An image capturing unit includes an imaging element and a dual-shot injection-molded optical folding element that are adjacent to each other. The imaging element is configured for an imaging light to pass through. The dual-shot injection-molded optical folding element includes a first part and a second part. The first part is made of transparent material. The first part has a reflective surface configured to reflect the imaging light. The second part is made of opaque material, and the second part is fixed at periphery of the first part. The second part includes a supporting portion configured to support the dual-shot injection-molded optical folding element. The supporting portion maintains the dual-shot injection-molded optical folding element at a predetermined position corresponding to the imaging element through mechanism assembly.

An optical lens (10), a camera module (100), and an electronic device (1000), where light that enters the optical lens (10) is axially folded by using a reflex optical element in the optical lens (10), so that the optical lens (10) can have a relatively long focal length to achieve a long-range photographing effect, and the optical lens (10) has a relatively short total track length. Therefore, when the optical lens (10) is used in the electronic device (1000), thinning of the electronic device (1000) is not affected. In addition, no prism is required to implement optical path folding in the optical lens (10).

The present disclosure relates to a camera module and an electronic apparatus, the camera module includes an imaging device and a lens including a lens group and a light guide member, wherein the light guide member includes a reflective surface and a curved incident surface formed by extending toward an outside of the light guide member, and wherein the reflective surface is used for reflecting external light incident from the incident surface to the imaging device.

Provided is an imaging lens system including a first lens having a positive refractive power, an image-side surface of the first lens is concave, a first reflecting member disposed adjacent to the first lens, an object-side surface of the first reflecting member is concave, a second lens having a negative refractive power, an image-side surface of the second lens is concave, a third lens disposed adjacent to the image-side surface of the second lens, a second reflecting member disposed adjacent to the second lens or the third lens, an image-side surface of the second reflecting member having a convex shape, and an image sensor, wherein the first lens, the second lens and the third lens are sequentially disposed from a side of an object toward the image sensor, and wherein the object-side surface of the first reflecting member and the image-side surface of the second reflecting member include reflective surfaces.

A Tele folded camera operative to compensate for an undesired rotational motion of a handheld electronic device that includes such a camera, wherein the compensation depends on the undesired rotational motion and on a point of view of the Tele folded camera.

A camera module includes a plastic carrier, an imaging lens assembly, a reflective element and a plurality of auto-focusing elements. The plastic carrier includes an inner portion and an outer portion, wherein an inner space is defined by the inner portion, and the outer portion includes at least one mounting structure. The imaging lens assembly is disposed in the inner space of the plastic carrier. The reflective element is for folding an image light by a reflective surface of the reflective element into the imaging lens assembly. The auto-focusing elements include at least two magnets and at least one wiring element, wherein the auto-focusing elements are for moving the plastic carrier along a second optical axis of the imaging lens assembly, and the magnets or the wiring element can be disposed on the mounting structure of the outer portion.

An auto-focus driving assembly used in an electronic device includes a lens kit and a sensor, where a light ray incident to the lens kit passes through the auto-focus driving assembly and enters the sensor, and where the auto-focus driving assembly includes a driving motor configured to drive the lens kit to move, a housing configured to accommodate the driving motor, and a first light-shielding body disposed on an inner wall of the housing and configured to prevent light irradiated on the first light-shielding body from being reflected into a cavity of the housing. The first light-shielding body is disposed on the inner wall.

An image capturing unit includes an imaging element and a dual-shot injection-molded optical folding element that are adjacent to each other. The imaging element is configured for an imaging light to pass through. The dual-shot injection-molded optical folding element includes a first part and a second part. The first part is made of transparent material. The first part has a reflective surface configured to reflect the imaging light. The second part is made of opaque material, and the second part is fixed at periphery of the first part. The second part includes a supporting portion configured to support the dual-shot injection-molded optical folding element. The supporting portion maintains the dual-shot injection-molded optical folding element at a predetermined position corresponding to the imaging element through mechanism assembly.

An optical collimating unit is provided that comprises a laser unit, and a lens having three optical surfaces, being a first refractive surface, a second reflective surface and a third refractive surface. Also provided is a light projection device comprising an optical collimating unit that comprises a laser unit, a lens and an optical component configured to shape laser beams being emitted into respective desired light patterns.

An ultra-wide angle imaging apparatus is provided, comprising a first optics having a first optical axis, a second optics having a second optical axis, and a prism placed at an intersection of the first and second optical axis. The prism is configured to reflect light from the first optics to the second optics and the second optics is configured to transmit light from the prism to an image surface. The first optics has a negative optical power, the second optics has a positive optical power, and the prism has an entrance surface for receiving light from the first optics and a reflective inner surface for reflecting light to the second optics. The entrance surface of the prism comprises a paraxial region that is concave.