An anti-dazzle imaging camera is provided that includes a photorefractive crystal that is wavelength-agnostic. The photorefractive crystal is configured to receive an optical beam. When the optical beam includes no laser, the photorefractive crystal is configured to pass the optical beam unchanged to an imaging detector. When the optical beam includes a laser, the photorefractive crystal is configured to attenuate the laser to generate a modified optical beam and to pass the modified optical beam to the imaging detector.

Provided is a microscope system including: an optical fiber in which laser light emitted from a light-source apparatus propagates; a microscope that irradiates a specimen with the laser light propagated in the optical fiber and that obtains an image of the specimen; a mode-scrambling device portion that causes elastic waves to propagate in the optical fiber to form elastic wave interference fringes in the optical fiber; and a control device that controls the driving of the mode-scrambling device.

A position detecting device for detecting a position of a magnet configured to move over a first target point and a second target point in steps includes a first hall device configured to generate a first hall voltage, a second hall device configured to generate a second hall voltage, a subtractor configured to generate a subtraction voltage based on a difference between the first hall voltage and the second hall voltage, an adder configured to generate an addition voltage based on a combination of the first hall voltage and the second hall voltage, a divider configured to calculate a ratio of the subtraction voltage to the addition voltage, and a subtraction voltage changing unit configured to maintain the subtraction voltage at the first target point and the second target point and in a transition section between the first target point and the second target point to be constant.

The present technology relates to a solid-state imaging device and an electronic device capable of improving a saturation characteristic. A photo diode is formed on a substrate, and a floating diffusion accumulates a signal charge read from the photo diode. A plurality of vertical gate electrodes is formed from a surface of the substrate in a depth direction in a region between the photo diode and the floating diffusion, and an overflow path is formed in a region interposed between a plurality of vertical gate electrodes. The present technology may be applied to a CMOS image sensor.

A vehicle is disclosed. The vehicle includes a first indicator light associated with a first function or a first state of the vehicle (e.g., a brake light), and circuitry coupled to the first indicator light. The circuitry is configured to cause the first indicator light to emit light when the vehicle is performing the first function or is operating in the first state, and detect an amount of light incident on the first indicator light. Thus, the indicator light can be used to detect incoming light to perform various vehicle functions (e.g., automatically dimming mirrors based on the incoming light) without the need for a dedicated light sensor.

A mammographic imaging device for analysis and detection of possible inhomogeneities in breast tissue of a patient using laser light in the near-infrared in diffuse reflectance geometry, includes a patient horizontal support comprising at least one transparent window in its cross-section and a measuring mechanism below the at least one transparent window and carried by said support. The measuring mechanism includes a laser-light producing mechanism for producing laser light beams in the near-infrared, a directing mechanism for directing said laser light beams towards the at least one transparent window, at least one wavelength filter, a light-sensing and imaging mechanism for sensing light and producing images and a controlling, processing and image-normalizing unit for controlling, processing and normalizing images.

An actuator for moving a platform having electrical connections is provided. The actuator includes an outer frame connected to an inner frame by one or more spring elements that are electrically conductive. The actuator further includes one or more comb drive actuators that apply a controlled force between the outer frame and the inner frame. Each of the comb drive actuators includes one or more comb drives. Moreover, a method for moving a platform having electrical connections is also provided. The method includes connecting an outer frame to an inner frame using one or more spring elements that are electrically conductive. The method further includes generating a controlled force using one or more comb drive actuators. Each of the comb drive actuators includes one or more comb drives. In addition, the method includes applying the controlled force between the outer frame and the inner frame.

An iris of a mobile terminal includes a cover having a through hole therein and forming an internal space, a first blade disposed in the internal space and having a first through hole communicating with the through hole, a second blade disposed to overlap the first blade in at least a portion thereof within the internal space, communicating with the through hole, and having a second through hole formed to adjust a region in which light is incident through interference with the first through hole, and a link member connected to one end portion of each of the first and second blades and varying an aperture of the iris by moving at least one of the first and second blades.

An optical instrument, comprising an optical system including a focus lens group, an aperture that restricts light flux that passes through the optical system, an aperture motor that sets opening amount for the aperture, a memory that stores first information that represents a relationship between position of the focus lens group and appropriate aperture value and second information that represents a relationship between the aperture value and opening amount of the aperture, and a controller that, when controlling opening amount of the aperture using the aperture motor in accordance with position of the focus lens group, calculates an appropriate aperture value based on the first information and position of the focus lens group, calculates opening amount of the aperture based on the second information and the aperture value that has been calculated, and controls the opening amount to the opening amount of the aperture that has been calculated.

There are provided an image capture portion, a luminance acquisition section, a luminance estimation section, and a capture mode setup section. The image capture portion cyclically captures a vehicle compartment. The luminance acquisition section acquires the luminance of a captured image captured by the image capture portion. The luminance estimation section estimates a cyclic change in the luminance of captured images to be captured subsequently. The capture mode setup section settles a capture mode for the image capture portion based on a result of estimating the cyclic change in the luminance of captured images.