Pastes are disclosed that are configured to coat a passage of a substrate. When the paste is sintered, the paste becomes electrically conductive so as to transmit electrical signals from a first end of the passage to ta second end of the passage that is opposite the first end of the passage. The metallized paste contains a lead-free glass frit, and has a coefficient of thermal expansion sufficiently matched to the substrate so as to avoid cracking of the sintered paste, the substrate, or both, during sintering.

Provided is a vehicle camera module including a lens, circuit board having an image sensor, front housing, and rear housing. The lens has a lens barrel and lens elements assembled. The front housing has front and rear sides to which the lens and the circuit board are assembled, respectively. The rear housing is coupled rearwardly of the front housing to seal the lens and circuit board. The front housing includes posts protruding rearward and a pin protruding distally of the post and having a smaller cross-sectional area than the post. The circuit board includes a plated through-hole configured to at least partially receive the pin. The front housing and circuit board are pre-assembled such that pin and plated through-hole have an assembly clearance, the io lens and image sensor are optically aligned in a pre-assembled state, and the assembly clearance is fixedly soldered through a laser solder-jet bonding process.

A method for producing a wired circuit board, the method including the steps of: a first step of providing an insulating layer having an opening penetrating in the thickness direction at one side surface in the thickness direction of the metal plate, a second step of providing a first barrier layer at one side surface in the thickness direction of the metal plate exposed from the opening by plating, a third step of providing a second barrier layer continuously at one side in the thickness direction of the first barrier layer and an inner surface of the insulating layer facing the opening, a fourth step of providing a conductor layer so as to contact the second barrier layer, and a fifth step of removing the metal plate by etching.

A printed circuit board (PCB) having an engineered thermal path and a method of manufacturing are disclosed herein. In one aspect, the PCB includes complementary cavities formed on opposite sides of the PCB. The complementary cavities are in a thermal communication and/or an electrical communication to form the engineered thermal path and each cavity is filled with a thermally conductive material to provide a thermal pathway for circuits and components of the PCB. The method of manufacturing may further include drilling and/or milling each cavity, panel plating the cavities and filling the cavities with a suitable filling material.

A resin multilayer substrate includes a laminate including resin layers including a first resin layer and a second resin layer that are laminated, a via conductor in the first resin layer, and a joint portion that includes at least a portion in the second resin layer and is joined to the via conductor. The joint portion is more brittle than the via conductor. A linear expansion coefficient of the second resin layer is larger than a linear expansion coefficient of the via conductor and a linear expansion coefficient of the joint portion, and is smaller than a linear expansion coefficient of the first resin layer.

Method for electroplating a metal onto a flat substrate P. Surfaces are electrically polarized for metal deposition by feeding thereto at least one first and second forward-reverse pulse current sequences. The first forward-reverse pulse current sequence includes a first forward pulse generating a first cathodic current during a first forward pulse duration t.sub.f1 and having a first forward pulse peak current i.sub.f1, and a first reverse pulse generating a first anodic current during a first reverse pulse duration t.sub.r1 and having a first reverse pulse peak current i.sub.r1, the second forward-reverse pulse current sequence including a second forward pulse generating a second cathodic current during a second forward pulse duration t.sub.f2 and having a second forward pulse peak current i.sub.f2, and a second reverse pulse generating a second anodic current during a second reverse pulse duration t.sub.r2, the second reverse pulse having a second reverse pulse peak current i.sub.r2.

An electronic module on a flexible planar circuit substrate with a conductor configuration on a first substrate surface and a plurality of electronic components on the opposite, second substrate surface, wherein the components have component contacts, which are electrically connected selectively by way of vias in the circuit substrate and the conductor configuration, wherein the circuit substrate is a thermoplastic polymer and the component contacts are melted or thermally pressed into the second substrate surface in the region of the vias.

A component carrier and a method of manufacturing the same are disclosed. The component carrier includes a stack having a plurality of electrically conductive layer structures and a plurality of electrically insulating layer structures and a coax structure with an electrically conductive substantially horizontally extending central trace and an electrically conductive surrounding structure at least partially surrounding the central trace with electrically insulating material in between. The coax structure is formed by material of the layer structures of the stack.

A method for producing a wired circuit board, the method including the steps of: a first step of providing an insulating layer having an opening penetrating in the thickness direction at one side surface in the thickness direction of the metal plate, a second step of providing a first barrier layer at one side surface in the thickness direction of the metal plate exposed from the opening by plating, a third step of providing a second barrier layer continuously at one side in the thickness direction of the first barrier layer and an inner surface of the insulating layer facing the opening, a fourth step of providing a conductor layer so as to contact the second barrier layer, and a fifth step of removing the metal plate by etching.

Various embodiments are directed to a method of forming an apparatus including placing a first electronic circuit in contact with a second electronic circuit, wherein each of the first and second electronic circuits have connector circuits configured and arranged to provide an electrical connection between the first and second electronic circuits and are formed with a polymer film that is configured to adhere, via self-healing, to another polymer film. The method further includes, in response to the contact, causing or facilitating the self-healing of the respective polymer films of the first and second electronic circuits, thereby creating the electrical connection therebetween.