A package structure includes a second substrate. A second component is connected to the second substrate, and at least a part of the second component is connected to the second connecting rod through the second heat dissipation block, so that heat of the at least a part of the second component can be further transferred to the second connecting rod through the second heat dissipation block, and then transferred, through the second connecting rod, to the second substrate or another structure connected to the second connecting rod. In this way, the heat of the second component is transferred out, and heat conduction paths of the second component are increased.

A package structure includes a second substrate. A second component is connected to the second substrate, and at least a part of the second component is connected to the second connecting rod through the second heat dissipation block, so that heat of the at least a part of the second component can be further transferred to the second connecting rod through the second heat dissipation block, and then transferred, through the second connecting rod, to the second substrate or another structure connected to the second connecting rod. In this way, the heat of the second component is transferred out, and heat conduction paths of the second component are increased.

An MEMS device includes a package (1), a bottom plate (2), and a first inertial component (3). The first inertial component (3) is located in packaging space (4) formed by the bottom plate (2) and the package (1). There is a first alignment part (21) on a surface that is of the bottom plate (2) and that faces the packaging space (4), and the first inertial component (3) has a first mounting part (31). A shape of the first mounting part (31) matches a shape of the first alignment part (21). The MEMS device is equipped with a mounting alignment reference, the first mounting part (31) is connected to the first alignment part (21), and the first inertial component is mounted on the bottom plate at a preset angle. In addition, a bottom part of the first inertial component is not directly connected to the bottom plate.

Electronic circuits and methods encompassing an RF switch comprising a plurality of series-coupled (stacked) integrated circuit (IC) SOI MOSFETs having a distributed back-bias network structure comprising groups of substrate contacts coupled to a bias voltage source through a resistive ladder. The distributed back-bias network structure sets the common IC substrate voltage at a fixed DC bias but resistively decouples groups of MOSFETs with respect to RF voltages so that the voltage division characteristics of the MOSFET stack are maintained. The distributed back-bias network structure increases the voltage handling capability of each MOSFET and improves the maximum RF voltage at which a particular MOSFET is effective as a switch device, while mitigating loss, leakage, crosstalk, and distortion. RF switches in accordance with the present invention are particularly useful as antenna switches.

Electronic circuits and methods encompassing an RF switch comprising a plurality of series-coupled (stacked) integrated circuit (IC) SOI MOSFETs having a distributed back-bias network structure comprising groups of substrate contacts coupled to a bias voltage source through a resistive ladder. The distributed back-bias network structure sets the common IC substrate voltage at a fixed DC bias but resistively decouples groups of MOSFETs with respect to RF voltages so that the voltage division characteristics of the MOSFET stack are maintained. The distributed back-bias network structure increases the voltage handling capability of each MOSFET and improves the maximum RF voltage at which a particular MOSFET is effective as a switch device, while mitigating loss, leakage, crosstalk, and distortion. RF switches in accordance with the present invention are particularly useful as antenna switches.

Embodiments are directed to a package that includes an electric device having a recess. In one embodiment, the electric device is a sensor and the recess reduces signal drift of the sensor caused by thermal expansion of the package. In another embodiment, the recess is substantially filled with adhesive material, thus increasing adhesion between the electric device and a substrate of the package while at the same time allowing for lower adhesive fillets.

A semiconductor device includes a package interface including N numbers of first group of data balls which are disposed on a first side thereof, N numbers of second group of data balls which are disposed on a second side thereof, and M numbers of command/address balls which are disposed between the first side and the second side; a first semiconductor chip which is stacked on the first side over the package interface, and includes 2N numbers of first group of data pads and M numbers of first command/address pads; and a second semiconductor chip which is stacked on the second side over the package interface, and includes 2N numbers of second group of data pads and M numbers of second command/address pads.

A composite circuit board includes a composite circuit board unit, a first solder mask formed on a first metal protection layer of the composite circuit board unit, and a second solder mask formed on a second metal protection layer of the composite circuit board unit. Two ends of a first outer conductive circuit are bent back toward each other and spaced apart a predetermined distance to form a first window. Two ends of a second outer conductive circuit are bent back toward each other and spaced apart a predetermined distance to form a second window.

A semiconductor device includes: a housing; a substrate inside the housing; first and second semiconductor circuits on the substrate; and first and second planar terminals electrically connected to the first and second semiconductor circuits, respectively, the first and second planar terminals stacked on top of each other, wherein each of the first and second planar terminals extends away from the housing.

A semiconductor device includes: a housing; a substrate inside the housing; first and second semiconductor circuits on the substrate; and first and second planar terminals electrically connected to the first and second semiconductor circuits, respectively, the first and second planar terminals stacked on top of each other, wherein each of the first and second planar terminals extends away from the housing.