A monolithic optoelectronic integrated circuit is provided, including: a substrate including photonic integrated device region and a peripheral circuit region; a first GaN-based multi-quantum well optoelectronic PN-junction device including a first P-type ohmic contact electrode and a first N-type ohmic contact electrode; and a first GaN-based field-effect transistor, where the first GaN-based field-effect transistor includes a first gate dielectric layer disposed on the surface of the substrate and having a first recess, a first gate filled within the first recess, and a first source and a first drain that are disposed the opposite sides of the first gate, where the first source is electrically connected to the first P-type ohmic contact electrode, the first drain is configured to be electrically connected to a first potential.

A monolithic optoelectronic integrated circuit is provided, including: a substrate including photonic integrated device region and a peripheral circuit region; a first GaN-based multi-quantum well optoelectronic PN-junction device including a first P-type ohmic contact electrode and a first N-type ohmic contact electrode; and a first GaN-based field-effect transistor, where the first GaN-based field-effect transistor includes a first gate dielectric layer disposed on the surface of the substrate and having a first recess, a first gate filled within the first recess, and a first source and a first drain that are disposed the opposite sides of the first gate, where the first source is electrically connected to the first P-type ohmic contact electrode, the first drain is configured to be electrically connected to a first potential.

A parallel optical interconnect having an optoelectronic substrate connected to a transceiver electronics substrate is disclosed. The optoelectronic substrate may hold optical transmitters and receivers and be electrically connected to the transceiver electronics substrate that may hold transmitter and receiver circuitries. The two substrates may be electrically connected with each other by inter-substrate interconnects, and the optoelectronic substrate may have through-substrate vias connecting the transmitters and receivers to the inter-substrate interconnects.

A parallel optical interconnect having an optoelectronic substrate connected to a transceiver electronics substrate is disclosed. The optoelectronic substrate may hold optical transmitters and receivers and be electrically connected to the transceiver electronics substrate that may hold transmitter and receiver circuitries. The two substrates may be electrically connected with each other by inter-substrate interconnects, and the optoelectronic substrate may have through-substrate vias connecting the transmitters and receivers to the inter-substrate interconnects.

A display panel, a method of manufacturing the display panel, a method of driving the display panel and a display device are provided. The display panel includes an array substrate and a plurality of micro light-emitting diodes arranged on the array substrate, and further includes: a photoelectric conversion structure in a one-to-one correspondence with a micro light-emitting diode, the photoelectric conversion structure is located on a side of the corresponding micro light-emitting diode facing the array substrate, connected to the corresponding micro light-emitting diode, and configured to convert a received light signal emitted by the micro light-emitting diode into an electrical signal, and charge the corresponding micro light-emitting diode by using the electrical signal. The display panel is used for display.

A semiconductor device is provided. The semiconductor device includes a substrate and a light-collimating layer. The substrate has a plurality of pixels. The light-collimating layer is disposed on the substrate, and the light-collimating layer includes a transparent material layer, a first light-shielding layer, a second light-shielding layer and a plurality of transparent pillars. The transparent material layer covers the pixels. The first light-shielding layer is disposed on the substrate and the first light-shielding layer has a plurality of holes corresponding to the pixels. The second light-shielding layer is disposed on the first light-shielding layer. The transparent pillars are disposed in the second light-shielding layer.

A system is disclosed that includes an electronic package. The electronic package includes a package base couplable to a host substrate, and a package lid mechanically coupled to the package base that includes one or more transparent lid areas, configured to permit transmission of light. The electronic package further includes a thermal spreader bonded on a first side to a first side of the package lid. The thermal spreader includes one or more transparent spreader areas that are configured to allow transmission of light through the thermal spreader. The electronic package further includes one or more integrated circuits bonded to a second side of the thermal spreader that communicatively coupled to the host substrate. The electronic package further includes one or more optical paths that include at least one of the one or more transparent spreader areas configured adjacent to at least one of the transparent lid areas.

A system is disclosed that includes an electronic package. The electronic package includes a package base couplable to a host substrate, and a package lid mechanically coupled to the package base that includes one or more transparent lid areas, configured to permit transmission of light. The electronic package further includes a thermal spreader bonded on a first side to a first side of the package lid. The thermal spreader includes one or more transparent spreader areas that are configured to allow transmission of light through the thermal spreader. The electronic package further includes one or more integrated circuits bonded to a second side of the thermal spreader that communicatively coupled to the host substrate. The electronic package further includes one or more optical paths that include at least one of the one or more transparent spreader areas configured adjacent to at least one of the transparent lid areas.

This invention provides an earphone with a low light transmittance and a non-porous sensor cover. Covering the sensing cover on the proximity sensing device can reduce the interference of most of the ambient light and improve measurement accuracy.

This invention provides an earphone with a low light transmittance and a non-porous sensor cover. Covering the sensing cover on the proximity sensing device can reduce the interference of most of the ambient light and improve measurement accuracy.