An electromagnetic wave transmission board proofed against internal signal leakage includes an inner plate, a first outer plate, a second outer plate, a first plate bump, a first conductive bump, a second plate bump, and a second conductive bump. The inner plate defines a first through hole with a plated metal layer on the hole wall. The first and second plated bumps are disposed between the first outer and inner plates. The second plate bump and the second conductive bump are disposed between the second outer plate and the inner plate. The plate metal layer, the first plate bump, the first conductive bump, the first outer plate, the second outer plate, the second conductive bump, and the second plated bump jointly form an air-filled chamber. A method for manufacturing the electromagnetic wave transmission board is also provided.

A method of manufacturing a circuit board having waveguides including forming a waveguiding structure by injection molding. The waveguiding structure includes a plurality of waveguides arranged at intervals and at least one connecting portion connecting two adjacent waveguides. Each waveguide includes a waveguiding substrate and at least one protrusion on the waveguiding substrate. The connecting portion is removed to obtain at least two waveguides. A metal layer is formed to wrap the whole outer surface of each waveguide. A plurality of receiving grooves is formed to penetrate a wiring board. Each waveguide wrapped by the metal layer is embedded in one of the receiving grooves. The waveguides and the wiring board are fixed. A portion of the metal layer on a surface of each protrusion facing away from the waveguiding substrate is removed. A circuit board is also provided.

The present disclosure relates to a display panel and a method for manufacturing a display panel. The display panel includes a first substrate having a first wiring, a second substrate having a second wiring, the first substrate, and the second substrate being laminated on each other to form a laminated structure, and a third wiring located on a side surface of the laminated structure, wherein the third wiring connects the first wiring and the second wiring.

An electronic device and a method for manufacturing such an electronic device are described. The electronic device includes an electronic component, and a component carrier in which the electronic component is embedded. The component carrier includes a first component carrier part having a first cut-out portion and a second component carrier part having a second cut-out portion, the first cut-out portion and the second cut-out portion facing opposite main surfaces of the electronic component. An electrically conductive material is provided on the surface of the first cut-out portion and on the surface of the second cut-out portion. The first cut-out portion and the second cut-out portion respectively form a first cavity and a second cavity on opposite sides of the electronic component.

A wiring substrate includes: an insulating substrate comprising a corner constituted by two adjacent surfaces; wiring located continuously across the corner; wherein on at least one of the two adjacent surfaces, a part of the wiring disposed at an edge located at the corner has a thickness larger than a part of the wiring disposed away from the edge.

A method is provided for forming waveguides in a PCB. The method may include forming an opening in a PCB core comprising a plurality of conductive layers interleaved with a plurality of insulating layers, the opening extending from a first side of the PCB core to a second side of the PCB core. The method may also include filling the opening with metal. The method may also include forming a cavity enclosed by sidewalls by removing a first portion of the filled opening, the cavity extending from the first side of the PCB core to the second side of the PCB core. A second portion of the filled opening is a heat transfer element configured to transfer heat from the first side of the PCB core to the second side of the PCB core. The at least one waveguide is embedded within the heat transfer element and configured for transmitting signals from the first side to the second side.

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.

A method for producing a waveguide in a multilayer substrate involves producing at least one cutout corresponding to a lateral course of the waveguide in a surface of a first layer arrangement comprising one or a plurality of layers. A metallization is produced on surfaces of the cutout. A second layer arrangement comprising one or a plurality of layers is applied on the first layer arrangement. The second layer arrangement comprises, on a surface thereof, a metallization which, after the second layer arrangement has been applied on the first layer arrangement, is arranged above the cutout and together with the metallization on the surfaces of the cutout forms the waveguide.

A component carrier includes a stack with at least one electrically conductive layer structure and at least one electrically insulating layer structure, and a microwave structure embedded at least partially in the stack. The microwave structure configured for exciting a microwave propagation mode and having at least two stack pieces being interconnected with each other at an electrically conductive connection interface.

The present invention relates to the field of integrating electronic systems that operate at mm-wave and THz frequencies. A monolithic multichip package, a carrier structure for such a package as well as manufacturing methods for manufacturing such a package and such a carrier structure are proposed to obtain a package that fully shields different functions of the mm-wave/THz system. The package is poured into place by polymerizing photo sensitive monomers. It gradually grows around and above the MMICs (Monolithically Microwave Integrated Circuit) making connection to the MMICs but recessing the high frequency areas of the chip. The proposed approach leads to functional blocks that are electromagnetically completely shielded. These units can be combined and cascaded according to system needs.