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 a 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.

In a flexible printed wiring board (1), a first electrical conduction pattern (4) prepared on the first surface (3a) on which a bare chip (2) is mounted is prepared only inside a mounting region (3c) of the bare chip. Preferably, the first electrical conduction patterns (4) are prepared so as to avoid positions opposite to test electrodes (2b) which the bare chip comprises. Thereby, in the flexible printed wiring board used for mounting the bare chip, occurrence of malfunction resulting from electrical connection with a part other than a bump of the bare chip can be certainly prevented, and reliability of various devices using the bare chip can be improved.

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 a 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.

A method for producing a printed circuit board is disclosed, In the method, a slot is formed in a substrate having at least three layers with the slot extending through at least two of the layers. The slot has a length and a width with the length being greater than the width. The sidewall of the substrate surrounding the slot is coated with a conductive layer. Then, the conductive layer is separated into at least two segments that are electrically isolated along the side wall of the substrate.

Methods for producing a printed circuit board and printed circuit boards are disclosed, including a method in which a slot is formed in a substrate, the substrate having at least three layers with the slot extending through at least two of the layers. The slot has a length and a width with the length being greater than the width. The sidewall of the substrate surrounding the slot is coated with a conductive layer. The conductive layer is separated into at least two segments that are electrically isolated along the side wall of the substrate.

A wiring board includes an insulating substrate, at least one external electrode disposed on a first surface of the insulating substrate, and wiring that is disposed in the insulating substrate and that is electrically connected to the at least one external electrode. The wiring includes a portion where an extension direction of the wiring is inclined relative to the first surface of the insulating substrate.

A double-sided and multilayer flexible printed circuit (FPC) substrate contains: a body, multiple tilted vias passing through the body, a sputtering layer, multiple conductive portions, and multiple copper circuit layers. The sputtering layer is adhered on the body and the multiple tilted vias. A respective conductive portion is formed in a respective titled via and is connected with the sputtering layer. The multiple copper circuit layers are located on a top and a bottom of the body and are connected with the sputtering layer, and the multiple copper circuit layers are connected via the multiple conductive portions.

The disclosure relates to systems and methods for fabricating printed circuit board (PCB) based transformers and/or coreless PCB-based circuits containing one or more coil inductor(s). More specifically, the disclosure is directed to systems and methods for fabricating PCB-based transformers and/or inductors having concentric or eccentric (non-concentric) continuous or concatenated coil architecture.

A double-sided and multilayer flexible printed circuit (FPC) substrate contains: a body, multiple tilted vias passing through the body, a sputtering layer, multiple conductive portions, and multiple copper circuit layers. The sputtering layer is adhered on the body and the multiple tilted vias. A respective conductive portion is formed in a respective titled via and is connected with the sputtering layer. The multiple copper circuit layers are located on a top and a bottom of the body and are connected with the sputtering layer, and the multiple copper circuit layers are connected via the multiple conductive portions.

The disclosure is and includes at least an apparatus, system and method for a ramped electrical interconnection for use in semiconductor fabrications. The apparatus, system and method includes at least a first semiconductor substrate having thereon a first electrical circuit comprising first electrical components; a second semiconductor substrate at least partially covering the first electrical circuit, and having thereon a second electrical circuit comprising second electrical components; a ramp formed through the second semiconductor substrate between at least one of the first electrical components and at least one of the second electrical components; and an additively manufactured conductive trace formed on the ramp to electrically connect the at least one first electrical component and the at least one second electrical component.