A method of manufacturing component carriers includes carrying out a test for each of multiple sections of a component-carrier structure, inserting at least one functional component in each of further sections of a further component-carrier structure to be connected with the component-carrier structure so that each further section assigned to a respective section having successfully passed the test is provided with at least one functional component, and inserting at least one functionally inactive dummy component in each of the further sections assigned to a respective section having failed the test.

A device that includes a substrate including a plurality of metal layers, and a plurality of dielectric layers. The device further includes a first passive component including a first terminal, a second terminal, and a first body, mounted to the substrate on one of the plurality of metal layers. The first terminal is coupled to a first ground signal and the second terminal is coupled to a second ground signal such that the first passive component is shorted.

A device that includes a substrate including a plurality of metal layers, and a plurality of dielectric layers. The device further includes a first passive component including a first terminal, a second terminal, and a first body, mounted to the substrate on one of the plurality of metal layers. The first terminal is coupled to a first ground signal and the second terminal is coupled to a second ground signal such that the first passive component is shorted. The first passive component may be an inductor, a capacitor or a resistor. The first passive component is operable as a heat sink, a heat shield, an electromagnetic shield, or as a tuning inductor.

A server box embodiment is disclosed that generally comprises an array of dummy HDDs that share a common set of universal disk drive components in a master components module, or power module. Each dummy HDDs is constructed without expensive onboard chipsets that control the normal functionality of a standard HDD. By sharing expensive chipsets in a master components module (power module) money can be saved in building and selling the dummy HDD server. Embodiments envision a power module possessing the needed chipset functionality that is missing in a dummy HDD. The power module can be made to move from dummy HDD to dummy HDD supplying the necessary chipset in a shared manner when data is being stored or retrieved for client or end-user.

A server box embodiment is disclosed that generally comprises an array of dummy HDDs that share a common set of universal disk drive components in a master components module, or power module. Each dummy HDDs is constructed without expensive onboard chipsets that control the normal functionality of a standard HDD. By sharing expensive chipsets in a master components module (power module) money can be saved in building and selling the dummy HDD server. Embodiments envision a power module possessing the needed chipset functionality that is missing in a dummy HDD. The power module can be made to move from dummy HDD to dummy HDD supplying the necessary chipset in a shared manner when data is being stored or retrieved for client or end-user.

A server box embodiment is disclosed that generally comprises an array of dummy HDDs that share a common set of universal disk drive components in a master components module, or power module. Each dummy HDDs is constructed without expensive onboard chipsets that control the normal functionality of a standard HDD. By sharing expensive chipsets in a master components module (power module) money can be saved in building and selling the dummy HDD server. Embodiments envision a power module possessing the needed chipset functionality that is missing in a dummy HDD. The power module can be made to move from dummy HDD to dummy HDD supplying the necessary chipset in a shared manner when data is being stored or retrieved for client or end-user.

A method for manufacturing a circuit, in particular of a hearing aid, in which method a printed circuit board is made available with a first region and with a second region which are separated by means of a boundary. A component is mounted on the printed circuit board, wherein the component is positioned on the boundary. The first region is covered by means of a mask which has an edge, wherein the edge is positioned on the component, and the printed circuit board is provided with a coating. The coating is cut away in the region of the component and the mask is removed.

A system includes a stress-engineered substrate comprising at least one tensile stress layer having a residual tensile stress and at least one compressive stress layer having a residual compressive stress. The at least one tensile layer and the at least one compressive layer are coupled such that the at least one tensile stress layer and the at least one compressive stress layer are self-equilibrating. At least one functional device is disposed on the stress-engineered substrate. The stress-engineered substrate is configured to fracture in response to energy applied to the substrate. Fracturing the stress-engineered substrate also fractures the functional device. The system includes at least one decoy device. Fragments of the decoy device are configured to obscure one or more physical characteristics of the functional device and/or one or more functional characteristics of the functional device after the functional device is fractured.

A printed circuit board includes a first build-up insulating layer; an interconnect structure buried in an upper side of the first build-up insulating layer and including one or more insulating layers, one or more wiring layers, and one or more via layers; an adhesive disposed between an upper surface of the first build-up insulating layer and an upper surface of the interconnect structure, and having an upper surface exposed from the upper surface of the first build-up insulating layer; and a metal bump including a via portion penetrating the adhesive and a protrusion protruding to the upper surface of the adhesive.

Tamper-respondent assemblies and methods of fabrication are provided which include at least one tamper-respondent sensor and a detector. The at least one tamper-respondent sensor includes conductive lines which form, at least in part, at least one tamper-detect network of the tamper-respondent sensor(s). In addition, the tamper-respondent sensor(s) includes at least one interconnect element associated with one or more conductive lines of the conductive lines forming, at least in part, the tamper-detect network(s). The interconnect element(s) includes at least one interconnect characteristic selected to facilitate obscuring a circuit lay of the at least one tamper-detect network. In operation, the detector monitors the tamper-detect network(s) of the tamper-respondent sensor(s) for a tamper event.