An optical module includes a substrate that has a first surface and a second surface opposite to the first surface and provided with a first hole portion having an opening surface on at least the first surface, an optical element that is provided on the substrate, the optical element having an optical axis located along a thickness direction from the first surface toward the second surface and located in the first hole portion, and a first light shielding portion that is provided on an inner peripheral surface which intersects the opening surface of the first hole portion and has a higher light shielding property than the substrate.

The present disclosure provides an optical imager and a method for imaging electromagnetic radiation. In one aspect, the optical imager includes an object array substantially located at an object plane, a first catadioptric element configured to substantially collimate, at a central plane, electromagnetic radiation emanating from the object array, a second catadioptric element configured to image the substantially collimated electromagnetic radiation from the central plane onto an image plane, and a detecting element substantially located at the image plane. The first catadioptric element includes at least one refractive surface and at least one reflective surface, and the second catadioptric element includes at least one refractive surface and at least one reflective surface.

An optical sensor assembly is provided. The optical sensor assembly includes a circuit board, an optical sensor positioned on the circuit board, and a front cover attached to the circuit board and covering the optical sensor. The front cover includes an optical element configured to guide or condense an incident light of a predetermined wavelength onto the optical sensor. The front cover is made of polypropylene or polyethylene. The predetermined wavelength is in a range from 8 micrometers to 12 micrometers.

A lens module includes a base and a filter. The base includes a through hole and a first thread. The through hole is surrounded by an inner surface of the base. The first thread is formed on the inner surface. The filter includes a sidewall and a second thread forming on the sidewall. The filter is received in the through hole, the second thread is engaged with the first thread. The disclosure also provides an electronic device having the lens module.

An IC integrated structure for an optical mouse of the invention comprises a bracket configured for being connected with a PCB, an LED wafer for emitting light, a main control IC wafer and an optical lens; wherein the LED wafer and the main control IC wafer are respectively mounted at two ends of a terminal surface inside a bracket frame, the LED wafer and the main control IC wafer are connected with the PCB by the bracket, and the optical lens is mounted above the LED wafer and the main control IC wafer; a light shield configured for shielding an external light source is arranged between the optical lens and the main control IC wafer, and a through hole configured for transmitting light is formed in the light shield.

A sensor and a portable terminal comprising the same, according to an embodiment, comprise: a substrate; a light-emitting unit and a light-receiving unit, which are arranged on the substrate at a distance from each other; a cover unit arranged on the light-emitting unit and the light-receiving unit so as to face the substrate; a first optical guide lens unit arranged between the cover unit and the light-emitting unit so as to refract light, which has been emitted from the light-emitting unit and to transfer the same to the outside of the cover unit; and a second optical guide lens unit arranged between the cover unit and the light-receiving unit so as to transfer light from the outside of the cover unit to the light-receiving unit. In connection with a proximity/illuminance sensor, the sensing range related to a spaced object is expanded, thereby improving the sensing performance.

An optical module includes a base member, a red semiconductor laser, a green semiconductor laser, a blue semiconductor laser, a first light receiving device having a first light receiving face that receives backward red light emitted from the red semiconductor laser, a second light receiving device having a second light receiving face that receives backward green light emitted from the green semiconductor laser, a third light receiving device having a third light receiving face that receives backward blue light emitted from the blue semiconductor laser, wherein the first light receiving face, the second light receiving face, and the third light receiving face are inclined relative to planes perpendicular to optical axes of the backward red light, the backward green light, and the backward blue light, respectively, to reduce the likelihood of occurrence of stray light.

A camera module includes a base, a circuit board bearing the base, and a metal plate bearing the circuit board and the base. The base includes a receiving portion and a bearing portion. The bearing portion surrounds the receiving portion. The bearing portion defines a cutout to receive an electronic component of the circuit board.

A proximity sensing device includes: a light source, a sensing unit, a light guide unit, and a window. The light source emits light, which is guided by the light guide unit to the window. The emitted light reflected by an object is received by the same window. The light guide unit includes a partial-transmissive-partial-reflective (PTPR) optical element, whereby the light emitted from the light source is reflected by the PTPR optical element, while the light reflected by the object passes through the PTPR optical element. There is only one window required.

A self-clocked photoreceiver device and a method of operating. The self-clocked photoreceiver device includes a light detector connected between a power supply node and a first node, and first to third switching elements. The light detector is configured to detect an incident optical data signal, and to output photocurrent corresponding to a magnitude of the optical data signal through the first node. The first switching element is connected between the first node and a ground node. The second switching element is connected between the power supply node and a second node. The third switching element is connected between the second node and the ground node. The third switching element has a control node connected to the first node.