A method for forming resistance on circuit board is provided and includes the following steps. First, a substrate is provided. Next, a second metal layer is provided on the substrate, and the first metal layer is covered by the second metal layer. Then, a resistance is formed on the second metal layer, and the resistance is directly above the first metal layer. Thereafter, the second metal layer is cut so that the edge of the second metal layer is aligned with that of the first metal layer. The second metal layer is separated from the first metal layer. Next, the second metal layer is pressed with a circuit board, and the resistance is attached to a dielectric layer of the circuit board. Then, the second metal layer is etched to form a circuit pattern on the resistance.

A wiring board includes a pair of hard substrates provided for each of a plurality of semiconductor elements connected in parallel; a soft substrate provided so as to be at least partially sandwiched between all of the pairs of hard substrates; a first electrode configured to connect a control terminal of the semiconductor element and the hard substrate or the soft substrate; a second electrode configured to connect a reference potential terminal of the semiconductor element and the hard substrate or the soft substrate; a first wiring configured to connect in parallel the first electrodes of each of the plurality of semiconductor elements, at least part of the first wiring being provided on the soft substrate; and a second wiring configured to connect in parallel the second electrodes of each of the plurality of semiconductor elements, at least part of the second wiring being provided on the soft substrate.

A PCB, printed circuit board, structure for forming at least one embedded electronic component. The structure comprises a multi-layer PCB board comprising at least one through-hole via, the via comprising a plurality of electrodes vertically aligned within the via, each electrode comprising a plated ring; and an isolation section separating each of the electrodes.

An apparatus is described. The apparatus includes a substrate and one or more sensor components formed on the substrate. And, the apparatus includes one or more electrical circuits formed on the substrate electrically coupled with at least one of the one or more sensor components formed on the substrate.

The present disclosure provides an electronic device including a substrate, a conductive element, an extending element and an insulating layer. The substrate includes an edge, the conductive element is disposed on the substrate, the extending element is disposed corresponding to at least a portion of the conductive element and extends to the edge of the substrate, and the insulating layer separates the conductive element and the extending element.

A circuit board is disclosed that has a pre-warming function. The circuit board includes a substrate and one or more conductive paths embedded in the substrate. The one or more electrically conductive paths include a logic control circuit containing a heating element and a temperature-sensitive element configured to control the heating element and deliver an input when the temperature-sensitive element has reached a threshold temperature. The one or more electrically conductive paths further includes a heater power circuit configured to deliver power to the logic control circuit. The one or more electrically conductive paths further includes an operational power circuit configured to switch off power to the heater power circuit and switch on power to the operational power circuit upon a delivery of the input from the logic control circuit.

An electronic device may include a printed circuit with a surface-mounted component. The component may produce resistive heating within the printed circuit. Resistive thermal devices (RTDs) may be embedded within the printed circuit. An RTD may at least partially overlap the electrical component. The RTD may include contact pads on a flexible substrate and a meandering conductive trace between the contact pads. The trace may have a resistance varying linearly as a function of temperature. A data acquisition system (DAQ) may measure the resistance of the RTD. Control circuitry may identify the temperature of the printed circuit based on the resistance of the RTD measured by the DAQ and may reduce power consumption by the component when the temperature exceeds a threshold. This may serve to prevent overheating in the printed circuit over time, thereby maximizing the operating life of the printed circuit.

A resistor-embedded circuit board and a method for processing the resistor-embedded circuit board are provided by the present disclosure. By opening an embedded-resistor cavity on a substrate, embedding a resistor into the embedded-resistor cavity to acquire a circuit board containing a built-in resistor. By opening the embedded-resistor cavity, it is very easy to realize high-precision control of a shape and a thickness of an embedded resistor, and realize very high-precision resistor-embedding; and it is easy to realize high-precision and massive processing. In a resistor-embedded layer, a resistor is built in a substrate. Then, in a process of pressing, a crack and a relatively large deformation will not be caused after pressing due to an irregular surface of the resistor-embedded layer, thereby improving a reliability and a quality rate of the circuit board.

A method of producing a functional vehicle component includes fixing a leather sheet over a surface of a vehicle component, applying a flexible electronic circuit to an A-surface of the leather sheet, and arranging a pigmented coating over the circuit. The pigmented coating inhibits or prevents the circuit from being visible through the pigmented coating. The method may include attaching an electronic element, such as a light source, a sensor, a wireless transmitter, or a switch, to the circuit. When the circuit includes a light source, the pigmented coating inhibits or prevents the light source from being visible through the pigmented coating, but light emitted by the light source is visible through the pigmented coating.

A method for improving flexibility of a circuit board, e.g., comprising a touch-based sensor, and reducing manufacturing costs by eliminating routing around a border of the touch-based sensor is presented herein. The method comprises forming an array of touch sensors on a first side of the circuit board, in which portions of the circuit board located between three edges of the circuit board and a border of the array of touch sensors exclude traces; and forming first traces between respective second traces in a singular direction on a second side of the circuit board, in which the first traces are electrically coupled, using a first group of vias, to respective rows of the array of touch sensors, and the second traces are electrically coupled, using a second group of vias, to respective columns of the array of touch sensors.