A touch LED component and a touch device, and the touch LED component includes a metal cap, a touch button sheathed on an inner wall of the metal cap, and an LED lamp bead coupled to an inner wall of the touch button, a first through hole formed at the top of the metal cap, an induction pin installed at the bottom of the touch button, and an anode pin and a cathode pin installed on both sides of the bottom of the LED lamp bead respectively. The touch device includes a touch panel, a circuit board, and plural touch LED components. The touch LED component with high integration can be packaged by carrier tapes to facilitate automatic plug-ins and simplify production and assembling processes for mass production. The touch device has the features of simple structure, high reliability, good effect and long life.

In accordance with one implementation, a method for multiple source light output smoothing includes measuring a light distribution generated by multiple light sources arranged within an electronic device and determining at least one brightness adjustment based on the measured light distribution that is sufficient to locally reduce light output within a discrete region of a surface of the electronic device to satisfy predefined luminosity criteria. The method further includes applying an optical filter between the multiple light sources and the surface, the optical filter configured to reduce light output within the discrete region according to the determined at least one brightness adjustment.

According to one embodiment, a vibration detecting device includes a housing, a vibration sensor, a circuit board, a flexible wiring member, and an elastic member. The vibration sensor is accommodated in the housing. The circuit board is accommodated in the housing, and is provided with a first electric component configured to process a detection signal of the vibration sensor. The wiring member electrically connects the vibration sensor and the circuit board to each other. The elastic member contains a polymer material, and is accommodated in the housing as being in contact with the housing and the circuit board, and being detachable from the housing. The circuit board is held by the housing through the elastic member.

An electronic assembly and a method of forming an electronic assembly. The electronic assembly including a printed circuit board including a first face, a flexible printed circuit connected to the first face of the printed circuit board, a filler component arranged over a first portion of the first face of the printed circuit board, a housing defining a cavity, wherein the filler component is arranged in the cavity, a channel guide extending from the housing, wherein the flexible printed circuit sits in the channel guide, and a substrate positioned adjacent to a second face of the printed circuit board, wherein the second face opposes the first face.

The present disclosure provides a PCB board, a manufacturing method of a PCB board, and an electrical device, where the PCB board includes an insulating dielectric layer which is a glass substrate layer including a top surface and a bottom surface disposed oppositely; a conductive wiring layer which is disposed on a top surface of the insulating dielectric layer; and a top ink layer which is coated on the conductive wiring layer. According to the technical solution provided by the embodiment of the disclosure, the PCB board does not generate the phenomenon of deformation warping, and the conductive wiring layer is not easily peeled off from the insulating medium layer, and the use performance of the PCB board is good.

A touch device usable for a hair dressing apparatus is disclosed. The touch device includes a touch sensing shell, an FPC (Flexible Printed Circuit) board and a PCB (Printed Circuit Board), wherein the touch sensing shell is mounted on the surface of the hairdressing apparatus. The FPC board is attached to the touch sensing shell and mounted between the touch sensing shell and the hairdressing apparatus. The PCB is connected with the FPC circuit board by use of a lead and mounted inside the hairdressing apparatus. The touch sensing shell is capable of sensing actions provided by the fingers of a user and preventing the FPC board from having direct contact with the user, A touch sensing region and a functional control unit are arranged on the FPC board and connected with a central processing unit.

A lighting memory device and a memory module are provided. A lighting control circuit receives at least one lighting mode selection signal through lighting mode control pins and controls luminous characteristics of a plurality of light sources according to a lighting control mode corresponding to the lighting mode selection signal.

A backlight lamp bar, a backlight module and a display device are provided in embodiments of the disclosure, all being relating to a technical field of display technology, the backlight lamp bar as disclosed including: a flexible circuit board; and a backlight source and a button light source both being provided on the flexible circuit board; the backlight source and the button light source being located on two opposite faces of the flexible circuit board perpendicular to a thickness direction thereof, and power supply terminals of the backlight source and the button light source are electrically connected with circuits on the flexible circuit board, respectively.

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.

An item may be formed from layers of material such as leatherboard layers. A leatherboard layer may include fibrous natural material such as leather or paper embedded in polymer. Portions of the leatherboard layer can be locally modified by incorporation of filler material with desired properties. The filler material may include magnetic particles, conductive particles, or other material. By incorporating the filler material in localized portions of the leatherboard layer, integral electrodes or magnets may be formed. The leatherboard layer may also include embedded circuitry. Items such as enclosures and other items may be formed from the leatherboard layer. The leatherboard layer in an item may include locally modified regions such as magnet regions that are configured to form a closure or other structures that interact with each other.