A printed substrate forming method includes: a resin layer forming step of forming a resin layer with curable resin in a specific region that is a region other than a predetermined region of a base which is composed of an insulating layer and a conductor layer, the predetermined region of which being a region on which a solder resist is formed; and a wiring forming step of forming a wiring by discharging metal-containing liquid which contains metal fine particles onto a top surface of the resin layer, and firing the metal-containing liquid.

A display device includes a display panel including a pixel layer displaying an image, and a pad part electrically connected to the pixel layer. The display device includes a flexible circuit film combined with the pad part of the display panel. The flexible circuit film includes a base film, a first conductive line disposed on a first surface of the base film, a first conductive pad extending from the first conductive line and electrically connected to the pad part of the display panel, a cover layer covering the first conductive line and exposing the first conductive pad, and a protrusion pattern disposed on the cover layer, adjacent to the first conductive pad, and facing a side surface of the display panel.

A printed circuit structure includes a printed conductive pattern and a printed conductive adhesive pattern. The printed conductive pattern includes a first wire and a second wire. One of a first main contact portion of the first wire and a first main contact portion of a first adhesive of the printed conductive adhesive pattern extends in a first direction, while another thereof extends in a second direction perpendicular to the first direction. With different lengths in the first direction, manufacturing errors between the first wire and the first adhesive in the first direction can be contained without affecting the connection in between. Similarly, a second main contact portion of the second wire and a second main contact portion of a second adhesive of the printed conductive adhesive pattern can also adopt the same design in the first direction to ensure the electric connection.

A circuit module includes a substrate module including an upper main surface with a normal line extending in a vertical direction, an electronic component on the substrate module, and a bonding adhesive fixing the electronic component to the upper main surface. The electronic component includes a first electrode. The substrate module includes a second electrode on the right of the bonding adhesive. The first electrode is electrically connected to the second electrode through solder. A first recess recessed downward and including a bottom is in the upper main surface. An upper end of the second electrode is above the bottom. The first recess includes a first area on the left of a first electrode and overlapping the second electrode when viewed in the lateral direction. A material of the first recess is identical to a material of the upper main surface.

An electronic component mounting substrate includes an electronic component and a substrate that are electrically connected at a plurality of places on a bottom surface of the electronic component. At least two places of the plurality of places are electrically connected by bonding using a conductive adhesive, and places other than the at least two places of the plurality of places are electrically connected by soldering using a paste solder.

A display device is provided. The display device includes an auxiliary substrate, a display substrate, and a circuit board. The auxiliary substrate includes an auxiliary circuit. The display substrate is disposed on the auxiliary substrate. The display substrate includes a circuit. The circuit board is electrically connected to the auxiliary substrate. The circuit of the display substrate is electrically connected to the auxiliary circuit through a first conductive via, and the circuit board provides a signal to the auxiliary circuit.

A biocompatible electrical connection includes: a substrate; a ferrule having a concentric flange at a first end of the ferrule; a first adhesive; and a second adhesive. The substrate includes a hole having a diameter that is a specified amount larger than an outside diameter of the ferrule forming an annular space between the hole and the ferrule, the first adhesive adheres a first surface of the concentric flange of the ferrule to a first surface of the substrate, and the second adhesive fills the annular space between the hole and the ferrule.

A curved full-array LED light panel, a curved backlight module including the curved full-array LED light panel, and a curved LCD including the backlight module are disclosed. The curved full-array LED light panel includes a flexible reflective sheet and a plurality of LED light bars wherein a plurality of LEDs are disposed. The plurality of LED light bars are attached to a sheet-rear side of the flexible reflective sheet alone a direction parallel to the height direction of the full-array LED light panel, and the plurality of LEDs disposed on the LED light bars are exposed from a plurality of openings of the flexible reflective sheet toward an LCD panel. Along a direction parallel to the width direction of the full-array LED light panel, the flexible reflective sheet is deformed to form a curved reflective surface. Each of the LED light bars further comprises a bar-shaped PCB, and a plurality of LED dimming-zone circuits are disposed on the bar-shaped PCB. Full-array local dimming of the curved full-array LED light panel can be achieved by controlling the electric current of the LED dimming-zone circuits.

A biocompatible electrical connection includes a substrate; a ferrule having a concentric flange at a first end of the ferrule; a first adhesive; and a second adhesive. The first adhesive adheres a first surface of the concentric flange of the ferrule to a surface of the substrate. The second adhesive fills an annular space between a hole in the substrate and the ferrule. The first adhesive or the second adhesive forms a conductive path on the surface of the substrate between the ferrule and a circuit pattern on the substrate.

An optical module includes a circuit board having a through hole for the lead terminal, a signal wiring connected to the lead terminal, a ground layer providing a reference potential, an opening through which the ground layer is exposed, and a bonding material connecting the ground layer to the metallic base. The lead terminal extends in a first direction, and the circuit board and the signal wiring extend in a second direction. When the circuit board is viewed from the first direction, the opening overlaps with the signal wiring, or when the opening does not overlap with the signal wiring, a first distance between the signal wiring and a closest point of the opening to the signal wiring is smaller than a second distance between the closest point and an edge of the circuit board.