Abstract: A method for controlling the contrast range of the image recording light falling on an image recording medium by means of control light coupled into the optical path of the image recording light, which is composed of several base colors whose brightness is adjusted independent of each other, is provided. The brightness at least of those base colors of the control light is varied, whose dynamics in the recorded image go beyond the admissible dynamic range.

Abstract: An image capturing apparatus includes: an image capturing device in which a plurality of pixels having sensitivity to visible light and illuminating light in a certain wavelength range are arranged and that captures a moving image having a plurality of frames; a radiation device that radiates the illuminating light onto an image capturing region of the image capturing device; and a processor that executes a procedure, the procedure comprising: selecting, from among a plurality of frames captured by the image capturing device, a frame captured during an OFF period of the radiation device, and outputting the selected frame as a frame representing a visible image of the image capturing region.

Abstract: To provide an electrochromic light control element in which a response speed in a low temperature environment can be easily and also efficiently improved. The electrochromic light control element includes a pair of transparent electrodes provided on a pair of substrates and an electrochromic layer and an ion conductive layer arranged between the pair of the transparent electrodes, in which one of the pair of transparent electrodes is connected via a heater that generates heat through a power distribution and an electrical insulation heat conductive layer.

Abstract: An image pickup apparatus for wireless-communicating with a camera accessory which periodically transits to a sleep state, transmits a change signal for changing the setting of a power saving state in an accessory apparatus, to the accessory apparatus in accordance with a first operation for instructing an image pickup preparation to decide an setting for image pickup or a second operation for instructing the image pickup based on the image pickup preparation operation being accepted by an operation unit of the image pickup apparatus, thereby efficiently suppressing stand-by electricity consumption and preventing a delay from occurring in timing when a predetermined process is executed between apparatuses.

Abstract: An appropriate white balance coefficient is calculated using an evaluation value of a specific chromaticity or an imaging condition, in addition to face area detection information, in the following manner. A first white balance coefficient is calculated by a first white balance coefficient calculation unit based on a color image, and a second white balance coefficient is calculated by a second white balance coefficient calculation unit based on a specific subject of the color image. Then, a third white balance coefficient is calculated by a white balance combining unit by weighting the first white balance coefficient and the second white balance coefficient based on an evaluation result of a specific chromaticity evaluation unit or an imaging condition of an imaging condition control unit.

Abstract: A method includes determining white balance calibration color ratios for a plurality of illumination sources by using a representative camera of a given type to establish a set of ratios. Because the ratios are fixed for the given camera type, a plurality of cameras of the type may store the fixed ratios, and calibrate by measuring only the reference illumination source. Later white balancing is achieved by using the measured reference illumination source color ratios and the stored fixed ratios as scaling factors to map from the reference illumination source to any other illumination source. The method includes an off-line advance calibration procedure to obtain the fixed ratios, an on-line per camera calibration procedure to obtain color ratios for the reference source, and subsequent white balancing which uses the fixed ratios/scaling factors and the reference source color ratios.

Abstract: A device suitable for producing an image of an object disposed in an object space by means of a sensor comprises at least the sensor, a first lens assembly disposed in front of the sensor, a stop plate comprising a light passage disposed in front of the first lens assembly, a second lens assembly disposed in front of the stop plate and the object space disposed in front of the second lens assembly. The device further comprises a light source, as well as a diffuser which is disposed on a side of the object space that is averted from the light source.

Abstract: An illumination source for a camera includes one or more LEDs, and an electrical circuit that selectively applies power from the DC voltage source to the LEDs, wherein the illumination source is suitable for handheld portable operation. In some embodiments, the electrical circuit further includes a control circuit for driving the LEDs with electrical pulses at a frequency high enough that light produced has an appearance to a human user of being continuous rather than pulsed, the control circuit changing a pulse characteristic to adjust a proportion of light output having the first characteristic color spectrum output to that having the second characteristic color spectrum output. Some embodiments provide an illumination source including a housing including one or more LEDs; and a control circuit that selectively applies power from a source of electric power to the LEDs, thus controlling a light output color spectrum of the LEDs.

Abstract: The present invention relates to an illumination device comprising at least one light source and a reflector system forming a spotlight (1), one or several actuators (5) arranged to pivot the spotlight (1) relative in a mounting base (4) for varying an illumination angle, and a camera (13) attached to the spotlight (1) and aligned to acquire images of an illumination region (7) to which the spotlight (1) is directed. The spotlight (1) is designed to comprise a central region from which the illumination region (7) is visible and which does not reflect or emit light of the light source towards the illumination region (7), wherein the camera (13) is arranged in said central region on an optical axis (14) of the spotlight (1). With the proposed illumination device an exact aiming of the spotlight (1) can be achieved even in applications in which the illuminated region (7) is close to the spotlight (1) without causing undesired shadows in the illumination region (7).

Abstract: Provided is an imaging apparatus capable of obtaining images of an object at high precision even if the intensities of illuminating light temporally varies. The imaging apparatus 1 comprises a lamp unit 10, lens 21, a half mirror 22, a lens 23, a liquid crystal tunable filter 24, a lens 25, a reference mirror 31, a reference mirror 32, an image capturing unit 40, an operation unit 50, and a display unit 60. The reference mirrors 31 and 32 are provided at the positions to which illuminating light led by an optical system for illuminating light is irradiated and which are located at a part of the view of the image capturing unit 40. The operation unit 50 corrects the value of the image part of the object 2 by using the value of the image part of the reference mirrors 31 and 32 out of the images captured by the image capturing unit 40.

Abstract: This invention provides a system and method for enabling control of an illuminator having predetermined operating parameters by a vision system processor/core based upon stored information regarding parameters that are integrated with the illuminator. The parameters are retrieved by the processor, and are used to control the operation of the illuminator and/or the camera during image acquisition. In an embodiment, the stored parameters are a discrete numerical or other value that corresponds to the illuminator type. The discrete value maps to a corresponding value in look-up table/database associated with the camera that contains parameter sets associated with each of a plurality of values in the database. The data associated with the discrete value in the camera contains the necessary parameters or settings for that illuminator type. In other embodiments, some or all of the actual parameter information can be stored with the illuminator and retrieved by the camera processor.

Abstract: A distributed agile illumination system and method associated with multiple coordinated illumination sources for projecting a large amount of illumination on a subject at a distance and with an eye safe level of illumination at a close range. An entire scene may be imaged via an image capturing device and a targeted subject with respect to the scene may be detected and prioritized. An initial calibration may be performed to determine a relative geometric location of the illumination sources and the image capturing device with respect to each other. The subject's predicted location and the geometric location may be employed to determine an offset position for each of the independent illumination sources. A pan/tilt device and optional mirror associated with each illumination source utilizes the offset position to point each illumination source towards the subject to acquire better imagery at varying subject distances.

Abstract: A method for capturing an image with an image capture device, such as a camera or mobile electronic device. The method includes initiating a master-slave relationship between the image capture device and at least one secondary device. Once the master-slave relationship is initiated, remotely activating one of an at least one light source of the at least one secondary device. As the light source is activated, capturing a test image of a scene illuminated by the at least one light source by the image capture device. Then, analyzing the test image to determine if an illumination of the scene should be adjusted and if the illumination of the scene is to be adjusted, providing a control signal to the at least one secondary device including at least one of a position instruction, an intensity level, or timing data.

Abstract: A process for determining the position of closed holes in a component is provided. By carrying out laser triangulation measurements on an uncoated component and a coated component with holes, the exact position of the holes to be reopened may be detected following the coating. A device used to carry out this process is also provided.

Abstract: Techniques for automatically adjusting and/or optimizing the color and/or intensity of the illuminating light used in a vision system is presented. The intensity of each of a plurality of illuminating light colors is allowed to be independently adjusted to adapt the illumination light based on the color of a part feature against the part feature background of a part being viewed by the vision system to produce high contrast between the part feature and background. Automated contrast optimization may be achieved by stepping through all available color combinations and evaluating the contrast between the part feature and background to select a color combination having a “best” or acceptable contrast level.

Abstract: A system and method for synchronizing a remote lighting device to a camera using a hot shoe connection and a wireless communication device connected via the hot shoe connector. The wireless communication device receives a request for flash data from the camera via the hot shoe connector. The wireless communication device responds to the request with response data that mocks information that a photographic lighting device would provide if the photographic lighting device were connected to the hot shoe connector, such that the camera continues to provide TTL data via the hot shoe connector to the wireless communication device.

Abstract: There is provided an image processing apparatus includes a spectral reflectance calculation unit that calculates spectral reflectances respectively in plural wavelength ranges, based on intensity of reflected light from an object to be imaged and irradiation intensity of light that the object to be imaged is irradiated with; a determination unit that obtains derivatives of a function represented on the basis of the spectral reflectances calculated by the spectral reflectance calculation unit, and determines a number of eigenvectors, depending on whether the derivatives are positive or negative; a coefficient calculation unit that calculates coefficients where the spectral reflectances are expressed by linear combination of the number of eigenvectors and the coefficients respectively related to the eigenvectors, the number of eigenvectors being determined by the determination unit; and an output unit that outputs the coefficients calculated by the coefficient calculation unit.

Abstract: An image capture apparatus comprises an image capture unit which captures an object image, a compensation unit which performs exposure compensation corresponding to a shooting scene when a display unit sequentially displays images based on image data obtained by continuously capturing images by the image capture unit, an illumination control unit which controls an illumination device for illuminating an object, and a control unit which, in turning on the illumination device which is OFF when the compensation unit performs exposure compensation and the display unit sequentially displays images based on image data obtained by continuously capturing images by the image capture unit, controls to decrease a compensation amount of exposure compensation by the compensation unit and then turn on the illumination device.

Abstract: An image processing apparatus includes a memory that memorizes a plurality of pickup images in which an object has been picked up by varying an irradiation direction of a light; an extracting portion that extracts an area image of an area indicated by a user from each of the pickup images memorized in the memory; a calculating portion that calculates at least one illumination parameter for each area image by one of calculating an amount of edges from each extracted area image, executing a clustering process to brightness of each extracted area image, and executing a totaling process of totaling differences in brightness between the extracted area images; and a generating portion that generates at least one synthetic image by synthesizing the extracted area images with the at least one illumination parameter.

Abstract: Disclosed herein is an apparatus and method for balancing the color of a flashed image using depth estimation. The apparatus includes a depth value measurement unit, a region identification unit, a color impression estimation unit, and a color balancing unit. The depth value measurement unit measures the depth values of the respective regions of an image to be captured using a camera preview image. The region identification unit identifies the regions of the preview image as a region influenced by camera flash or a region not influenced by camera flash using the depth values measured by the depth value measurement unit. The color impression estimation unit estimates the color impression of actual illumination in the region not influenced by camera flash. The color balancing unit corrects the color of the region influenced by camera flash.

Abstract: A reflected dark field structure includes a bottom plate, a support tube, a light unit, a diffuser structure, and a reflector unit that provides reflected dark field illumination, such that a gem held by the support tube and surrounded by the diffuser structure is illuminated and viewable through an aperture in the reflector unit. A method for imaging and analyzing a gem includes placing the gem onto a support tube where it is illuminated with dark field and reflected dark field illumination, and viewing the gem via an aperture located on a top reflector unit, which provides a top cover for the gem. Furthermore, a method and apparatus for obtaining images of a gem includes a dark field stage, a reflector unit, and an image-acquiring device, such that a gem placed in the dark field stage is illuminated, and such that the reflector unit covers the dark field stage and provides reflected dark field illumination, and such that the image-acquiring device is directed towards an aperture in the reflector unit.

Abstract: Certain exemplary embodiments can provide a system comprising: a diffuser defining a camera lens hole in a top portion of said diffuser, said diffuser adapted to receive at least one set of low angle lights; and a plurality of lights mounted on said diffuser in proximity to said camera lens hole.

Abstract: A mobile communication device includes a wireless communication interface arranged to transmit and receive data with a wireless data network; a microprocessor in operable connection with memory storing one or more computer applications that include a digital image capture application; a housing at least partially surrounding the wireless communication interface and the microprocessor and defining an outer surface for the mobile communication device; a camera lens in an aperture in the housing and arranged on a first side of the wireless communication device and located at least partially in the housing, and serving as a centerpoint for an intersection of a pair of axes that define four quadrants; and a plurality of flash generating devices on the first side of, and on the outer surface of, the wireless communication device, two of the flash generating devices located in quadrants that are positioned opposite of, and not adjacent to, each other.

Abstract: A system and method are provided for imaging in scattering media such as fog, water and biological tissues. Normally, such images suffer from poor visibility due to backscattering and signal attenuation. At least two images are taken of the scene using active widefield polarized illumination, with different states of a camera-mounted polarizer. The degree of polarization of backscatter is estimated in every point of the scene, leading to an estimation of the backscatter in every point of the scene. A portion or all of the value of backscatter can be deducted in each point of the scene resulting in an enhanced image with improved contrast and brightness range across the field of view.

Abstract: An image processing apparatus includes a distribution detection unit configured to detect whether a luminance distribution on the screen changes to a hill-shaped form, based on a result of adding photometric values of each of divided photometry areas by rows and by columns, a difference calculation unit configured to calculate a luminance value difference between one portion of the screen and the peripheral portion thereof, a ratio calculating unit configured to calculate a ratio of pixels having a luminance value higher than or equal to a threshold value in the one portion, and a spotlight determination unit configured to determine whether a scene of the captured image is a spotlight scene according to a detection result of the distribution detection unit, calculation result of the difference calculation unit, and a calculation result of the ratio calculation unit.

Abstract: An apparatus for optically inspecting a test specimen has an at least partly reflective surface including a camera having a number of pixels and an illumination device having a multiplicity of spatially distributed light sources. A workpiece receptacle serves for positioning the test specimen relative to the illumination device and the camera, such that light from the light sources is reflected by the surface to the camera. An evaluation and control unit generates a series of different illumination patterns on the surface, wherein in the course of the series different light sources are switched on. An individual light origin region is determined on the basis of the images recorded by the camera for at least one pixel, whereby the region represents a spatial distribution of individual light contributions generated by the light sources via the surface on the at least one pixel.

Abstract: A device and methods are provided for low-light imaging enhancement by a digital imaging device. In one embodiment, a method includes detecting an image associated with ambient lighting of a scene, detecting an image associated with artificial lighting of the scene, aligning the image associated with ambient lighting relative to the image associated with artificial lighting based on a motion parameter of ambient lighting image data and artificial lighting image data, and calculating data for a combined image based on aligned ambient lighting image data and artificial lighting image data, wherein image data for the combined image is selected to maximize an objective quality criterion of the combined image. The method may further include determining an image parameter based on ambient lighting image data, blending image data associated with the artificial lighting and the combined image based on the image parameter to generate a tone rendered image.

Abstract: A flash device includes a stationary frame, a light emitting portion, a driving unit and a resilient plate. The light emitting portion is moveably received in the stationary frame and is spaced from the stationary frame. The driving unit includes a first magnetic assembly and a second magnetic assembly. The first magnetic assembly is positioned on the stationary frame. The second magnetic assembly is positioned on the light emitting portion and faces the first magnetic assembly. The driving unit is configured for driving the light emitting portion to move relative to the stationary frame through magnetical interaction between the first magnetic assembly and the second magnetic assembly. The resilient plate interconnects the stationary frame and the light emitting portion. The resilient plate is configured for moving the light emitting portion relative to the stationary frame.

Abstract: A light source control device according to the present invention includes an image capturing unit for capturing an image by using light emitted from a light source and reflected or scattered on a subject; a user interface for receiving information regarding optical characteristics of the light source; a control unit for generating a light source control signal for setting a lighting state of the light source by using the received information regarding optical characteristics; and a wireless communication module for transmitting the generated light source control signal to the light source.

Abstract: A portable digital image acquisition device includes multiple lenses and/or multiple flashes. A main digital image and first and second reference images are acquired. The first and second reference images are acquired with different flash-lens combinations that have different flash-lens distances. One or more flash eye defects are detected and corrected in the main image based on analysis of the first and second reference images.

Abstract: An image processing apparatus includes an image processing circuit. The image processing circuit is configured by an image processing portion for performing an image process on a first image so as to generate a third image, an image composing portion for composing the first image and the third image, and an addition-ratio calculating portion for calculating a degree of composition of a composing process between the first image and the third image by the image composing portion based on a difference signal from a difference calculating portion.

Abstract: An image-capturing system includes: an image-capturing device that captures an image of a subject; and an illumination device that illuminates the subject. The image-capturing device includes a control unit that calculates a light quantity needed to illuminate the subject based upon at least, either an exposure time or an aperture value and image-capturing sensitivity. The illumination device includes a current-controlled light emission unit that emits light used to illuminate the subject and a light emission control unit that controls the light emission unit so as to emit light in the light quantity calculated by the control unit.

Abstract: The invention provides a video-lighting system (100). This video-lighting system comprises a lighting system (110) comprising a plurality of lighting units with unique lighting unit identifiers. The identifiers are embedded in the light. The system further comprises a lighting unit sensor (120) configured to sense light of the plurality of lighting units and configured to detect the unique unit identifiers of the plurality of lighting units and a video device (130) configured to generate an optical image (131). The video device has an on status and an off status. The system further comprises a video sensor (132) configured to sense the status of the video device and configured to generate a corresponding video sensor signal, and a controller (150) configured to control according to a lighting plan the intensity of the light of the plurality of lighting units as a function of the video sensor signal.

Abstract: A method is described for displaying an image of an illumination field of a medical operation. The method includes recording an image at an illumination field of an operation, receiving a color temperature signal representative of an operating lamp that illuminates the illumination field of the operation, based on the received color temperature signal, adjusting parameters to compensate for differences in the received color temperature signal from white balance to produce a white balanced image, and outputting the white balanced image to a monitor.

Abstract: An electronic camera includes a plurality of light emitters. Each of a plurality of light emitters emits light in a mutually different manner. A plurality of optical systems are respectively corresponding to the plurality of light emitters. A selector selects a desired shooting mode from among a plurality of shooting modes in each of which a scene is captured in a mutually different manner. A driver drives a light emitter corresponding to the shooting mode selected by the selector out of the plurality of light emitters. A creator creates an electronic image based on an optical image went through an optical system corresponding to the light emitter driven by the driver out of the plurality of optical systems.

Abstract: An electromagnetic field high speed imaging apparatus, using an image sensing element having a filter function for each pixel, converts a local polarization state in detection light containing a difference frequency component ?f (|fLO?fRF|) between the modulation frequency fLO of irradiated light and the frequency fRF of the electromagnetic field emitted from a subject into local intensity of light, and captures it by an image sensor of an imaging unit to generate a two-dimensional image of distribution of the near electromagnetic field emitted from the subject. Each pixel of the image sensor comprises a photoelectric conversion element for converting the detection light from the optical unit into an electric charge, a plurality of charge storages, and a charge splitting part for dividing the electric charge generated in the photoelectric conversion element between the plurality of charge storages.

Abstract: Embodiments of the present invention provide a light emitting diode (LED) video camera system comprising a movable video camera apparatus including a video camera having a lens. The movable video camera apparatus further includes a plurality of LED lights arranged around at least a portion of a periphery of the lens of the video camera. The LED video camera system further comprises an actuator for panning and tilting the video camera, and a control unit for controlling the actuator, the lens of the video camera, and the LED lights. The control unit comprises a plurality of drivers, including an LED driver for controlling lighting effects of the LED lights, an actuator driver for controlling movement of the actuator, and an optics driver for controlling zooming and focusing of the lens of the video camera.

Abstract: An imaging unit images a subject having an unevenness pattern on a surface. The imaging unit includes: a surface light source that emits with a constant output illumination light illuminating the surface of the subject; an imager that receives reflected light reflected by the surface of the subject; and a beam splitter that is arranged at a location at which the illumination light emitted from the surface light source and the reflected light incident on the imager intersect with each other. The illumination light emitted from the surface light source is incident on the surface of the subject via the beam splitter. The reflected light reflected by the surface of the subject is incident on the imager via the beam splitter. The illumination light incident on the surface of the subject includes parallel light that is perpendicularly incident on the surface of the subject, and diffused light.

Abstract: A boresight alignment system facilitates aligning a plurality of cameras and/or images of the cameras with respect to one another. The system may have a mount configured to facilitate attachment of a bezel containing a plurality of cameras to the mount. The system may have a plurality of targets and each target may be configured to provide light of at least two different wavelengths and/or ranges of wavelengths. One or more baffles may be disposed optically between the mount and the target assembly to inhibit stray light from being incident upon the cameras.

Abstract: An object to be imaged is illuminated with a structured (e.g., sinusoidal) illumination at a plurality of phase shifts to allow lateral superresolution and axial sectioning in images. When an object is to be imaged in vitro or in another situation in which the phase shifts cannot be accurately determined a priori, the images are taken, and the phase shifts are estimated a posteriori from peaks in the Fourier transforms. The technique is extended to the imaging of fluorescent and non-fluorescent objects as well as stationary and non-stationary objects.

Abstract: An apparatus and method are provided for creating an indirect image of an object. The apparatus includes a light source and an imaging system. Light emitted from the light source is reflected by a first non-specular surface toward the object. Light reflected by the object is further reflected by a second non-specular surface toward the imaging system. The imaging system is configured to create the indirect image from the reflected light.

Abstract: An imaging apparatus includes: an image sensor including a plurality of charge storage-type photoelectric conversion elements disposed along a first and a second direction; a rolling shutter control unit that executes storage control to store electrical charges in a first element row and in a second element row with different timing for electrical charging, the first element row including a plurality of the charge storage-type photoelectric conversion elements along the first direction and the second element row including a plurality of the charge storage-type photoelectric conversion elements along the first direction at a different position along the second direction; a detection unit that detects light emission timing indicating a light emission cycle of each of a plurality of color components in light entering the image sensor; and a start instruction unit that engages the rolling shutter control unit to start the storage control based upon the light emission timing.

Abstract: A method, apparatus and computer program product are provided for facilitating the capture of an image of an illuminated area of interest. A method, apparatus and computer program product may tailor the operation of the illumination source based upon the illumination conditions of one or more regions within the area of interest. Additionally, the method, apparatus and computer program product may coordinate the operation of the illumination sources and one or more image sensors to facilitate improved image capture.

Abstract: A camera module having a flash that is provided therein. The flash may be an LED light source. The LED may come in a package that is generally rectangular, with the exception that one corner is flattened. The camera module includes a housing that receives the light source, an image sensor, and a lens. The housing includes mating features that receive the LED package, those features including a flattened corner so that the LED package can only be received within the housing when it is properly oriented. The housing also includes electrical terminals for connection to the LED that include springs. When the LED package is properly oriented and received within the housing, contact pads on the LED package and the electrical terminals on the housing are pressed together against the resilient force of the spring.

Abstract: Multi-spectral imaging technique embodiments are presented which involve an active imaging approach that uses wide band illumination of known spectral distributions to obtain multi-spectral reflectance information in the presence of unknown ambient illumination. In general, a reflectance spectral distribution of a captured scene is computed by selecting a number of different illumination spectra and capturing multiple images of the scene. Each of these images is captured when the scene is illuminated by a different one of the selected illumination spectra in addition to the ambient light. The reflectance spectral distribution of the scene is computed for each pixel location based on the relative response between pairs of the radiometric responses of the corresponding pixels in the captured images, given a set of parameters including the added illumination spectra used to capture each of the images and the response function and spectral sensitivity of the camera used to capture the images.

Abstract: An image pickup apparatus includes: a photoelectric transduction portion to transduce an optical image of a subject formed on an image plane through a lens to output an image signal; a movement portion provided between the photoelectric transduction portion and a base to move the photoelectric transduction portion relative to the base; an illumination portion placed at a predetermined position from the base to emit light onto the image plane of the photoelectric transduction portion in a state in which a shutter is closed to block light entering from the lens; a light-blocking portion placed at a predetermined position from the base to interrupt part of light from the illumination portion at between the illumination portion and the image plane; an adjustment image obtaining portion to obtain an image signal output by the photoelectric transduction portion as a result of photoelectric transduction, in a state in which the illumination portion emits light; and a relative position detection portion to detect a r

Abstract: A brightness adjusting system for an image of an object captured by a camera includes a plurality of light sources configured for emitting light to the object, a driving device driving the light sources to emit the light, and an adjustment device electrically connected to the camera and the driving device. The adjustment device pre-stores a plurality of standard brightness value ranges, analyzes a brightness distribution of the image, compares the brightness distribution of the image with the standard brightness value ranges, determines required adjustment of the brightness distribution of the image according to the comparison, and directs the driving device to drive the light sources to emit the light with a required intensity according to the required adjustment of the brightness distribution of the image.

Abstract: The invention provides an adjuster for adjusting the direction of a light beam (5). The adjuster (1) has an off-state and an on-state and comprises a stack (10) of layers. The stack (10) comprises a first solid material layer (100) having a first optic axis (111), a second solid material layer (200) having a second optic axis (211), and switchable birefringent material (30). Further, the stack includes a first interface (130) between the first solid material layer (100) and birefringent material (30) and a second interface (230) between the second solid material layer (200) and birefringent material (30). In the off-state, the birefringent material (30) at the first interface (130) is configured to have an optic axis parallel to the first optic axis (111) and the birefringent material (30) at the second interface (230) is configured to have an optic axis parallel to the second optic axis (211).

Abstract: In one embodiment, an element 106 transforms non-polarized light into plane polarized light with an arbitrary plane of polarization. A synchronizer 112 gives the element 106 an instruction to rotate the plane of polarization, thereby getting the plane of polarization of the illumination rotated and casting that polarized illumination toward the object. At the same time, the synchronizer 112 sends a shooting start signal to an image sensor 110, thereby getting video. The synchronizer 112 performs these processing steps multiple times. A captured video signal is sent to an image processing processor 108. Candidates for the azimuth angle of a surface normal are obtained based on an intensity maximizing angle image, the zenith angle of the surface normal is obtained based on a degree of intensity modulation image, and the ambiguity of the azimuth angle is solved, thereby generating a surface groove normal image.

Abstract: A light source apparatus is designed in accordance with an object, and following elements and phosphors are disposed in a casing, a first light emitting element that emits a light in a first irradiation mode, which is selected so that a light emission band has a portion that overlaps a first-specific-band, a first phosphor selected so as to include the first-specific-band in an excitation band and include a second-specific-band in a fluorescence-emission-band, a second phosphor selected so that an excitation intensity compared with the first phosphor is low in the first-specific-band, and high in a second-fluorescence-excitation-band at a short wavelength side in a second-irradiation-band and a fluorescence-emission-band includes the second-irradiation-band other than the second-fluorescence-excitation-band, and a second light emitting element that emits a light in a second irradiation mode, which is selected so that a light emission band is included in the second-fluorescence-excitation-band.