Receiver (1), in particular an implantable receiver (1) for transmitting energy to an implant, with a multi-layer circuit board comprising a plurality of electrically conductive layers (11-16), wherein the circuit board comprises an outer coil area and a multi-layer inner area enclosed by the coil area, a coil which is integrally incorporated at least partially in the layers (11-16) of the circuit board in the coil area, wherein the number of the layers (11-16) of the circuit board is smaller within this inner area than in the coil area.

The present disclosure provides a display module and a method for coating the same, which can prevent and/or reduce the occurrence of black seam between display modules that are arranged adjacent to each other. According to an example aspect of the present disclosure, a display module includes a printed circuit board; a plurality of luminous elements arranged at predetermined intervals on the printed circuit board; and a coating layer comprising a coating disposed between the respective luminous elements, disposed around side surfaces of the respective luminous elements positioned at an outermost, and formed to have a height that is substantially equal to a height of the side surfaces of the luminous elements, the coating being configured to block side light of the respective luminous elements.

The present disclosure relates to the method of manufacturing circuit having lamination layer using LDS (Laser Direct Structuring) to ease the application on surface structure for applied product of various electronic circuit and particularly, in which can form circuit structure of single-layer to multiple-layer on the surface of injection-molded substrate in the shape of plane or curved surface, metal product, glasses, ceramic, rubber or other material.

Methods are provided for manufacturing shape-retaining non-flat devices comprising components integrated on a device surface, the non-flat devices being made by deformation of a flat device. Based on the layout of a non-flat device, a layout of a flat device is designed. A method for designing the layout of such a flat device is provided, wherein the method includes inserting mechanical interconnections between pairs of elements to define the position of the elements on a surface of the non-flat device, thus leaving zero or less degrees of freedom for the location of the components. Based on the layout of a flat device thus obtained, the flat device is manufactured and next transformed into the shape-retaining non-flat device by means of a thermoforming process, thereby accurately and reproducibly positioning the elements at a predetermined location on a surface of the non-flat device.

A three-dimensional (3D) circuit structure includes a 3D insulating substrate having at least one circuit forming zone and at least one exposed contact forming zone; at least one circuit pattern portion provided on the 3D insulating substrate and having at least one circuit trace layout layer located in the circuit forming zone and at least one exposed contact located in the exposed contact forming zone and connected to the circuit trace layout layer; and an insulating encapsulation member covering at least the circuit forming zone and the circuit trace layout layer. With the insulating encapsulation member, the circuit trace layout layer is waterproof, dustproof, scratch-resistant, peeling-proof, secure for use, and compliant with safety codes of electrical insulation, enabling the 3D circuit structure in use to have stable electrical characteristics.

A three-dimensional (3D) circuit structure includes a 3D insulating substrate having at least one circuit forming zone and at least one exposed contact forming zone; at least one circuit pattern portion provided on the 3D insulating substrate and having at least one circuit trace layout layer located in the circuit forming zone and at least one exposed contact located in the exposed contact forming zone and connected to the circuit trace layout layer; and an insulating encapsulation member covering at least the circuit forming zone and the circuit trace layout layer. With the insulating encapsulation member, the circuit trace layout layer is waterproof, dustproof, scratch-resistant, peeling-proof, secure for use, and compliant with safety codes of electrical insulation, enabling the 3D circuit structure in use to have stable electrical characteristics.

An electronic device comprising an array antenna according to various embodiments of the present invention may comprise: a housing comprising a first plate, a second plate facing away from the first plate, and a side member surrounding the space between the first plate and the second plate; a display visible through a part of the first plate; a first printed circuit board comprising a first surface facing the side member, a second surface facing away from the first surface, a first edge adjacent close to the first plate, and a second edge closer to the second plate than the first edge, the first printed circuit board comprising one or more conductive plates on the first surface; a second printed circuit board extending from the first edge so as to bend at an obtuse angle with regard to the first surface, the second printed circuit board comprising one or more first conductive patterns; a third printed circuit board extending from the second edge so as to bend at an obtuse angle with regard to the first surface, the third printed circuit board comprising one or more second conductive patterns; and a wireless communication circuit electrically connected to the conductive plates, the first conductive patterns, and the second conductive patterns and configured to transmit and/or receive signals. Various other embodiments may be possible.

A method for manufacturing an electronics assembly, includes obtaining or producing an electronics module, which includes a first circuitry on a first surface at a first side of a circuit board, at least one electronics component on the circuit board in electrical connection with the first circuitry, and at least one first connection portion on the first surface and/or an adjacent side surface at a peripheral portion of the circuit board, wherein the at least one first connection portion is electrically connected to or comprised in the first circuitry. The method further includes arranging the electronics module on a second substrate including a second connection portion connected to a second circuitry on a surface of the second substrate and arranging electrically conductive joint material onto the first and second connection portions to extend between them for electrically connecting the electronics module to the second circuitry.

A method to plastically deform a flexible conductive element (1) wherein is provided a device (11) configured to expand the volume thereof, wherein the method comprises the steps of arranging the flexible conductive element (1) at least partially around said device (11); expanding the volume of the device (11) up to a predetermined value, whereby at least one portion (8) of the flexible conductive element (1) which is in contact with the device (11) during the expansion of the device (11) is plastically deformed.

A quick mounting junction box for connecting a power source and a ceiling fan motor of a ceiling fan includes a circuit board having a mounting portion on which a start capacitor and a positive and reverse switch are disposed, and a power connecting portion and a motor connecting portion which are formed adjacent to a side edge and on which a power source connector and a motor connector are respectively disposed. The start capacitor and the positive and reverse switch are electrically connected with the power source connector and the motor connector through the circuit board. The power source and the ceiling fan motor can be easily assembled and connected through the power source connector and the motor connector.