A camera device is provided that comprises a camera having an image sensor for recording images of the objects and at least one first deflection element, and wherein the field of view of the camera has at least one first part field of vision with detection of the first deflection element and a second part field of vision with detection of the first deflection element. In this respect, the first deflection element is arranged such that a first perspective of the first part field of vision is a different one than a second perspective of the second part field of vision; the first part field of vision thus provides a different perspective of the object than the first part field of vision so that at least two sides of the object are simultaneously recorded by the image sensor.

An illumination device including a light source and a reflector with 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 includes a concave region positioned proximate a light source, and a convex region positioned distal the light source. The pairs of vertically opposed symmetrical reflective surfaces and horizontally opposed symmetrical reflective surfaces of the reflector redistribute light emitted from the light source such that the illumination device outputs a field of illumination having a substantially uniform intensity of light.

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.

Provided is an image sensor lighting unit including at least one light guide extending in a main scanning direction; a first light source group facing a first end surface of at least two end surfaces of the at least one light guide in the main scanning direction; and a second light source group facing a second end surface of the at least two end surfaces. The first light source group includes a first light source that emits light having a predetermined wavelength band. The second light source group includes a second light source that emits light having the wavelength band. An X-coordinate of the first light source in a corresponding XY-coordinate system is equal in absolute value to an X-coordinate of the second light source in a corresponding XY-coordinate system, with the at least one light guide viewed from the first end surface side in the main scanning direction.

A 360-degree camera device having atmosphere lamp includes a supporting platform, a supporting spindle, a supporting base, and a rotating shooting bracket. The supporting platform includes a first supporting element, a tempered glass, a first light source, and a reflecting mirror. The first supporting element is configured to support the tempered glass. The tempered glass is a single-sided perspective glass including a light-transmitting surface and a reflecting surface. An interval area is disposed between the tempered glass and the reflecting mirror. The reflecting mirror and the reflecting surface are oppositely disposed. The first light source is disposed in the interval area. The first light source is in a shape of graphics and/or characters. The first light source includes a plurality of point-shaped light-emitting parts. The first light source is substantially disposed in an annular shape and disposed along edge contour of the tempered glass or the reflective mirror.

The disclosure relates to a light supplement device or module, and a light supplement control method, a terminal, and an apparatus for the light supplement module, and belongs to the technical field of electronic devices. The light supplement module includes a circuit substrate; n Light Emitting Diodes (LED) disposed in an array on the circuit substrate, n being an integer greater than 1, and there being at least two LEDs having different colors; and a light guiding layer disposed on an upper layer of the n LEDs, wherein the LEDs are color LEDs, or the n LEDs constitute a color LED group.

A portable micro imaging device includes a lens and a lens body. The portable micro imaging device is detachably connected with a portable imaging device having a camera and an illuminator. The lens body is made of a transparent or semi-transparent solid material. An outer surface of a front surface of the lens body is partially provided with an independent specular reflection layer or diffuse reflection layer to cover the illuminator, and the specular reflection layer or the diffuse reflection layer is made of an opaque material. A closed annular light-transmission ring is formed between the specular reflection layer or the diffuse reflection layer and an outer periphery of the front surface of the lens body. An opening size of a mounting hole of the lens body in the front surface of the lens body is larger than a size of the lens.

An example electronic device includes at least one glass assembly provided to be adjacent to the outside of a camera module or an electronic device, wherein the glass assembly may include glass; a first reflective layer stacked on the glass and provided to transmit and reflect light emitted from a light source; a second reflective layer which is provided to be spaced apart from the first reflective layer, and which has a higher reflectivity than that of the first reflective layer; a reflective space formed between the first reflective layer and the second reflective layer; the light source disposed on one side of the reflective space to emit light; and a pattern layer which is stacked on the first reflective layer to face the reflective space, and which includes a pattern that becomes darker as the distance from the light source increases.

A light source device includes: a plurality of light source parts configured to emit light. Each of the light source parts comprises a light-emitting element and a light guiding member. the plurality of light-emitting elements are configured to emit light passing through the light guiding members from the light source parts in an array in an irradiated region. One or more of the plurality of light source parts are arranged in a placement region in a different arrangement from an arrangement of the light in the irradiated region.

A detection system determines to-be-test products to be qualified or not. The detection system includes a first detection module, a sensing module, and a control module. The first detection module includes a first photographing apparatus and a first light source. The first light source being a plane light source emits light and illuminates the to-be-tested product while the first photographing apparatus captures an image of the to-be-tested product. The control module controls the first light source to emit light and control the first photographing apparatus to capture the image of the to-be-tested product when receiving the sensing signal generated by the sensing module. The control module further analyzes the captured image for determining the to-be-tested product to be qualified or not.