Abstract: Herein disclosed is an image fiber imaging apparatus comprising an image guide fiber bundle having a plurality of optical fibers, a receiving end, at which one ends of said optical fibers are arranged, and a transmitting end, at which other ends of said optical fibers are arranged, said receiving end being directed to an object to receive an image of said object, said optical fibers transmitting said image received at said receiving end to said transmitting end, said image including a plurality of image portions, each corresponding to one of said optical fibers; a solid-state imaging device arranged at said transmitting end of said image guide fiber bundle for converting said image including a plurality of image portions transmitted by said optical fibers of said image guide fiber bundle into an image signal; an electrical spatial filter for filtering said image signal converted by said solid-state imaging device to output a filtered image signal; and a display unit for displaying said filtered image signal o

Abstract: A lens-fiber alignment housing for passively aligning an optical fiber with a lens, for improved alignment of a laser with the fiber, via the lens. The fiber is disposed in a substantially cylindrical, annular ferrule, the bottom end of which is disposed in the first end of a ferrule sleeve. The housing has an upper cylindrical mating section at a first end for mating with the second end of the ferrule sleeve, and a bottom lens-receiving section for securely receiving and mounting a lens. The lens may be mounted into the lens-receiving section of the housing, so that, when the housing is inserted into the second end of the ferrule sleeve, the lens and fiber are automatically, passively aligned, thereby forming an aligned lens-fiber assembly that can be aligned with the laser in a single active alignment procedure.

Abstract: The present invention comprises a shifting unit that uses optical fibers to shift beams among various outputs. The shifting unit comprises a shifting entrance plane and a shifting exit plane. The shifting entrance plane comprises at least one row of signal input positions. Each signal input position is adapted to receive an optical signal from a source. The shifting exit plane comprises a respective number of rows of signal output positions. Each signal output position is adapted to output an optical beam. Each signal input position of a given row is connected by an optical fiber to a corresponding signal output position. Also, each optical fiber is the same length as every other optical fiber in the shifting unit. The present invention also comprises methods and apparatus comprising the shifting unit.

Abstract: First and second optical-redirectors mounted on a catheter couple radiation to a target along separate first and second paths. Either the first or second optical-redirectors, or both, can include a steering mechanism for selecting the first and/or second path.

Abstract: An intravascular device for locating a coronary sinus of a patient's heart and method of using the same. In one embodiment, the intravascular device includes an elongated member having at least one lumen and at least one optical fiber coupled to the elongated member. The optical fiber has a distal end configured to contact with a blood flow within the patient's heart and a proximal end coupled to a laser Doppler velocimetry system for performing a plurality of laser Doppler velocity measurements of the blood flow within the heart to locate the coronary sinus of the heart. Incorporating LDV technology into an intravascular device such as a catheter or a guidewire system provides diagnostic information of the physiologic environment of the lesion before, during, or after a therapeutic procedure.

Abstract: An optical crossconnect constructed of micro -electromechanical systems (MEMS) tilt mirror arrays for selectively routing optical signals to optic fibers. The crossconnect includes a lens array for directing optical signals from a fiber array to the MEMS mirror array. Individual mirror elements in the mirror array reflect the optic signals to additional optic elements such as a planar mirror, a transmissive/reflective optical element or a second MEMS mirror array for routing the optical signals to output optic fibers.

Abstract: A multi-fiber optical collimator includes a plurality of optical fibers for carrying optical signals, a first lens and a beam expander. The first lens has first and second sides and a first focal length. The first side of the first lens is positioned a distance of about the first focal length from first ends of the optical fibers. The beam expander has first and second sides and the first side of the beam expander is positioned to face the second side of the first lens. The second side of the beam expander provides collimated beams associated with the optical signals carried by the optical fibers.

Abstract: Each of optical fibers 1 includes on the outer peripheral portion thereof a plate member 2 which is used when assembling the optical fiber arrangement portion, and an optical fiber arrangement portion 29 includes an optical fiber array in which the plate members 2 of the optical fibers 1 are superimposed on top of each other in such a manner that they are arranged in parallel to each other.

Abstract: A single channel M×N optic switch is provided in accordance with the present invention to steer light radiating from any one fiber in an input bundle into any selected fiber in an output bundle. Precision beam-steering optics is implemented using a Risley prism pair controlled by a small computer. In order to efficiently couple light between two single-mode optical fibers a low-aberration lens approximately collimates the light from the source fiber before it is passed through the Risley prisms in order to minimize the aberrations introduced by the prisms as they collectively deflect the beam through some precise angle. A second low-aberration objective lens is used to refocus the light at the core of a selected output fiber. The focusing lens transforms the angular deflection of the beam into a change in the position of the focused spot in the focal plane of the lens.

Abstract: A method for aligning optical fibers with an optical component includes making a lens on an end of each optical fiber to form a microlensed fiber and arranging the microlensed fibers such that an optical axis of each of the optical fibers is oriented along a common direction. The method further includes positioning each lens a selected distance from the optical component so as to couple light into and out of the optical component.

Abstract: Optical cross-connect switches include input optical paths, output optical paths, and an array of electromechanical optical switches such as movable reflectors that are arranged in rows of the electromechanical optical switches and columns of the electromechanical optical switches, and that selectively move to couple the input optical paths to the output optical paths. Row address lines also are provided, a respective one of which is electromagnetically (i.e. electrically and/or optically) coupled to a respective row of the electromechanical optical switches. Column address lines also are provided, a respective one of which is electromagnetically coupled to a respective column of the electromechanical optical switches. If there are n2 electromechanical optical switches that couple n optical paths to n optical output paths, less than n2 row and column address lines may be provided. Preferably, 2n row and column address lines may be provided.

Abstract: A light transport device comprises light fibers that individually have predetermined cross sections at one end that may be bundled together to provide a continuous plane, suitable for light input or output, that is substantially free of voids and free of non-light-transmitting materials. The other end of the individual light fibers has a cross section that is useful for injection or emission of light from a single fiber.

Abstract: Described herein is a system and method for extending the performance of a simple lens system with curvature of field to image a set of optical light guide sources extended over a wide field of view. Embodiments are applicable to systems using integrated optical light guides as the sources for imaging. Further, the systems and methods allow for a wide field of view using simple aspheric lenses with resulting savings in complexity, size, mass, and cost.

Abstract: An endoscope cable for use in an endoscope viewing apparatus for viewing an objective has an image viewing cable end portion for association with an image viewing device, a distal, image forming end portion including image forming means for forming an image of the objective, an image transmission means for transmitting the image from the image forming means to the image viewing cable end and a plurality of illumination light conducting fibers extending from an illumination light receiving end at the image viewing cable end to an illumination light emitting end at the image forming end of the cable. A first set of the illumination light conducting fibers has an illumination light emitting end portion axis parallel to the cable image forming end portion axis. A second set of the illumination light conducting fibers has an illumination light emitting end portion axis at a first acute angle to the cable image forming end portion axis.

Abstract: A projection display composed of a plurality of tiles (101) is illuminated by a plurality of projectors (400), one for each tile. The light from a plurality of light engines (200) is combined in a homogenizer to form a common illumination source which is then separated by a light separation unit (300) into individual primary colors. The individual primary colors are then transmitted over a second set of fiber optic cables (502) to the individual projectors.

Abstract: An apparatus and method for illuminating a projection display which includes multiple light sources which are integrated through a multi-input ported light pipe disposed between the multiple lamps and the remainder of the projection display.

Abstract: A variety of polarization independent optical isolators, including a single stage polarization independent optical isolator, a single stage broadband polarization independent optical isolator, a double stage polarization independent optical isolator, a double stage broadband independent optical isolator, and an optical isolator/monitor/amplifier, provide improved isolation characteristics and functionality. Optical systems are based upon input light traveling twice through the optical isolator/monitor/amplifier, and upon input light traveling twice through the optical isolator/monitor/amplifier connected in cascade with a double stage broadband polarization independent optical isolator.

Abstract: A small reflection mirror type optical fiber switch solves a problem of an inconsistent angle of a shutter operating position in a conventional reflection mirror type optical fiber switch. A reflection mirror type 2×2 optical fiber switch includes a first collimator lens assembly C1 having a pair of optical fibers disposed symmetrically with respect to an optical axis of a lens, and a second collimator lens assembly C2having a pair of optical fibers also disposed symmetrically with respect to an optical axis of a lens. In an aligning block B, the first and second collimator lens assemblies are opposed and supported, with their optical axes aligned. A driving means MO moves a mirror of a reflection mirror assembly between a position where light is reflected and a position where light is transmitted.

Abstract: An imaging optical apparatus comprising a gradient-index rod lens array and two transparent or light transmitting optical elements that are substantially identical in shape and imaging characteristics and which are provided in the object space and the image space in the optical path of said gradient-index rod lens array in such a way that they are symmetrical with respect to said gradient-index rod lens array.

Abstract: The head of an optical fiber comprising the sensing probe of an optical heterodyne sensing device includes a planar surface that intersects the perpendicular to axial centerline of the fiber at a polishing angle &thgr;. The planar surface is coated with a reflective material so that light traveling axially through the fiber is reflected transverse to the fiber's axial centerline, and is emitted laterally through the side of the fiber. Alternatively, the planar surface can be left uncoated. The polishing angle &thgr; must be no greater than 39° or must be at least 51°. The emitted light is reflected from adjacent biological tissue, collected by the head, and then processed to provide real-time images of the tissue. The method for forming the planar surface includes shearing the end of the optical fiber and applying the reflective material before removing the buffer that circumscribes the cladding and the core.

Abstract: An optical transceiver system including a plurality of transceiver nodes with at least one two-dimensional integrated circuit array of optical emitters and detectors mounted on an ASIC drive circuit and forming a focal plane; a lens or light collimator located adjacent for directing light to and from the emitter and detectors; an epoxy stand off located peripherally around each focal plane to prevent contact between the focal plane and the lens or collimator and to prevent entry of contaminants therebetween; and at least one fiber optic bundle to convey light between each of the transceiver nodes through the perspective lenses or collimators.

Abstract: An object of the present invention is to make the light distribution by a light guide even. In the light guide, an amount of light emitted from the central region in the light emission end face is relatively small in comparison with an amount of light emitted from a peripheral region in the light emission end face. For example, a mask for shielding light is provided near the light emission end face of the light guide. The mask is, for example, circular, and is aligned with an optical axis Z0 as the center. By providing the mask, the light emitted from the central region in the light emission end face is shielded around the optical axis Z0.

Abstract: A fiber optic probe is provided that includes a housing, at least one optical fiber disposed within the housing, one end of each of the at least one optical fiber being disposed adjacent an opening in the housing forming a probe face, a binding agent that binds the at least one optical fiber within the housing, and a protective coating sealingly covering the probe face to prevent contaminants from contacting the at least optical fiber. A method for protecting a fiber optic probe having a housing, at least one optical fiber disposed within the housing, one end of each of the at least one optical fiber being disposed adjacent an opening in the housing forming a probe face, and a binding agent that binds the at least one optical fiber within the housing, includes polishing the probe face to create a substantially flat probe face, cleaning the probe face after polishing the probe face and sealing the probe face with a protective coating.

Abstract: In accordance with the invention, a hermetic optical fiber array comprises a substrate having a planar surface including an array of perforations for receiving optical fibers, a plurality of fibers having cores disposed in the perforations, the fibers bonded to the substrate with a set of fiber ends substantially coplanar with the surface, and a sealing coating disposed on the planar surface and co-planar ends, the sealing coating covering the substrate/fiber joints but having openings to the cores of fibers in the array. The fiber array can be bonded within a hollow tubular fiber array housing, and the fiber array housing, in turn, can be adapted to support a microlens in spaced relation to the coplanar arrayed fiber ends and to hermetically attach to an apertured system housing.

Abstract: An endoscope optics including a housing receiving an image-observation device and a tubular stem. The stem is secured to a distal end of the housing. An image transmitting device is mounted inside the stem. The image-observation device is aligned inside the housing with the image transmitting device regarding image position and image center. An insert element is used to adjust the image-observation device and includes an outer contour, which allows stationary affixation to the housing, and an inner, axially continuous borehole, which receives the image-observation device in geometrically interlocking manner. The relative position between the borehole and the outer-wall contour inside the insert element is determined by spatial coordinates ascertained for the particular endoscope optics and specifying the position at which to adjust the image-observation device inside the housing relative to the image transmitting device.

Abstract: An image magnifying/reducing optical device includes a base member having first and second surfaces which are approximately parallel to one another; and a plurality of high-refractive-index regions formed in the base member. The plurality of high-refractive-index regions continuously extending from the first surface to the second surface of the base member; and a sectional area of each of said plurality of high-refractive-index regions around the second surface being larger than that around the first surface.

Abstract: An apparatus for continuous cardiac output monitoring ascertains cardiac output by measuring the cross-sectional area of the vessel and the flow rate of fluid flowing through the vessel. The cross-sectional area is derived from the measured resistance within the vessel whereby a pair of signal electrodes injects a known electrical signal into the vessel and the resistance is derived from the known signal and the differential voltage between first and second measuring pairs of electrodes. Resistivity of the fluid is a component of the cross-sectional area derivation, and a temperature sensor is provided to allow for compensating for variations in resistivity with temperature. A velocity sensor is preferably of an optic fiber, Doppler shift type, and the accuracy of the velocity measurement is improved by focusing light emissions from the optic fiber(s) by either providing a Fresnel plate on the terminal end of the fiber or by forming the terminal end of the fiber in a generally conical shape.

Abstract: An ultrathin optical panel, and a method of producing an ultrathin optical panel, are disclosed, including stacking a plurality of glass sheets, which sheets may be coated with a transparent cladding substance or may be uncoated, fastening together the plurality of stacked coated glass sheets using an epoxy or ultraviolet adhesive, applying uniform pressure to the stack, curing the stack, sawing the stack to form an inlet face on a side of the stack and an outlet face on an opposed side of the stack, bonding a coupler to the inlet face of the stack, and fastening the stack, having the coupler bonded thereto, within a rectangular housing having an open front which is aligned with the outlet face, the rectangular housing having therein a light generator which is optically aligned with the coupler. The light generator is preferably placed parallel to and proximate with the inlet face, thereby allowing for a reduction in the depth of the housing.

Abstract: A line scan apparatus having a linear array of objective lenses which pair up with an associated linear array of optical sensors. The apparatus further comprises a bundle of tapering optical fibers which optically couple the pairs of objective lenses and optical sensors. Each fiber is arranged such that it optically couples at a wide end to one of the objective lens, and at a narrow end to one of the optical sensor. In operation, the linear array of objective lenses are scanned across the object, with the linear array of optical sensors capturing a one dimensional image line by line to build up a two dimensional image of the object.

Abstract: An illumination technique and system employing an optical waveguide to transmit light from a source, typically a light emitter which operates at high temperature, to a light head which creates a desired light dispersion pattern. The light head includes a member which emulates the light source and the emitted light is coupled from the source into the optical waveguide by a compact and efficient columnator comprising a pair of dissimilar three dimensional reflectors and a lens.

Abstract: Disclosed is an oriented, heat shrinkable, thermoplastic vacuum bag having a protective heat shrinkable patch attached thereto such that said heat shrinkable patch covers substantially all area exposed to bone, thereby protecting the bag from puncture by sharp protruding bones in bone-in cuts of meat which are vacuum packaged within the bags. The protection is especially directed to prevention of bag puncture by, bone-in cuts of both fresh and smoked or processed meat.

Abstract: A two-fibre optic probe or sensor performs accurate measurements of fluids flowing within a remote vessels, such as blood flowing within arteries or veins or fluid flowing within pipes. One of the fibre transmits a light that is intercepted by a reflective surface. The reflective surface reflects the light out of the probe through an optically transparent window, located in the probe, and into the volume of the fluid. A portion of the emitted light scatters back, as backscatter, through the optical window into the probe where the light once again encounters the reflective surface. The reflective surface then directs the backscattered light directly into the terminal ends of the other fibre that receives the light. The detected light is used to measure the volume of the fluid at the area where the incident beam of the emitted light and the backscattered light overlaps.

Abstract: A method and device for optical multiplexing or demultiplexing of optical signals. The device has a grating for dispersing an input beam into a plurality of sub-beams which are focused by a simple lens and a GRIN lens on a glass block having a plurality of waveguides embedded therein with a predetermined spacing therebetween. In order to correct for an offset in alignment, e.g. due to ambient temperature changes, between the sub-beams and the waveguides of the block, the latter is mounted to a thermally activated actuator for an controlled angular displacement which is selected to compensate for the offset.

Abstract: A variable-view arthroscope or like instrument (endoscope, etc.) includes an elongated housing tube extending from an outer control end to an inner image input end that is closed by an input lens; the input lens preferably is a diverging lens. In the form shown FIGS. 6A-6C, the input lens has a concave inner surface and a concave outer surfaces. A lighting apparatus illuminates a surgical working area beyond the image end of the housing tube; the illumination may be projected outwardly through the input lens. A movable mirror intercepts light reflected from the surgical working area to produce a working image that is reflected to a fixed mirror that in turn reflects the working image to impinge upon the input end of a relay lens assembly. The working image is transmitted to a receptor, which is located near the outer (control) end of the housing tube. The relay lens applies the image to an image device, such as a conventional CCD unit, that transmits the image to a location exterior to the scope.

Abstract: An optical system (20) projects light into a planar optical display (10). The display includes laminated optical waveguides (12) defining an inlet face (14) at one end and an outlet screen (16) at an opposite end. A first mirror (26) collimates light from a light source (18) along a first axis, and distributes the light along a second axis. A second mirror (28) collimates the light from the first mirror along the second axis to illuminate the inlet face and produce an image on the screen.

Abstract: A surgical endoscopic instrument for surgery in a region directly underneath a layer of tissue covering a body cavity and traversed by the instrument which has a tubular sleeve with an operating duct and an optical system. The optical system image guide exits through a lateral outlet, the operating duct is mounted in a cross-sectional zone adjacent to the outlet and the optical system is mounted in a cross-sectional zone of the sleeve substantially opposite the outlet. The image guide of the operating duct extends laterally around the sleeve.

Abstract: A probe for use in spectroscopic analysis comprises an optical fiber with a rod-like end piece. One form of the probe has a local detector which can be deposited on the end piece or located close to it. This improves collection efficiency of radiation diffusely scattered from a sample being investigated. An alternative arrangement uses a local source of radiation.

Abstract: A fiber-optic probe uses imaging optics between the remote ends of the excitation and collection fibers and the sample under investigation to enhance working distance and efficiency. In one embodiment a plurality of collection fibers are disposed circumferentially around a central excitation fiber, enabling a conventional focussing lens arrangement to be used for imaging purposes. The assembly may optionally include a rotationally symmetric diffraction grating to cause the excitation energy to assume an annulus superimposed over the image of the collection fibers. The excitation and collection fiber may alternatively be physically spaced apart from one another sufficient to permit one or more optical elements to be disposed in either or both of the excitation and collection paths, depending upon the application.

Abstract: An optical element comprises zones of different refraction power or curvature in order to achieve a desired pattern of brightness distribution. In Particular, a darker spot in a central illumination region of an illuminating arrangement including a cold light reflector lamp the light of which is supplied over a fiber optic light guide should be avoided. The optical element has a rotational symmetric annular zone of low or no curvature the outer ring diameter of which being larger and the inner ring diameter being smaller than the diameter of the light exit surface of the fiber optic light guide. A second rotational symmetric zone has a stronger curvature than the first zone. This second zone is situated within the inner ring diameter of the first zone. Both zones face the light exit surface of the light guide. A third zone has a curvature different to the curvatures of the first and second zones, and is situated at the light exit side of the optical element.

Abstract: A method of arranging an item imager with a least two imaging site, each lit by a beam through a fibre-optic array, this method including: providing a beam-intensity-adjust array including a lens stage for focusing each beam on each fibre optic array such that a shift in lens-focus changes output light from the array.

Abstract: A relay lens assembly and a method for manufacturing a relay lens system for an endoscope includes the steps of providing at least one rod member having first and second curved end surfaces, positioning a mold surface at a predetermined distance from one of the curved end surfaces of the rod member wherein the mold surface has a profile which is the negative of a required optical profile to be formed on the curved end surface, filling a space defined by the predetermined distance between the mold surface and the curved end surface with a moldable light transmissive material and solidifying the moldable material to form a molded layer adhered to the curved end surface.

Abstract: A color image sensor has a white fluorescent tube as a light source, a microlens array with three rows of microlenses arranged vertically, a three-layer optical waveguide array and a three-line color CCD with color filters. The waveguides in each waveguide array layer are bent so that the interval between successive waveguides becomes narrower from the input end toward the output end. The three-line color CCD has three lines of light-receiving elements (photodiodes) as the light sensing portion. These lines in the light-receiving element array are arranged vertically at the same intervals as the waveguide layers are arranged. Further, a cylindrical lens is attached to cover the microlens array. Because of the presence of this cylindrical lens, the images of light beams incident on different microlenses of the microlens array corresponding to different waveguide layers are the same image from an identical area on the original.

Abstract: The optical scanner comprises a light source, an image sensor, a planar array of elongate optical waveguides, and input and output coupling optics for communicating light to and from the image transmission optics. The light source is adapted to direct light toward and reflect light from an object to be scanned. The planar array of elongate optical waveguides is formed in a substrate. Each of the waveguides include an input end and an output end and can be tapered along the length of the waveguide. The input optics disposed between the object and the waveguide array can include tubes, single lenses per waveguide, larger lenses per cluster of waveguides, a GRIN lens array or comparable mirror systems for directing light reflected from the object to be scanned to the input ends of the waveguides. The output optics disposed between the waveguide array and the image sensor can include lenses or mirror systems similar to that used for the input coupling optics.

Abstract: A applied diffusor structure for lightguides fabricated out of a flexible transparent film substrate. The substrate having high resolution complex patterns printed on the surface of the substrate using any high resolution printing process. The substrate affixed to the lightguide using a transparent adhesive or alternatively the substrate is molded to the lightguide.

Abstract: In order to improve a laser system comprising several laser radiation sources, each of which generates laser radiation which is coupled into a first end of a respective optical single-mode fiber, wherein all optical single-mode fibers form a fiber bundle and have second ends lying at a fiber bundle end, the laser radiation exiting from the second ends and thereby forming a total laser radiation field, and further comprising an optical transformation means which transforms the total laser radiation field onto an object, such that a focal point with a highest possible power per area and per solid angle can be generated therewith, it is proposed that the optical transformation means comprise a collimating element which collimates the laser radiation exiting divergently from each individual second end of the single-mode fibers and forms a collimated radiation bundle therefrom, and that the optical transformation means comprise a focusing element which images the collimated radiation bundle as a whole onto a focal

Abstract: The invention relates to a fiber-optic coupled diffuse reflectance probe that is adapted to detachably connect to a bifurcated fiber bundle. The probe includes one or more lenses for imaging the bundle onto a target with more space between the bundle and the target than otherwise possible. The collecting lens adjacent to the bundle preferably has a reflection stop which diverts reflected light away from the bundle to minimize the problem of stray light. The preferred probe also uses an objective lens to increase the distance between the bundle and the target. The rays emerging from the collecting lens will diverge or spread because of the finite diameter of the transmitting fibers in the bundle.

Abstract: A blind spot viewing system capable of transferring an optical image between two locations by use of a coherent bundle of optical fibers with a lenslet array placed on each end of the bundle or formed integral thereto. The lenslet input assembly focuses light onto the core of each optical fiber in the coherent bundle. The output of the coherent bundle is also coupled to a lenslet array wherein each lens in the array is positioned along the output end of the coherent optical fiber bundle to collect the light emerging from the single optical fiber for focusing it towards a viewing position. Alternatively, the ends of the optical fibers can be modified to include a focusing lenslet. The viewing position might include a direct viewing or charge coupled device (CCD) for subsequent viewing on a video monitor.

Abstract: A planar parallel plate direct vision prism including two glasses for dispersing light as a function of color is disclosed. Also disclosed is an optical system which includes a first optical assembly having two planar parallel plate direct vision prisms for dispersing light as a function of color. The degree and orientation of the light dispersed is controlled by rotating the two prisms of the first assembly in relation to each other and together in unison. A fiber optic bundle transmits the dispersed light and a second optical assembly having two planar parallel plate direct vision prisms recombines the dispersed light emerging from the fiber optic bundle. The degree and orientation of the light recombined is controlled by rotating the prisms of the second optical assembly in relation to each other and together in unison.

Abstract: An imaging system that can tolerate high intensity optical beams without a reduction in the system's field-of-view, comprises an imager, a fiber array positioned at the image plane of the imager, a sensor array positioned at the output end of the fiber array, a panel display positioned in proximity of the fiber array and an image processor for electronically processing the information from the sensor array.

Abstract: A transducer is deposited on each fiber of an optical fiber scene projector to convert portions of electromagnetic radiation to emitted radiation, h as IR. The transducer, is adaptable to large arrays of optical fibers and can be fabricated using mature conventional processes, such as vapor deposition, for example. The components of the transducer can be tailored to handle different incident radiation and produce desired emitted radiation. Dielectric layers having thicknesses equal to odd-numbered multiples of quarter wavelengths of the electromagnetic radiation receive the electromagnetic radiation and a reflector adjacent to the layers reflects unabsorbed portions of radiation back through the layers. An absorber layer interposed between adjacent dielectric layers absorbs the received and the reflected radiation so as to convert the absorbed radiation into heat energy.