A receiving device includes a shield case which is in a hollow box shape that is open on one side. The shield case reduces external interfering signals which interfere with an input signal of a broadcast wave. A printed wiring board includes a conductive portion that is electrically connected with an electronic component. A soldered portion is formed along a protrusion-free linearly extending side of an opening edge of the shield case. The soldered portion electrically connects with solder the shield case and the conductive portion.

A circuit shielding structure, relating to a technical field of electronics, includes a substrate, wherein: at least one radio frequency component circuit is fixed on the substrate; a wave-absorbing material layer is embedded in the substrate; a shielding wall made of wave-absorbing material is arranged on the substrate and around the radio frequency component circuit; a conductive material layer covers the shielding wall; a closed space is formed among the substrate in which the wave-absorbing material layer is embedded, the shielding wall and the conductive material layer, and the radio frequency component circuit is sealed in the closed space, so that omnidirectional shielding is achieved.

A method of manufacturing electronic package module is provided. The method provides selective molding by attaching tapes on the circuit substrate on which electric components are mounted thereon, forming molding compound to cover the circuit substrate, and removing tapes along with the molding compound thereon.

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.

Audio device, electronic circuit, and related methods, in particular a method of manufacturing an electronic circuit for an audio device is disclosed, the method comprising providing a circuit board; mounting one or more electronic components including a first electronic component on the circuit board; applying a first insulation layer outside the first electronic component; and applying a first shielding layer outside the first insulation layer.

An assembly is provided which includes a package and a printed circuit board. The package includes a housing bounding a region and an acoustic sensor within the region. The housing includes a base with a first hole. The sensor is configured to generate signals indicative of sound received by the sensor through the first hole. The printed circuit board is in mechanical communication with the base and includes a second hole aligned with the first hole such that sound received by the second hole propagates through the first hole to the sensor. The printed circuit board further includes an electrically conductive layer, at least a portion of which extends across the second hole and is configured to allow the sound to propagate through the second hole and to at least partially shield the region containing the sensor from electromagnetic interference.

The present disclosure relates to a radar apparatus including a circuit board provided inside a housing having an upper side open, and on which an RF element is mounted on an upper surface, and a cavity having an open lower side and coupled to the upper surface of the circuit board for accommodating the RF element, wherein the cavity includes a coupling portion extending downwardly in a region of a surface coupled to the circuit board, and the coupling portion is inserted into a coupling hole formed in the circuit board to contact a ground plane of the circuit board.

Particular embodiments described herein provide for an electronic device that can be configured to include a support structure that includes a radiation shield groove that extends past a surface of the support structure and into the support structure, a radiation source on the substrate, and a radiation shield around the radiation source, where the radiation shield includes a wall secured to the support structure and a groove channel coupling wall that extends past a surface of the support structure and into the radiation shield groove.

An electronic device according to various embodiments of the present invention may comprise: a circuit substrate comprising a first layer including a first wire, a second wire formed at one side surface of the first wire along the first wire, and a third wire formed at the other side surface of the first wire along the first wire, a second layer including a ground plane formed along the first wire, the second wire, and the third wire and electrically connected to the second wire and the third wire, and an insulation layer disposed between the first layer and the second layer and having first permittivity; and a conductive member which is disposed above the first layer to have a dielectric-fillable interval space along the first wire and is electrically connected to the ground of the electronic device, the dielectric having second permittivity lower than the first permittivity.

According to one embodiment, in a semiconductor storage device, a conductive cover is provided on a side of the principal surface, and covers at least a part of the memory and the controller. A substrate has a first notched portion and a second notched portion in an outer edge. The conductive cover has a top plate portion, a first side plate portion, a second side plate portion, a first claw portion, and a second claw portion. The first claw portion is extended from a lower end of the first side plate in a direction intersecting with the principal surface. The first claw portion is fitted into the first notched portion. The second claw portion is extended from a lower end of the second side plate in the direction intersecting with the principal surface. The second claw portion is fitted into the second notched portion.