An electronic device module includes: a substrate; a sealing portion disposed on a first surface of the substrate; an exothermic device disposed on the first surface of the substrate and embedded in the sealing portion; and a heat radiating portion at least partially embedded in the sealing portion. A lower surface of the heat radiating portion is bonded to one surface of the exothermic device. A side surface of the heat radiating portion is curved and is entirely in contact with the sealing portion. A plurality of grooves are disposed in the side surface of the heat radiating portion.

A free grounding film and a manufacturing method therefor, and a shielding circuit board including the free grounding film and a grounding method. The free grounding film includes at least one conductor layer. The shielding circuit board including the free grounding film is formed in a manner that an electromagnetic wave shielding film is arranged on a printed circuit board, and the upper surface of the electromagnetic wave shielding film is provided with the free grounding film. The grounding method for the shielding circuit board adopts one of three modes.

Provided is an electronic circuit board assembly. The electronic circuit board assembly includes an electronic circuit board, a plurality of electronic circuit devices disposed on the electronic circuit board, an electromagnetic interference (EMI) shielding structure configured to shield an electromagnetic wave generated from the plurality of electronic circuit devices, and a thermal pad configured to dissipate heat generated from the plurality of electronic circuit devices. The EMI shielding structure covers the plurality of electronic circuit devices and is attached to the electronic circuit board, and the thermal pad is disposed between the plurality of electronic circuit devices and the EMI shielding structure, contacts the plurality of electronic circuit devices and the EMI shielding structure, and thereby can transfers the heat generated from the plurality of electronic circuit devices to the EMI shielding structure.

An electronic device module, includes a substrate including a grounding electrode disposed on a surface of the substrate, an insulating portion encapsulating a portion of the surface of the substrate, an electronic component disposed on the surface of the substrate, wherein the electronic component is at least partially encapsulated by the insulating portion, and a sealing portion, having electrical conductivity, disposed on the substrate and the insulating portion. The sealing portion is electrically connected to the grounding electrode.

A flexible flat cable structure capable of improving crosstalk interference includes plural telecommunication signal conductors separated from one another and provided for transmitting differential signals, two support members installed on two lateral sides of the telecommunication signal conductor respectively, at least one filled material disposed between the telecommunication signal conductors. The ratio of the equivalent dielectric constant of the filled material to the equivalent dielectric constant of the support members falls within a range of 0.39˜0.27, and the ratio of the thickness of the filled material to the thickness of the support members falls within a range of 1.49˜1.37. Therefore, the flexible flat cable structure achieves the effects of reducing the time delay of the signal transmission of the flexible flat cable (FFC), suppressing the ringing noise of resonance, and improving the eye height of amplitude measurement, so as to suppress crosstalk interference and improve signal transmission quality effectively.

Provided is a method for masking a sensitive signal by injecting noise into planes of a printed circuit board (PCB). The method comprises detecting, by a secondary integrated circuit (IC), a noise signal on a shared plane of a PCB that includes the secondary IC. The noise signal may be analyzed to determine the characteristics of the noise signal. A masking signal may be generated based on the characteristics. The masking signal may then be injected onto the shared plane.

An electroless surface treatment plated layer of a printed circuit board, a method for preparing the same, and printed circuit board including the same. The electroless surface treatment plated layer includes: electroless nickel (Ni) plated coating/palladium (Pd) plated coating/gold (Au) plated coating, wherein the electroless nickel, palladium, and gold plated coatings have thicknesses of 0.02 to 1 μm, 0.01 to 0.3 μm, and 0.01 to 0.5 μm, respectively. In the electroless surface treatment plated layer of the printed circuit board, a thickness of the nickel plated coating is specially minimized to 0.02 to 1 μm, thereby making it possible to form an optimized electroless Ni/Pd/Au surface treatment plated layer.

An electronic device includes a signal sender that sends a pair of transmission signals of mutually opposite phases to an external device via a pair of transmission paths. The signal sender differentiates each amplitude of the pair of transmission signals.

An electronic device may have a printed circuit to which electrical components are mounted. Electromagnetic shields may be mounted to the printed circuit over the components to suppress interference. A shield may have a metal frame covered with a conductive fabric. The conductive fabric may cover an opening in the top of the frame. An insulating layer may be formed on the lower surface of the conductive fabric to prevent shorts between components on the printed circuit and the conductive fabric. An insulating cap such as an elastomeric polymer cap may also be formed over each component to provide electrical isolation between the components and the conductive fabric. Shields may be formed by coupling shield cans to subscriber identity module shields or other metal structures in a device. Intervening wall structures may be removed to help provide additional shielding volume.

A method for manufacturing an electromagnetic shielding film comprising providing an insulating layer, wherein the insulating layer is metallized to obtain a silver layer; and painting a conductive adhesive on a surface of the silver layer to form a conductive adhesive layer. The conductive adhesive layer comprises bisphenol A diglycidyl ether with a mass percentage between 9.8% and 10.5%, bisphenol S diglycidyl ether with a mass percentage between 4.54% and 4.86%, bisphenol F diglycidyl ether with a mass percentage between 2.27% and 2.43%, polyamide with a mass percentage between 7.11% and 7.62%, silver copper powder with a mass percentage between 48.6% and 68.3%, and silver strips with a mass percentage between 6.44% and 25.9%.