A memory device comprising a programmable command-and-address (CA) interface and/or a programmable data interface is described. In an operational mode, two or more CA interfaces may be active. In another operational mode, at least one, but not all, CA interfaces may be active. In an operational mode, all of the data interfaces may be active. In another operational mode, at least one, but not all, data interfaces may be active. The memory device can include circuitry to select: an operational mode; a sub-mode within an operational mode; one or more CA interfaces as the active CA interface(s); a main CA interface from multiple active CA interfaces; and/or one or more data interfaces as the active data interfaces. The circuitry may perform these selection(s) based on one or more bits in one or more registers and/or one or more signals received on one or more pins.

A memory device comprising a programmable command-and-address (CA) interface and/or a programmable data interface is described. In an operational mode, two or more CA interfaces may be active. In another operational mode, at least one, but not all, CA interfaces may be active. In an operational mode, all of the data interfaces may be active. In another operational mode, at least one, but not all, data interfaces may be active. The memory device can include circuitry to select: an operational mode; a sub-mode within an operational mode; one or more CA interfaces as the active CA interface(s); a main CA interface from multiple active CA interfaces; and/or one or more data interfaces as the active data interfaces. The circuitry may perform these selection(s) based on one or more bits in one or more registers and/or one or more signals received on one or more pins.

The present disclosure provides a LED display device, which includes: a LED display substrate and a driving substrate opposite to each other, the LED display substrate includes: a base and a plurality of LED chips located on a side of the base distal to the driving substrate; the driving substrate includes: a PCB and a driving control element located on the PCB, and the driving control element is electrically coupled to the LED chips through a plurality of first signal wires for providing driving signals for the LED chips.

A semiconductor power module including an insulating substrate having one surface and another surface, an output side terminal arranged at a one surface side of the insulating substrate, a first power supply terminal arranged at the one surface side of the insulating substrate, a second power supply terminal to which a voltage of a magnitude different from a voltage applied to the first power supply terminal is to be applied, and arranged at another surface side of the insulating substrate so as to face the first power supply terminal across the insulating substrate, a first switching device arranged at the one surface side of the insulating substrate and electrically connected to the output side terminal and the first power supply terminal, and a second switching device arranged at the one surface side of the insulating substrate and electrically connected to the output side terminal and the second power supply terminal.

Gates of a plurality of semiconductor switching elements are electrically connected to a common gate control pattern by gate wires. Sources of the plurality of semiconductor switching elements are electrically connected to a common source control pattern by source wires. The gate control pattern is disposed to interpose the source control pattern between the gate control pattern and each of the plurality of semiconductor switching elements that are connected in parallel and that operate in parallel. Hence, each of the gate wires becomes longer than each of the source wires, and has an inductance larger than the source wire. Accordingly, gate oscillation is reduced or suppressed in the plurality of semiconductor switching elements that are connected in parallel and that operate in parallel.

Embodiments described herein provide an electronic device having an integrated circuit disposed in a surface mount package. The surface mount integrated circuit package comprises a first pin and a second pin of the integrated circuit configured to couple the integrated circuit to a first terminal and a second terminal disposed on a circuit board. The first pin and second pin define a first connector and a second connector of a differential connector pair in the surface mount integrated circuit package for transferring differential signals from the integrated circuit to the circuit board. The surface mount integrated circuit package comprises an isolation stud disposed between the first pin and the second pin. The isolation stud is disconnected from the integrated circuit and configured to enlarge a gap between the first pin and the second pin relative to respective gaps of other pins coupling the electronic device to the circuit board.

A semiconductor package includes at least one die attach pad of a leadframe, at least one semiconductor die mounted on the at least one die attach pad; and a plurality of lead terminals disposed around the at least one die attach pad and electrically connected to respective input/output (I/O) pads on the at least one semiconductor die through a plurality of bond wires. The plurality of lead terminals comprises first lead terminals, second lead terminals, and third lead terminals, which are arranged in triple row configuration along at least one side of the semiconductor package. Each of the first lead terminals, second lead terminals, and third lead terminals has an exposed base metal on a cut end thereof.

A semiconductor package includes at least one die attach pad of a leadframe, at least one semiconductor die mounted on the at least one die attach pad; and a plurality of lead terminals disposed around the at least one die attach pad and electrically connected to respective input/output (I/O) pads on the at least one semiconductor die through a plurality of bond wires. The plurality of lead terminals comprises first lead terminals, second lead terminals, and third lead terminals, which are arranged in triple row configuration along at least one side of the semiconductor package. Each of the first lead terminals, second lead terminals, and third lead terminals has an exposed base metal on a cut end thereof.

In one example embodiment, a PCBA, an optoelectronic module, an electrical coupling, and/or a high speed interconnect may include a first contact pad, a second contact pad adjacent to and spaced apart from the first contact pad, a first wire coupled to the first contact pad via a first ball bump, and a second wire coupled to the second contact pad via a double ball bump.