Abstract: A congruence reduction algorithm that forms composite lenslets by reducing data of a plurality of focal spot locations using linear transformations. Use of the congruence reduction algorithm increases the speed of calculations by which corrective elements such as deformable mirrors function, reduces the number of lenslets in an array and improves reconstruction time and focal spot quality.

Abstract: Provided are an imaging device unit and a photographing apparatus. The imaging device unit includes an imaging device having an imaging plane on which an optical image of a subject is formed, wherein the imaging unit is configured to convert the optical image into an electrical signal; an optical unit disposed nearer to the subject than the imaging device; a plate that is mounted on a boundary portion of the optical unit, wherein at least an outer portion of the plate extends over an outer edge of the optical unit; a piezoelectric element that is mounted on the plate and configured to vibrate the plate and the optical unit; and a supporting frame that supports the at least outer portion of the plate extending over the outer edge of the optical unit.

Abstract: The invention refers to a compact multispectral scanning system comprising a primary mirror (1) and secondary mirror (2), wherein the mirrors face each other, are adapted to be rotated at the same angular speed in opposite directions, and are tilted with respect to their rotation axes. The primary mirror is concave, the secondary mirror is smaller than the primary mirror and the rotation axes of both mirrors are aligned. This arrangement makes the system more compact than prior art devices and avoids the dependency of the system on the operation frequency.

Abstract: An image display device is provided, by which variations in drive sensitivity of a scan mirror is corrected. Processing executed by a CPU in a laser projector includes the steps of: driving a scanner mirror in a vertical direction; allowing at least one of a green laser and red/blue lasers to emit light; calculating stay time in a light-receiving region in a photoreceptor; comparing the calculated stay time with ideal stay time Tideal; decreasing a tilt of a drive signal for driving the scanner mirror in the vertical direction if the calculated stay time is shorter than the stay time Tideal; and increasing the tilt of the drive signal if the calculated stay time is longer than the stay time Tideal.

Abstract: A method and apparatus for in-situ metrology of a workpiece disposed in a vacuum processing chamber. The apparatus may include an optical assembly external to the processing chamber configured to focus a relatively large optical spot over a relatively large working distance to acquire a TE and TM spectra from a periodic array on the workpiece. The workpiece may be disposed in the processing chamber with an arbitrary orientation which is first determined via a reflectance measurement. TE and/or TM spectra may then be acquired by initiating a periodic triggering of a flash lamp based on the determined workpiece orientation to account for variation in placement of the workpiece within the processing chamber. The periodic array from which spectra are collected may be a memory array being fabricated in a semiconductor wafer.

Abstract: A scanning endoscope comprising a light transmitter, an actuator, and a force transmitter, is provided. The light transmitter emits a beam of the light exiting the first emission end. The light transmitter is flexible. A longitudinal direction of the light transmitter is a first direction. The actuator is mounted near the first emission end. The actuator bends the light transmitter in a second direction by pushing a side of the light transmitter in the second direction. The second direction is perpendicular to the first direction. A force transmitter is oriented lengthwise in the first direction. The force transmitter is elastic. The force transmitter is positioned between the light transmitter and the actuator. The force transmitter exerts a pushing force supplied by the actuator on the side of the light transmitter while the force transmitter is deformed elastically toward the first direction.

Abstract: A bidirectional optical scanner assisting in mammography is revealed. The optical scanner that calculates functional images obtained by diffuse optical tomography, used in combination with a mammography machine can reduce the number of mammograms taken and the dose exposure. The bidirectional optical scanner includes a first compression plate, a first optical detection module, a second optical detection module and a second compression plate. The same test position of the tested breast can be detected twice in different directions by the first and the second optical detection modules. No matter where the tumor is located, the tumor can be detected. Besides structural images provided by the mammography machine, functional tomographic images of the breast are obtained by the bidirectional optical scanner. Thus diagnostic accuracy in the detection of breast cancer is improved.

Abstract: A device for handling a substantially circular wafer is provided. The device includes an interior accessible through a plurality of entrances, and a plurality of sensors consisting of two sensors for each one of the plurality of entrances, each sensor capable of detecting a presence of the substantially circular wafer, at a predetermined location within the interior, wherein the plurality of sensors are arranged so that at least two of the plurality of sensors detect the wafer for any position of the wafer entirely within the interior, wherein a first one of the two sensors is positioned to detect the wafer when the wafer has passed entirely into the interior through one of the plurality of entrances, and a second one of the two sensors is positioned immediately outside a diameter of the wafer when the wafer has passed entirely into the interior through one of the plurality of entrances.

Abstract: Light beams from light sources 1, 2 are scanned by a galvano mirror 10a to illuminate a predetermined portion 15b of an object to be observed 15 via an objective lens 14. The reflected light from the object is re-scanned by the galvano mirror 10a to obtain a two-dimensional image via an image-capturing element 25. Measuring means composed of an OCT interferometer 32 is branched or coupled in the optical path between the objective lens 14 and the galvano mirror 10a to obtain a tomographic image of the object. In this configuration, the two-dimensional image and the tomographic image of the object can be displayed simultaneously on a display device 28.

Abstract: A laser radar system is provided with a laser light source which emits laser light, a light scanning portion which causes the laser light to scan a target area, an optical filter which removes light of an angle component different from an angle component of reflected light of the laser light from the target area, a photodetector which receives the reflected light transmitted through the optical filter, and a light collecting element which collects the reflected light on the photodetector.

Abstract: A method and a device for scanning-microscopy imaging of a specimen (28) are described. Provision is made that a plurality of specimen points are scanned by means of a scanning beam (14) in successive scanning time intervals, the intensity of the radiation emitted from the respectively scanned specimen point is repeatedly sensed within the associated scanning time interval, an intensity mean value is determined, as a mean value image point signal, from the intensities sensed in the respectively scanned specimen point, and the mean value image point signals are assembled into a mean value raster image. Provision is further made for additionally determining an intensity variance value, as a variance image point signal, from the intensities sensed in the respectively scanning specimen points, and for assembling the variance image point signals into a variance raster image signal.

Abstract: A disclosed chemical detection system for detecting a target material, such as an explosive material, can include a cantilevered probe, a probe heater coupled to the cantilevered probe, and a piezoelectric element disposed on the cantilevered probe. The piezoelectric element can be configured as a detector and/or an actuator. Detection can include, for example, detecting a movement of the cantilevered probe or a property of the cantilevered probe. The movement or a change in the property of the cantilevered probe can occur, for example, by adsorption of the target material, desorption of the target material, reaction of the target material and/or phase change of the target material. Examples of detectable movements and properties include temperature shifts, impedance shifts, and resonant frequency shifts of the cantilevered probe. The overall chemical detection system can be incorporated, for example, into a handheld explosive material detection system.

Abstract: An image reading apparatus has a platen, first and second carriages, a light source supported on the first carriage, a first mirror to deflect reflected light from the original document toward the second carriage, one or more second mirrors supported on the second carriage to guide the light from the first mirror to image reading device, and rail members. The first carriage has first and second mirror support portions for supporting one side edge portion of the first mirror by two points, and a third mirror support portion for supporting the other side edge portion by one point. The first carriage is supported slidably at its opposite side edge portions respectively on the rail members via slide members disposed at four right and left places including two front and back places, and a height position is adjustable for supporting the first mirror by one point.

Abstract: In one embodiment, a system includes an optical monitoring system configured to optically communicate with an interior of a rotary machine. The optical monitoring system is configured to redirect a field of view toward different regions of a component within the interior of the rotary machine while the rotary machine is in operation, and to capture an image of each region.

Abstract: A method of manufacturing an SPM probe having a support element, a cantilever, and a scanning tip on an underside of the cantilever, and having a mark located on the top side of the cantilever opposite the scanning tip. The mark on the top side of the cantilever is located exactly opposite the scanning tip on the underside of the cantilever. This makes it possible to identify the exact position of the scanning tip in the scanning probe microscope from the upward-pointing top side of the cantilever, which significantly simplifies the alignment of the SPM probe. The support element with the cantilever may be prefabricated conventionally and the scanning tip and the mark are then produced on the cantilever in a self-aligning way by means of a particle-beam-induced material deposition based on a gas-induced process.

Abstract: An image data combining apparatus combines m lines of image data that have been output from a reading unit. The reading unit outputs m lines of image data based upon the pixel data that has been output upon being divided into the plurality of lines, and stored then in a memory. An upper address for accessing the memory is decided based upon first data indicating position, along the sub-scan direction, of an image that has been read by the reading unit, and a lower address for accessing the memory is decided based upon second data indicating position of the image along the main-scan direction. For the lower address utilizes values in which the sequence of a plurality of bits constituting the first data is interchanged, so that p items of pixel data at a time are extracted successively from each of the m lines of image data.

Abstract: An optical module that effectively observes a rapidly moving event or object is provided. The optical module includes first and second mirrors, and an optical signals detector, which are installed in a body thereof. The first mirror has a wide field of view and detects the event or object over a wide observing region. The second mirror observes the event or object detected by the first mirror at a high resolution. The focal length of the second mirror is greater than that of the first mirror. The optical signal detector detects an optical signal in light transmitted from the first mirror or the second mirror. The body forms apertures which correspond to the first and second mirrors, respectively and provides an optical path from the first and second mirrors to the optical signal detector. Therefore, the optical module can observe the event or object detected by the first mirror at a high resolution.

Abstract: A confocal microscope includes an objective lens for converging light which is emitted from a light source to a sample, a scanning mechanism for relatively scanning the sample with the light converged to the sample, and a plurality of confocal diaphragm apertures that are arranged at positions optically conjugate to the light-gathering position of the objective lens and have different diaphragm diameters. The confocal microscope further includes a plurality of photodetectors for detecting the intensities of lights respectively transmitting through the confocal diaphragm apertures, and a weighting/combining arithmetic processing unit for combining signals output from the photodetectors after weighting the signals.

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: A bidirectional optical scanner assisting in mammography is revealed. The optical scanner that calculates functional images obtained by diffuse optical tomography, used in combination with a mammography machine can reduce the number of mammograms taken and the dose exposure. The bidirectional optical scanner includes a compression module, a first optical detection module, and a second optical detection module. The same test position of the tested breast can be detected twice in different directions by the first and the second optical detection modules. No matter where the tumor is located, the tumor can be detected. Besides structural images provided by the mammography machine, functional tomographic images of the breast are obtained by the bidirectional optical scanner. Thus diagnostic accuracy in the detection of breast cancer is improved.

Abstract: In an apparatus for measuring a quasi-static error of a rotation driving shaft, a positional error and an angular error in each of X, Y, and Z axis directions during rotation of a driving shaft is measured by means of a single measurement apparatus. In the apparatus, a first splitter, a second splitter, and a reflector spectrally output or reflect a laser beam, which is output from a laser driving device, to a first position sensor and a second position sensor, so that it is possible to obtain every error information on positional errors and angular errors in X, Y, and Z axis directions of a rotation driving shaft through input position change data of the inputted laser beam.

Abstract: An image reading apparatus is provided that can prevent image streaks due to dirt, stain or the like from being produced in an image of an original that is read while being conveyed. The image reading apparatus (A) includes an ADF (40) having a scanner unit (59) incorporated therein and comprised of a cylinder (60) having an outer peripheral surface thereof on which a plurality of read pixels (61) are arranged in a matrix. In reading an original (D), the scanner unit is rotatably driven in an original conveying direction at a circumferential speed approximately equal to an original conveying speed, and reads image information on the original passing through an image reading position (P1).

Abstract: An image forming apparatus performs multi-color image formation using a plurality of scanning type optical devices which deflect and scan an optical beam using a rotating polygonal mirror. The image forming apparatus includes, for example, a detecting unit that detects a phase of rotating speed unevenness of rotating polygonal mirrors respectively provided in the plurality of scanning type optical devices, and an adjusting unit that adjusts, based on a phase of rotating speed unevenness detected for each rotating polygonal mirror, the rotating speed of each rotating polygonal mirror to reduce the phase differences between the phases.

Abstract: Provided with a time-lapse imaging unit which repeatedly captures a specimen at predetermined time intervals and generates a plurality of images, and a recording unit which records at least one of an image group including one or more of the images captured during a predetermined period among a period of a time-lapse capturing performed by the time-lapse imaging unit or an image group including one or more of the images picked at predetermined time intervals among the period of the time-lapse capturing performed by the time-lapse imaging unit. Thus, data generated in time-lapse photography are managed favorably in a microscope apparatus provided with a time-lapse imaging unit which repeatedly captures a specimen at predetermined time intervals and generates a plurality of images.

Abstract: A modular focus system for image based code readers includes swappable lens attachments enables fixed focus, manual focus, and variable focus operation from a single reader. A manual focus lens cap includes a manually adjustable focus ring to change the focus of the reader. A variable focus lens module includes a liquid lens that is manipulated by a voltage delivered via a pair of electrodes to adjust the focus of the reader. The lens attachments can be swapped out and replaced as needed.

Abstract: A device for handling a substantially circular wafer is provided. The device includes an interior accessible through a plurality of entrances, and a plurality of sensors consisting of two sensors for each one of the plurality of entrances, each sensor capable of detecting a presence of the substantially circular wafer, at a predetermined location within the interior, wherein the plurality of sensors are arranged so that at least two of the plurality of sensors detect the wafer for any position of the wafer entirely within the interior, wherein a first one of the two sensors is positioned to detect the wafer when the wafer has passed entirely into the interior through one of the plurality of entrances, and a second one of the two sensors is positioned immediately outside a diameter of the wafer when the wafer has passed entirely into the interior through one of the plurality of entrances.

Abstract: An optical beam scanning device includes a polygon mirror 80 in which tilt angles with respect to a rotation axis of the polygon mirror 80 of respective plural reflecting surfaces are set to angles corresponding to photoconductive members associated with the respective reflecting surfaces, a post-deflection optical system A1 that guides light beams reflected and deflected by the respective plural reflecting surfaces in the polygon mirror 80 to the photoconductive surfaces of the photoconductive members corresponding to the respective reflecting surfaces, and a pre-deflection optical system 7a that shapes the light from the light source to be a light beam of a predetermined sectional shape and guides the light beam to the polygon mirror 80, the pre-deflection optical system 7a guiding the light from the light source to the polygon mirror 80 through an optical path that passes, in the main scanning direction, on an optical axis of the post-deflection optical system A1 and passes, in the sub-scanning direction,

Abstract: A light scanning unit includes: a light source; a beam deflector to form forward direction and reverse direction scanning lines on an image section and first and second non-image sections respectively disposed at opposite sides of the image section; a reflecting member to reflect the light beam input from the beam deflector; a light detector to receive a first light beam directly input from the beam deflector and a second light beam input via the reflecting member; a control unit to determine whether the scanning line is a forward direction scanning line or a reverse direction scanning line based on signals respectively corresponding to the first and second light beams detected in the light detector, and to control the light source so that a light beam including image information corresponding to a scanning direction of the scanning line can be emitted; and a synchronization adjusting unit to correct an alignment error between the forward direction scanning line and the reverse direction scanning line due to

Abstract: A scanning microscope is provided with a scan unit that scans a sample, the scanningmicroscope including: a transmissive VPH grating for dispersing light from the sample; and a photodetector for detecting the light diffracted by the VPH grating.

Abstract: A system for measuring the thickness of substrates in a vacuum chamber is provided. The system includes a sender adapted to emit electromagnetic radiation and a receiver including a multi-zone sensor for detecting the electromagnetic radiation. The multi-zone sensor includes a first detection zone for measuring the thickness of the substrates and a second detection zone adapted to generate a signal indicative of an alignment between the sender and the receiver. The system further includes an adjustment system adapted to automatically adjust the sender and the receiver with respect to each other based on the signal. Further, a method for adjustment of a sender and a receiver relative to each other is provided.

Abstract: In a method for removing moisture from an optical system at high altitude, the improvement comprises using the difference in flow resistance between the desiccant path and the optical cavity path to enable airflow through the desiccant unit and not through the optical path.

Abstract: A deviation of an optic axis of a laser projector is detected, and the deviation is corrected. Laser projector's CPU executes: commanding a laser beam source of one color, out of laser beam sources of three colors, to emit a laser beam; shutting off the laser when sensing that the laser beam is received in a light-receiving region; applying a laser of a color to be detected as to the presence or absence of a deviation of the axis until its reception in the light-receiving region is sensed; keeping time starting when light reception in the light-receiving region is sensed and ending when light reception in a light-receiving region adjacent thereto is sensed; calculating a relative time difference of each of the colors with respect to a reference color; and correcting a light emission timing of the laser beam source of each of the color, based on the calculated time.

Abstract: A system and method is provided for illuminating a subject using a light pipe that transmits light from a source, such as an LED ring illuminator to an outlet that directs the light appropriately as either bright field illumination, dark field illumination or both. The light pipe can include concentric cylinders, typically with a bright field illuminator nested within a dark field illuminator. The tip of the dark field illuminator may be angled so as to internally reflect light inwardly toward the central optical axis of a camera at a low angle. The tip can be located near the focal plane of the camera for the desired field of view. The field of view of the camera sensor can be modified to reject data outside of a illumination field of a particular shape. This illumination field can be created by shaping the light pipe in a predetermined form that projects the modified illumination field.

Abstract: An optical device including: a laser light emitting portion that emits laser light; a polygon mirror having a reflective surface that reflects the laser light, the polygon mirror being driven to rotate and deflecting the laser light emitted from the laser light emitting portion; a first lens through which the laser light reflected by the polygon mirror is transmitted, the first lens refracting the laser light; a second lens through which the laser light having passed through the first lens is transmitted, the second lens refracting the laser light; and an adjustment unit that adjusts at least one of a length of a first optical path between the polygon mirror and the first lens, and a length of a second optical path between the first lens and the second lens.

Abstract: A laser display device, which is capable of ensuring the safety of a person's eyes and reducing speckle noise even when a screen is arranged at an arbitrary position, includes a laser light source emitting a laser light, a modulator modulating the laser light and emitting a modulated light, and a branching unit branching the modulated light into a plurality of branched lights. Further, at least two of the plurality of branched lights reach same positions on a screen at substantially same timings.

Abstract: A synchronization detecting apparatus includes a counter, an error detector, and a line length generator. The counter counts to a predetermined counter value in response to a clock signal. The error detector generates an error, which is the difference between a current counter value received from the counter and a previous line length, in response to a synchronization flag signal. The line length generator generates a current line length based on a compensated error and the predetermined counter value. The synchronization flag signal has an active level at a transitioning edge of a synchronization pulse signal contained in an input signal.

Abstract: The invention provides an apparatus for reducing speckle in a projection visual display (PVD) system, a method of reducing visible speckle in a PVD system and a PVD system incorporating the method or apparatus. In one embodiment, the apparatus includes a diffuser interposable in an optical path of a PVD system and a diffuser actuator having a single drive axis configured to cause the diffuser to travel in a lissajous curve at least partially transverse to the optical path.

Abstract: An optical device is provided with an optical unit for forming an optical path of a laser beam, and a housing defining an internal space for accommodating the optical unit. The housing includes a partition for dividing the internal space into a first space and a second space. The optical unit includes a sensor arranged in the first space to detect the laser beam in the second space, a mirror arranged in the second space to define a direction of the optical path, a drive source arranged in the second space to operate the mirror to adjust the direction of the optical path, a power line for supplying power to the drive source, and a signal line for transmitting an output signal of the sensor. The signal line extends in the first space and the power line extends in the second space.

Abstract: In a method for correcting a control of an optical scanner (14) which has a beam deflecting element (31) for deflecting a beam of optical radiation and a drive unit (30, 30?) for moving the beam deflecting element (31), said drive unit deflecting a beam of optical radiation directed at the beam deflecting element (31) according to a predetermined target movement using at least one parameter and/or a transfer function, preferably optical, said parameter or transfer function being used to control or regulate the system. In a determination step at least one current value of a drive unit transfer function that reproduces the response of the drive unit (30, 30?) to a predetermined target movement or a change in a target movement is ascertained for at least one frequency, and in a correction step at least one parameter and/or the transfer function is corrected as a function of the current value of the drive unit transfer function.

Abstract: Locations of the origins of the photons are acquired from a scanned sample with reference to a scan frame. The location on the sample from which a photon was emitted is inferred from the location of the scan as commanded by a scan drive signal, a feedback signal related to the position of the scan device, or alternatively by the point in time during a scan at which the photon is detected. A position function, e.g., photon probability density, is associated with a photon position. Summing or other processing of photon probability density functions can require fewer photons to converge to an ideal density distribution associated with an image feature than are required using conventional pixel binning. Stored data can be mapped into pixels or voxels of a display or otherwise processed. Original data remains available in the digital storage for post-hoc analysis. Imprecision introduced by the display process need not adversely affect the precision of the collected data.

Abstract: A method and system to capture geometry of a three dimensional target while disambiguating multiple projected target elements. The system projects at least three light pattern elements toward a target at a diverse spacing relative to each other. The system captures at least one image of the target while illuminated by at least one of the pattern elements. The pattern elements are moved relative to the target. The system disambiguates one pattern element from any other contained within an image of the target, at least in part based on the diverse spacing. The system measures triangulation locations of points on a three-dimensional surface of the target.

Abstract: A configurable scanner (1), for contactless measurement of the depth and perimeter of a wound on a target body part (9), has a scan head (4), and is configured to be controlled by a processor (3) for controlling a scanning procedure and analyzing the results. The scan head (4) projects a contour line onto a surface the target body part, and captures an image of the projected contour line. A series of captured images are analyzed to create a three dimensional model of the wound, and determine at least one of depth, perimeter and volume of the wound from the three dimensional model.

Abstract: A method for using an image sensor includes steps that permit the calculation of a resolution of the image that is greater than the designed resolution of the image sensor. A specimen is placed onto a known background within the field of view of an image sensor having multiple pixels. The specimen is focused onto the image sensor in a first position relative thereto such that the known background is also focused on the image sensor. An image is recorded for the specimen and the known background focused on the image sensor in the first position, and a specimen region and background pixels are established from the image recorded. The specimen is moved to a second position relative to the image sensor so as to place a portion of the specimen region within a target background pixel. An image is recorded for the specimen and the known background focused on the image sensor in the second position, and the bit depth is calculated for the portion of the specimen region moved into the background pixel.

Abstract: The invention provides for a device comprising an apparatus comprising (a) a transmission grating capable of diffracting a photon beam into a diffracted photon output, and (b) an image detector capable of detecting the diffracted photon output. The device is useful for measuring the spatial profile and diffraction pattern of a photon beam, such as a vacuum ultraviolet (VUV) beam.

Abstract: A system, method and apparatus for eliminating image tearing effects and other visual artifacts perceived when scanning moving subject matter with a scanned beam imaging device. The system, method and apparatus uses a motion detection means in conjunction with an image processor to alter the native image to one without image tearing or other visual artifacts. The image processor monitors the motion detection means and reduces the image resolution or translates portions of the imaged subject matter in response to the detected motion.

Abstract: A detector array for use in a laser imaging apparatus, comprises a plurality of housings disposed in an arc around an opening in which an object to be scanned is disposed, each housing including an open front end, a rear end and a longitudinal axis; and a detector disposed within each housing at a distance from the front end, thereby to restrict the field of view of each detector. The housings are adapted to be orbited around the object about an orbit axis. Each detector is adapted to simultaneously detect light exiting from the object within the respective field of view of each detector. A method for collecting light exiting from a object being scanned with a light source is also disclosed.

Abstract: A laser scanning microscope apparatus comprising, a controlling unit for obtaining height information at each scanning point of a sample to be examined by obtaining a relative distance that maximizes an intensity output from a photo-detecting unit, which is obtained when the sample to be examined is scanned with a light from a laser light source, when a relative distance is changed by a Z scanning unit, includes an arithmetic processing unit for obtaining a plurality of height profiles of one line acquired by scanning the sample to be examined in a state of light with the light defecting unit while shifting the plurality of height profiles of one line in a scanning direction by a predetermined amount, and for obtaining one profile by linking the plurality of height profiles.

Abstract: The present image display device is an image display device that scans laser beams emitted from light sources 101, 102 and 103 to form an image on a projection surface, and includes laser beam diameter-converting optical systems 104 that shape a beam waist of a laser beam, and horizontal scanner 106 and vertical scanner 107 for scanning a laser beam. Beam diameter-converting optical systems 104 adjust the beam diameter at the position of mirror 26, which is a beam deflector for scanner 106 and 107, to be smaller than the mirror diameter. Also, beam diameter-converting optical systems 104 shape beam waist 110 so that a full width at half maximum of the intensity, which corresponds to beam diameter 114 or 116, is always smaller than pixel pitch 115 or 117 in projection range 118 defined between first projection surface 112 and second projection surface 113.

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: A single step multi-section exposure scanning method for a scanner. The scanner includes a photo-sensor and a stepper motor. The photo-sensor has N rows of sensor cells that correspond to each primary color. The scanning device is driven forward an exposure distance for each revolution of the stepper motor. The single step multi-section exposure scanning method includes the following steps. First, the photo-sensor moves forward one exposure distance. One row of sensor cells is exposed after moving every 1/Nth of the exposure distance. Thereafter, analogue voltages obtained through the exposed row of sensor cells are transmitted to an analogue/digital converter. The above process is repeated until the entire document is scanned.