A camera module according to the present invention may comprise: a barrel that accommodates a lens therein; a printed circuit board formed under the barrel and mounted with an image sensor; a body portion integrally formed with the barrel; a holder comprising a leg portion formed by being extended downward from the lower end of the body portion to the same height as the image plane of the lens; and a fixing portion formed downward from the leg portion to have a predetermined thickness to fix the holder to the printed circuit board, wherein the thickness of the fixing portion may be equal to the height from the upper surface of the printed circuit board to the image plane of the image sensor.

A hybrid integration method includes: assembling a motherboard chip, assembling a daughterboard chip, and assembling an integrated chip. The motherboard chip includes a motherboard chip body, a first metal region, a first vertical support assembly, and a first waveguide region arranged on the motherboard chip body, and the first waveguide region includes a first conventional waveguide region and a first coupling waveguide region used for vertical coupling which are fixedly connected to each other; the daughterboard chip includes a daughterboard chip body, a second metal region, a second vertical support assembly and a second waveguide region arranged on the daughterboard chip body, and the second waveguide region includes a second conventional waveguide region and a second coupling waveguide region used for vertical coupling which are fixedly connected to each other.

A liquid crystal display device 10 includes a liquid crystal panel 11 having a display area AA capable of displaying an image and a non-display area NAA outside the display area AA, a flexible board portion 40 having flexibility and connected to the non-display area NAA at a first end 40a thereof, and a rigid board portion 30 connected to a second end 40b of the flexible board portion 40 opposite the first end 40a and configured to supply signals to the liquid crystal panel 11 through the flexible board portion 40. The rigid board portion 30 at least includes a rigid portion 31a having a higher rigidity than the flexible board portion 40, a rigid portion 31b located next to the rigid portion 31a and having a higher rigidity than the flexible board portion 40, and a low rigidity portion 32a located between the rigid portion 31a and the rigid portion 31b and having a lower rigidity than the rigid portion 31a and the rigid portion 31b.

Research on practical realization of various types of printable devices has progressed, and the realization of devices in which these printable devices are integrated on a flexible board is expected. However, there is the problem that, if a plurality of printable devices are simply integrated on the same board, the area of the integrated device increases, and the yield ratio greatly decreases. An integration technique that solves the problem of an increase in the area and a decrease in the yield ratio is in demand. Electronic devices to be integrated are formed on individual boards, the boards are laid to overlap each other in a predetermined relationship, and then through-vias are formed at predetermined positions. With this, the electronic devices are electrically connected to each other, and function as an integrated device.

A flexible printed circuit and printed circuit board soldered structure is provided. The structure includes signal transmission lines which dispense with any through hole, thereby enhancing integrity of high-frequency signals. The special design of the signal line structure of the flexible printed circuit and the printed circuit board together provides a satisfactory high-frequency signal transmission interface and enables a soldering technique which is highly practicable and compatible with the flexible printed circuit and printed circuit board soldered structure.

Embodiments of the invention include LED lighting systems and methods. For example, in some embodiments, an LED lighting system is included. The LED lighting system can include a flexible layered circuit structure that can include a top thermally conductive layer, a middle electrically insulating layer, a bottom thermally conductive layer, and a plurality of light emitting diodes mounted on the top layer. The LED lighting system can further include a housing substrate and a mounting structure. The mounting structure can be configured to suspend the layered circuit structure above the housing substrate with an air gap disposed in between the bottom thermally conductive layer of the flexible layered circuit structure and the housing substrate. The distance between the layered circuit structure and the support layer can be at least about 0.5 mm. Other embodiments are also included herein.

A display device and a manufacturing method thereof are provided. The display device includes a display panel and a flexible circuit board electrically connected with the display panel. The flexible circuit board includes a first circuit board, a second circuit board and a conductive portion; the first circuit board includes a first substrate, and a main contact pad, a first wire and a second wire provided on the first substrate; the second circuit board includes a second substrate, a relay contact pad and a third wire provided on the second substrate; and the conductive portion is configured for electrically connecting the main contact pad and the relay contact pad.

An electronic assembly that includes a rigid printed circuit board having an upper surface with a first plurality of lands. The electronic assembly further includes a flexible printed circuit board having a second plurality of lands on an upper surface. The lower surface of the flexible printed circuit board is directly attached to the upper surface of the rigid printed circuit board. The electronic assembly further includes a plurality of wires. Each of the wires is bonded to the first plurality of lands on the upper surface of the rigid printed circuit board and the second plurality of lands on the upper surface of the flexible printed circuit board.

Disclosed is an electronic card, in the form of a flexible smart card provided with a flexible circuit, that includes a bottom face receiving electronic components and a top face provided with contact tabs intended to be connected to conductive tracks of a garment textile. The flexible circuit being covered on its bottom face with at least one bottom layer of bonding adhesive, first polymer layers provided with cutouts for receiving components and second polymer layers for encapsulating the components, and covered on its top face with a top layer of bonding adhesive and at least one top layer forming an outer face of the card made from polymer material provided with cutouts for accessing the contact tabs, in which at least some of the contact tabs are produced on the rim of the card and provided with an end part on the edge of the card.

A tiled display including discrete luminous sources distributed over at least two adjacent flexible display tiles, each of the flexible display tiles being configured to drive the discrete luminous sources on it when connected to a power supply and when receiving data and control signals. The power, data and control signals are provided to the tiles through conducting tracks formed on a carrier substrate, where an electrical connection between a first conductor on the carrier substrate and a second conductor on a tile is established by using a connecting element having a resilient means keeping it pressed and in contact with a surface of the first conductor or second conductor. Additionally, a carrier substrate and to a flexible display tile for use in such tiled displays.