Abstract: A scanning probe microscope includes a cantilever, a scanning mechanism which relatively scans the cantilever and a sample which exist in liquid, and an application mechanism which applies photolytic light to a caged compound existing in the liquid or the sample.

Abstract: Briefly, in accordance with one or more embodiments, an operational state of a MEMS device of a scanner system may be determined. In the event it is determined that the MEMS device is possibly operating in an unsafe mode, the laser may be turned off and/or the MEMS device may be shut down. An operational state of the MEMS device may be determined for example by obtaining a MEMS drive voltage sense signal and/or a MEMS drive current sense signal, and a potentially unsafe mode of operation may be identified if one or more of such signals are not at proper values with respect to predetermined threshold values.

Abstract: An optical scanning system and an image forming apparatus having the same. The optical scanning system includes a light source, a deflector, an input optical system for directing a light beam from the light source to the deflector, and an imaging optical system for directing the light beam deflected by the deflector onto a surface to be scanned. The input optical system includes a first optical element having a power both in a main-scan sectional plane and in a sub-scan sectional plane, and a second optical element having a power in the sub-scan sectional plane. At least one surface of the first optical element has a shape being rotationally asymmetrical and, in the sub-scan sectional plane, being non-arcuate.

Abstract: An apparatus is adapted for confocal imaging of a non-flat specimen, and includes a light source for producing a light beam, imaging optics adapted to focus the light beam into at least one spot on a surface of a specimen, and a detector adapted to receive and detect light reflected from the specimen surface. The light source includes an optical system for converting a coherent beam into a plurality of beams, each of which is modified by a moving diffuser within a range of movement that is correlated to the detector's integration time.

Abstract: A scan data collection operation includes performing a scanning operation using a scan path that includes a directional component that is additional to a data collection directional component. The collected scan data is mapped to another set of locations, thus allowing for detection of surface features using fewer scans.

Abstract: A method and apparatus for focusing an image on a pixel array. The method includes the steps of continuously changing the distance between a lens and a pixel array between a first distance and a second distance and obtaining an image projected onto the pixel array through the distance is changing. The apparatus includes a lens and an electromechanical structure to continuously change the distance between the lens and the pixel array between the first distance and the second distance.

Abstract: A MEMS oscillator, such as a MEMS scanner, has an improved and simplified drive scheme and structure. Drive impulses may be transmitted to an oscillating mass via torque through the support arms. For multi-axis oscillators drive signals for two or more axes may be superimposed by a driver circuit and transmitted to the MEMS oscillator. The oscillator responds in each axis according to its resonance frequency in that axis. The oscillator may be driven resonantly in some or all axes. Improved load distribution results in reduced deformation. A simplified structure offers multi-axis oscillation using a single moving body. Another structure directly drives a plurality of moving bodies. Another structure eliminates actuators from one or more moving bodies, those bodies being driven by their support arms.

Abstract: A display apparatus is provided. A light beam emitted from a light source is applied through a light modulator and a projecting optical system to a scanning mirror. The light beam is reflected and scanned by the scanning mirror, and applied to a magnifying projection system entrance unit. A detection light beam emitted from a mirror angle detecting light source is reflected and scanned by the scanning mirror, and applied to a linear detector. Operation of the scanning mirror is controlled based on the position of the detection light beam which is detected by the linear detector. The present invention is applicable to a front projector or a rear projector.

Abstract: An illumination device that illuminates an original document by propagating an illuminating light beam output from each of a plurality of light emitting diodes from a first end surface of a light guide to a second end surface of the light guide. Assuming that A is a dimension from the first end surface of the light guide to the second end surface of the light guide, B is an interval between adjoining light emitting diodes, the light emitting diodes being arranged in an array format in a main scanning direction, n1 is a refractive index of atmosphere outside of the light guide, and n2 is a refractive index of the light guide, a condition of tan?1(B/2A)????/2?{sin?1(n1/n2)} is satisfied.

Abstract: An image forming apparatus is provided which includes a plurality of optical scanners, each including a rotating polygon mirror adapted to scan and expose a surface of an image bearing medium to create an electrostatic latent image on the surface in accordance with image data. The apparatus further includes a plurality of phase detectors, each assigned to a respective one of the plurality of optical scanners for detecting rotated phases of the rotating polygon mirrors. Moreover, the apparatus includes a rotated phase controller configured to control the rotated phases of the rotating polygon mirrors. The rotated phase controller is configured to control the rotated phases of the rotating polygon mirrors in accordance with results of detection by the plurality of rotated phase detectors so that rotated phase relationships of the rotating polygon mirrors are set to a predetermined pattern.

Abstract: The invention provides a scanning platform for high speed scanning of microarrays. The platform uses a novel flexible a metal strip/wheel linear driving system to convert rotary movement of motors into linear movement, thereby drives movement of a stage/microarray in the direction of scanning. The platform of the present invention provides high movement speed, high resolution, and low return deviation. It is also simple in structure and low in manufacturing cost.

Abstract: The invention provides a method of detecting a chemical species with an oscillating cantilevered probe. A cantilevered beam is driven into oscillation with a drive mechanism coupled to the cantilevered beam. A free end of the oscillating cantilevered beam is tapped against a mechanical stop coupled to a base end of the cantilevered beam. An amplitude of the oscillating cantilevered beam is measured with a sense mechanism coupled to the cantilevered beam. A treated portion of the cantilevered beam is exposed to the chemical species, wherein the cantilevered beam bends when exposed to the chemical species. A second amplitude of the oscillating cantilevered beam is measured, and the chemical species is determined based on the measured amplitudes.

Abstract: A scanner optical module has a single transmission axle used to support a scanning module (containing a traditional optical device or CIS). The scanning module has a plurality of protrusions (or rollers) slidably (or rotatably) contacting the transparent document platform (view). The scanner optical module has fewer assembled components, a simpler structure, a decreased material cost and production cost, and is modular.

Abstract: A scanning microscope for the optical measuring of an object in which a measurement beam emitted by the light source impinges the object and is reflected by the object as a reflection beam that reenters through the lens into the radiation path of the microscope. A scanner control unit controls a displacement to change the relative position of the object and the measuring beam so that the beam is directed to at least two different measuring points on the object. An excitation unit periodically excites the object. The reflection beam is visualized on a signal detector, and a signal storage unit saves a measuring sequence of signals of the signal detector. The scanner control unit cooperates with the excitation and signal storage units to control them such that for each measuring point on the object at least one measuring sequence of measuring signals of the signal detector is saved.

Abstract: Apparatus and techniques are provided for modifying and measuring surfaces of diamond workpieces and other workpieces with nanoscale precision. The apparatus and techniques exploit scanning probe microscopy (SPM) and atomic force microscopy (AFM) at a wide range of operating temperatures. In some embodiments, the SPM/AFM apparatus also includes an interferometric microscope and/or acoustic-wave microscope for making high-precision measurements of workpiece surfaces.

Abstract: In one embodiment a micro-electro mechanical system is disclosed. A MEMS structure can include a frame, a movable structure and a set of structural beams to suspend the movable structure from the frame. The system can also include a set of conductor routing beams. The conductor routing beams can provide a conductive path from the frame to the movable structure. The set of structural beams can have a spring rate that is more than ten times the spring rate of the set of conductor routing beams. Accordingly, multiple routing beams can be utilized to support multiple conductors without significantly affecting the mechanical movement or dynamic properties of the movable structure.

Abstract: A system and method for dispersion-force-based actuation are disclosed. In some embodiments, a light beam is used to change the dispersion force between two spaced apart surfaces. The change in the dispersion force causes a change in the gap between the surfaces. The actuation system can be used in conjunction with a deformable mirror to provide an improved adaptive optics system.

Abstract: A system for driving a torsion based on frequency, amplitude and offset control signals includes a pulse width modulator subsystem configured to generate output pulses having controlled pulse durations alternately to each of two channels, the output pulses encoding the frequency, amplitude and offset control signals. A driver circuit is configured for driving the torsion oscillator with a voltage of one polarity during a pulse output to the one of the channels, and a voltage of opposite polarity during a pulse output to the other of the channels.

Abstract: Array scanning methods that focus on the far side and devices configured for use in the same are provided. In reading arrays according to the subject methods, an array is placed in a reading position of a scanning device so that the nominal focal plane of the scanning device is present within the array substrate at a predetermined fixed substrate thickness fraction distance from the far-side of the array, and the array is then read by the device. As such, the subject scanner devices of the present invention are configured to hold an array substrate in a reading position of the device in which the device's nominal focal plane is present within the array substrate. The subject methods and devices find use in a variety of different applications, including both genomic and proteomic applications.

Abstract: A scanned beam imager or laser scanner is operable to scan an object moving through its field-of-view. The system may include means for detecting direction and/or speed of the object. The velocity detection means may include sensors, an interface for receiving velocity information from other system elements, or image analysis that examines the skew, stretch, or compression in images. Responsive to object movement direction and speed, the scanned beam imager may alter its pixel capture rate and/or its scan rate to compensate. Alternatively or in combination, the imager may perform software-based image motion compensation. In some embodiments, the system may allow the image capture region to pace objects moving rapidly through its field-of-view.

Abstract: A flexure carriage assembly (24) has a carriage (25) formed of a substantially rigid material. The carriage has four elongate columns (32A, 32B, 32C, 32D) arranged spaced apart and parallel to one another. Each of the elongate columns has first and second ends. The flexure carriage (25) has four first cross members disposed between adjacent pairs of elongate columns and arranged to interconnect the first ends. The flexure carriage also includes four second cross members (38A-D) arranged between adjacent pairs of elongate columns and arranged to interconnect the bottom ends. The elongate columns and first and second cross members define a three-dimensional rectangular structure. The flexure carriage also has disposed centrally between the four elongate columns a translating section (29) spaced equidistant between the first and second ends of the columns.

Abstract: A method for sorting integrated circuit (IC) devices of the type having a fuse identification (ID) into those devices requiring enhanced reliability testing and those requiring standard testing includes storing fabrication deviation data, probe data, and test data in association with the fuse ID of each of the devices indicating each of the devices requires either enhanced reliability testing or standard testing. The fuse ID of each of the devices is then automatically read before, during, or after standard testing of the devices. The testing process requirement data stored in association with the fuse ID of each of the devices is then accessed, and the devices are sorted in accordance with the accessed data into those devices requiring enhanced reliability testing and those requiring standard testing.

Abstract: A system is provided to monitor a structure within an outer casing of a gas turbine engine. The system may comprise an optical fiber bundle, a fiber bundle palette and a camera palette assembly. The optical fiber bundle may have first and second ends. The first end is adapted to pass through a bore in the outer casing of the gas turbine engine so as to be positioned adjacent the structure within the gas turbine engine casing to be monitored. The fiber bundle palette is adapted to be located outside of the engine casing to receive the second end of the optical fiber bundle. The camera palette assembly comprises a fixture movable relative to the fiber bundle palette and a first camera mounted to the fixture. The first camera is adapted to be positioned adjacent to the second end of the optical fiber bundle so as to receive electromagnetic radiation received by the first end of and transmitted through the optical fiber bundle.

Abstract: An optical scanning probe is provided and includes an optical scanning element which scans a subject with light, and a signal switching section for switching a drive signal for making the optical scanning element perform optical scanning. The optical scanning element includes a movable portion having a micro mirror which is displaced in a first rotating direction and a second rotating direction, and first and second drivers which apply physical acting forces to the movable portion. The signal switching section has a function for switching a driving preparation signal for attracting the movable portion in either the first rotating direction or the second rotating direction into a scanning drive signal for attracting the movable portion in the first rotating direction and the second rotating direction alternately. The maximum voltage of the driving preparation signal is set value to be higher than the maximum voltage of the scanning drive signal.

Abstract: An optical waveguide device includes: a channel waveguide which is positioned at a predetermined height relative to a bottom surface of a substrate; and a slab waveguide having a cross-sectional shape wider than that of the channel waveguide, being positioned at a predetermined height relative to the channel waveguide. Initially, an input end face of the optical waveguide device is vertically scanned with a light beam to achieve optical coupling with the slab waveguide, followed by transversely scanning to achieve optical coupling with the channel waveguide, hence, alignment of an optical axis with a minute channel waveguide can be effected easily and quickly.

Abstract: A scanning near-field optical microscope detects the evanescent field formed about an illuminated sample 14 via an interaction between the field and a local probe 20.The probe 20 is scanned across the sample surface in order to collect a complete image as a succession of scan lines. In the microscope of this invention, image collection is more rapidly performed by translating the probe 20 whilst it is oscillated at or near its resonance frequency. In this way a series of scan lines covering an area of the sample surface are rapidly collected, the length of each scan line being determined by oscillation amplitude.

Abstract: In a wound scanning apparatus and method, a beam or sheet of light is scanned on a wound and reflections of the scanned beam or sheet of light interacting with the wound at a plurality of points thereof is detected. The detected reflections are processed into data representative of the wound. The data or a representation thereof is reproduced in a human understandable form.

Abstract: A circuit for detecting a phase error between a clock signal and a beam position includes a beam generator, a sensor, and a phase detector. The beam generator directs a beam toward a beam sweeper in response to the clock signal, and the sensor detects the beam as directed from the beam sweeper. The phase detector determines from the detected beam the error in the clock phase relative to the beam position. Such a circuit can automatically detect the phase error in the pixel clock and correct this error, thus eliminating the need for a manual phase-error corrector. The circuit may also be able to adjust the width and/or the height of a scan region, and thus may also be able to adjust the width and/or height of an image frame within the scan region.

Abstract: For a confocal scanning electron microscope (1) an optical zoom system (41) with linear scanning is provided, which not only makes a zoom function possible, in that a variable magnification of an image is possible, but rather which additionally produces a pupil image in the illuminating beam path (IB) [BS] and thereby makes a variable imaging length possible (distance between the original pupil (En.P) [EP] and the imaged/reproduced pupil (Ex.P) [AP]) so that axially varying objective pupil positions can thereby be compensated.

Abstract: A scanning microscope with a first and at least one other detection channel is disclosed. The first detection channel comprises at least one first detector and the other detection channel comprises at least one other detector to detect the detection light given off by a sample. A switching mechanism is provided that selectively directs the detection light into the first or into the other detection channel.

Abstract: An observation laser beam for observing a specimen and a manipulation laser beam for manipulating the specimen are multiplexed; the multiplexed beams irradiate the specimen, which is mounted on a stage, via an objective lens; and fluorescence emitted from inside the specimen in the observation optical axis direction is detected. In a preparation mode, a focal-position adjusting unit is controlled so that the focal position of the observation laser beam and the focal position of the manipulation laser beam are coincident, independent of the movement of the objective lens or the stage by a focusing mechanism; and in an observation mode, the focal-position adjusting unit is controlled so as to cancel out the shift of the focal position of the manipulation laser beam according to the movement of the objective lens or the stage.

Abstract: An optical scanner device, comprising a scanning unit, which casts irradiation light emitted from a light source in an arbitrary direction to scan an observation object, an objective lens system, which converges the irradiation light on the observation object, and a photo-detector unit, which is disposed on an optical axis of the objective lens system to have the irradiation light transmit therethrough, is provided. A position of the irradiation light converged on the observation object is detected based on a position of a light spot of the irradiation light transmitting through the photo-detector unit.

Abstract: A radar device includes a light projecting part that generates laser light, a light projecting lens that converges the generated laser light to form a beam, a reflective mirror for reflecting the converged beam to project it in a specified search direction and for reflecting returning light from this search direction, a light receiving lens for converging the returning light reflected by the reflective mirror, and a scanning part for moving the beam in a scanning manner. There are two light receiving parts which are different in photosensitivity, and a synthesizing part outputs a synthesized signal formed by synthesizing output signals from these two light receiving parts.

Abstract: To provide a technique that can contribute to improvement of an optical characteristic of an optical beam scanning device while realizing an increase in scanning speed of a light beam.

Abstract: The invention relates to an apparatus and a method for a scanning probe microscope, comprising a measuring assembly which includes a lateral shifting unit to displace a probe in a plane, a vertical shifting unit to displace the probe in a direction perpendicular to the plane, and a specimen support to receive a specimen. A condenser light path is formed through the measuring assembly so that the specimen support is located in the area of an end of the condenser light path.

Abstract: A scanning probe microscope detects or induces changes in a probe-sample interaction. In imaging mode, the probe 54 is brought into a contact distance of the sample 12 and the strength of the interaction measured as the probe 54 and sample surface are scanned relative to each other. Image collection is rapidly performed by carrying out a relative translation of the sample 12 and probe 54 whilst one or other is oscillated at or near its resonant frequency. In a preferred embodiment the interaction is monitored by means of capacitance developed at an interface between a metallic probe and the sample. In lithographic mode, an atomic force microscope is adapted to write information to a sample surface.

Abstract: The optical device 10 includes a light source 13, a mirror element 12 including a mirror 36 for reflecting light emitted from the light source 13 in a predetermined direction, and a mirror element housing body 11 that accommodates the mirror element 12 as well as seals a space D where the mirror element 12 is accommodated, characterized in that the light source 13 is provided inside the mirror element housing body 11.

Abstract: A method for scanning a surface, consisting of focusing an array of beams using optics having an axis, so as to irradiate a region of the surface intercepted by the axis, such that each beam irradiates a portion of a respective sub-region within the region. The method further includes moving at least one of the array and the surface so as to cause a translation of the surface relative to the axis in a first direction. During the translation in the first direction, each of the beams is scanned over the respective sub-region in a second direction, which is different from the first direction.

Abstract: A method for scanning a surface, consisting of focusing an array of optical beams using optics having an axis, so as to illuminate a region of the surface intercepted by the axis, such that each optical beam illuminates a portion of a respective sub-region within the region. The method further includes moving at least one of the array and the surface so as to cause a translation of the surface relative to the axis in a first direction. During the translation in the first direction, each of the optical beams is scanned over the respective sub-region in a second direction, which is different from the first direction.

Abstract: A measurement system that optically measures in turn a plurality of samples arranged in an array via an objective lens and an imaging lens is disclosed, which is characterized by comprising an actuator means that moves the above described objective lens corresponding to each position of the above mentioned samples, and a photo-detecting part that detects a sample image via the above objective lens and imaging lens.

Abstract: A method and system for fluorescence imaging of a target in a subject comprising a scattering medium is provided. The method comprises illuminating one or more points on a surface of the scattering medium using an illumination source, wherein the plurality of points define an illumination region, collecting emitted light from an illumination region and an area away from the illumination region, and generating an image of the scattering medium using the emitted light.

Abstract: The invention provides imaging apparatus and methods useful for obtaining a high resolution image of a sample at rapid scan rates. A rectangular detector array having a horizontal dimension that is longer than the vertical dimension can be used along with imaging optics positioned to direct a rectangular image of a portion of a sample to the rectangular detector array. A scanning device can be configured to scan the sample in a scan-axis dimension, wherein the vertical dimension for the rectangular detector array and the shorter of the two rectangular dimensions for the image are in the scan-axis dimension, and wherein the vertical dimension for the rectangular detector array is short enough to achieve confocality in a single axis.

Abstract: The invention provides a confocal microscope comprising a light source; a light scanning unit; an array device; a line-beam generating unit for imaging illumination light in the form of a straight line extending, on the array device, in a direction intersecting the scanning direction of the light scanning unit; an objective lens for imaging the illumination light reflected or transmitted at the array device on a specimen; a beamsplitter, between the array device and the light scanning unit, for splitting off from the illumination light detection light from the specimen; a two-dimensional image-acquisition unit for acquiring the split off detection light; and a control unit for controlling the light scanning unit and the array device, wherein the array device is disposed in an optically conjugate positional relationship with a focal plane of the objective lens, and the control unit performs control so as to synchronize the light scanning unit and the array device.

Abstract: When an image-reading module moves along and scans a glass plate of an original document bed, a flexible wiring connecting the image-reading module to a fixing point takes various shapes depending on the position of the image-reading module so as to come close to or apart from a second metallic casing of an image-reading apparatus and a first metallic casing accommodating a signal processing unit. Since insulating members are provided on the first metallic casing, a predetermined or more distance between the wiring and the surface of the first metallic casing can be always kept constant, so that an analog signal transmitting through a conductive member within the wiring can be prevented from being largely affected by changes in electrostatic capacitance.

Abstract: Briefly, in accordance with one or more embodiments, an operational state of a MEMS device of a scanner system may be determined. In the event it is determined that the MEMS device is possibly operating in an unsafe mode, the laser may be turned off and/or the MEMS device may be shut down. An operational state of the MEMS device may be determined for example by obtaining a MEMS drive voltage sense signal and/or a MEMS drive current sense signal, and a potentially unsafe mode of operation may be identified if one or more of such signals are not at proper values with respect to predetermined threshold values.

Abstract: A MEMS oscillator, such as a MEMS scanner, has an improved and simplified drive scheme and structure. Drive impulses may be transmitted to an oscillating mass via torque through the support arms. For multi-axis oscillators drive signals for two or more axes may be superimposed by a driver circuit and transmitted to the MEMS oscillator. The oscillator responds in each axis according to its resonance frequency in that axis. The oscillator may be driven resonantly in some or all axes. Improved load distribution results in reduced deformation. A simplified structure offers multi-axis oscillation using a single moving body. Another structure directly drives a plurality of moving bodies. Another structure eliminates actuators from one or more moving bodies, those bodies being driven by their support arms.

Abstract: Aspects of the subject matter described herein relate to reducing error in images obtained from an image-acquiring system. An image-acquiring system may be modeled as light received from a primary path, light received from a secondary path, and light received from all other paths. Light received from the secondary and other paths may cause error in images captured by the image-acquiring system. By compensating for this light, the error may be reduced. Other aspects are described in the specification.

Abstract: A reading-line adjusting device of an image scanner includes an image sensing module, a shaft, a bush member, and a fixing and adjusting member. The image sensing module has a reading line for sensing an electronic signal of an image. The shaft is arranged in a first direction. The bush member includes a base and a bushing body. The base is coupled with the image sensing module. The bushing body is sleeved around the shaft and moved along the shaft. The fixing and adjusting member is used for fixing the base of the bush member onto the image sensing module and adjusting an angle between the base and the image sensing module such that the reading line of the image sensing module is arranged in a second direction.

Abstract: A positioning apparatus for a printer is provided. The positioning apparatus includes at least one encoder, an OPC belt, and a code strip consisting of a reference bar code region, a blank region and normal bar code region. The OPC belt is moved relatively to the encoder and has a joint region. The code strip is mounted on the OPC belt and has a plurality of bar codes. The encoder is used for detecting the bar codes and generating a displacement signal representing a displacement of the OPC belt moved relatively to the encoder. The blank region may be adjoined the joint region. Therefore, a home position can be located precisely by the displacement signal due to the existence of the reference bar code region and blank region. Moreover, a positioning method for a printer is also disclosed.

Abstract: Light barrier device, comprising a housing, a light source, by means of which a radiation beam may be emitted, and a light receiver, wherein the light source and/or the light receiver is positioned on the housing with a joint device, by means of which the light source and/or the light receiver is movable relative to the housing for alignment of the optical axis.