A flexible printed circuit board according to the present disclosure includes: a first base sheet, a second base sheet, and a first protection sheet. The first base sheet includes a first Teflon film and a first circuit pattern disposed on the first Teflon film. The second base sheet includes a second Teflon film and a second circuit pattern disposed on the second Teflon film, and is laminated on the first base sheet. The first protection sheet covers the first base sheet. A portion of the first base sheet that is exposed to the first protection sheet is surface-modified.

A method for manufacturing a multilayer substrate including first and second insulating resin base material layers including different materials, includes configuring a conductor film-attached insulating resin base material with a conductor film on the first insulating resin base material layer, or a second conductor film-attached insulating resin base material with a conductor film on a main surface of the first insulating resin base material layer including a main surface of a stacked body including at least the first insulating resin base material layer, and stacking the first or second conductor film-attached insulating resin base material and another base material layer such that the conductor film is in contact with the second insulating resin base material layer. An adhesion strength of the first insulating resin base material layer to the conductor film is higher than an adhesion strength of the second insulating resin base material layer to the conductor film.

A method for manufacturing a circuit board comprising: providing an inner circuit substrate board comprising a first transmission area, a bendable area, and a second transmission area which are connected in an order, wherein the inner circuit substrate board further comprises a substrate layer and an inner circuit layer on the substrate layer, the inner circuit layer comprises a first signal circuit; pressing a first outer circuit substrate board on the inner circuit layer; wherein the first outer circuit substrate board comprises a first dielectric layer formed on the inner circuit layer and a first outer circuit layer formed on the first dielectric layer; the first dielectric layer is located in the first transmission area and the second transmission area; two ends of the first signal circuit are electrically connected to the first outer circuit layer.

Systems, apparatus, methods for manufacturing and techniques for interconnecting integrated circuit devices are disclosed. A flexible printed circuit (FPC) provides EMI shielding with reduced insertion loss. The FPC includes a first signal layer fabricated from a planar conductive material and having traces configured to carry signals between a circuit boards. The FPC may include a first non-conductive layer disposed in a plane above the first signal layer, a second non-conductive layer disposed in a plane below the first signal layer, a first copper ground plane disposed in a plane above the first non-conductive layer, a second copper ground plane disposed in a plane below the second non-conductive layer, and a second signal layer provided in a plane above the first copper ground plane or below the second copper ground plane. Signals carried in the first signal layer may have a higher frequency than signals carried in the second signal layer.

A method of manufacturing a press pad is disclosed. The method includes: providing a planar pad having a first surface and a second surface opposite to the first surface and a release film sheet, the release film sheet including a polyimide-based film; cleaning the planar pad, the cleaning including electrostatically removing particulates from surfaces of the planar pad; and attaching a release film sheet to the first surface of the planar pad, the release film sheet being attached to the first surface using an acrylic-based adhesive containing thermoplastic polyolefin and methyl acrylate.

Wireless sensor devices are described which harvest energy and provide an antenna or antennas for wireless communication on a relatively small form factor, preferably one that is co-extensive with a largest component of the device, e.g., an antenna layer or sensor layer. The devices are able to sense and/or control certain specific parameters of a system; store energy, e.g., in a supercapacitor system or battery system; transmit that as information/signals via a wireless link, e.g., RF or optical link; receive information from other devices and relay that information. Such devices accordingly may be self-powered and wireless devices, and not dependent on a separate device or form factor to provide a power source. Such devices can be entirely autonomous or substantially so, can be mobile or fixed, and may require little servicing over a period of time. The devices can be used as sensor nodes in a wireless mesh network.

A method for manufacturing a circuit board comprising: providing an inner circuit substrate board comprising a first transmission area, a bendable area, and a second transmission area which are connected in an order, wherein the inner circuit substrate board further comprises a substrate layer and an inner circuit layer on the substrate layer, the inner circuit layer comprises a first signal circuit; pressing a first outer circuit substrate board on the inner circuit layer; wherein the first outer circuit substrate board comprises a first dielectric layer formed on the inner circuit layer and a first outer circuit layer formed on the first dielectric layer; the first dielectric layer is located in the first transmission area and the second transmission area; two ends of the first signal circuit are electrically connected to the first outer circuit layer.

A flexible printed circuit and a display device are provided. The flexible printed circuit includes: a plurality of sub-circuit boards arranged in a stack, wherein the plurality of sub-circuit boards include at least a first sub-circuit board and a second sub-circuit board; and a pressure sensor arranged on the first sub-circuit board, wherein the first sub-circuit board includes: a substrate film; a conductive film arranged on a side of the substrate film away from the second sub-circuit board; an adhesive layer arranged on a side of the conductive film away from the substrate film; a cover layer arranged on a side of the adhesive layer away from the substrate film; and an electromagnetic shielding layer arranged on a side of the cover layer away from the substrate film, wherein at least a part of the conductive film is formed as an electrode of the pressure sensor.

A composite circuit board includes a composite circuit board unit, a first solder mask formed on a first metal protection layer of the composite circuit board unit, and a second solder mask formed on a second metal protection layer of the composite circuit board unit. Two ends of a first outer conductive circuit are bent back toward each other and spaced apart a predetermined distance to form a first window. Two ends of a second outer conductive circuit are bent back toward each other and spaced apart a predetermined distance to form a second window.

A composite circuit board includes a composite circuit board unit, a first solder mask formed on a first metal protection layer of the composite circuit board unit, and a second solder mask formed on a second metal protection layer of the composite circuit board unit. Two ends of a first outer conductive circuit are bent back toward each other and spaced apart a predetermined distance to form a first window. Two ends of a second outer conductive circuit are bent back toward each other and spaced apart a predetermined distance to form a second window.