A resin substrate includes an insulating base material in which conductive particles are mixed with resin, and conductor patterns provided on the principal surfaces of the insulating base material. When a length at a position at which a distance between two conductor patterns that are adjacent to each other without directly electrically connecting to each other on the same principal surface of the insulating base material is smallest is indicated by L1 and a length at a position at which a distance between two conductor patterns that face each other without directly electrically connecting to each other between the different principal surfaces of insulating base materials is smallest is indicated by L2, L1 is larger than or equal to L2 (L1 L2).

The invention provides a printed circuit board assembly (1) comprising (i) an at least partly folded flexible printed circuit board (100), and (ii) an at least partly folded support (200), wherein:—the at least partly folded flexible printed circuit board (100) comprises a first PCB region (110) and a second PCB region (120), wherein at least part of the second PCB region (120) is configured folded over at least part of the first PCB region (110);—the at least partly folded support (200) is configured to support at least part of the at least partly folded flexible printed circuit board (100), wherein the at least partly folded support (200) comprises a first support region (210) and a second support region (220), wherein at least part of the second support region (220) is configured folded over at least part of the first support region (210), wherein at least part of the at least partly folded flexible printed circuit board (100) is configured between the first support region (210) and the second support region (220), and wherein the at least partly folded support (200) is configured to maintain the at least partly folded flexible printed circuit board (100) folded.

Provided is an electronic circuit including a substrate having a flat device region and a curved interconnection region. A conduction line may extend along an uneven portion in the interconnection region and may be curved. The uneven portion and the conductive line may have a wavy shape. An external force applied to the electronic circuit may be absorbed by the uneven portion and the conductive line. The electronic device may not be affected by the external force. Therefore, functions of the electronic circuit may be maintained. A method of fabricating an electronic circuit according to the present invention may easily adjust areas and positions of the interconnection region and the device region.

In an embodiment, a smart connector includes an Application Specific Electronics Packaging (ASEP) device formed by an ASEP manufacturing process, and a separate printed circuit board electrically connected to electrical components of the ASEP device. The ASEP manufacturing process includes forming a continuous carrier web having a plurality of lead frames, overmolding a substrate onto the fingers of each lead frame, each substrate having a plurality of openings which exposes a portion of the fingers, electroplating the traces, and electrically attaching at least one electrical component to the traces to form a plurality of ASEP devices. In some embodiments, the printed circuit board has electrical components configured to control the functionality of the electrical components. In some embodiments, the printed circuit board has electrical components configured to modify properties of the smart connector.

A tool adapted for insertion into a physiological lumen of a patient is provided. The tool includes a hub, a core extending distally from the hub, and a printed circuit board (PCB) assembly. The PCB assembly includes a PCB substrate coupled to the core and an electronic component disposed on the PCB substrate and electrically coupled to the hub. The tool further includes an outer sheath disposed about each of the core and the PCB assembly.an outer sheath disposed about each of the core and the PCB assembly. The PCB substrate may be in the form of a ring disposed at a distal end or about the core or may be a flexible PCB substrate adapted to be wrapped about the core and coupled to the core using an adhesive backing.

A tool provided that individually creates three-dimensional structural elements which are sequentially positioned into formation of a shaped object.

A package structure includes a substrate, a sensor, a base, a lead frame, conductive vias and patterned circuit layer. The substrate includes a component-disposing region and electrode contacts. The sensor is disposed at the component-disposing region and electrically connected to the electrode contacts. The base covers the substrate with its bonding surface and includes a receiving cavity, a slanted surface extended between a bottom surface of the receiving cavity and the bonding surface, and electrodes disposed on the bonding surface and electrically connected to the electrode contacts respectively. The sensor is located in the receiving cavity. The lead frame is disposed at the base. The conductive vias penetrates the base and electrically connected to the lead frame. The patterned circuit layer is disposed on the slanted surface and electrically connected to the conductive vias and the electrodes.

A stretchable contractible wiring sheet includes: stretchable contractible first elastomer sheet; stretchable contractible second elastomer sheet facing and bonded on the first elastomer sheet, and lead that has a transverse section having any cross-sectional shape selected from circular shape, elliptical shape, and track shape, and is plastically deformed in wavy shape periodically curving along longer direction, the lead being interposed between the first elastomer sheet and the second elastomer sheet in a manner that height direction of waves in wavy shape is along in-plane direction of facing surfaces of the first elastomer sheet and second elastomer sheet. The wiring sheet that can be produced easily at low costs, has high flexibility and durability, and undergoes small resistance value change along with stretching and contracting, and stretchable contractible touch sensor sheet.

A three-dimensional molded circuit component, includes: a base member which includes a metal part and a resin part; a circuit pattern which is formed on the resin part; and a mounted component which is mounted on the base member, and is electrically connected to the circuit pattern. The resin part includes a resin thin film as a portion thereof, which includes a thermoplastic resin, of which a thickness is in the range of 0.01 mm to 0.5 mm, and which is formed on the metal part. The mounted component is arranged on the metal part via the resin thin film.

There is provided a computer readable storage medium storing a program executable by a computer, and the program causes the computer to execute functions including: forming a first image in accordance with an electronic circuit diagram, in which a resistance value of a wiring portion is defined, to form the wiring portion by printing with a conductive ink; and correcting the first image in accordance with a second image, which is formed with a photothermal conversion material, when the first image is formed at least partially overlapping the second image, wherein the second image is an image for expanding a thermally expandable layer that thermally expands with heat and, when the image is irradiated with light, expanding the thermally expandable layer by converting the light into heat with the photothermal conversion material.