An object of the present invention is to provide a conductive film that is excellent in flexibility while maintaining its sufficient transparency and conductivity, and a conductive film roll, an electronic paper, a touch panel, and a flat-panel display having the same. A conductive film having a transparent substrate and a conductive part having a fine metal wire pattern disposed on one side or both sides of the transparent substrate, wherein the fine metal wire pattern is constituted by a fine metal wire, and the conductive film satisfies the following condition (i) or (ii): (i) the fine metal wire has voids, and when the cross-sectional area of the fine metal wire is defined as S.sub.M and the total cross-sectional area of the voids included in the cross-section of the fine metal wire is defined as S.sub.Vtotal on the cross-section of the fine metal wire perpendicular to the direction of drawing of the fine metal wire, S.sub.Vtotal/S.sub.M is 0.10 or more and 0.40 or less; and (ii) when the maximum thickness of the fine metal wire on the cross-section of the fine metal wire perpendicular to the direction of drawing of the fine metal wire is defined as T, the width of the fine metal wire at a height of 0.90T from the fine metal wire interface on the transparent substrate side is defined as W.sub.0.90 and the width of the fine metal wire on the fine metal wire interface on the transparent substrate side is defined as W.sub.0, W.sub.0.90/W.sub.0 is 0.40 or more and 0.90 or less.

System, apparatuses and methods are disclosed which relate to the use of substrate integrated waveguide technology in front-end modules. An example circuit card assembly for use as a cellular base station front-end is disclosed which includes at least one component printed circuit board (PCB) layer having front-end module hardware components and at least one filter PCB layer including at least one substrate integrated waveguide (SIW) filter.

The present invention relates to a method for manufacturing an electronic or electrical system, the method comprising the layer-free production of at least one physical structure (101, 102) which is designed to guide electromagnetic waves, using at least one additively operating apparatus, wherein the layer-free production of the spatial, layer-free structure comprises the simultaneous or sequential application and/or removal of one or more materials in the spatial arrangement, as a result of which the electronic or electrical system is partially or completely formed. The invention further relates to a system which is manufactured in accordance with the method.

An object of the present invention is to provide a composition for sintering capable of suppressing a crack from occurring in a wiring after sintering. Provided is the composition for sintering including silver nanoparticles, an organic dispersant for coating the silver nanoparticles, and a solvent. When the composition for sintering is heated, a weight loss rate in a range of 260 C. to 600 C. is 2.92% or less.

A method for manufacturing a mode converter including a substrate that is a single member and includes a first main surface, a second main surface opposite to the first main surface, and a micro hole which is formed in the first main surface, grounding conductor layers that are formed on the first main surface and the second main surface, a plane circuit that is formed on the first main surface, and a pin that is formed so as to cover an inner surface of the micro hole and is electrically connected to the plane circuit, the method includes: irradiating the substrate with laser light to form a first modified portion to a desired depth from one main surface of the substrate; removing the first modified portion to form the micro hole; and filling the micro hole with a conductive material to form the pin.

The present application discloses a filtering cable, which solves the problem that the cable in the related art cannot ensure a simple and reasonable structural design while having good filter performance. One or several core wires and N defective conductor layers surrounding the core wires are sequentially provided from inside to outside in the cross section in the radial direction of the filtering cable; wherein the defective conductor layer has an etching pattern; the etching pattern is distributed in the axial direction of the filtering cable; the etching pattern is used to make the filtering cable equivalent to a preset filter circuit to filter the signal transmitted in the filtering cable.

A printed wiring board is provided with: a core substrate corresponding to a stack area in which an interlayer connection conductor constituting an inner via is continuous; and a build-up layer comprising a resin layer stacked on the core substrate and a conductor layer on said resin layer. A via inner space inside the interlayer connection conductor constituting the inner via is hollow, and said via inner space communicates to the outside via a hole section provided in the build-up layer.

A packaging assembly and methodology provide a PCB substrate with one or more waveguide apertures and a conductive pattern which includes a plurality of landing pads that are disposed around peripheral edges of each waveguide aperture and that are connected to one another by trace lines so that, upon attachment and reflow of solder balls to the plurality of landing pads, the solder balls reflow along the trace lines to form a fully closed solder waveguide shielding wall disposed around peripheral edges of the first waveguide aperture.

A method for manufacturing a circuit board structure with a waveguide is provided. The method includes: providing a first substrate unit, a second substrate unit, a third substrate unit, and two adhesive layers, the first substrate unit including a first dielectric layer and a first conductive layer, the first conductive layer including a first shielding area and two first artificial magnetic conductor areas disposed on two sides of the first shielding area; the second substrate unit including a second dielectric layer and a second conductive layer, the second conductive layer including a second shielding area; the third substrate unit defining a first slot, and the adhesive layer defining a second slot; stacking the first substrate unit, one of the adhesive layers, the third substrate unit, another one of the adhesive layers, and the second substrate unit in that order; pressing the intermediate body.

A sensor device includes a printed circuit board (PCB) substrate having a top surface, a bottom surface, a slot between the top and bottom surfaces, and two holes through the top surface and reaching into the slot. The sensor device further includes a sensor chip mounted on the top surface of the PCB substrate and above one of the two holes. The sensor device further includes a molding compound covering the sensor chip and sidewall surfaces and the top surface of the PCB substrate.