Embodiments disclosed herein include modular electronics packages and methods of forming such packages. In an embodiment, the electronics package comprises a first connector module having a notch on a first end and a plurality of surface mount technology (SMT) pads on a second end. In an embodiment, the electronics package further comprises a second connector module having a keyed connector on a first end and a plurality of SMT pads on a second end. In an embodiment, the electronics package further comprises a system in package (SIP) module between the first connector module and the second connector module, the component module electrically and mechanically coupled to the SMT pads of the first connector and the SMT pads of the second connector.

A communication system includes a circuit board assembly including a mating circuit board having a mating edge and a plurality of mating pads at the mating edge, the circuit board assembly having an electrical component electrically coupled to the mating circuit board. The communication system includes a cable receptacle connector removably coupled to the mating edge of the mating circuit board. The cable receptacle connector includes a connector housing having a connector cavity and a card slot. A cable extends from the connector housing. The cable receptacle connector includes signal contacts each having a mating end mated with the corresponding mating pads and a terminating end electrically connected to a cable conductor of the cable.

The present invention relates to electric components of interventional devices. In order to provide further miniaturization of medical interventional devices, an electric component (10) of an interventional device is provided. The component comprises a flat carrier base (12), at least one electric circuit (14) provided on a substrate (16) and at least one electric wire (18) connected to the electric circuit by a wire connection (20). The substrate is attached to the carrier base. Further, for the wire connection, the carrier base is provided with at least one opening (22) that is provided at least partly with a conductive edge portion (24), which edge portion is connected to the at least one electric circuit. Still further, the substrate is provided with at least one recess (26) aligned with the location of the at least one opening in the carrier base. Furthermore, an end portion of the wire is arranged in the at least one recess; and the end portion of the wire is conductively coupled to the conductive edge portion by electrically conductive material (30).

3D electrical integration is provided by connecting several component carriers to a single substrate using contacts at the edges of the component carriers making contact to a 2D contact array (e.g., a ball grid array or the like) on the substrate. The resulting integration of components on the component carriers is 3D, thereby providing much higher integration density than in 2D approaches.

A connection structure includes: a circuit body including a flexible printed circuit having a wiring pattern; and a conductive body connected to a mounting surface of the circuit body using a solder. The conductive body has a pair of connection portions opposed to each other and extending along the mounting surface. The solder forms solder fillets located around the pair of connection portions and extending along the mounting surface. A first fillet width of one solder fillet among the solder fillets located in an inside region between the pair of connection portions is larger than a second fillet width of another solder among the solder fillets located in an outside region of one of the pair of connection portions, which is on a side opposite to the inside region across the one of the pair of connection portions.

An imaging module of the invention includes: an imaging element; and a substrate positioned on a rear surface opposite to an imaging surface of the imaging element and provided to extend from the rear surface to a side opposite to the imaging surface. An electrode pad provided on the rear surface of the imaging element and a front end portion of an electrode pad provided on a main surface of the substrate at a position close to the imaging element are electrically connected via a conductive connecting material portion. A notch portion recessed from a distal end of the front end portion is formed at the front end portion of the electrode pad of the substrate.

An electrical device that comprises a printed circuit board, which has a first mounting surface, a second mounting surface, a mounting edge, and a plurality of mounting pads on the first mounting surface and the second mounting surface, and an electrical component that has a ball grid array. The electrical device further comprises an adaptor, interposed between the mounting edge and the electrical component, and comprising a body, made of an electrically non-conductive material, and a plurality of electrical pins, made of an electrically conductive material and passing at least partially through the body of the adaptor. The first end of each one of the plurality of electrical pins is electrically directly mounted to a corresponding one of the spaced apart solder balls. The second end of each one of the plurality of electrical pins is electrically directly mounted to a corresponding one of the plurality of mounting pads.

An electronic-element mounting package includes a wiring substrate having a first surface and a wiring pattern thereon; a base having a second surface and a through hole whose opening is on the second surface; a signal line penetrating the through hole and having a first end exposed from an opening of the through hole; and an insulating member between an inner surface of the through hole and the signal line and has an end portion and a main portion. The end portion has an end surface on a side of the opening of the through hole, and the main portion is farther from the opening of the through hole than the end portion. The electronic-element mounting package also has a conductive joining material with which the wiring pattern and the first end are joined. Permittivity of the end portion is larger than permittivity of the main portion.

A multilayer coil component 1 includes an element body 2, a coil 10, and a pair of terminal electrodes 3. The element body 2 has a groove portion 20 provided on a main surface 2c. The groove portion 20 is disposed between the pair of terminal electrodes 3 and extends over one side surface 2e and the other side surface 2f. The depth of the groove portion 20 in the direction in which the main surface 2c and a main surface 2d, which are a pair, face each other is smaller than the thickness of each of the pair of terminal electrodes 3 in the facing direction.

A soldering aid for connecting a cable to a printed circuit board includes an electrically insulating body having a first, second and third recesses, and an electrically conductive contact structure coupled thereto. The contact structure is partially embedded in the body to be connected to a cable core therein, and partially protrudes from the body to be connected the printed circuit board. The first recess is conically tapered to receive an end portion of the cable and has first and second sections for non-stripped and stripped portions of the cable end portion, respectively. An end of the second recess adjoins the second section of the first recess to enable optical verification of formation of a connection between the cable core and the contact structure. The third recess is configured to receive and transfer solder to the second section of the first recess to thereby form the connection.