A connector assembly comprising a housing, first and second circuit boards, and substantially flat cables. The housing includes a mating end for mating with a mating connector and an opposite cable end for receiving a cable. The first and second circuit boards are disposed inside the housing. Each circuit board includes a plurality of conductive front pads disposed closer to the mating end of the housing and a plurality of conductive rear pads disposed closer to the cable end of the housing and electrically connected to the front pads. At least one front pad of the first circuit board faces, aligns with, and is electrically connected to, at least one rear pad of the second circuit board. The substantially flat cables include a plurality of conductors. The uninsulated front ends of the conductors of the cables terminate at the corresponding rear pads of the first circuit board.

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.

In general, the present invention relates to electrically conducting, polymer coated wires that are in electric contact with, as well as touching, electrically conducting substrates. In particular, the present invention relates to a connection unit for achieving the aforementioned electric connection and touching, as well as a method for producing said connection unit. The present invention also relates to a use for such a connection unit.

Disclosed is a measuring sensor of a measuring device for detecting a mass flow rate. The measuring sensor comprises a measuring tube, a vibration exciter, and at least two vibration sensors. The vibration exciter and the vibration sensors each have a coil apparatus having at least one coil and at least one magnetic apparatus. The coil apparatus comprises a printed circuit board having at least one printed circuit board layer, wherein the coil is formed by means of an electrically conductive conductor track, wherein the coil is arranged on the first side and/or second side of a printed circuit board layer, wherein the printed circuit board comprises at least two contact-making elements for connecting the coil to an electronic measuring and/or operating circuit of the measuring device by means of connection elements, and is characterized in that at least one contact-making element has a hole.

A printed circuit board (PCB) includes a substrate defining a major plane. A first side of the major plane is configured for mounting of functional circuit elements. A cable connector is mounted on a second side of the major plane of the substrate, opposite the first side, for coupling to a shielded radiofrequency (RF) communications cable. At least one component grounding layer is parallel to the major plane and configured for coupling to the functional elements. At least one cable grounding layer is parallel to the major plane and is separated from the at least one component grounding layer. Each cable grounding layer in the at least one cable grounding layer is coextensive with the substrate and is configured for coupling, through the connector, to shielding of the shielded RF communications cable, without coupling to any other component. Nodes of an RF communications system may be mounted on such PCBs.

A cable assembly comprising a connector with a termination that enables high density and high signal integrity. Shields of cables are terminated to a paddle card via a conductive structure attached to a surface of the paddle card. The signal conductors of the cables are terminated to pads on the paddle card that are exposed within openings of the conductive structure. Such a structure creates a ground structure per cable that provides low insertion loss and low crosstalk, even when multiple cables are aligned side by side and terminated in one or more rows. The cables may be drainless, enabling a large number of cables, such as eight cables, to be packed within the width of a paddle card specified in high density standards such as QSFP-DD or OSFP. The cables may nonetheless have large diameter signal conductors, enabling 2.5 or 3 meter assemblies with less than 17 dB insertion loss.

The present disclosure relates to a support device for a phase shifter for a base station antenna. The support device includes a support plate suitable for fixation of a main printed circuit board of the phase shifter. The support plate includes a plate-shaped body and at least one support leg located at a lower portion of the body. At least one said support leg extends along a direction perpendicular to the body and is located on one side of the body, so that the support plate can be arranged in the base station antenna in a first orientation by at least one said support leg, or arranged in the base station antenna in a second orientation by the body itself according to layout requirements. The present disclosure also relates to an assembly for a phase shifter for a base station antenna and a method for soldering a coaxial cable to a phase shifter for a base station antenna.

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.

A coupling device for coupling a plurality of cable units to a component carrier includes a base plate that is flat in at least one plane. A connecting device is disposed on a first side of the base plate and is configured to mechanically couple the base plate to the component carrier. An opening extends through the base plate for each cable end of a plurality of cable ends of the cable units. The opening in each case is disposed on the base plate at a position corresponding to the respective cable unit.

Cable management systems for rotatable sensors on an autonomous vehicle (AV) are described herein. In some examples, a rotatable cable assembly can include a first portion having a spool, a sidewall surrounding the spool to form a cavity, and a shaft extending from the spool; a second portion coupled to the shaft and configured to rotate relative to the first portion; a flexible cable stored by the spool in a coiled configuration within the cavity; a first circuit on the first portion including a first connector coupled to an end of the flexible cable and configured to connect to components on an AV and/or a sensor platform base that is coupled to the AV and includes the rotary cable assembly; and a second circuit on the second portion including a second connector coupled to another end of the flexible cable and configured to rotate with the second portion.