Abstract: The difficulties encountered in conventional LED multiple chip modules where wire bonding is used to connect the chips to electrodes can be overcome by using an interconnect to connect the chip to electrodes in a module where the interconnect is supported at points along its length other than at endpoints thereof, by a carrier either directly or indirectly. This improves reliability of the interconnect over conventional designs. Preferably, the contacts of the chips, and the electrodes are all within, or do not extend beyond, two parallel planes that are 400 microns apart for a compact design.

Abstract: In one embodiment of the invention, a bonding material is used to bond a substitute substrate to the LED, wherein the bonding material does not including gold or tin. The bonding material preferably includes gallium (Ga), such as a combination of Ga and Al or Cu. This bonding material has high thermal conductivity, high strength, high temperature stability and is low cost. In another embodiment of the invention, the substitute substrate is first thinned before it is bonded to the LED structure, so that the substitute substrate is flexible and conforms to the shape of the LED structure. In yet another embodiment of the invention, an apparatus is used for bonding a substitute substrate to a LED which comprises a plurality of semiconductor epitaxial layers, said semiconductor epitaxial layers having been grown on the growth substrate so that said semiconductor epitaxial layers are curved in shape.

Abstract: The optical lens embodiment of the invention refracts and reflects light emitted from the light emitting diode chips on a unique combination of curved surfaces to obtain the desired coupling to a lateral light guide. The system of curved surfaces redirects rays from multiple LED chips laterally by multiple refraction and/or reflection. The optical lens has an optical axis, and comprises a bottom surface and a curved reflecting surface having a concave side. The concave side is oriented to face said bottom surface at an oblique angle. The reflecting surface surrounds the optical axis. The lens comprises a first curved refracting surface having a concave side facing the concave side of the reflecting surface and a second refracting surface extending as a smooth curve from the bottom surface to the first refracting surface.

Abstract: In one embodiment of an epitaxial LED device, a buffer layer (e.g. dielectric layer) between the current spreading layer and the substitute substrate comprises a plurality of vias and has a refractive index that is below that of the current spreading layer. A reflective metal layer between the buffer layer and the substitute substrate is connected to the current spreading layer through the vias in the buffer layer. The buffer layer separates the current spreading layer from the reflective metal layer. In yet another embodiment, stress management is provided by causing or preserving stress, such as compressive stress, in the LED so that stress in the LED is reduced when it experiences thermal cycles.

Abstract: The optical lens embodiment of the invention refracts and reflects light emitted from the light emitting diode chips on a unique combination of curved surfaces to obtain the desired coupling to a lateral light guide. The system of curved surfaces redirects rays from multiple LED chips laterally by multiple refraction and/or reflection. The optical lens has an optical axis, and comprises a bottom surface and a curved reflecting surface having a concave side. The concave side is oriented to face said bottom surface at an oblique angle. The reflecting surface surrounds the optical axis. The lens comprises a first curved refracting surface having a concave side facing the concave side of the reflecting surface and a second refracting surface extending as a smooth curve from the bottom surface to the first refracting surface.

Abstract: At least one diffraction element is used to diffract light of multiple wavelengths into different wavelength components. Instead of moving the diffraction element as in certain prior filters, light from the at least one element is reflected back towards the at least one element so that light is diffracted at least twice by the at least one element. The reflection is such that at least one selected wavelength component of said wavelength components will pass from an input port to an output port or to another device.

Abstract: The difficulties encountered in conventional LED multiple chip modules where wire bonding is used to connect the chips to electrodes can be overcome by using an interconnect to connect the chip to electrodes in a module where the interconnect is supported at points along its length other than at endpoints thereof, by a carrier either directly or indirectly. This improves reliability of the interconnect over conventional designs. Preferably, the contacts of the chips, and the electrodes are all within, or do not extend beyond, two parallel planes that are 400 microns apart for a compact design.

Abstract: In an epitaxial structure of a solid state lighting system, electrical current injection into the active layer is used to excite the photon emission. The present invention employs a unique waveguide layer in the epitaxial structure for trapping the light generated by the active layer in the fundamental waveguide mode. Multiple photonic crystal regions located either outside or inside one or more current injection regions extract photons from the waveguide layer(s). This novel design optimizes the interplay of electrical pumping, radiation and optical extraction to increase the optical output to several times that of conventional LEDs. A transparent and conductive ITO layer is added to the surface of an epitaxial structure to reduce the interface reflection in addition to functioning as a current spreading layer. The present invention creates solid state lighting with high optical output and high power efficiency.

Abstract: A light-emitting diode (LED) for both AlGaInP- and GaN-based materials needs a good transparent current spreading layer to disseminate electrons or holes from the electrode to the active layer. The present invention utilizes a conductive and transparent ITO (Indium Tin Oxide) thin film with an ultra-thin (to minimize the absorption) composite metallic layer to serve as a good ohmic contact and current spreading layer. The present invention avoids the Schottky contact due to direct deposition of ITO on the semiconductor. For AlGaInP materials, a thick GaP current spreading layer is omitted by the present invention. For GaN-based LEDs with the present invention, semi-transparent Ni/Au contact layer is avoided. Therefore, the light extraction of LED can be dramatically improved by the present invention. Holes may be etched into the semiconductor cladding layer forming a Photonic Band Gap structure to improve LED light extraction.

Abstract: A light-emitting diode (LED) for both AlGaInP- and GaN-based materials needs a good transparent current spreading layer to disseminate electrons or holes from the electrode to the active layer. The present invention utilizes a conductive and transparent ITO (Indium Tin Oxide) thin film with an ultra-thin (to minimize the absorption) composite metallic layer to serve as a good ohmic contact and current spreading layer. The present invention avoids the Schottky contact due to direct deposition of ITO on the semiconductor. For AlGaInP materials, a thick GaP current spreading layer is omitted by the present invention. For GaN-based LEDs with the present invention, semi-transparent Ni/Au contact layer is avoided. Therefore, the light extraction of LED can be dramatically improved by the present invention. Holes may be etched into the semiconductor cladding layer forming a Photonic Band Gap structure to improve LED light extraction.

Abstract: An electrostatic actuator with inter-digital rotor and stator fingers formed in a the insulating and conductive layers of a wafer. The actuator is used to drive MicroElectroMechanical (MEMS) components, specifically micro-optical components such as mirrors, attenuators, switches, and tunable filters.

Abstract: The optical hybrid device includes input optical fiber(s), output optical fiber(s), a lens, a broadband or passband filter, a movable mirror, and an actuator operative to move the mirror or the filter. Depending on a voltage applied to the actuator, the actuator selectively sets the mirror or filter to each of a plurality of positions, so that selected portion(s) of radiation from one or more input beams carried by the input optical fiber(s) are conveyed to the output optical fiber(s); whereby the device performs two or more of the functions of wavelength division multiplexing or demultiplexing, attenuation, switching, filtering and tapping functions.

Abstract: Two optical input channels carry two input optical signals in orthogonal polarization states while located at different radial distances relative to a GRIN lens, so that the two input signals exit the lens at different angles. The two signals exiting the lens pass through an optical member having transverse optical axes where the member has different indices of refraction along the two axes. The member passes and combines the two input optical signals into one signal plus a single output optical channel.

Abstract: An interleaver employs two birefringent crystals with opposite behavior under temperature variations and chromatic dispersion to achieve temperature stability and to compensate for chromatic dispersion. The interleaver employs a third birefringent crystal made of a birefringent material different from the materials of the other two crystals so that the wavelength components of radiation passing through the interleaver conform to the predetermined International Telecommunications Union grid. One of the three birefringent crystals includes a Faraday rotator placed in a magnetic field. By changing the direction of the magnetic field relative to the optical paths of beams passing through the interleaver, the behavior of the interleaver can be fine tuned to achieve temperature stability and chromatic dispersion compensation in a way that does not require very accurate dimension control of the three crystals.

Abstract: In an optical amplifier, a filter is employed to reflect pump power into an erbium optical fiber carrying an input radiation signal, causing the signal to be amplified. The filter passes the amplified radiation signal to a partially reflecting optical interface which passes a small portion of the amplified radiation signal for monitoring purposes. Most of the amplified radiation signal is reflected by the interface and reflected again by another interface towards an output channel preferably parallel to the input channel for a compact design. Isolators may be employed between the filter and a first partially reflecting interface.

Abstract: The optical switch includes input optical fibers, output optical fibers, a lens, a movable mirror, and an actuator operative to move the mirror. Depending on a voltage applied to the actuator, the actuator selectively set the mirror to a first position corresponding to a first combination of optical paths, through which the light beam travels from the first set of the input optical fibers to the second set of the output optical fibers; and to a second position corresponding to a second combination of optical paths, through which the light beam travels from the first set to the second set. The first combination is different from the second combination, and a number of optical fibers of the first set and the second set is more than two.

Abstract: An optical circulator for transmitting light along a first optical path from a first optical port to a second optical port and along a second optical path from the second optical port to a third optical port, an optical interface in the first and second optical paths that passes the first beam but deflects the second beam to a highly reflective surface, wherein the plane of the highly reflective surface is at an angle to the optical interface such that the second beam is deflected from the highly reflective surface to the third port, and wherein the first port and the third port can be configured to utilize the same GRIN lens.

Abstract: A variable attenuator employs a shutter element that is inserted into the path of a beam of radiation. The shutter element comprises a transparent substrate with an opaque layer formed on top of the substrate. The opaque layer forms a pattern in the shape of dots on one part of the substrate and in the shape of a solid layer with holes therein on another part of the substrate. The pattern of holes and dots are such that the radiation transmission function of the element varies as a smooth linear function with the length of the shutter element. Therefore, by inserting the shutter element in a direction along its length into the path of the radiation beam, the amount of attenuation of the beam can be accurately controlled.

Abstract: In an optical amplifier, a filter is employed to reflect pump power into an erbium optical fiber carrying an input radiation signal, causing the signal to be amplified. The filter passes the amplified radiation signal to a partially reflecting optical interface which passes a small portion of the amplified radiation signal for monitoring purposes. Most of the amplified radiation signal is reflected by the interface and reflected again by another interface towards an output channel preferably parallel to the input channel for a compact design. Isolators may be employed between the filter and a first partially reflecting interface.

Abstract: A distributed matrix switch comprises a number of collimators each comprising a ferrule and a GRIN lens. A partially reflective coating is provided at the GRIN lens surface to pass a portion of an incoming light beam and to reflect the remainder. If the reflected portion is conveyed by means of an optical path to another collimators of similar construction, selected percentages of an incoming beam may be distributed along two or more optical paths. A receiving channel is then moved to different positions for receiving the portion of the light that is passed by one of the collimators to accomplish switching.