Integrated circuit assemblies, electronic systems, and methods for fabricating the same are disclosed. An integrated circuit assembly is formed by thermally contacting at least two integrated circuit packages to opposite sides of a shared heat dissipation device. In one embodiment, the at least two integrated circuit packages are electrically attached to an electronic card to form an intermediate integrated circuit assembly. In a further embodiment, the integrated circuit assembly includes at least one intermediate integrated circuit assembly electrically attached to an electronic board.

A modularly expandable enclosure including a top end plate, a bottom end plate, and one or more elongated tray modules. The top end plate, the bottom end plate and the tray modules define an interior space of the enclosure. Opposite vertical ends of each tray module define an upper end connecting portion and a lower end connecting portion. The upper end connecting portion is configured for engagement with the top end plate and further configured for engagement with a lower end connecting portion of a vertically upwardly adjacent module tray. The lower end connecting portion is configured for engagement with the bottom end plate and further configured for engagement with an upper end connecting portion of a vertically downwardly adjacent tray module.

Examples herein include modules and connections for modules to couple to a computing device. An example module includes a housing comprising an end to couple to a computing device, multiple capacitive pads that each include data contacts to enable data transfer, a power contact pad to provide or receive power, and a ground contact pad to couple to ground. The ground contact pad is larger in size than the power contact pad, and the ground contact pad is positioned closer than the power contact pad to the end of the housing configured to couple to the computing device.

A fluid control apparatus is provided which makes it possible to effortlessly perform cable connection even when a plurality of the fluid control apparatuses are disposed adjacent to each other. The fluid control apparatus includes fluid control units to control a flow rate or pressure of a fluid, an electric circuit board to send and receive a signal to and from the fluid control units, a casing to accommodate therein the fluid control units and the electric circuit board, and an apparatus-side connector interposed between the electric circuit board and a cable electrically connected thereto. The fluid control apparatus further includes a connector board configured to mount thereon the apparatus-side connector. The connector board is secured to the electric circuit board with at least a part of the connector board in surface contact with the electric circuit board, or overlapping the electric circuit board with a clearance therebetween.

A method to fabricate a tamper respondent assembly is provided. The tamper respondent assembly includes an electronic component and an enclosure at least partly enclosing the electronic component. A piezoelectric sensor is integrated in the enclosure. The integrating includes providing a base structure that includes a first conductive layer, depositing a piezoelectric layer on the first conductive layer, covering the piezoelectric layer with a second conductive layer, and providing sensing circuitry for observing sensing signals of the piezoelectric layer. The piezoelectric layer includes a plurality of nanorods. Aspects of the invention further relates to a corresponding assembly and a corresponding computer program product.

A circuit board and an electronic device, the circuit board includes a first wiring board including a first substrate and a first wiring layer disposed on a first side surface of the first substrate, and the first wiring layer includes a first ground wiring; the circuit board further includes a first protective layer and a first electromagnetic interference shielding layer sequentially stacked on a side of the first wiring layer away from the first substrate; the first protective layer has a first opening exposing at least a portion of a first ground wiring, the first opening is filled with a first conductive material, height difference between a surface of the first conductive material and a surface of the first protective layer away from the first substrate ranges from 0 to 2 microns, and the first conductive material connects the first electromagnetic interference shielding layer to the first grounding wiring.

The present invention relates to a circuit board including: a base board having a circuit region and a terminal region; a circuit pattern formed on an upper portion of the base board; and a low-melting-metal layer formed on an upper portion of the circuit pattern. A circuit board capable of reducing manufacturing time and manufacturing costs may be manufactured by omitting a photoresist process.

A cooling module includes an electroosmotic pump. The electroosmotic pump includes a first electrode which is permeable to a cooling fluid, a second electrode which is located with an interval from the first electrode and is permeable to the fluid, and a dielectric layer which is located between the first electrode and the second electrode and includes a microchannel which is permeable to the fluid. The first electrode and the second electrode have different polarities.

Disclosed is an apparatus and method for wirelessly transmitting power to power receivers from a power transmitter. The present disclosure provides a rational search procedure for locations of the power receivers, and provides a function of simultaneously charging multiple receivers using microwave multi-focusing. The wireless power transmission method performed by a power transmitter includes determining angular coordinates of the power transmitter in relation to a position of at least one power receiver; determining a distance between the at least one power receiver and the power transmitter based on the determined angular coordinates by using a focused microwave field; determining a location of the at least one power receiver based on the determined angular coordinates and the distance; and wirelessly transmitting power by focusing the microwave field to the determined location of the at least one power receiver.

A heat-dissipating board structure and a circuit board module are provided. The heat-dissipating board structure includes a first board, a second board, a heat-transmitting layer and a buffering liquid. The first board has a first inner surface and the first inner surface has a plurality of first metal protrusions thereon. The second board is correspondingly engaged with the first board to form an accommodating chamber therebetween. The second board has a second inner surface and the second inner surface has a plurality of second metal protrusions thereon. The heat-transmitting layer is disposed in the accommodating chamber and arranged between the first metal protrusions and the second metal protrusions. The buffering liquid is filled in a residual space of the accommodating chamber. Therefore, the heat-dissipating board structure can meet the design requirements of a light-weight and thin electronic product and can effectively remove heat from a heat source.