A dual printed circuit board assembly for vehicle lights, the dual printed circuit board including a dual printed circuit board and a dual connector. The dual printed circuit board having a first substrate with a first layout, a second substrate opposite to the first substrate with a second layout, and a common panel that supports the first substrate on a first side and the second substrate on a second side, wherein the first layout is populable by a first plurality of light sources to be used in a first light of the vehicle lights and the second layout is populable by a second plurality of light sources to be used in a second light of the vehicle lights. The dual connector having a first jumper connector electrically connected to the first layout, and a second jumper connector opposite to the first jumper connector and electrically connected to the second layout.

An electronic component is able to be mounted on a mounting substrate on which a first electronic component and a second electronic component are able to be mounted. When dimensions of the first electronic component and the second electronic component in a width direction is designated as W1 and W2, respectively, and dimensions of the first electronic component and the second electronic component in a length direction are designated as L1 and L2, respectively, dimensions of the electronic component in the width direction and the length direction are any one of combinations of W1 and L2, and of W2 and L1. The electronic component includes a third laminate and a pair of third external electrodes. Each of the pair of third external electrodes includes a fired layer, and a resin layer provided on an external surface of the fired layer.

Provided are a transparent conductor and a display device including the same, the transparent conductor including: a substrate layer; and a transparent conductive pattern layer formed on the substrate layer, and the transparent conductive pattern layer includes a plurality of conductive areas and non-conductive areas, the non-conductive areas are formed every between neighboring conductive areas, the non-conductive area in the transparent conductive pattern layer has a deviation as calculated by Equation 1 herein, which has a value larger than about 1 and equal to or smaller than about 1.25, and the non-conductive areas have a minimum line width of 40 m or less.

One example of a system includes a printed circuit board. The printed circuit board includes a switch chip footprint to receive a higher lane count switch chip or a lower lane count switch chip. The printed circuit board includes a plurality of transceiver module footprints. Each transceiver module footprint is electrically coupled to the switch chip footprint. Each transceiver module footprint may receive a higher lane count transceiver module or a lower lane count transceiver module.

A substrate for mounting a semiconductor device includes an insulating layer having first and second opposed surfaces defining a thickness. First and second electrically conductive lands are included in the insulating layer. The first electrically conductive lands extend through the whole thickness of the insulating layer and are exposed on both the first and second opposed surfaces. The second electrically conductive lands have a thickness less than the thickness of the insulating layer and are exposed only at the first surface. Electrically conductive lines at the first surface of the insulating layer couple certain ones of the first electrically conductive lands with certain ones of the second electrically conductive lands. The semiconductor device is mounted to the first surface of the insulating layer. Wire bonding may be used to electrically coupling the semiconductor device to certain ones of the first and second lands.

The invention relates to a variable sensor interface for a control unit, this variable sensor interface including a circuit board which is provided with components. In a sensor interface which can easily be used for the use of different sensor types, the circuit board has a predefined conductive track layout having a plurality of predefined mounting locations, the mounting locations being provided with components in a sensor-specific manner.

According to one embodiment, an electronic device includes a substrate including a first face, a plurality of first conductors on the first face, a plurality of second conductors on the first face, and a first electronic component mounted on the first face, and including a first terminal connected to the plurality of first conductors, and a second terminal connected to the plurality of second conductors.

A PCB and a signal transmission system are provided. The PCB includes a connection module, and at least two signal layers and at least two reference layers spaced apart. The connection module comprises a first connection terminal and a second connection terminal. The first connection terminal is connected to at least one first signal layer and is connectable to an external optical interface. The second connection terminal is connected to at least one second signal layer and is connectable to an external electrical interface. Each reference layers is provided with a through-hole, and for each reference layers, there is an overlapping region between a projection region of an orthogonal projection of the connection module onto the reference layer and a hole region of the through-hole arranged on the reference layer.

A display device includes a substrate, a first electrode extending in a first direction on the substrate, a first partition wall extending in the first direction on a central portion of the first electrode, a second electrode extending in parallel with the first electrode on the substrate, a second partition wall extending in the first direction on a central portion of the second electrode, and a plurality of light-emitting diodes electrically connected between the first electrode and the second electrode.

Electronic devices and methods including a printed circuit board configured to accept CPUs and memory modules are described. One apparatus includes a printed circuit board that includes a first row of elements including a first CPU positioned between first and second groups of dual in-line memory modules (DIMMs). The printed circuit board also includes a second row of elements including a second CPU positioned between third and fourth groups of DIMMs. The apparatus also includes a third row of elements including a fifth group of DIMMs, wherein the second row of elements is positioned between the first row of elements and the third row of elements. Other embodiments are described and claimed.