The method for removing partial metal wall of hole of the present invention includes the following steps. First, a circuit board is provided. The circuit board includes a plurality of circuit layers, a plurality of dielectric layers, and a plated through hole. Each of the dielectric layers is between two adjacent circuit layers. The wall of the plated through hole includes at least one residual copper. The circuit layer immediately below the residual copper is defined as a signal layer. Next, a position of the signal layer and a position of the residual copper in the plated through hole are obtained. Next, a drill is provided, the drill includes a main body and at least one needle, and the drill is moved to the position of the residual copper. The main body is rotated around the central axis of the main body, so the needle can remove part of the residual copper.

The present disclosure provides a printed circuit board and a wire arrangement method thereof. The printed circuit board includes a packaged chip and at least two connectors, wires of the packaged chip that are connected to different connectors are distributed on different board layers; and when the packaged chip is connected to one of the connectors, a via is backdrilled to form a high-speed path from the packaged chip to the connector, and copper walls of board layers corresponding to other connectors are drilled out. The wires of the packaged chip that are connected to different connectors are distributed on different board layers. When the packaged chip is connected to one of the connectors, according to backdrilling of different depths, the via is backdrilled to form a high-speed path from the packaged chip to the connector, and copper walls of board layers corresponding to other connectors are drilled out.

Methods and systems for making a multi-layer circuit board are disclosed, including electrically connecting a boring device with a plated multi-layered circuit board; cutting a first bore having a first diameter through a first layer of the plated multi-layered circuit board; reciprocally extending a second cutting device a first predetermined distance into a barrel plated multi-layered circuit board and retracting the cutting device a second predetermined distance that is less than the first predetermined distance to form a second bore; after each retraction, sensing for electrical contact indicating a closed circuit between the cutting device and the plated multi-layered circuit board; if a closed circuit is sensed, determining if the second bore has reached an expected depth of a contact layer; and if the expected depth of the contact layer has not been reached, determining that a sliver has been formed in the barrel.

A printed circuit board has multiple stacked layers laminated together. A through hole is formed through the laminated stack, and plating is applied to the side walls of the though hole, thereby forming a plated through hole. Second through holes are then formed through the laminated stack, where each second through hole overlaps an edge of the plated through hole. By aligning the second through holes at the edge of the plated through hole, the plating of the plated through hole coincident with each second through hole is removed, thereby separating the plated through hole into two separate circuit paths. Forming second through holes in this manner effectively splits the circuit path of the plated through hole into multiple separate circuit paths, which increases the circuit density of the printed circuit board.

The present invention relates to printed circuit boards (PCBs), and more particularly, to methods of forming high aspect ratio through holes and high precision stub removal in a printed circuit board (PCB). The high precision stub removal processes may be utilized in removing long stubs and short stubs. In the methods, multiple holes of varying diameter and depth are drilled from an upper and/or lower surface of the printed circuit board utilizing drills of different diameters.

A circuit board includes a baseboard, a first conductive circuit layer, a second conductive circuit layer, at least one through hole, and a number of conductive lines. The first conductive circuit layer includes a number of first conductive circuit lines formed on a first side of the baseboard. The second conductive circuit layer includes a number of second conductive circuit lines formed on a second side of the baseboard. The through hole is defined through the first conductive circuit layer, the baseboard, and the second conductive circuit layer. The number of conductive lines are formed in an inner wall of the through hole and spaced apart around the through hole. Each conductive line electrically couples one of the first conductive circuit lines to a corresponding one of the second conductive circuit lines.

Provided is an example of a technology capable of accurately controlling impedance.

Provided is a substrate including a first through hole that penetrates a substrate from a first face to a second face of the substrate, and is electrically connected to a transmission line through which a signal is transmitted, a second through hole that is provided adjacent to the first through hole in plan view of the substrate, penetrates the substrate from the first face to the second face, and is electrically connected to a ground, and an adjustment unit that adjusts a distance between the first through hole and the second through hole in plan view of the substrate to adjust an impedance of a connection end of the first through hole with the transmission line.

A printed circuit board (PCB) core structure is provided for the transition of signals from one side of a PCB to an opposing side of the PCB. The PCB core structure may include a laminated core including an inner core including a plurality of conductive layers (N layers), a first dielectric layer, a first conductive trace disposed over the Nth conductive layer on a first side of the laminated core. The PCB core structure may also include a signal via extending from a first conductive layer to an Nth conductive layer through the laminated core, the signal via configured to connect the first conductive trace to a pin or a second conductive trace on a second side of the laminated core. The PCB core structure may also include a shielding structure surrounding the signal via and partially extending from the first conductive layer to the Nth conductive layer. The PCB core structure may also include a cavity removing a portion of the shielding structure in the Nth conductive layer and filled with a dielectric material. The cavity filled with the dielectric material prevents the first conductive trace from shorting to the shielding structure. The PCB core structure may be fabricated by using a single-lamination cycle.

The present invention relates to printed circuit boards (PCBs), and more particularly, to methods of forming high aspect ratio through holes and high precision stub removal in a printed circuit board (PCB). The high precision stub removal processes may be utilized in removing long stubs and short stubs. In the methods, multiple holes of varying diameter and depth are drilled from an upper and/or lower surface of the printed circuit board utilizing drills of different diameters.

An embedded component structure includes a board, an electronic component, and a dielectric material layer. The board has a through cavity. The board includes an insulating core layer and a conductive member. The insulating core layer has a first surface and a second surface opposite thereto. The through cavity penetrates the insulating core layer. The conductive member extends from a portion of the first surface along a portion of the side wall of the through cavity to a portion of the second surface. The electronic component includes an electrode. The electronic component is disposed in the through cavity. The dielectric material layer is at least filled in the through cavity. The connection circuit layer covers and contacts the conductive member and the electrode. A manufacturing method of an embedded component structure is also provided.