A flexible electronic system includes a flexible electronic substrate having a first and second contact pads opposed to each other, one of the first and second contact pads is electrically coupled to a battery. A protective cover is disposed on the flexible electronic substrate. The flexible electronic system further includes a base support fixedly attached to the flexible electronic substrate, the base support having an adhesive surface opposed to the flexible electronic substrate, and a foil having a first portion removably coupled to at least a portion of the adhesive surface and a second portion, wherein the foil configures to permit a removal of the second portion disposed between the first and second contact pads and wherein the removal of the second portion activates the system.

A process of utilizing a heat-activated conductive spinel material for PCB via overcurrent protection includes forming a PCB laminate structure that includes a spinel-doped insulator layer having a heat-activated conductive spinel material incorporated into a dielectric material as a spinel-based electrically non-conductive metal oxide. A sensing via is formed in the PCB laminate structure at a location that is proximate to a power via in the PCB laminate structure. The sensing via is electrically isolated from the power via by a region of the spinel-doped insulator layer and is electrically connected to a monitoring component configured to detect current flow through the sensing via that results from an overcurrent event in the power via that generates sufficient heat to cause the spinel-based electrically conductive metal oxide to release metal nuclei into the region to provide a conductive pathway through the region from the power via to the sensing via.

An apparatus for toggling circuits includes a plurality of parallel channels each having a first end and a second end, a plurality of ports transverse to the plurality of parallel channels, wherein each port has a plurality of valves corresponding to the plurality of parallel channels, wherein each valve selectively opens and closes in response to an input and wherein opening a valve fills a portion of a port with a conducting fluid. The apparatus also includes a controller communicatively coupled to the input of each valve and configured to complete an electric circuit between the first end of the parallel channel and the port corresponding to the valve when the controller opens the valve. A method executed by a computer and a corresponding computer program product are also disclosed herein.

An electronic assembly, has at least one circuit board with conductor tracks, at least one current-limiting arrangement in the form of a thermal predetermined breaking point in at least one of the conductor tracks, and a fire-containment device in the region of the current-limiting arrangement.

Structures of and methods for fabricating fine-scale interconnects and fuses are disclosed. A mushroom-type structure with a narrow stalk supporting a wider cap can be used for fine-scale interconnects with widths on the scale of hundreds of nanometers that have low resistivity. Micro-air bridges can be introduced by omitting the stalk in sections of the interconnect, allowing the interconnect to bridge over obstacles. The mushroom-type micro-air bridge structure can also be modified to create fine-scale fuses that have low resistivity overall and sections of significantly higher resistivity where the micro-air bridges exist. The significantly higher resistivity results in preferential fusing at the micro-air bridges. Both mushroom interconnects and mushroom fuses can be fabricated using electron beam lithography.

In a customizable circuit an interconnect matrix is provided that includes only two conductive layers, the matrix defining a first layer of L-shaped conductive lines and a second layer of substantially L-shaped conductive line segments that are connected to electrical components.

A detonator module comprising: a housing with a first housing half and a second housing half, a detonator contained within the housing, a child board comprising a terminal header, wherein the child board is contained within the housing and the first housing half exposes the terminal header to an exterior of the housing, a switch mounted to an exterior surface of the housing, and a plurality of switch leads connecting the switch to the terminal header.

A package structure includes a protection structure, a circuit board, and a chip. The circuit board includes a first cabling layer, a dielectric layer, and a second cabling layer that are laminated. The protection structure is disposed inside the dielectric layer. The protection structure is configured to electrically connect the first cabling layer to the second cabling layer, and the chip is electrically connected to the first cabling layer or the second cabling layer. When the chip is short-circuited, the protection structure blows first.

The present invention relates generally to electric circuit testing, building, or implementing using a breadboard-style printed circuit board (PCB). Aspects of the present invention include eliminating the need to use hookup wires when building and testing electric circuits on PCBs. In one or more embodiments, a PCB system having rows and columns of signal tie points connected in a breadboard layout and using an embedded wire and a solder bridge to form partial connections between signal tie points may be built. In one or more embodiments, an embedded wire and solder bridge is capable of connecting a column of signal tie points, and/or an embedded wire and solder bridge is capable of connecting a power rail to a signal tie point. Thus, a circuit may be implemented and tested by applying a small amount of solder to the solder bridge without the need for hookup wire.

A voltage determination device includes: a printed wiring board on which first to third substrate terminals are arranged in substantially one line; first and second voltage determination circuits mounted on the printed wiring board and disposed on a first side of the printed wiring board divided by a line passing through the first to third substrate terminals; a first printed wiring connecting the first substrate terminal and the first voltage determination circuit; a second printed wiring connecting the second substrate terminal and the first voltage determination circuit; a third printed wiring connecting the third substrate terminal and the second voltage determination circuit; and a fourth printed wiring connecting the second substrate terminal and the second voltage determination circuit, in which the first to fourth printed wirings are provided without intersecting each other and without bypassing a second side of the printed wiring board divided by the first arrangement line.