A tape feeder is configured such that plural tape suppliers guiding plural component supply tapes to a component pick-up position are individually and detachably mounted on plural slots of the feeder body. A read component ID from a code label of a tape reel is input into a feeder management computer. The feeder management computer performs instruction display of the slot to be mounted among the plural slots to an instruction display section based on component ID. If a mounting confirmation sensor confirms the tape supplier is mounted on one of the slots, the feeder management computer determines whether or not a component in which the component ID is read is supplied from a correct slot depending on whether or not the slot in which the mounting of the tape supplier is confirmed matches the slot in which the instruction display is performed.

An optical component optically coupled to an optical fiber includes a substrate and an edge-emitting laser. The substrate includes an accommodating cavity, a plurality of openings, a waveguide, an optical coupler and a plurality of pads. The waveguide and the optical coupler are distributed outside the accommodating cavity. The openings are distributed at the bottom surface of the accommodating cavity and the pads are located at the bottom of the openings. The optical coupler is optically coupled to an end of the waveguide and includes a light-incident surface. The edge-emitting laser is embedded in the accommodating cavity and includes a light-emitting layer and a plurality of bumps located in the openings and electrically connected to the pads. The ratio of the level height difference between the light-emitting layer and the optical coupler to the thickness of the optical coupler ranges from 0 to 0.5.

A flexible circuit board and a cutting device are provided. The flexible circuit board includes a board body including a cutting region. A plurality rows of testing terminals are located in the cutting region, a first spacing being provided between two adjacent rows of testing terminals. The testing terminals can be respectively cut off from the board body along a cutting direction which is along the extending direction of the first spacing in the board body. A testing circuit is located on a surface of the board body. The testing circuit is arranged in a region outside the cutting region and the testing circuit is independently and electrically connected to each row of the testing terminals.

An optical component optically coupled to an optical fiber includes a substrate and an edge-emitting laser. The substrate includes an accommodating cavity, a plurality of openings, a waveguide, an optical coupler and a plurality of pads. The waveguide and the optical coupler are distributed outside the accommodating cavity. The openings are distributed at the bottom surface of the accommodating cavity and the pads are located at the bottom of the openings. The optical coupler is optically coupled to an end of the waveguide and includes a light-incident surface. The edge-emitting laser is embedded in the accommodating cavity and includes a light-emitting layer and a plurality of bumps located in the openings and electrically connected to the pads. The ratio of the level height difference between the light-emitting layer and the optical coupler to the thickness of the optical coupler ranges from 0 to 0.5.

An optical receiver including a photodetector and a waveguide is provided. The photodetector includes a plurality of photosensitive regions arranged in an array. The waveguide is disposed on the photodetector and includes a plurality of gratings, a plurality of optical channels, and a plurality of light-deflection elements. The gratings are respectively adapted to collect light beams incident on the waveguide at different angles. The optical channels are adapted to propagate the light beams collected by the gratings. The light-deflection elements are disposed on transmission paths of the light beams propagating in the optical channels and are located above the photosensitive regions. The light-deflection elements are adapted to propagate the light beams propagating in the optical channels to the photosensitive regions. An optical transceiver is also provided.

A detection method for electronic devices including steps as follows is provided. The detection method includes: providing an electronic device substrate; attaching a portion of electronic devices of the electronic device substrate through an electronic device transfer module, wherein the electronic device transfer module includes a plurality of detecting elements corresponding to the portion of the electronic devices, and each of the detecting elements includes at least one pair of electrodes; detecting whether a conducting path between the at least one pair of electrodes is generated or not to confirm a status of contact between the portion of the electronic devices and a contact target; and transferring the portion of the electronic devices attached to the electronic device transfer module to a target substrate. An electronic device transfer module having detecting elements is also provided.

This application provides a circuit board assembly soldering apparatus and corresponding method. The soldering apparatus is provided with at least two bearing seats on a base plate, the bearing seats are located in a space between the base plate and a pressing plate assembly, the bearing seats each include a workbench, the workbench is located on a side of the bearing seat that faces the pressing plate assembly, a circuit board assembly is placed on the workbench. At least one adjustable bearing seat is provided, and a spacing between the workbench of the adjustable bearing seat and the base plate is adjustable. Further, a spacing between the workbench of the adjustable bearing seat and the pressing plate assembly is adjusted, to implement soldered connection between circuit board assemblies with different thicknesses, and the soldering apparatus can connect at least two circuit board assemblies by soldering at a single time.

Disclosed are a thin, stretchable and flexible printed circuit and a manufacturing method therefor. The manufacturing method comprise: attaching an adhesion-reducing carrier film to a first side of a flexible circuit board provided with a circuit layer and two protective films, wherein the adhesion-reducing carrier film has a large first preset adhesive force; and attaching a first elastomer composite film, and then performing an adhesion-reducing operation on the adhesion-reducing carrier film to allow the adhesion-reducing carrier film to have a small second preset adhesive force. The elastomer composite film is formed by two polymer films with different melting points. The invention can increase the product yield in mass production based on the adhesion-reducing carrier film and can wrap a serpentine circuit by means of the elasticity of a composite structure of the polymer films to realize thin and light design and miniaturization.