A semiconductor device includes a base, a first switching unit disposed on the base, the first switching unit having a substantially rectangular shape and including plural first switches, and an amplifier unit disposed on the base, the amplifier unit including plural amplifier circuits to which a radio-frequency signal is inputted after passing through the first switching unit. In plan view of the base, the first switching unit has four edges including a first edge, a second edge orthogonal to the first edge, and a third edge parallel to the first edge and orthogonal to the second edge, the amplifier unit includes a first region extending along the first edge, a second region extending along the second region, and a third region extending along the third edge, and at least one of the plural amplifier circuits is disposed in each of the first region, the second region, and the third region.

A module is provided with a substrate including a principal surface, a plurality of electronic components arranged on the principal surface, a sealing resin covering the principal surface and the plurality of electronic components, a ground electrode arranged on the principal surface or inside the substrate, a conductive layer covering the sealing resin and electrically connected to the ground electrode, and a magnetic member. The magnetic member includes a magnetic plate member arranged so as to cover at least a part of the sealing resin and a magnetic wall member arranged in a wall shape between any of the plurality of electronic components. The module is further provided with a metal pin or a metal wire provided along the magnetic wall member and connected to the ground electrode.

The present disclosure relates to segmented shielding using wirebonds. In an exemplary aspect, a shield is formed from a series of wires (e.g., wirebonds) to create a wall and/or shielded compartment in an integrated circuit (IC) module. The wires can be located in any area within the IC module. The IC module may be overmolded with an insulating mold compound, and a top surface of the insulating mold can be ground or otherwise removed to expose ends of the wires to a shield layer which surrounds the insulating mold. Some examples may further laser ablate or otherwise form cavities around the ends of the wires to create stronger bonding between the wires of the shield and the shield layer.

Disclosed are a housing for receiving an electronic device and an electronic system having the same. The electronic system includes a case having lower and upper cases detachably combined with the lower case, a circuit board arranged in an inner space of the case and secured to the lower case such that at least a grounding line and at least a connection line are provided with the circuit board, a plurality of devices arranged on the circuit board such that each device is separated from one another by the grounding line and is connected with one another by the connection line, and at least an electromagnetic shielding member embedded onto the upper case such that the electromagnetic shielding member is in contact with the grounding line around the device to provide a shielding space receiving the device. The device is protected from unexpected electromagnetic waves by the electromagnetic shielding member.

A printed circuit board includes a core layer, a plurality of conductive pattern layers disposed on one side and the other side of the core layer, a plurality of insulating layers disposed on the one side and the other side of the core layer, and a plurality of via layers disposed on the one side and the other side of the core layer. The printed circuit board has a wiring region and a dummy region surrounding at least a portion outside of the wiring region on a plane. A metal ratio in the dummy region on one side and a metal ratio in the dummy region on the other side are different from each other.

The electronic device includes: a substrate having an electronic circuit formed therein; a housing for housing the substrate; and a connector disposed on the substrate and serving as an interface between outside and inside of the housing. The substrate has a main circuit pattern portion that forms a main circuit and a frame ground pattern portion that forms a frame ground. The main circuit pattern portion and the frame ground pattern portion are disposed so as not to overlap each other on the substrate and in the substrate. A terminal of the connector is disposed in the frame ground pattern portion.

Disclosed are a housing for receiving an electronic device and an electronic system having the same. The electronic system includes a case having lower and upper cases detachably combined with the lower case, a circuit board arranged in an inner space of the case and secured to the lower case such that at least a grounding line and at least a connection line are provided with the circuit board, a plurality of devices arranged on the circuit board such that each device is separated from one another by the grounding line and is connected with one another by the connection line, and at least an electromagnetic shielding member embedded onto the upper case such that the electromagnetic shielding member is in contact with the grounding line around the device to provide a shielding space receiving the device. The device is protected from unexpected electromagnetic waves by the electromagnetic shielding member.

A printed circuit board includes a core layer, a plurality of conductive pattern layers disposed on one side and the other side of the core layer, a plurality of insulating layers disposed on the one side and the other side of the core layer, and a plurality of via layers disposed on the one side and the other side of the core layer. The printed circuit board has a wiring region and a dummy region surrounding at least a portion outside of the wiring region on a plane. A metal ratio in the dummy region on one side and a metal ratio in the dummy region on the other side are different from each other.

A LED based lighting apparatus is disclosed. The light engine used in the lighting apparatus may use printed circuit board and have a plurality of LED groups that are independently controllable by a control unit. The power supply input and return paths connected to each LED group may be implemented on different layers to allow a compact footprint that may be used with traditional fluorescent encasements with relatively little modification. The LEDs may comprise a subset of LEDs having a first colour and a subset of LEDs having a second colour different from said first colour intertwined on the light engine.

A multilayer board includes a layered body including insulating base material layers that are laminated, and first and second signal lines, a first ground conductor including a first opening, a second ground conductor, a third ground conductor, and an interlayer connecting conductor. The first signal line overlaps the first opening when seen in a layering direction. The second signal line is provided on a layer different from a layer including the first signal line and includes a portion extending side by side with the first signal line when seen in the Z-axis direction. The first, second, and third ground conductors are connected by the interlayer connecting conductor. The third ground conductor is disposed on a layer including the first signal line or a layer positioned between the first signal line and the second signal line.