A shield is provided. The shield includes a shield frame surrounding an electronic component mounted on a printed circuit board and a shield cover partially coupled to the shield frame. The shield frame includes a column part mounted on the printed circuit board and a bending part bent from an upper end portion of the column part. An angle between both end portions of the bending part is smaller than about 90 degrees.

A module 1a includes an electronic component 3a, and also includes a wiring substrate 2 on one principal surface of which the electronic component 3a is mounted and in which a radiator 4 for dissipating heat generated from the electronic component 3 is provided. The radiator 4 includes a heat dissipation section 4a that is provided so that a part thereof is exposed to a side surface of the wiring substrate 2. In this case, because the heat dissipation section 4a is provided so that a part thereof is exposed to the side surface of the wiring substrate 2, the heat from the electronic component 3a can be dissipated through the side surface of the wiring substrate 2.

Disclosed is a system, a hearing device and a method for encapsulating one or more electronic components on a substrate. The method comprises providing a dam on the substrate, the dam is provided around the one or more electronic components, the dam comprises a dam material comprising an electrically conducting material. The method comprises providing a liquid fill encapsulation material within the dam on the substrate, the fill encapsulation material encapsulates the one or more electronic components, the fill encapsulation material is configured to solidify, the solidified fill encapsulating material comprises a first surface exposed to surroundings. The method comprises applying a cover material on the first surface of the solidified fill encapsulation material, the cover material comprising an electrically conducting material, whereby the one or more electronic components are encapsulated and electromagnetically shielded.

The present disclosure provides a circuit board for high frequency transmission and a shielding method. The circuit board for high frequency transmission includes: a first shielding film, a second shielding film and a circuit board body. The circuit board body includes a first surface and a second surface that are arranged opposite to each other. The first shielding film covers the first surface, and the second shielding film covers the second surface. The circuit board body is provided with a wire region. The first shielding film and the second shielding film are in electrical connection at a lateral side of the wire region. Therefore, leaky waves at the lateral side of the circuit board body are effectively avoided, and the circuit board body is thin in structure.

An inhomogeneous dielectric medium high-speed signal trace system includes first and second ground layers. A first dielectric layer has a first dielectric constant and is located adjacent the first ground layer, and a second dielectric layer has a second dielectric constant that is different than the first dielectric constant and is located between the first dielectric layer and the second ground layer. A first differential trace pair is located between the first and second dielectric layer. A plurality of first vias extend between the first ground layer and the second ground layer and are spaced part from each other and the first differential trace pair. A plurality of second vias extend between the first ground layer and the second ground layer, are spaced part from each other and the first differential trace pair, and are located opposite the first differential trace pair from the plurality of first vias.

Provided is a method of producing a shielded printed wiring board capable of sufficiently adhering to each other a printed wiring board, an adhesive layer of an electromagnetic wave shielding film on one face of the printed wiring board, and an adhesive layer of an electromagnetic wave shielding film on the other face of the printed wiring board. The method of producing a shielded printed wiring board of the present invention includes a printed wiring board preparing step of preparing a printed wiring board including a base film, a printed circuit formed on the base film, and a coverlay covering the printed circuit; a first electromagnetic wave shielding film preparing step of preparing a first electromagnetic wave shielding film sequentially including a first protective film, a first insulating layer, and a first adhesive layer; a second electromagnetic wave shielding film preparing step of preparing a second electromagnetic wave shielding film sequentially including a second protective film, a second insulating layer, and a second adhesive layer; a first electromagnetic wave shielding film placing step of placing the first electromagnetic wave shielding film on the printed wiring board so that the first adhesive layer is in contact with one face of the printed wiring board, and part of the first adhesive layer protrudes from an end of the printed wiring board to form a first extending end portion; a second electromagnetic wave shielding film placing step of placing the second electromagnetic wave shielding film on the printed wiring board so that the second adhesive layer is in contact with the other face of the printed wiring board, and part of the second adhesive layer protrudes from an end of the printed wiring board to form a second extending end portion; a stacking step of stacking the first extending end portion on the second extending end portion so that a gap is created between the first extending end portion and the second extending end portion, whereby a shielded printed wiring board before pre-pressing is prepared; a pre-pressing step of pressurizing and heating the shielded printed wiring board before pre-pressing to the extent that the first adhesive layer and the second adhesive layer are not completely cured, whereby a pre-pressed shielded printed wiring board is prepared; a protective film peeling step of peeling off the first protective film and the second protective film from the pre-pressed shielded printed wiring board, whereby a shielded printed wiring board before post-pressing is prepared; and a post-pressing step of pressurizing and heating the shielded printed wiring board before post-pressing to cure the first adhesive layer and

An electronic device module includes a substrate, a first component disposed on a first surface of the substrate, a sealing portion disposed on the first surface of the substrate, a second component disposed on the first surface of the substrate and embedded in the sealing portion, and a shielding wall at least partially disposed between the first component and the second component and including a portion having a height, with respect to the first surface of the substrate, that is lower than a height of the sealing portion.

An interposer and method of providing spatial and arrangement transformation are described. An electronic system has an electronic package, a motherboard and an interposer between the package and the motherboard. The interposer has signal and ground contacts on opposing surfaces that are respectively connected. The contacts opposing the package has a higher signal to ground contact ratio than the contacts opposing the motherboard, as well as different arrangements. Ground shielding vias in the interposer, which are connected to a ground plane, electrically isolate the signals through the interposer. The package may be mounted on a shielded socket such that signal and ground pins are mounted respectively in signal and ground socket mountings, ground shielding vias are between the signal socket mountings, and the ground socket mountings contain plated socket housings.

An additive printing method depositing a functional print pattern on a surface of a 3D object, an associated computer program, and a computer-readable medium storing the program. The method comprises as steps (i) providing the object on a planar surface; (ii) providing a print head having print nozzles defining a plane non-parallel to the planar surface; (iii) generating 3D geometrical surface data of an exposed surface of the object on the planar surface; (iv) generating 2D geometrical surface data of the exposed surface on the basis of the 3D geometrical surface data; (v) determining an amount of printing fluid to be discharged at a discharge time from each of the print nozzles; (vi) generating a relative movement between the object and the print head; and (vii) printing a print pattern on at least one portion of the exposed surface during the relative movement. A step of correcting data is included.

A wireless communication device is provided and includes a communication module, a dust and moisture resistant adhesive, and a nano-metallic layer. The communication module includes a circuit board, a communication chip and a plurality of passive components mounted on a carrying surface of the circuit board, and an insulating sheet that is disposed on the passive components and that has a thickness smaller than or equal to 150 μm. The dust and moisture resistant adhesive covers any electrically conductive portions of the communication module on the carrying surface. The nano-metallic layer covers the dust and moisture resistant adhesive, the communication chip, the passive components, and the insulating sheet, and is electrically coupled to a grounding portion of the circuit board. The wireless communication device does not include any grounding metal housing mounted on the circuit board.