One aspect of the present disclosure is an imaging system including an optical sensor defining an optical axis. The system further includes a light source. The system may include an optical beam splitter, and may also include an optional diffusing lens that may be configured to diffuse and/or collimate light from the light source and direct light exiting the diffusing lens to the optical beam splitter. The optical beam splitter is configured to direct light from the light source along the optical axis of the optical sensor.

A device includes a light-emitting device (LED) having at least two vertical light-emitting sides, and a ring-shaped light guide having a bottom side, a top side comprising a light-emitting surface, an inner sidewall, and an outer sidewall defining an indentation having at least two vertical in-coupling surfaces mated to the at least two vertical light-emitting sides of the LED.

A camera accessory mounting element includes attachment elements configured to mount to a component of a camera, such as a lens or a flash device. One or more peripheral devices may be attached to the camera accessory mounting element using attachment elements such as magnets. Peripheral devices include a grid, a light directing dish, a lens hood, a lens adaptor, a step-ring, a lens filter, a lens extension tubes, a light diffusers, a light filter, and a light directing device.

The disclosure provides a portable imaging module detachably connected to a portable imaging device including a camera and an illuminator. The portable imaging module includes a lens assembly and a lens body. The lens body includes a mounting hole, and the lens assembly is at least partially disposed in the mounting hole. The lens assembly includes a lens and a lens enclosure. The lens assembly is disposed on the portable imaging device and is in front of the camera of the portable imaging device. The lens body includes transparent or semitransparent solid material; one end of the lens body includes a reflecting end; a projection area of the reflecting end on a mounting surface of the portable imaging device at least partially covers the illuminator.

The invention provides an imaging system comprising an optical element for deflecting axially incident light into a series of axially spaced outward radial projections, and further comprising an image collection means for collecting reflected light. The element comprises a plurality of light deflecting surfaces or features which are arranged at axially successive points along the element, each at a different radial location. The light-deflecting surfaces are arranged to deflect light incident upon them from an axial direction in a radial direction, each thereby generating a radial projection of light from the element. A beam or beam bundle projected along the element has successive outer annular layers stripped by the facets and deflected outwards at different axial points along the structure.

A camera accessory mounting element includes attachment elements configured to mount to a component of a camera, such as a lens or a flash device. One or more peripheral devices may be attached to the camera accessory mounting element using attachment elements such as magnets. Peripheral devices include a grid, a light directing dish, a lens hood, a lens adaptor, a step-ring, a lens filter, a lens extension tubes, a light diffusers, a light filter, and a light directing device.

Provided are an image inspection device and an illumination device capable of thinning and downsizing the illumination device. An image inspection device includes a photographing part photographing an object, a light transmissive illumination part, and an optical member. The illumination part is arranged between the object and the photographing part and has a light emitting surface arranged to face the object. The optical member is arranged on the light emitting surface of the illumination part and transmits light emitted by the illumination part toward the object. The optical member includes a plurality of optical regions. The optical regions are arranged so as to surround a central region of the light emitting surface centered on an optical axis of the photographing part, and are configured to emit light having mutually different color characteristics toward the object.

The disclosure provide an image inspection device and an illumination device. The image inspection device includes a photographing part; an illumination part including a light guide plate disposed at any position between the object and the photographing part; and a control part. The illumination part includes a first light emitting part and a second light emitting part disposed around the light guide plate; and a first reflective part and a second reflective part. The reflective parts are configured so that a light emitting surface of the light guide plate has an emission intensity distribution of a first pattern when the first light emitting part emits light under control of the control part, and the light emitting surface has an emission intensity distribution of a second pattern different from the first pattern when the second light emitting part emits light under control of the control part.

A visualization module (1, 50, 100, 200), in particular for an endoscope (2), having an image sensor (3) and an illumination unit (4) for lighting a field of view of the image sensor (3), wherein the illumination unit (4) is arranged in the shadow of the image sensor (3) in the case of light that is incident perpendicularly on an end face (32) of the visualization module (1, 50, 100, 200), and the image sensor (3) and the illumination unit (4) are encapsulated at least partially in a transparent encapsulation material (5). A method for producing a visualization module (1, 50, 100, 200) is also provided.

An illumination device that includes a light source and a reflector having a pair of vertically opposed symmetrical reflective surfaces and a pair of horizontally opposed symmetrical reflective surfaces. Each of the vertically and horizontally opposed symmetrical reflective surfaces is formed according to a local surface slope and redirection relationship so as to have a first region that is concave, and a second region that is convex. For each of the vertically and horizontally opposed symmetrical reflective surfaces, the first region is formed proximate to a mounting location of the light source, the first region being positioned to reflect high angle light emitted from the light source. The second region is formed on a distal side of the first region relative to the mounting location of the light source, the second region being positioned to reflect moderate angle light emitted from the light source.