A multilayer substrate connecting body includes first and second multilayer substrates. The first and second multilayer substrates each include a step portion defined by a difference of a number of stacked layers of insulating base material layers, and a portion of a conductor pattern is exposed to the step portion. An anisotropic conductive film is disposed between the step portions of the first and second multilayer substrates, and portions of conductor patterns that are exposed to the step portions of the first and second multilayer substrates are electrically connected through an electrically connecting portion of the anisotropic conductive film.

Tamper-respondent assemblies and methods of fabrication are provided which include an enclosure, an in-situ-formed tamper-detect sensor, and one or more flexible tamper-detect sensors. The enclosure encloses, at least in part, one or more electronic components to be protected, and the in-situ-formed tamper-detect sensor is formed in place over an inner surface of the enclosure. The flexible tamper-detect sensor(s) is disposed over the in-situ-formed tamper-detect sensor, such that the in-situ-formed tamper-detect sensor is between the inner surface of the enclosure and the flexible tamper-detect sensor(s). Together the in-situ-formed tamper-detect sensor and flexible tamper-detect sensor(s) facilitate defining, at least in part, a secure volume about the one or more electronic components.

The present invention provides a flexible flat cable. The flexible flat cable including: a first flexible flat cable and a second flexible flat cable, wherein: an end of the first flexible flat cable is connected with a first terminal; an another end of the first flexible flat cable is provided with a plurality of first pads; an end of the second flexible flat cable is connected with a second terminal; an another end of the second flexible flat cable is provided with a plurality of second pads connected with the plurality of first pads in one-to-one correspondence. The flexible flat cable according to the exemplary embodiments of the present invention can improve versatility, reusability and repairability of the flexible flat cable.

An RF circuit module having RF and DC contacts on a surface of a circuit board. An RF component having RF and DC contacts is disposed in a cavity of the circuit board. Electrical connectors bridge the cavity to connect the RF contacts on the circuit board to the RF contacts on the RE component and the DC, contacts on the circuit board to the DC contacts on the RF component. A plug member is disposed in the cavity which has a dielectric member with an outer portion disposed over the RF and DC contacts on the circuit board and an inner portion elevated above the RF and DC contacts the RF component. The plug member has one portion of electrical conductors disposed on an upper surface of the inner portion and another portion disposed under the outer portion on, and electrically connected to, the DC contacts on the circuit board.

A cable connection structure includes a substrate and a coaxial cable connected to the substrate. The coaxial cable has: a conductor; an inner insulator that coats an outer periphery of the conductor; a shield that coats an outer periphery of the inner insulator; and an outer insulator that coats an outer periphery of the shield. The substrate has: a plate-shaped insulating base material; a conductor connection electrode to which the conductor is connected; and a shield connection electrode to which the shield is connected. A ground is provided on a back surface of the base material opposite to where the conductor connection electrode is formed. The shield connection electrode is an exposed portion of the ground. At a connection part of the substrate to which the coaxial cable is connected, the shield connection electrode, the base material, and the conductor connection electrode are bared in a stepwise fashion.

Provided is a multilayer wiring board for inspection of electronic components which has excellent reliability by improving the adhesiveness between a resin wiring portion and a ceramic wiring substrate. A multilayer wiring board 10 according to the present invention includes: a ceramic wiring substrate 20 having a substrate main surface 21 and a substrate rear surface 22; substrate-side conductive layers 32, 33 formed on the substrate main surface 21; and a resin wiring portion 40 stacked on the substrate main surface 21 so as to cover the substrate-side conductive layers 32, 33. Inspection pads 50, 51 for inspection of electronic components are formed on a front surface 49 of the resin wiring portion 40. End surfaces of the substrate-side conductive layers 33 are exposed from side surfaces 13 of the multilayer wiring board 10. An outer peripheral edge of a rear surface of the resin wiring portion 40 is in contact with the surfaces of the substrate-side conductive layers 33, and end surfaces of the resin wiring portion 40 and the end surfaces of the substrate-side conductive layers 33 are positioned closer to the center of the board than end surfaces 23 of the ceramic wiring substrate 20.

Various configurations of a grounding element or conductive element for a printed circuit board (PCB), as well as a process for manufacturing, are disclosed. For example, a PCB can include a solder grounding element connecting a copper track to a metal substrate, where the solder grounding element is applied via ultrasonic soldering during a manufacturing process. In another example, a PCB can include a spring pin grounding element connecting a copper track to a metal substrate. In yet another example, a PCB can include an auto splice grounding element connecting a copper track to a metal substrate. In yet another example, a PCB can include a press fit pin grounding element connecting a copper track to a metal substrate. In yet another example, a PCB can include a clip pin grounding element connecting a copper track to a metal substrate.

This disclosure relates generally to interfaces between memory modules and circuit boards. More specifically, this disclosure relates to interfaces for coupling a memory module to a circuit board such that the memory module is arranged in a plane that is substantially parallel with a plane of the circuit board. Various embodiments disclosed herein include interfaces, memory modules including interfaces or portions of interfaces, and/or circuit boards including interfaces and/or portions of interfaces. Associated devices and systems are also disclosed.

An EMI shielding structure includes a shielding pad surrounding at least one circuit component mounted on a printed circuit board and grounded to a ground pad disposed on the printed circuit board; and a shield can configured to cover the at least one circuit component, wherein a portion of the shield can is attached to the shielding pad.

Printed circuit boards (PCBs) may include embedded lateral connectors. The embedded lateral connectors may be configured to enable components to quickly couple to or plug into a PCB, thus saving time to form connections. The embedded lateral connectors may also reduce weight and/or size by avoiding need for bulky tradition collections with conventional components (e.g., solders, external pin connectors, etc.). The connectors may include male connectors, female connectors, and/or mounting connectors. The connectors may be configured to connect multiple PCBs together, such as using a stacked configuration, which may enable reducing a volume of space needed in a housing for the PCBs.