An electronic assembly includes an electronic package connected to a host circuit board. The electronic assembly includes interposer assemblies electrically connected to the electronic package. The electronic assembly includes cable modules coupled to upper separable interface of the interposer assemblies. The electronic assembly includes carrier assemblies configured to be coupled to an upper surface of the electronic package. Each carrier assembly includes a carrier base block and a carrier lid configured to hold at least one interposer assembly and at least one cable module. The carrier assemblies hold the cable modules with the module contacts in electrical connection with upper mating interfaces of the interposer contacts. The carrier assemblies hold lower mating interfaces of the interposer contacts in electrical connection with upper package contacts of the electronic package. The carrier assemblies are separately removable from the electronic package to separate the interposer assemblies from the electronic package.

A camera module with compression-molded circuit board is manufactured by compression-molding that can obtain properties such as high flatness, ultra-thin, fine wiring width and high integration.

A camera module and an array camera module based on an integral packing process are disclosed. The camera module or each of the camera module units of the array camera module includes a circuit board, an integral base, a photosensitive element operatively connected to the circuit board, a lens, a light filter holder installed at the integral base and a light filter installed at the light filter holder. The light filter is not required to be directly installed to the integral base, so that the light filter is protected and the requiring area of the light filter is reduced.

A hollow shielding structure for different types of circuit elements is provided. The hollow shielding structure includes at least one element mounted on a printed circuit board (PCB), a shield dam surrounding the at least one element, and a shield cover is configured to be electrically coupled to an upper portion of the shield dam and cover the at least one element, with a gap formed between the at least one element and the shield cover.

An implantable connector for connecting an electronics package and a neural interface is made by way of a compressible contacts (e.g., a spring) that physical contacts a corresponding exposed bond pad. The compressible contact is held in compression with the exposed bond pad using a mechanical coupler. The compressible contact is physically separated and electrically isolated from other contacts by way of a compressible gasket. The compressible gasket is also held in compression using the mechanical coupler.

A method for fabricating an assemble substrate is provided, including stacking a circuit portion on a plurality of circuit members. The circuit members are spaced apart from one another in a current packaging process to increase a layer area. The assemble substrate thus fabricated meets the requirements for a packaging substrate of a large size, and has a high yield and low fabrication cost.

A touch device is provided. The touch device includes a substrate, a light-emitting element, a light-shielding member, a sensing board, and a light-passing board. The light-emitting element is disposed on the substrate. The light-shielding member is disposed on the substrate, wherein the light-shielding member has a first opening, and the light-emitting element is located in the first opening. The sensing board is disposed on the light-shielding member, and is electrically connected to the substrate. The sensing board has a second opening, and the first opening and the second opening overlap. The light-passing board is disposed on the sensing board, and covers the first opening and the second opening.

A system for controlling a robotic arm is disclosed. The system includes a robotic arm including a surgical tool, a tool driver, and at least two sensors disposed on the robotic arm to redundantly monitor a status of the robotic arm and to verify an operational parameter of the surgical robotic tool. A central control circuit is configured to measure a first physical property of the robotic arm based on readings from the first sensor, measure a second physical property of the robotic arm based on readings from the second sensor, and determine a status of the robotic arm based on the first and second measurements of the first and second physical properties of the robotic arm.

A method for fabricating an assemble substrate is provided, including stacking a circuit portion on a plurality of circuit members. The circuit members are spaced apart from one another in a current packaging process to increase a layer area. The assemble substrate thus fabricated meets the requirements for a packaging substrate of a large size, and has a high yield and low fabrication cost.

The disclosure provides a low-cost near-hermetic package, which may a substrate configured to support one or more internal components. The package may also include an enclosure comprising a cavity surrounding the one or more internal components and a first sidewall extending upward from the substrate. The first sidewall may be coupled to the substrate. The package may further include a first flexible circuit comprising conductive traces configured to connect to the one or more internal components. The first flexible circuit may include a first section outside the first sidewall of the enclosure, a second section inside the enclosure, and a third section between the first section and the second section joining to the enclosure and the substrate.