A resin multilayer substrate includes a multilayer body including resin base-material layers in a thickness direction, a side-surface conductor on at least a side surface of the multilayer body and made of a metallic material with a coefficient of thermal expansion whose difference from a coefficient of thermal expansion of the resin base-material layers in a plane direction is smaller than a difference from a coefficient of thermal expansion of the resin base-material layers in the thickness direction, a circuit component in the multilayer body and defining a circuit, and inner conductors in the multilayer body, located between the side-surface conductor and the circuit component along the side-surface conductor, and at least partially overlapping each other when viewed in the thickness direction, each of the inner conductors being one of a dummy conductor and a ground conductor.

A flexible printed circuit and an antenna structure are provided. The flexible printed circuit has a main body part and a bending part and includes a substrate, two copper foil layers, and two coverlays. The substrate includes a first surface and a second surface, and one surface of each of the two copper foil layers is disposed on the first surface and the second surface of the substrate, respectively. Each of the two coverlays is disposed on another surface of each of the two copper foil layers. Each of the two coverlays includes at least two coverlay holes, and the at least two coverlay holes penetrate through the coverlay and are disposed on the main body part.

A smart functional leather assembly includes a leather substrate, an electronic circuit layer including one or more conductive traces and optional electronic elements arranged on the leather substrate, optionally a pigmented coating arranged on the circuit layer, and an optional anti-soiling layer arranged on the pigmented layer. The entire smart functional leather assembly, including the circuit, are embossed to provide an embossed smart functional leather assembly with an embossed pattern.

The present invention comprises an apparatus for manufacturing electronics without PCBs.

A flexible board includes a flexible resin base material, a conductor pattern on a principal surface of the resin base material and including first and second electrodes electrically separated from each other, a first protective film having lower flexibility than the resin base material and covering a portion of the conductor pattern, and a second protective film having higher flexibility than the first protective film and extending over the principal surface of the resin base material and the first protective film to cover another portion of the conductor pattern. The first protective film is closer to the first and second electrodes on the principal surface of the resin base material than the second protective film. The first protective film includes a first opening exposing a portion of the first electrode and a second opening exposing a portion of the second electrode in planar view.

A formable transparent conductive film are described that comprise a sparse metal conductive layer, a thermoplastic polymer substrate supporting the sparse metal conductive layer, a viscoelastic polymer with a thickness from about 15 microns to about 150 microns over the sparse metal conductive layer. A layered film structure can be formed that is suitable for contouring on the surface of a three dimensional object without unacceptable increases in sheet resistance and with good optical transparency and low haze. The formable films can be placed into a frozen configuration bent 90 degrees with a radius of curvature of no more than about 5 centimeters while exhibiting a surface resistance of no more than about 500 ohms/sq. with a total transmittance with respect to visible light of at least about 80%.

A stretchable sensor includes a stretchable layer including an elastomer, and a conductive layer at least partially buried in the stretchable layer and including a conductive nanostructure. The stretchable layer includes a plurality of first regions including a ferromagnetic material buried in the elastomer, and a second region excluding the plurality of first regions.

Provided are a method for producing a thermoplastic liquid crystal polymer (TLCP) film having an improved thermo-adhesive property, a circuit board, and a method for producing the same. The production method of the TLCP film includes preparing a TLCP film as the adherend film and a TLCP film as the adhesive film;

examining each of the prepared TLCP films for a relative intensity calculated as a ratio in percentage of a sum of peak areas of C—O bond peak and COO bond peak based on the total area of C1s peaks in the XPS spectral profile so as to calculate a relative intensity X (%) as for the prepared adherend film and a relative intensity Y (%) as for the prepared adhesive film; and

controlling the TLCP film as the adhesive film to have a relative intensity Y by selection or activation treatment of the adhesive film so that the relative intensity X of the adherend film and the relative intensity Y of the controlled adhesive film satisfy the following formulae (1) and (2):

38<X+Y<65   (1)

−8.0<Y−X<8.0   (2).

A method of producing a double-sided metal-clad laminate comprises a supplying step of supplying an insulating film interposed between two metal foils continuously to between a pair of endless belts, a heat and pressure applying step of forming a laminate of the insulating film and the metal foils by heating and applying a pressure to the insulating film and the metal foils under predetermined condition while the insulating film is interposed by the two metal foils in between the endless belts, and a cooling step of cooling the laminate, wherein the insulating film has a thickness of 10 to 500 μm, a degree of planar orientation of 30% or more, an average coefficient of linear expansion in an MD direction of −40 to 0 ppm/K and an average coefficient of linear expansion in a TD direction of 0 to 120 ppm/K.

A method for manufacturing a wiring board according to the present disclosure includes: in the following order, (a) a step of irradiating an insulating layer composed of a resin composition with active energy rays; (b) a step of adsorbing an electroless plating catalyst to the insulating layer; and (c) a step of forming a metal layer on a surface of the insulating layer by electroless plating, in which in the step (a), a modified region having a thickness of 20 nm or more in a depth direction from the surface of the insulating layer and voids communicating from the surface of the insulating layer is formed by irradiation of the active energy rays.