Disclosed are three-dimensional semiconductor memory devices and electronic systems including the same. The three-dimensional semiconductor memory device comprises a first structure and a second structure in contact with the first structure. Each of the first and second structures includes a substrate, a peripheral circuit region on the substrate, and a cell array region including a stack structure on the peripheral circuit region, a plurality of vertical structures that penetrate the stack structure, and a common source region in contact with the vertical structures. The stack structure is between the peripheral circuit region and the common source region. The common source regions of the first and second structures are connected with each other.

The present disclosure relates to a hermetic package capable of handling a high coefficient of thermal expansion (CTE) mismatch configuration. The disclosed hermetic package includes a metal base and multiple segments that are discrete from each other. Herein, a gap exists between every two adjacent ceramic wall segments and is sealed with a connecting material. The ceramic wall segments with the connecting material form a ring wall, where the gap between every two adjacent ceramic wall segments is located at a corner of the ring wall. The metal base is either surrounded by the ring wall or underneath the ring wall.

The present disclosure relates to a hermetic package capable of handling a high coefficient of thermal expansion (CTE) mismatch configuration. The disclosed hermetic package includes a metal base and multiple segments that are discrete from each other. Herein, a gap exists between every two adjacent ceramic wall segments and is sealed with a connecting material. The ceramic wall segments with the connecting material form a ring wall, where the gap between every two adjacent ceramic wall segments is located at a corner of the ring wall. The metal base is either surrounded by the ring wall or underneath the ring wall.

An electronic device having a package structure with conductive leads, first and second dies in the package structure, as well as first and second conductive plates electrically coupled to the respective first and second dies and having respective first and second sides spaced apart from and directly facing one another with a portion of the package structure extending between the first side of the first conductive plate and the second side of the second conductive plate to form a capacitor. No other side of the first conductive plate directly faces a side of the second conductive plate, and no other side of the second conductive plate directly faces a side of the first conductive plate.

A module assembly includes an adapter substrate with at least one cavity and a surface mounted die mounted on a top surface of the adapter substrate. The first cavity extends through the adapter substrate and has at least one first side wall. A first metallization layer is provided within the cavity. A first recessed die is attached to the first metallization layer and mounted within the cavity such that the first recessed die is at least partially recessed into the first cavity and surrounded by a gap filler that resides between side portions of the first recessed die and the at least one first side wall. The top surface of the gap filler is flush with the top surface of the adapter substrate and a top surface of the first recessed die.

An improved system for measuring current within a power semiconductor module is disclosed, where the system is integrated within the power module. The system includes a point field detector sensing a magnetic field resulting from current flowing in one phase of the module. A lead frame conductor may be provided to shape the magnetic field and minimize the influence of cross-coupled magnetic fields from currents conducted in other power semiconductor devices within one phase of the module. Optionally, a second point field detector may be provided at a second location within the module to sense a magnetic field resulting from the current flowing in the same phase of the module. Each phase of the power module includes at least one point field detector. A decoupling circuit is provided to decouple multiple currents flowing within the same phase or to decouple currents flowing within different phases of the power module.

An antenna module includes an antenna substrate including a glass substrate having first and second surfaces opposing each other, an antenna pattern disposed on the first surface, and a wiring structure connected to the antenna pattern and extending to the second surface, and a semiconductor package including a semiconductor chip, having an inactive surface and an active surface, on which a connection pad is disposed, an encapsulant encapsulating the semiconductor chip, a connection member including a redistribution layer connected to the connection pad, and a through-via penetrating the encapsulant and connecting the redistribution layer and the wiring structure to each other.

A voltage determination device includes: a printed wiring board on which first to third substrate terminals are arranged in substantially one line; first and second voltage determination circuits mounted on the printed wiring board and disposed on a first side of the printed wiring board divided by a line passing through the first to third substrate terminals; a first printed wiring connecting the first substrate terminal and the first voltage determination circuit; a second printed wiring connecting the second substrate terminal and the first voltage determination circuit; a third printed wiring connecting the third substrate terminal and the second voltage determination circuit; and a fourth printed wiring connecting the second substrate terminal and the second voltage determination circuit, in which the first to fourth printed wirings are provided without intersecting each other and without bypassing a second side of the printed wiring board divided by the first arrangement line.

An integrated circuit isolation product includes a first integrated circuit die. The first integrated circuit die includes a first terminal and a second terminal adjacent to the first terminal. The first terminal and the second terminal are configured as a differential pair of terminals configured to communicate a differential signal across an isolation barrier. The first integrated circuit die includes at least one additional terminal adjacent to the differential pair of terminals. The at least one additional terminal is disposed symmetrically with respect to the differential pair of terminals. The first terminal may have a first parasitic capacitance and the second terminal may have a second parasitic capacitance. The first parasitic capacitance may be substantially the same as the second parasitic capacitance. The at least one additional terminal may be disposed symmetrically with respect to a line of symmetry for the differential pair of terminals.

A semiconductor device in chip size package includes first and second metal oxide semiconductor transistors both vertical transistors formed in first and second regions obtained by dividing the semiconductor device into halves. The first metal oxide semiconductor transistor includes one or more first gate electrodes and four or more first source electrodes provided in one major surface, each of the first gate electrodes is surrounded, in top view, by the first source electrodes, and for any combination of a first gate electrode and a first source electrode, closest points between the first gate and first source electrodes are on a line inclined to a chip side. The second metal oxide semiconductor transistor includes the same structure as the first metal oxide semiconductor transistor. A conductor that connects the drains of the first and second metal oxide semiconductor transistors is provided in the other major surface of the semiconductor device.