Abstract: The invention disclosed herein includes various embodiments and components of a solid state analog altimeter switch useful for generating switching signals based on altitude determined from barometric pressure. Embodiments of the solid state analog altimeter switch disclosed herein are designed to be extremely accurate, small, robust and inexpensive to produce. Such solid state analog altimeter switches are particularly useful for generating switching events based on predetermined altitudes in sounding rockets.

Abstract: An encoder includes a scale that includes a plurality of unit block patterns arranged in a position measuring direction with a period of a pitch. A pattern of the unit block pattern has a symmetrical shape with respect to a symmetry line perpendicular to the position measuring direction. Each unit block pattern includes a plurality of divided sections along a direction perpendicular to the position measuring direction. An area ratio of the pattern which is a value made by dividing an area of the pattern in each divided section by an area of the divided section is different between two adjacent divided sections. The pattern in each divided section has a rectangular shape defined by two parallel lines that extend in the position measuring direction and two parallel lines that extend in the direction perpendicular to the position measuring direction.

Abstract: A detection device detects a thickness anomoly region within a strip of stock and includes a first roller operatively rotating as the strip of stock passes over a first roller surface; a pivotally mounted pinch roller positioned to operatively pivot about a pivot axis against the strip of stock passing over the first roller; a photoeye mask positioned to rotate about the pivot axis responsive to pivotal movement of the pinch roller; a photoeye slot within the photoeye mask extending between a slot leading end and a slot trailing end; and the transmitting and receiving optical devices positioned on opposite sides of the photoeye slot of the photoeye mask and operative in an photoeye mask-aligned position to project a centered through-beam through the photoeye slot between the transmitting and receiving optical devices.

Abstract: A detection device detects a thickness anomoly region within a strip of stock and includes a first roller operatively rotating as the strip of stock passes over a first roller surface; a pivotally mounted pinch roller positioned to operatively pivot about a pivot axis against the strip of stock passing over the first roller; a photoeye mask positioned to rotate about the pivot axis responsive to pivotal movement of the pinch roller; a photoeye slot within the photoeye mask extending between a slot leading end and a slot trailing end; and the transmitting and receiving optical devices positioned on opposite sides of the photoeye slot of the photoeye mask and operative in an photoeye mask-aligned position to project a centered through-beam through the photoeye slot between the transmitting and receiving optical devices.

Abstract: In an example embodiment, a system detects the degree of rotation of a knob, the system comprises a shaft having a length and a first end and a second end; the second end has an oblique reflective surface defined thereon; the first end fixedly attached to the knob. Containing the shaft is a rotation body, having a receptacle to accommodate the second end of the shaft with the oblique reflective surface exposed. An integrated circuit optical module is optically coupled the rotation body and the optical module detects light irradiance profile from the oblique reflective surface. The optical module includes a solid state light source and a plurality of photo detectors which generate an electrical signal upon exposure to light. As the knob is rotated, the oblique reflective surface generates a changing asymmetric irradiance profile, the change being translated into an electrical signal via the photo detectors. The electrical signal corresponds to the degree of rotation of the knob.

Abstract: An optical encoder is configured as follows. Namely, the optical encoder includes a signal processing circuit which processes encoder signals output from a plurality of encoder heads, a control unit which specifies one of the plurality of encoder heads, sets the signal output of the specified encoder head in an on state, and further sets the outputs of the encoder heads not specified in an off state, thereby causing only the specified encoder head to output an encoder signal to the signal processing circuit, switch signal lines, and a common wiring line which is shared by the plurality of encoder heads and which transmits the encoder signals to the signal processing circuit.

Abstract: A method for determining the position of one of two components in relative motion with respect to each other, using optical means, comprises: directing at least one light beam emitted by a light source attached to one component towards a diffractive support attached to the second component, calculated and manufactured for generating an optical signal indicative of the positioning of said support, the optical signal being produced by the diffractive support in transmission and/or in reflection, and the optical signal including information indicative of its quality; detecting and reading at least one optical code formed by said signal, which corresponds to a unique position of the diffractive support relatively to the beam; and assigning a position to each detected optical code.

Abstract: A reflection mirror that causes an illumination light to be incident on a movable scale is oscillated in an X-axis direction based on a modulation signal. Accordingly, the optical path of the illumination light, of the illumination light and another illumination light generated at an index scale, periodically changes, and as a consequence, the illumination light is periodically modulated. Accordingly, an extra scanner that scans the illumination light or another illumination light with respect to the movable scale does not have to be arranged, which allows an apparatus to be reduced in size and cost.

Abstract: The present invention relates to a method for calibrating a grating of an encoder measurement system between two adjacent calibrated locations, the method includes moving one of a sensor object including an encoder-type sensor and a grating along the other one of the sensor object and the grating with a speed, wherein the speed is selected such that disturbances in the grating substantially extending over a distance smaller than a distance between the two calibrated locations can not or only partly be followed by the one of the sensor object and the grating, and measuring during the moving the position of the sensor object with respect to the grating at a plurality of locations between the two calibrated locations.

Abstract: A method for determining the position of one of two components in relative motion with respect to each other, using optical means, comprises: directing at least one light beam emitted by a light source attached to one component towards a diffractive support attached to the second component, calculated and manufactured for generating an optical signal indicative of the positioning of said support, the optical signal being produced by the diffractive support in transmission and/or in reflection; detecting and reading at least one optical code formed by said signal, which corresponds to a unique position of the diffractive support relatively to the beam; and assigning a position to each detected optical code.

Abstract: A method for determining the position of one of two components in relative motion with respect to each other, using optical means, comprises: directing at least one light beam emitted by a light source attached to one component towards a diffractive support attached to the second component, calculated and manufactured for generating an optical signal indicative of the positioning of said support, the optical signal being produced by the diffractive support in transmission and/or in reflection, and the optical signal including information indicative of its quality; detecting and reading at least one optical code formed by said signal, which corresponds to a unique position of the diffractive support relatively to the beam; and assigning a position to each detected optical code.

Abstract: The instrument panel gauge assembly includes an applique having gauge graphics printed thereon and a needle pointer for a gauge assembly positioned adjacent thereto. A transparent chaplet is formed within the applique to allow light to pass through. The needle passes over the chaplet as the needle moves. When the needle is positioned directly in front of the chaplet, light is blocked from passing through the chaplet. A light sensing element is positioned behind the applique to detect the presence of light passing through the chaplet. A light baffle guides light passing through the chaplet to the light sensing element. A controller receives a signal from the light sensing element indicating when the needle pointer is directly in front of the chaplet. The controller then compares the actual input to the gauge with the position of the needle pointer, calculates a correction factor, and calibrates the gauge accordingly.

Abstract: A method and system for generating modulated optical vortices. Optical vortices can be used for a variety of applications, such as applying controlled torque or controlled force patterns to objects from a few nanometers to hundreds of micrometers in size. Numerous optical modes of optical vortices can be created to meet virtually any desired need in manipulating of objects. Furthermore, one can modify the wavefront of a beam of light in a specific way to create a new type of optical trap useful for manipulating mesoscopic materials. When the modified beam is brought to a focus, the resulting optical trap exerts forces transverse to the optical axis that can be used to transport mesoscopic matter such as nanoclusters, colloidal particles, and biological cells.

Abstract: A method and system for generating modulated optical vortices. Optical vortices can be used for a variety of applications, such as applying controlled torque or controlled force patterns to objects from a few nanometers to hundreds of micrometers in size. Numerous optical modes of optical vortices can be created to meet virtually any desired need in manipulating of objects. Furthermore, one can modify the wavefront of a beam of light in a specific way to create a new type of optical trap useful for manipulating mesoscopic materials. When the modified beam is brought to a focus, the resulting optical trap exerts forces transverse to the optical axis that can be used to transport mesoscopic matter such as nanoclusters, colloidal particles, and biological cells.

Abstract: An optical accelerometer for detecting an acceleration of a proof mass includes a source of optical radiation for generating a pair of beams of output radiation. The pair of beams of optical radiation exerts radiation pressure on the proof mass, so as to maintain the proof mass in an equilibrium position along a sensing axis. A position detecting system detects a displacement from the equilibrium position of the proof mass along the sensing axis in response to an inertial force acting on the proof mass. A modulator adjusts the intensity of each one of the pair of beams, so as to restore the proof mass to the equilibrium position along the sensing axis. The difference in the adjusted intensities of each one of the pair of beams is representative of the acceleration, resulting from the inertial force, of the proof mass along the sensing axis.

Abstract: An apparatus and method sensing the absolute position of a gauge. A pointer having a predefined rotation with a circular travel pattern. At least one light emitting diode that generates an optical signal. An optical sensor placed in a fixed position along the circular travel pattern of the pointer. A pointer driver for driving the pointer.

Abstract: An apparatus (100) for sensing angular rotation includes a rotor (102) that is rotatable about an axis (104). The rotor (102) has an outer periphery (e.g., cylindrical outer sidewall 106) with a plurality of reflective facets (e.g., 108A-108J). Each juncture between each adjacent pair of the facets (e.g., 108A and 108B) defines a vertex (e.g., 125A). A light source (118) emits a light beam (120) onto the rotor (102). The light beam (120) is reflected by the facets (e.g., 108B) and occasionally bifurcated by the vertices (e.g., 125A). A light detector (126) detects light from the reflected light (124). The light detector (126) provides a detector signal (116) indicative of the angular rotation of the rotor (102). Compensation circuitry (134, 138) compensates for bifurcation of the reflected light (124) and provides a compensated output signal (140) indicative of angular rotation of the rotor (102).