The present invention relates to an embedded printed circuit board including: an insulation substrate including a cavity; a sensor device disposed on the cavity; an insulating layer disposed on the insulation substrate, having an opening part exposing the sensor device; and a pad part disposed on the lower surface of the opening part exposing the sensor device.

An optical module includes a circuit board having a through hole for the lead terminal, a signal wiring connected to the lead terminal, a ground layer providing a reference potential, an opening through which the ground layer is exposed, and a bonding material connecting the ground layer to the metallic base. The lead terminal extends in a first direction, and the circuit board and the signal wiring extend in a second direction. When the circuit board is viewed from the first direction, the opening overlaps with the signal wiring, or when the opening does not overlap with the signal wiring, a first distance between the signal wiring and a closest point of the opening to the signal wiring is smaller than a second distance between the closest point and an edge of the circuit board.

An electronic device with high density for component arrangement includes a first substrate, a second substrate, a plural of passages formed through the first and the second substrates, a first contact arranged on the first face of the first substrate to conceal the corresponding one of the passages, a second contact arranged on the second substrate and adjacent to the corresponding one of the passages, and a conductor disposed in the passages. A first end of the conductor electrically connects the first contact, while a second end of the conductor electrically connects the second contact.

A circuit board according to an embodiment includes an insulating portion; and a pattern portion disposed on the insulating portion, wherein the insulating portion includes: a first insulating region, and a second insulating region disposed outside the first insulating region and spaced apart from the first insulating region with a separation region therebetween; wherein the pattern portion includes: a first pattern portion for signal transmission; and a second pattern portion including a dummy pattern separated from the first pattern portion, wherein the first pattern portion includes: a first terminal portion disposed on the first insulating region; a second terminal portion disposed on the second insulating region; and a connection portion disposed on the separation region and connecting between the first terminal portion and the second terminal portion, wherein the second pattern portion includes: a second-first pattern portion disposed on the first insulating region; and a second-second pattern portion disposed on the second insulating region and separated from the second-first pattern portion.

Microelectronic assemblies including photonic integrated circuits (PICs), related devices and methods, are disclosed herein. For example, in some embodiments, a photonic assembly may include a PIC in a first layer having a first surface and an opposing second surface, wherein the first layer includes an insulating material, wherein the PIC has an active side, an opposing backside, and a lateral side substantially perpendicular to the active side and backside, and wherein the PIC is embedded in the insulating material with the active side facing up; an integrated circuit (IC) in a second layer at the second surface of the first layer, wherein the IC is electrically coupled to the active side of the PIC; and an optical component, having a reflector, optically coupled to the lateral side of the PIC and extending at least partially through the insulating material in the first layer along the lateral side of the PIC.

A three-dimensional optoelectronic device package is disclosed. The three-dimensional optoelectronic device package comprises a first board having at least one surface on which one or more optoelectronic devices is disposed, and a second board having at least one surface on which a plurality of optoelectronic devices is disposed. A side of the second board is attached to the surface of the first board on which one or more optoelectronic devices is disposed to form an angle between the surface of the first board on which one or more optoelectronic devices is disposed and the surface of the second board on which one or more optoelectronic devices is disposed. A method for manufacturing a three-dimensional optoelectronic device package is also disclosed.

A circuit board (100) has a first surface (102). A semiconductor chip (200) (first semiconductor chip) is located at the first surface side (102) of the circuit board (100). An insulating layer (300) covers the first surface (102) of the circuit board (100) and the semiconductor chip (200). A conductive path (310) (first conductive path) is electrically connected to the semiconductor chip (200) and extends in the insulating layer (300). A waveguide (320) is optically coupled to the semiconductor chip (200) and extends in the insulating layer (300).

A vaporizer device may include a pressure sensor and an ambient pressure sensor. The pressure sensor may be configured to measure a first pressure in an air flow path in the vaporizer device. The ambient pressure sensor may be configured to measure a second pressure corresponding to an atmospheric pressure. The vaporizer device may further include a controller. The controller may be configured to transition the vaporizer device to a first standby mode when the first pressure is equal to or greater than the second pressure for a first threshold quantity of time. While the vaporizer device is in the first standby mode, the controller may be further configured to transition the vaporizer device to a second standby mode when the second pressure is a threshold quantity greater than the first pressure and no motion event is detected for a second threshold quantity of time.

A surface mountable laser driver circuit package is configured to mount on a host printed circuit board (PCB). A surface mount circuit package includes a lead-frame. A plurality of laser driver circuit components is mounted on and in electrical communication with the lead-frame of the surface mount circuit package. A dielectric layer is located between the lead-frame and the host PCB and includes portals through the dielectric layer each arranged to accommodate an electrical connection between the lead-frame and the host PCB. The lead-frame and the dielectric layer are arranged such that a first lead-frame portion and a first dielectric layer portal align with a first end of a host PCB trace configured to provide a current return path for the surface mount laser driver, and a second lead-frame portion and a second dielectric layer portal align with a second end of the host PCB trace.

A lighting element is disclosed that provides a projection of light forming a substantially uniform bright light on a surface a known distance from the lighting element. The lighting elements includes a dome lens that is removably positioned on a light source, such that the light source is retained at a location within a focal length of a projection lens and at or within a focal length of the dome lens. The dome lens magnifies the light outputted by the light source, such that the projected light is brighter than the light generated by the light source.