Embodiments are directed to short and/or near short etch rework. A microfluidic device is positioned on a portion of a circuit having a defect. The microfluidic device is caused to dispense etchant that removes the defect of the circuit, where a flow of the etchant is controlled to access the portion of the circuit having the defect to thereby etch away the defect, the flow of the etchant being obstructed from accessing other portions of the circuit. The microfluidic device is used to extract the etchant from the portion of the circuit such that the etchant avoids contact with the other portions of the circuit. The microfluidic device is removed from the circuit.

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.

An electronic device with an active region comprising a substrate; a first conducting layer, disposed on the substrate, comprising a first pad in the active region; a second conducting layer, disposed on the first conducting layer, comprising a second pad in the active region; a first electronic component, disposed on the first pad, and electronically connected to the first pad; and a second electronic component, disposed on the second pad, and electronically connected to the second pad.

The present invention relates to a prelaminate for an electronic card, wherein at least a first group of pads is formed from a metal plate formed from a piece comprising a central part and branches extending from the central part, the branches of the metal plate forming the pads of the first group. The invention also relates to a method for producing such a prelaminate and an electronic card comprising such a prelaminate.

A method for forming a printed circuit board includes: forming on a substrate a first conductive layer for a first edge connector pin and a first conductive layer for a second edge connector pin, wherein the first conductive layer for the first edge connector pin and the first conductive layer for the second edge connector pin are electrically coupled to one another via a first conductive layer for an electrical bridging element; electroplating a second conductive layer onto both the first conductive layer for the first edge connector pin and the first conductive layer for the second edge connector pin via a plating current conductor; and removing at least a portion of the electrical bridging element to electrically separate the first edge connector pin from the second edge connector pin.

A printed circuit board assembly comprises a printed circuit board (PCB) defining a mounting end and an opposite contacting end, a row of first pads on the mounting end, a row of second pads on the contacting end, and an edge connector on the contacting end electrically contacted with the second pads, and a high speed line module mounted on a top side of the PCB and including a group of conductive lines, the conductive lines extending parallel to each other over the plane of the PCB, each conductive line having two ends electrically connected to corresponding first and second pads, respectively.

There is provided a method for manufacturing a component interconnect board (150) comprising a conductor structure for providing electrical circuitry to at least one component (114) when mounted on the component board, the method comprising providing a conductor sheet (100) with a first predetermined pattern (115), providing a solder resist sheet (112) with a second predetermined pattern for defining solder areas (125) of the component board, forming a subassembly (120) by laminating the solder resist sheet on top of the conductor sheet, applying solder onto the subassembly, placing the at least one component onto the subassembly, performing soldering, and laminating the subassembly to a substrate (130). The solder resist sheet is further arranged to act as a carrier for the conductor sheet.

A system and method for disabling the Wi-Fi on a handheld console whereby the handheld console may have an integrated chip that is a ball grid array whereby each solder ball provides certain voltages or data signals whereby the approach will be determined based on the specific handheld console as well as other factors including new manufacturer integrated chips, chipset architecture, software/firmware changes, or where is the best location on the handheld console for each circuit line to apply the short cut for the circuit to not be completed by either diverting the signal to another location on the logic board such as ground or creating an open line.

Some embodiments of the present invention are generally directed to testing connections of a memory device to a circuit board or other device. In one embodiment, a memory device that is configured to facilitate continuity testing between the device and a printed circuit board or other device is disclosed. The memory device includes a substrate and two connection pads that are electrically coupled to one another via a test path. A system and method for testing the connections between a memory device and a circuit board or other device are also disclosed, as are additional techniques for detecting excess temperature and enabling special functionalities using multi-stage connection pads.

A method for fabricating a conductive trace structure includes the steps: forming a first metal layer on a non-conductive substrate; removing a part of the first metal layer to expose the non-conductive substrate so as to form the first metal layer into a plating region and a non-plating region, the plating region being divided into at least two trace-forming portions and at least one bridge portion; forming a second metal layer on the plating region by electroplating the plating region using one of the trace-forming portions and the bridge portion as an electrode; and removing the bridge portion and the second metal layer formed on the bridge portion.