An apparatus may include a breadboard. The breadboard may include a substantially flat board, which may include a top surface and a bottom surface. The top surface may be disposed opposite the bottom surface. The board may include one or more openings disposed in the board. The apparatus may include a pallet. The pallet may include a top surface and a bottom portion disposed opposite the top surface. The pallet may include a plurality of risers, which may be disposed on the bottom portion and extend in a direction opposite the top surface. The bottom surface of the breadboard may be mountable to the top surface of the pallet. One or more circuit breakers may be disposable on the top surface of the board of the breadboard. The breadboard and pallet may be reusable in transporting circuit breakers.

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.

An example electronic device may include a first printed circuit board including a specified area. The first printed circuit board may include at least one first pad and at least one second pad formed in the specified area, wherein, when a first radio frequency (RF) front end module is disposed in the specified area of the first printed circuit board, at least one first pad is in contact with the first RF front end module and at least one second pad is not in contact with the first RF front end module, and, when a second RF front end module is disposed in the specified area of the first printed circuit area, at least one first pad and at least one second pad are in contact with the second RF front end module.

According to an embodiment, an electronic device includes a substrate, first conductors, second conductors, a connector, third conductors, an electronic component, and a first wiring. The first conductor is complied with a first USB standard. The second conductor is complied with a second USB standard. The connector is mounted on the first conductors or the second conductors. The first wiring connects one of the first conductors, one of the second conductors, and one of the third conductors.

A battery charger may include a printed circuit board (PCB) having a first portion supporting alternating current (AC) electrical components and a second portion supporting direct current (DC) electrical components; an indicator including a light-emitting diode (LED) supported on the first portion of the PCB and operable to emit light; and an isolating member positioned on the first portion between the AC electrical components and the LED. A trace on the PCB may be electrically connected to the second portion of the PCB, the trace extending from the second portion and along the first portion, and the LED may be electrically connected to and receiving DC power through the trace, the LED being selectively positioned along a length of the trace. The LED may be positioned more than about 8 mm from the AC electrical components.

A flexible printed circuit board and optical network allocation device comprising same. The flexible printed circuit board comprises a circuit board body (1), a plurality of protruding interfaces (101) on the circuit board body, an adhesive layer (2) covering the upper surface of the circuit board body (1), components (102), and an uplink interface (103) used for information interaction with the components (102) on the circuit board body (1). Each protruding interface (101) is provided with an electronic label read/write interface (1011) used for reading electronic label information on an optical fiber head and an indicator (1012). The adhesive layer (2) is provided with an open window region (201) in the middle. The components (102) are immobilized on the upper surface of the circuit board body (1) and located in the open window region (201) of the adhesive layer, and are connected to the electronic label read/write interface (1011), the indicator (1012), and the uplink interface (103) respectively, used for controlling and monitoring the read/write information of the electronic label read/write interface (1011) and controlling on/off of the indicator (1012).

A circuit module includes a circuit board and electronic components mounted on the circuit board. The mounted electronic components include at least one discrimination-target electronic component and at least one module-discrimination electronic component. In addition, the circuit board includes land electrodes allowing the module-discrimination electronic component to be mounted at different positions and/or orientations with respect to the circuit board, and the module-discrimination electronic component is mounted at any one position and/or orientation among different positions and/or orientations with respect to the circuit board in accordance with the type of the discrimination-target electronic component.

A component determination system for determining, in a case when a first component to be mounted on a board by a first mounting operation and a second component mounted on the board by a second mounting operation have a particular corresponding relationship, whether a combination of the first component and the second component mounted is permissible, the component determination system including: a first characteristic information acquiring section configured to acquire first characteristic information of the first component for which the first mounting operation has been completed; a second characteristic information acquiring section configured to acquire second characteristic information of the second component prepared prior to the second mounting operation; and a combination determining section configured to determine whether to allow the combination of the first component and the second component based on the acquired first characteristic information and the acquired second characteristic information.

Provided are a nano-scale LED assembly and a method for manufacturing the same. First, a nano-scale LED device that is independently manufactured may be aligned and connected to two electrodes different from each other to solve a limitation in which a nano-scale LED device having a nano unit is coupled to two electrodes different from each other in a stand-up state. Also, since the LED device and the electrodes are disposed on the same plane, light extraction efficiency of the LED device may be improved. Furthermore, the number of nano-scale LED devices may be adjusted. Second, since the nano-scale LED device does not stand up to be three-dimensionally coupled to upper and lower electrodes, but lies to be coupled to two electrodes different from each other on the same plane, the light extraction efficiency may be very improved. Also, since a separate layer is formed on a surface of the LED device to prevent the LED device and the electrode from being electrically short-circuited, defects of the LED electrode assembly may be minimized. Also, in preparation for the occurrence of the very rare defects of the LED device, the plurality of LED devices may be connected to the electrode to maintain the original function of the nano-scale LED electrode assembly.

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.