Abstract: Optical systems such as, for example, optical switches, are disclosed comprising a solid component and a refractive index-matching liquid composition interfaced with the solid component. The liquid composition has a refractive-index that is substantially equal to that of the solid component. In one approach the liquid composition is a saturated cyclic compound consisting essentially of carbon and hydrogen and optionally oxygen such as, e.g., cyclic alkanes, alcohols or ketones. In another approach the liquid composition is benzene substituted with one or more electron-donating groups attached directly to the ring and one of more fluoro groups attached to the ring or to the electron-donating groups. In yet another approach the liquid composition is a combination comprising one or more of benzene or substituted benzene and optionally at least one of an alkane or substituted alkane having a boiling point less than about 130° C.

Abstract: A system for manipulating optical signals in an optical switch utilizes a piezoelectric membrane. The membrane is selectively enabled to switch among an outward position, an inward position and a relaxed orientation in relation to a sidewall of a trench that is provided as part of the switch. The membrane is in fluidic communication with an intersecting gap of the trench that crosses a first input waveguide and a first output waveguide. Displacing the membrane to a first position causes the gap to be filled with an index-matching liquid such that light from the first input waveguide is transmitted to the first output waveguide. Alternatively, displacing the membrane to a second position causes the gap to be filled with a gaseous bubble, resulting in a refractive index mismatch, such that the light from the first input waveguide is diverted at the gap. In another embodiment, there are two membranes utilized for manipulating optical signals.

Abstract: A system for manipulating optical signals in an optical switch utilizes a light-absorbing region. The region efficiently converts light to thermal energy and is in thermal communication with an index-matching fluid disposed within an intersecting gap between a first input optical waveguide and a first output optical waveguide. In one embodiment, exposing the region to optical radiation elevates the temperature of the fluid within the gap, resulting in vaporization of the fluid into gas. Filling the gap with gas creates a refractive index mismatch that causes light from the first input waveguide to be diverted to a second output waveguide. In another embodiment, the manipulation of optical signals is achieved by exposing a light-absorbing fluid to the source radiation.

Abstract: A system for manipulating optical signals in an optical switch utilizes a light-absorbing region. The region efficiently converts light to thermal energy and is in thermal communication with an index-matching fluid disposed within an intersecting gap between a first input optical waveguide and a first output optical waveguide. In one embodiment, exposing the region to optical radiation elevates the temperature of the fluid within the gap, resulting in vaporization of the fluid into gas. Filling the gap with gas creates a refractive index mismatch that causes light from the first input waveguide to be diverted to a second output waveguide. In another embodiment, the manipulation of optical signals is achieved by exposing a light-absorbing fluid to the source radiation.

Abstract: Optical systems such as, for example, optical switches, are disclosed comprising a solid component and a refractive index-matching liquid composition interfaced with the solid component. The liquid composition has a refractive-index that is substantially equal to that of the solid component. In one approach the liquid composition is a saturated cyclic compound consisting essentially of carbon and hydrogen and optionally oxygen such as, e.g., cyclic alkanes, alcohols or ketones. In another approach the liquid composition is benzene substituted with one or more electron-donating groups attached directly to the ring and one of more fluoro groups attached to the ring or to the electron-donating groups. In yet another approach the liquid composition is a combination comprising one or more of benzene or substituted benzene and optionally at least one of an alkane or substituted alkane having a boiling point less than about 130° C.

Abstract: A system for manipulating optical signals in an optical switch utilizes a piezoelectric membrane. The membrane is selectively enabled to switch among an outward position, an inward position and a relaxed orientation in relation to a sidewall of a trench that is provided as part of the switch. The membrane is in fluidic communication with an intersecting gap of the trench that crosses a first input waveguide and a first output waveguide. Displacing the membrane to a first position causes the gap to be filled with an index-matching liquid such that light from the first input waveguide is transmitted to the first output waveguide. Alternatively, displacing the membrane to a second position causes the gap to be filled with a gaseous bubble, resulting in a refractive index mismatch, such that the light from the first input waveguide is diverted at the gap. In another embodiment, there are two membranes utilized for manipulating optical signals.

Abstract: Optical systems for selectively altering the propagation of light are provided. A representative optical system incorporates an optical device that includes a first para-electric holographic medium. The first para-electric holographic medium stores a first hologram that can exhibit a first active mode. The first hologram exhibits the first active mode when a first electric field is applied to the first para-electric holographic medium. When in the first active mode, the first hologram directs light incident upon the first holographic medium to a first location. Methods and other systems also are provided.

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 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: 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: A method for determining the optimum ambient pressure at which to form a bubble in a liquid. Forming a bubble in a liquid has application in a variety of applications in which a bubble is formed in a liquid. Determining the optimum ambient pressure minimizes the amount of energy required to form the bubble in the liquid.

Abstract: An optical switching device and a method of providing temperature control for the device utilize compensating thermal energy to maintain a consistent operating temperature. The optical switching device may be a thermally activated optical switch that routes optical signals using bubbles that are strategically created along optical paths within the device. The bubbles are created by thermal energy generated by switching heating elements. The compensating thermal energy may be generated by at least one compensating heating element or by at least one switching heating element that is not currently being used for optical switching, i.e., bubble creation. The compensating thermal energy is varied so that total thermal energy generated by the device is constant, which results in a consistent operating temperature. In a first embodiment, the device includes additional heating elements that are selectively activated to generate the compensating thermal energy.

Abstract: An optical switch that is constructed on a substrate having first and second waveguides that intersect at a gap having a predetermined width. The first and second waveguides are positioned such that light traversing the first waveguide enters the second waveguide when the gap is filled with a liquid having a first index of refraction. The gap is part of a trench in the substrate having a first region that includes the gap and a second region adjacent to the first region. The second region has a width greater than the width of the first region. A liquid having the first index of refraction is disposed in the first region. The liquid generates a gas when heated to a predetermined temperature. A first heater is disposed in the first region for heating the liquid to the predetermined temperature thereby generating a gas bubble in the liquid at the gap. Light traversing the first waveguide is reflected by the gap when the gap is filled with a gas.

Abstract: A switching device includes a substrate, a first waveguide segment, a second waveguide segment, a heating device, a liquid, and a pressure controlling mechanism. The substrate is coupled to the first waveguide segment and the second waveguide segment, and the substrate includes a chamber that separates the first waveguide segment from the second waveguide segment. The liquid is disposed in the chamber and is responsive to the heating device. The pressure controlling mechanism controls a pressure in the chamber such that inadvertent bubbles are prevented from forming between the first waveguide segment and the second waveguide segment.

Abstract: The invention discloses and claims a signal amplification method for detecting a target nucleic acid analyte having a homopolymeric region and a target sequence. The method comprises (a) contacting an analyte under hybridizing conditions with a multiplicity of reporter probes, each probe including a signal region and an oligonucleotide sequence which is complementary to, and capable of forming a stable hybrid with the analyte homopolymeric region; and (b) forming an analyte:capture probe hybrid by contacting the analyte target sequence with a capture probe under hybridizing conditions.

Abstract: A signal amplification method for detecting a target nucleic acid analyte having a homopolymeric region and a target sequence includes steps of: contacting an analyte under hybridizing conditions with a multiplicity of reporter probes, each reporter probe including a signal region and an oligonucleotide sequence which is complementary to and capable of forming a stable hybrid with the analyte homopolymeric region to form an analyte:reporter probe hybrid; and forming an analyte:capture probe hybrid by contacting the analyte target sequence with a capture probe under hybridizing conditions. The analyte:reporter probe hybrid may formed prior to contacting the analyte target sequence with the capture probe, so the result of contacting the analyte target sequence with the capture probe results in formation of an analyte:reporter probe:capture probe complex. The analyte:capture probe hybrid may be immobilized on a solid generally planar surface in an array format.

Abstract: The invention discloses and claims a signal amplification method for detecting a target nucleic acid analyte having a homopolymeric region and a target sequence. The method comprises (a) contacting an analyte under hybridizing conditions with a multiplicity of reporter probes, each probe including a signal region and an oligonucleotide sequence which is complementary to, and capable of forming a stable hybrid with the analyte homopolymeric region, whereby the hybridization of multiple reporter probes to the homopolymeric region provides for signal amplification; and (b) forming an analyte:capture probe hybrid by contacting the analyte target sequence with a capture probe under hybridizing conditions.

Abstract: A method and system of operating a laser device includes utilizing an integral power-regulation sensor of the laser device to detect energy back reflected from an object of interest and then using the detected signal as a basis for determining a characteristic related to the object of interest. In the preferred embodiment, the determined characteristic is the position of the beam focus relative to a surface of the object. Also in the preferred embodiment, the integral power-regulation sensor is disconnected from power-regulation circuitry during the focusing operation. Interaction of the back reflected energy and the outgoing beam can be reduced by introducing beam rotation, such as by providing a quarter-wave plate along the beam path. Focusing sensitivity can be increased by locating reflective targets over the surface and by executing AC measurements to filter DC components from the signal.

Abstract: An optical measurement system includes a test surface having disposed thereon a plurality reference markings and a plurality of test spots containing chemical and biological substances. Molecules of interest contained in the chemical and biological substances are tagged with optically detectable labels. A light source generates a beam of light which is then directed by a deflecting sub-system across the test surface, thereby individually impinging the test spots and the reference markings. Optical signals resulting from the impingement are detected by a detection means, which records such detection and the time of the detection. The reference markings have optically unique signatures to distinguish the markings from the optical signatures of the signals emitted from the chemical and biological substances in the test spots. The reference markings are spaced apart at known distances and serve to provide a constant calibration of the scan speed of the beam of light.

Abstract: Composite holograms are disclosed wherein microvoids between the holographic interference fringes are filled with a liquid crystal. The diffraction efficiency and other holographic properties of such composite holograms may be varied by external stimuli, e.g., application of an electric field of thermal energy.