that reduce the amount of electrical connections required and reduce the complexity for constructing large optical switches. Movement of the switch mirror arrays is controlled by one or more scanning beams. The optical switch includes one or more arrays of optical switch inputs and outputs and one or more arrays of movable mirrors to direct light beams from the optical switch inputs to the optical switch outputs. The optical switch also includes one or more control elements to control the movable mirrors based on scanning beams directed to the one or more control elements.

Abstract: MEMS optical switches can include a substrate having first and second opposing faces and at least one side therebetween. An input is obliquely angled towards the face and optically couples optical radiation towards the face. A movable reflector is on the face and moves from a first position to a second position that is parallel to the first position to reflect the optical radiation from the input to provide reflected optical radiation. A output is obliquely angled away from the face and optically couples the reflected optical radiation away from the face.

Abstract: A method and apparatus are disclosed for selectively passing or blocking an optical signal using an opaque or reflective shutter that is selectively positioned in or out of the light path. The disclosed wavelength blocker can be employed to filter input wavelength-division multiplexed (WDM) signal comprised of N wavelength channels, where a mechanical shutter array selectively passes each of the N wavelength channels. Each mechanical shutter may be controlled, for example, by a micromachine control element that physically lifts the shutter into or out of the lightpath. The disclosed wavelength blockers may be utilized in wavelength-selective cross connects, as well as other optical devices. In an exemplary wavelength-selective cross connect, an array of mirrors are employed in a planar waveguide having two sets of waveguide gratings intersecting at an angle.

Abstract: An optical device comprises a substrate having a plane surface. An optical path is disposed on the substrate and extends in a plane parallel to the surface of the substrate. A recess intercepts the optical path. An optical element is provided for modifying light incident thereon. The optical element is moveable within the recess between a first position in which the optical element is located in the path and a second position in which optical element is remote from the path. A cantilever suspends the optical element for movement within the recess between the second and first positions in a direction normal to the surface of the substrate.

Abstract: An optical switch (99) includes a base (10), two input ports (20, 40), two output ports (30, 50), a movable reflector assembly (60), a driving means (70) and a cover (80). The movable reflector assembly has a first reflector (61) with two outer reflecting surfaces (611, 612) and a second reflector (62) with two inner reflecting surfaces (621, 622). The light beams from the input ports propagate to the output ports by moving the movable reflector assembly up and down between a first position and a second position and switching the first reflector and the second reflector into the path of the light beams in turn.

Abstract: An optical cross connect switch directs an optical data signal from an incoming optical fiber in a first fiber array to a first controllable mirror in a first controllable mirror array, a second controllable mirror in a second controllable mirror array into an outgoing optical fiber in a second fiber array. Single or multiple optical position sensing systems or electrical position sensing systems or their combination provide feedback control to the controllable mirror arrays.

Abstract: A Mach-Zehnder interferometer has first and second arms with first and second optical paths, and an optical phase shifter for introducing a phase into an optical signal passing through the second optical path. The optical phase shifter includes first and second waveguides, and a phase shift element disposed in a trench between the waveguides and selective movable between a first position in which the optical signal passing from the first waveguide to the second waveguide does not pass through the phase shift element, and a second position in which the optical signal passing from the first waveguide to the second waveguide passes through the phase shift element to shift the optical signal in phase relative to an optical signal passing along the first optical path.

Abstract: An optical switch utilizing an actuator to move an optical element into or out of an optical pathway is described. The optical element may be coupled to a movable shuttle and driven by a motor between two rest positions. The shuttle may be latched in the rest positions. The optical element's position may be controlled with a stop that contacts the shuttle to provide accuracy and precision about multiple axes. The material used to construct the actuator's components may aid in repeatedly positioning the optical element with precision. The actuator may incorporate features that allow the optical element to be passively aligned in a bank of actuators to make a M×N switch.

Abstract: An optical network element using arrays of mirrors in an optical switch. A lens system is placed in between the mirror arrays and optical signals are passed through the lens system in an off-axis manner in order to increase switching capacity so that larger arrays of mirrors can be used, shorten the optical path through the switch or a combination of both.

Abstract: A control system is designed to control an optical cross-connect having a switch core defined by first and second independently movable beam deflectors capable of selectively defining an optical path between a pair of ports of the optical cross-connect. An optical element having optical power is arranged in a propagation path of light beams between the first and second beam deflectors. The control system includes a pilot light source, an optical sensor associated with each beam deflector, and a feedback path. The a pilot light source inserts a pilot light into the switch core colinearly with live traffic. The optical sensor detects a predetermined geometric property of the pilot light emerging from the switch core. This predetermined geometric property is unambiguously associated with an angular position of the associated beam deflector. The feedback path actively controls a position of the associated beam deflector based on the detected geometric property.

Abstract: An optical matrix switcher which does not use mechanical means of optical alignment of input and output fibers in order to accomplish switching is disclosed. The optical matrix switcher of the present invention comprises a number of input assemblies, a number of output assemblies and a screen disposed between the input assemblies and output assemblies. The input assemblies are in an optical connection with inputs of the optical matrix switcher and the output assemblies are in an optical connection with the outputs of the optical matrix switcher. The input and output assemblies each comprise beam shaping means. A beam of light that passes through the beam shaping means is shaped and compressed into a plane (“shaped beams”). The screen (which is opaque and does not permit the light to pass through) comprises a number of switching means. The switching means can be placed in an “on” or “off” position.

Abstract: The present invention provides an optical switching element causing less loss of light and permitting high response, thinning of an optical system for illumination, and the realization of an image display device exhibiting precise grayscale properties. In the optical switching element, an extraction surface of a light extraction unit mounted to a thin film is brought into contact with the total reflection surface of a light guide serving as a light guide unit comprising a glass plate or the like for transmitting light by total reflection, or near at a distance from the total reflection, surface for allowing extraction of evanescent waves, to extract the incident light transmitted through the light guide and emit the extracted light to the outside through an emission member.

Abstract: A bi-stable micro-actuator is formed from a first and a second silicon-on-insulator wafer fused together at an electrical contact layer. A cover with a V-groove defines an optical axis. A collimated optical signal source in the V-groove couples an optical signal to an optical port in the V-groove. A mirror surface on a transfer member blocks or reflects the optical signal. The transfer member has a point of support at the first and second end. The mirror blocks or reflects the optical axis. An expandable structure applies a compressive force between the first and second point of support of the transfer member along a compressive axis to hold the transfer member in a bowed first state or a bowed second state. A control signal applied to a heating element in the expandable structure reduces the compressive force, switching the transfer member to a second state.

Abstract: An optical switch (80) includes a base (11), two input ports (20, 40), two output ports (30, 50), a reflector assembly (60), a driving means (70) and a cover (12). The reflector assembly has a first reflector (61) with two reflecting surfaces (611, 612) and a second reflector (62) with two reflecting surfaces (621, 622). The light beams from the input ports selectively propagate to the output ports by controlling the rotation angle (90° or N×90°; N: natural number) of the reflector assembly to be in a first position or a second position and therefore to switch different reflecting surface of the first reflector and the second reflector into the path of the light beams.

Abstract: A thermally actuated spectroscopic optical switch including reflective surfaces which are selectively moved into a position intersecting a beam of light by applying electrical or heat energy to a selected composite cantilever beam on which the reflective surface is mounted.

Abstract: The present invention pertains to an optical shutter comprising a photon-absorbing layer and a surface layer in a transparent state on at least one side of the photon-absorbing layer, wherein the optical shutter is characterized by the absorption of photons to change the photon-absorbing layer to an opaque state and to change the surface layer to a reflective state. The optical shutter is reversibly imageable between these transparent and reflective states. The optical shutter may comprise a metallized layer on at least one side of the photon-absorbing layer. Preferably, the optical shutter comprises an organic free radical compound, such as a salt of an aminium radical cation, in the photon-absorbing layer. Also provided are optical switch devices and optical buffers comprising such optical shutters and methods of switching an optical signal utilizing such optical shutters and switch devices.

Abstract: A modular three-dimensional (3D) optical switch that is scalable and that provides monitor and control of MEMS mirror arrays. A first switch module includes an array of input channels. Light beams received from the input channels are directed toward a first wavelength selective mirror. The light beams are reflected off of the first wavelength selective mirror and onto a first array of moveable micromirrors. The moveable micromirrors are adjusted so that the light beams reflect therefrom and enter a second switch module where they impinge upon a second array of moveable micromirrors. The light beams reflect off of the second array of moveable micromirrors and impinge upon a second wavelength selective mirror. The light beams reflect off of the second wavelength selective mirror and into an array of output channels. The alignment or misalignment of a data path through the switch is detected by directing two monitor beams through the data path, one in the forward direction and one in the reverse direction.

Abstract: An optical multiplexing/demultiplexing device with variable branching ratio is disclosed. The device includes a first collimator lens assembly having a first collimator lens 14, and first and second optical fibers F1 and F2 which have distal ends thereof optically coupled to the lens, and are away from each other by a distance “d,” an optical axis of the lens being positioned at a midpoint therebetween, a second collimator lens assembly having a second collimator lens 15 and a third optical fiber F3 which has a distal end thereof optically coupled to the lens, being away from an optical axis of the lens by a distance “d/2” and reflection mirror means. The reflection mirror means reflects and couples a part or all of a parallel beam of an expanded mode field area, which is emitted from the first optical fiber and formed on a reference plane, to the second optical fiber, or transmits and connects all or a part of the parallel beam to the third optical fiber.

Abstract: A light blocking device for an optical transmitter includes a flap (46) that is movable to a first position in which light is allowed to pass unhindered from a laser (18), and is movable to a second position to block the light emitted from the laser. The light blocking device further includes a panel member (48) connectable to a housing (10) of the optical transmitter. The flap (46) is connected to an edge of the panel member (48).

Abstract: To provide a small and lightweight optical switching element with a simple structure capable of fast response, and an optical switching apparatus employing the optical switching element. Optical extraction unit contacts an upper substrate with electrostatic attraction generated between a transparent electrode of the optical extraction unit and a transparent electrode of the upper substrate. In the case that light enters one V-shaped trench of the upper substrate vertically, the light enters the optical extraction unit of the upper substrate and is emitted from a back of the optical extraction unit (a tapered unit). Subsequently, the incident light P1 passes through a lower substrate and is converted into transmission light. With electrostatic attraction generated between a transparent electrode of the lower substrate and a transparent electrode of the optical extraction unit, the optical extraction unit is attracted to a lower substrate side.

Abstract: There is described a switching device comprising a mobile element (2) that is able to at least move back and forth along a defined trajectory between a zero position (O) and at least one predetermined switching position (A, B), an elastic member (3, 30, 32) connecting the mobile element to a base (4) and at least one stationary actuating electrode (5, 6) located in the vicinity of the predetermined switching position for producing electrostatic forces to cause the mobile element to move to and/or away from the predetermined switching position.

Abstract: An actuator having a fixed portion, a vibrating portion supported on the fixed portion so as to undergo vibrations, and an actuating portion including a first and a second electrodes formed on both sides or one side of a deformable layer is provided. The actuator generates a displacement motion by holding the offset electric potential of the first electrode at a desired valve and variable-controlling an electric potential of the second electrode. A cathode for emitting electrons is formed on the actuator. The current controlling element changes the position of the cathode with respect to the plate by the displacement motion of the actuator obtained by changing an electric potential difference of the second electrode to the offset electric potential, and adjusts the offset position of the cathode according to the offset electric potential, to adjust a control range of a current value taken out of the plate.

Abstract: A variable optical attenuator having a waveguide and an MEMS actuator. In the variable optical attenuator, the input waveguide and the output waveguide face each other and are separated by a gap. The input waveguide increases in width along an optical path in order to expand the width of the light entering through an optical fiber of the input end. The output waveguide decreases in width along the optical path in order to make the expanded light converge towards the optical fiber of the output end. The optical shutter moves in the space between the two waveguides under the control of the MEMS actuator and attenuates the amount of the light. The variable optical attenuator having such configuration can be mass-produced in array form and are unaffected by ambient temperature changes.

Abstract: An optical switching device routes optical signals, completely within optical media, from an arbitrary number of N input optical fibers to a different set of M output optical fibers. The switching device uses a thermal microcantilever bimorph optical switch to redirect optical radiation emitted by a laser light source, or from the end of an optical fiber, to an input end of another optical fiber. The modulated optical radiation containing signals from the input fiber optic bundle or laser light source is collimated into parallel beams and projected in free space across the tops of an array of the microcantilever bimorph optical switches. When selected, a particular switch is activated, pops up, intercepts, and reflects the optical radiation down into a cavity and then into a short section of parallel waveguide. The radiation is directed into a transverse waveguide and then to an output optical coupler. This radiation is then coupled into the selected output optical fiber.

Abstract: An optical fiber switching device includes a holding base, a threaded axle and two guide spindles installed in the holding base, a motor connected with the threaded axle to drive the threaded axle to rotate, and a positioning block meshed with the threaded axle and supported by the two guide spindles. When the motor is actuated, the positioning block is linearly moved along the threaded axle and kept in balance, thus a first collimating lens disposed on the positioning block is able to be precisely aligned with a second collimating lens which is disposed at a side of the holding base. Because the first collimating lens and the second collimating lens are precisely in alignment, any possible insertion loss of the optical fiber switching device is minimized.

Abstract: An optical switching element for use in an optical cross-bar array, includes a magnetically responsive curtain that switches between an extended state and a deflected state in response to an applied switching-field. The switching element includes a curtain that moves in response to a magnetic field. The curtain has a fixed edge attached to a substrate and a free edge opposite the fixed edge. A first magnetic-field source magnetically coupled to the curtain generates a first magnetic field that urges the curtain into an extended position in which the curtain intercepts the optical beam. A second magnetic-field source, also magnetically coupled to the curtain, generates a second magnetic field that urges the curtain into a deflected position in which the curtain avoids intercepting the optical beam.

Abstract: A microelectromechanical (MEMS) device has a substrate, and a generally planar moving element, such as a mirror, disposed in parallel to the surface of the substrate. An actuator is operatively engageable with the moving element for selectively actuating the moving element between a first position in a plane horizontal to the surface of the substrate and a second position in that plane. The MEMS device may be effectively used as an optical switch. Various different actuators can be used. Preferably, the device is fabricated using a surface micromachining process.

Abstract: An optical switch for processing an optical signal includes a refractive material and an input waveguide formed in the refractive material that is operable to receive an optical signal. First and second output waveguides are also formed in the refractive material. A switchplate is coupled to the refractive material and has a first position spaced apart from the input waveguide and a second position in proximal contact with the input waveguide. When the switchplate is placed in the first position, the input waveguide totally internally reflects the optical signal toward the first output waveguide. When the switchplate is placed in the second position, the switchplate frustrates the total internal reflection of the optical signal such that the second output waveguide receives the optical signal.

Abstract: An optical switch having a fiber/lens array and a switching substrate may be properly aligned using one or more static mirrors or photodetectors provided on the switching substrate. The static mirrors may be designed to reflect incident light back into an input fiber, where the back reflected light may be detected, or to a detector provided at a predetermined position. Accordingly, the position of the switching substrate and/or fiber/lens array may be adjusted until reflected light having predetermined power is detected. In another embodiment, the position of the switching substrate and/or fiber/lens array may be adjusted until predetermined power is detected by the photodetectors provided on the switching substrate.

Abstract: An exchange switch for an optical switching network utilizes the manipulation of fluid to selectively exchange outputs for two optical transmission paths. That is, when the switch is in a signal-exchange state, first and second transmission paths reciprocally exchange optical signals that are received at input waveguides of the transmission paths. In one embodiment, the exchange switch includes an optical switching arrangement having first and second switching members. The first switching member is positioned to selectively interrupt the continuation of signal propagation along the first transmission path, while the second switching member is positioned to selectively interrupt the continuation of signal propagation along the second transmission path. When fluid resides within the chambers of the two switching members, the exchange switch is in a signal-continuation state.

Abstract: An optical switch having an input waveguide and two output waveguides separated by and disposed around a trench. The input waveguide and a first output waveguide have respective optical paths defined by their respective cores which are coaxial with each other. Those waveguides are also separated by a trench having a medium provided therein that has a refractive index different from that of the waveguides. The input waveguide and a second output waveguide are arranged generally on the same side of the trench such that an optical signal passing from the input waveguide to the second output waveguide does not completely traverse the trench.

Abstract: An object of the disclosed technology is to realize, at low cost, an optical communication module capable of high-speed operation and having an excellent EMC property.

Abstract: The optical switch comprises a substrate, a planar waveguide circuit, an index-matching liquid, a working fluid and a displacing device. The planar waveguide circuit is supported by the substrate. The planar waveguide circuit and the substrate collectively define a trench that includes a first trench region and a second trench region adjacent the first trench region. The second trench region has a width greater than the first trench region. The planar waveguide circuit includes a first waveguide and a second waveguide. The waveguides intersect at the first trench region and are positioned such that light traversing the first waveguide enters the second waveguide when an index-matching material is present in the first trench region, and is otherwise reflected by said the first trench region. The index-matching liquid is located in at least part of the first trench region. The working fluid is located in the second trench region.

Abstract: An optical switch for switching an optical path of an input optical signal comprises a substrate composed of a silica glass substrate, a separation layer formed on the silica glass substrate, a plurality of cantilever beams and formed in parallel to one another on the separation layer and connected at their tip ends to a connection member, at least one silica glass optical waveguide core formed on the cantilever beams, a plurality of optical waveguide fixed in opposition to the silica glass optical waveguide core, a cover for covering the cantilever beams, and a switch drive unit for bending the cantilever beams. The switch drive unit comprises electromagnetic actuators, which comprise soft magnetic bodies formed on the connection member for the cantilever beams and on the substrate, soft magnetic yokes formed of a soft magnetic body, permanent magnets, and wire coils.

Abstract: An apparatus comprising an optical fiber array, a spacer to receive a light beam from the optical fiber array, and a lens array having an input to receive the light beam from the spacer and an output to output the light beam is disclosed. The spacer has a first refraction index and the lens has a second refraction index.

Abstract: The present invention provides an optical switching element causing less loss of light and permitting high response, thinning of an optical system for illumination, and the realization of an image display device exhibiting precise grayscale properties. In the optical switching element, an extraction surface of a light extraction unit mounted to a thin film is brought into contact with the total reflection surface of a light guide serving as a light guide unit comprising a glass plate or the like for transmitting light by total reflection, or near at a distance from the total reflection, surface for allowing extraction of evanescent waves, to extract the incident light transmitted through the light guide and emit the extracted light to the outside through an emission member.

Abstract: An efficient optical coupling arrangement of waveguides is achieved by providing compensation for the Goos-Hänchen effect along a total internal reflection interface. In one embodiment, the lateral shift of reflected light along the interface is calculated in order to determine a distance between axes of two waveguides. The spacing between the axes may be calculated to maximize coupling of light having a transverse electric polarization or light having a transverse magnetic polarization. Preferably, the spacing between axes is established to minimize polarization dependent loss. In another embodiment of the invention, the incidence angles of the two waveguides are selected on the basis of achieving equal lateral shifts of the two polarizations, so that polarization dependent loss is minimized.

Abstract: An optical switch includes a first fluid, and a second fluid positioned adjacent to and in contact with the first fluid. The interface between the first fluid and the second fluid defines a reflective surface. The optical switch also includes electrodes for applying an electrical field across the second fluid to alter the geometry of the reflective surface and redirect an incident light beam in one or more directions.

Abstract: To provide an optical function module in which an optical functional part may easily and rapidly be displaced in a position where the optical functional part work exactly and parts may easily be exchanged and reused, an arrangement unit (105) provided on a substrate (104) with a recess portion and a holder base engaged exactly with the recess portion for disposing an optical functional part (124) so as to exactly work on a light flux (106) between collimators (101) and (101′).

Abstract: The present invention provides a method and apparatus for optical switching devices utilizing a bi-morphic piezoelectric apparatus. The optical switching devices include an arm comprising a piezoelectric material, the arm including a first and a second face and a first and a second end, wherein the first face is opposite to the second face, wherein the first end is opposite to the second end; at least one electrode coupled to the arm for providing a voltage difference between the first and second faces of the arm; a support coupled to the first end of the arm for fixedly supporting the first end; an object with a convex surface coupled to the second end of the arm; an optical element coupled to the second face of the arm capable of deflecting an optical signal traveling therethrough; a first magnet proximately located to the object and to the first face of the arm; and a second magnet proximately located to the object and to the second face of the arm.

Abstract: A variable optical attenuator to provide a new drive mechanism for an actuator, whereby the amount of attenuation does not increase in geometric progression as voltage increases, and an exceptional resolution effect is achieved.

Abstract: A method and apparatus are disclosed for selectively passing or blocking an optical signal using an opaque or reflective shutter that is selectively positioned in or out of the light path. The disclosed wavelength blocker can be employed to filter input wavelength-division multiplexed (WDM) signal comprised of N wavelength channels, where a mechanical shutter array selectively passes each of the N wavelength channels. Each mechanical shutter may be controlled, for example, by a micromachine control element that physically lifts the shutter into or out of the lightpath. The disclosed wavelength blockers may be utilized in wavelength-selective cross connects, as well as other optical devices. In an exemplary wavelength-selective cross connect, an array of mirrors are employed in a planar waveguide having two sets of waveguide gratings intersecting at an angle.

Abstract: Various configurations of micromachined optomechanical switching cells are disclosed herein. In accordance with the invention, an optomechanical switching cell is provided which includes an actuator positioned on a substrate and a mirror coupled to the actuator. The switching cell also includes an electrode disposed upon the substrate under the actuator. An insulator may also be interposed between the substrate and the electrode. In another aspect of the present invention the switching cell includes a latch having a first end region connected to the substrate and a second end region engaged by the mirror.

Abstract: Various configurations of optomechanical matrix and broadcast switches are disclosed herein. One such optomechanical matrix switch includes a substrate and a plurality of optomechanical switching cells coupled thereto. Each of the optomechanical switching cells includes a mirror and an actuator. The matrix switch further includes an array of collimator elements, each of the collimator elements being in optical alignment with one of the optomechanical switching cells. Also disclosed herein is a distributed matrix switch including first and second optomechanical matrix switches. The first and second optomechanical matrix switches respectively include first and second pluralities of optomechanical switching cells mounted upon first and second substrates. A collimator array is interposed between the first and second matrix switches in optical alignment with the first and second pluralities of optomechanical switching cells.

Abstract: Various 3-port and 4-port micromachined optomechanical matrix switches are disclosed herein. In accordance with one aspect of the invention there is provided an optomechanical matrix switch including a substrate and a first plurality of optomechanical switching cells coupled thereto. Each of the first plurality of optomechanical switching cells is arranged to be in optical alignment with a first input port. A second plurality of optomechanical switching cells is also coupled to the substrate, each of the second plurality of optomechanical switching cells being in optical alignment with a second input port. In another aspect of the present invention an optomechanical matrix switch is provided which includes a substrate and a first plurality of optomechanical switching cells coupled thereto. Each of the first plurality of optomechanical switching cells is placed in optical alignment with one of a corresponding first plurality of input ports and with one of a corresponding first plurality of output ports.

Abstract: This switching device comprises at least one cell made up of a moving structure consisting in a flexible cantilever beam (14): and an integral screen (6) attached to said beam, being able to move between two end positions (A, B) and of actuating electrodes (20) for subjecting said structure to forces of attraction to control its movements The electrodes (20) are located on each side of the beam (14) in such a way as to follow its exact shape when it is in one of its two end positions. A regular movement of the moving structure and a reliable operating of the switching device are thus obtained This invention may be used in optical switching applications.

Abstract: An optical attenuator has first and second lenses provided individually on the respective end faces of first and second optical fibers that are opposed to each other across a space, and a shutter plate interposed between the lenses. The distance between the shutter plate and the second lens and a mode-field radius of propagating light on the second-lens-side surface of the shutter plate are set so that the respective signs of the real and imaginary parts of an evaluation function, representing a diffraction pattern of the propagating light that propagates from the first optical fiber to the second optical fiber, are inverted 60 times or more when a variable of the evaluation function is changed within an evaluation range.

Abstract: The present invention provides a double fiber optic cross connect (OXC) package. The double package includes an input optical fiber; a substrate with a first surface and a second surface, optically coupled to the input optical fiber; a first cap optically coupled to the second surface of the substrate; a micromirror array optically coupled to the first cap; a second cap optically coupled to the micromirror array; and an output optical fiber optically coupled to the second cap. The first cap, along with a substrate populated with a micromirror array and a set of sidewalls, form at least one volume which is preferably hermetically sealed. This volume is further enclosed by the second cap with another set of sidewalls.

Abstract: An optical communication system which conserves electrical power is disclosed. Electrical power is conserved in the optical communication system by coupling a splitter to an optical amplifier. The optical amplifier is configured to receive optical signals as well as pump light. The splitter provides a portion of the pump light used in the optical amplifier to other devices (e.g., optical amplifiers, filters, modulators) of the optical communication system. Providing a portion of the pump light used in the optical amplifier to other devices in the optical communication systems conserves electric power by reducing the total electrical power needed to operate the optical communication system.