A memory stick configured for use with a processor in a computer is provided. The memory stick includes a printed circuit board with first and second sides, each of the first and second sides including eighteen memory chips, each of the memory chips being an ×8 DRAM chip; the eighteen memory chips being distributed into first, second, third and fourth rows, the first row and the second row being on a left half of the printed circuit board and the third and fourth row being on a right half of the printed circuit board; and the printed circuit board including at least 400 pins including at least 16 pins for ECC bits and at least 128 pins for data bits; wherein at least the memory chips and the 128 pins for data bits establish a 128-bit data width to communicate.

The present application discloses a semiconductor device with an interface structure and a method for fabricating the interface structure. The interface structure includes an interface board configured to be fixed onto and electrically coupled to a chuck of a testing equipment, and a first object positioned on a first surface of the interface board and electrically coupled to the interface board. The first object is configured to be analyzed by the testing equipment.

Features relating to a vaporizer body are provided. The vaporizer body may include an outer shell that includes an inner region defined by an outer shell sidewall. A support structure is configured to fit within the inner region of the outer shell. The support structure includes a storage region defined by a top support structure, a bottom support structure, a bottom cap, and a gasket. An integrated board assembly is configured to fit within the storage region of the support structure. The integrated board assembly may include a printed circuit board assembly formed of multiple layers that form a rigid structure and that include an inner, flexible layer. A first antenna is integrated at a proximal end of the flexible layer, and a second antenna is integrated at a distal end of the flexible layer.

An electronic assembly includes an electronic package connected to a host circuit board. The electronic assembly includes interposer assemblies electrically connected to the electronic package. The electronic assembly includes cable modules coupled to upper separable interface of the interposer assemblies. The electronic assembly includes carrier assemblies configured to be coupled to an upper surface of the electronic package. Each carrier assembly includes a carrier base block and a carrier lid configured to hold at least one interposer assembly and at least one cable module. The carrier assemblies hold the cable modules with the module contacts in electrical connection with upper mating interfaces of the interposer contacts. The carrier assemblies hold lower mating interfaces of the interposer contacts in electrical connection with upper package contacts of the electronic package. The carrier assemblies are separately removable from the electronic package to separate the interposer assemblies from the electronic package.

A high-speed transmission circuit comprises a connector pin that serves as part of a signal path, has a first conductivity, and has a connector pin leg that is coupled to a pad that has a second conductivity lower than the first conductivity. The connector pin leg and at least a portion of the pad form a resonant sub-circuit coupled to the signal path. The second conductivity causes a reduction in insertion loss in the signal path by damping a current in the resonant sub-circuit.

A printed circuit board corner connector designed to connect a first printed circuit board to a second printed circuit board, having a substantially flat contact body, from which a first connection end for connecting to the first printed circuit board extends, wherein two soldering pins for producing a soldered connection to the second printed circuit board protrude from a lateral surface of the contact body, wherein depressions are provided on lateral surface lying opposite lateral surface in positions corresponding to the soldering pins.

A power converter, for a vehicle that is at least partially electrically powered, has a first printed circuit board with DC link capacitors, a circuit breaker group for each alternating current phase, and terminals for alternating current busbars and direct current busbars. A second printed circuit board has a control apparatus for actuating the circuit breaker groups. Also, it has a respective signal pin carrier for the respective circuit breaker group. The signal pin carrier connects the first and the second printed circuit board. Thus, signals between the first and the second printed circuit board can be transmitted via the respective signal pin carrier. The signal pin carrier has six signal pins that are arranged on a plastic carrier.

A semiconductor device, including a substrate having an insulating plate and a conductive plate formed on the insulating plate, a semiconductor chip formed on the conductive plate, a contact part arranged on the conductive plate with a bonding member therebetween, a rod-shaped external connection terminal having a lower end portion thereof fitted into the contact part, and a lid plate having a front surface and a back surface facing the substrate. An insertion hole pierces the lid plate, forming an entrance and exit respectively on the back and front surfaces of the lid plate. The external connection terminal is inserted in the insertion hole. The semiconductor device has at least one of a guide portion with an inclined surface, fixed to a portion of the external connection terminal located in the insertion hole, or an inclined inner wall of the insertion hole.

A semiconductor module includes a housing, a pin arranged in the housing and including a first contact region which has a press-fit connection, a semiconductor component arranged in the housing and electrically conductively connected to the pin, and a first substrate arranged in the housing and clamped in the housing via the pin by a non-positive locking connection, which, when formed, causes the press-fit connection to be deformed elastically and/or plastically with the first substrate. The first substrate has a first recess which is open and at least in part encompasses the pin in the first contact region. A metallic coating is applied to the first substrate at least in a region of the first recess so as to electrically conductively connect the first substrate to the semiconductor component, and a second substrate is in contact with the pin and connected within the housing in a non-releasable manner.

A module includes: a substrate having a first surface; a first component mounted on the first surface; a resin film that covers the first component along a shape of the first component, and also covers a part of the first surface; a conductor film that covers at least a part of the resin film along the shape of the first component, and covers at least a part of a portion in which the resin film covers the part of the first surface; and a conductor structure disposed to extend over a part of the resin film. The conductor structure includes a first end portion, a second end portion, and an intermediate portion. The first end portion and the second end portion are connected to the first surface. The intermediate portion is in contact with the conductor film.