There is described an apparatus comprising a first optical element, a second optical element and a spacing element for use with a mobile user device. The first optical element is configured to provide an image of an object to an intermediate image plane and the second optical element magnifies the image to provide a final image in a final image plane in which a camera aperture of the device is supported. The spacing element maintains a fixed separation between the object and the first optical element. Image magnification is achieved while also providing a space for tool access. Mirrors may be used to divert the optical path, allowing the optical path to be folded for more compact apparatus. A third optical element disposed at the intermediate image plane may be used to reduce vignetting effects in the final image.

A signal processing device includes a processor including at least one or more pieces of hardware. The processor is configured to: when a first synchronization signal from a first synchronization signal generation circuit, the first synchronization signal generation circuit receiving a first clock signal and outputting the first synchronization signal, and a second synchronization signal output from a second synchronization signal generation circuit are not synchronized, reset the first synchronization signal generation circuit, and in a period in which the first synchronization signal generation circuit is reset, set a frequency of the first clock signal to be higher than a frequency in another period.

A medical image processing device a reference image that is a medical image with which boundary line information related to a boundary line that is a boundary between an abnormal region and a normal region and landmark information related to a landmark that is a characteristic structure of the subject are associated and a captured image that is the medical image captured in real time, detects the landmark from the captured image, calculates a ratio of match between the landmark included in the reference image and the landmark included in the captured image, estimates a correspondence relationship between the reference image and the captured image on the basis of the ratio of match and information regarding the landmarks included in the reference image and the captured image, and generates a superimposition image in which the boundary line associated with the reference image is superimposed on the captured image on the basis of the correspondence relationship.

A light source device includes: a first light source configured to emit first light including a white wavelength band or one or more wavelength bands of at least red, green, and blue; a second light source configured to emit second light including a specific wavelength band included in the first light; a first detector configured to detect an amount of the light of the specific wavelength band in the first light; a first optical member configured to multiplex light of a wavelength band different from the specific wavelength band in the first light, and the second light; and a processor configured to control the first light source based on a detection result of the first detector.

An endoscope or the like that prevents crosstalk between multiple light-emitting parts is provided. An endoscope includes: an observation window that is disposed at a distal end of an insertion part; a plurality of first light-emitting parts that are disposed around the observation window; a second light-emitting part that is disposed between the first light-emitting parts and emits light at a bandwidth different from a bandwidth of light emitted by the first light-emitting parts; and a light-shielding body that is disposed between one of the first light-emitting parts and the second light-emitting part.

A first illumination light beam is switched to a second illumination light beam and the second illumination light beam is emitted for a period of at least one frame, during a period in which the first illumination light beam is emitted. A first image or a second image obtained by imaging an observation target illuminated with the first illumination light beam or the second illumination light beam is acquired for each frame. At least one first image and at least one second image that satisfy a preset selection condition are selected and stored from a plurality of the first images and a plurality of the second images acquired in a preset period prior to a time of a processing start operation of image storage processing.

An endoscope includes a housing with a distal end insertable into a cavity; an image capture device at the distal end to obtain 3D images, and process them to form a video signal; and a folded substrate folded into a U-shape having first and second legs. The image capture device includes a detector and a lens system with right and left multi-band pass filters having right pass bands that are complements of left pass bands. The lens system receives the 3D images including right and left images. The detector faces the lens system to obtain the right and left images. A processing circuit faces the proximal end behind the detector to process signals from the detector. The folded substrate includes the detector at an outer side of the first leg facing the lens system and the processing circuit at an outer side of the second leg facing the proximal end.

Offset illumination using multiple emitters in a fluorescence imaging system is described. A system includes an emitter for emitting pulses of electromagnetic radiation and an image sensor comprising a pixel array for sensing reflected electromagnetic radiation. The emitter comprises a first emitter and a second emitter for emitting different wavelengths of electromagnetic radiation. The system is such that at least a portion of the pulses of electromagnetic radiation emitted by the emitter comprises one or more of a hyperspectral emission, a fluorescence emission, and/or a laser mapping pattern.

Provided herein is a handle of a multi-camera endoscope, the handle includes a user interface activating unit which includes one or more external activating/control buttons, and an internal activating element, the handle optionally includes a converter configured to receive one or more parallel signals and transform the one or more parallel signals to one or more corresponding serial signals, wherein the parallel signals are output by one or more cameras of the endoscope. Further provided are endoscopes and medical imaging system which include the handle, as well as methods of use thereof.

A plurality of kinds of illumination light are emitted while being switched according to a specific light emission pattern. A plurality of observation images, which are obtained from image pickup of an object to be observed illuminated with each illumination light, are acquired. Control to display the plurality of observation images on a display unit while switching the plurality of observation images according to a specific display pattern is performed. The specific light emission pattern is fixed and the specific display pattern is changeable.