An image display device includes: a flexible board, a vibrational structure including a light reflecting film for reflecting light, and a molded circuit component including a mounting portion which is electrically connected to the vibrational structure and on which the vibrational structure is mounted and a connecting portion which is electrically and mechanically connected to the flexible board and which has a lower dynamic rigidity than the mounting portion. The flexible board and the vibrational structure are electrically connected via the molded circuit component.

A semiconductor package includes a VLSI semiconductor die and one or more output circuits connected to supply power to the die mounted to a package substrate. The output circuit(s), which include a transformer and rectification circuitry, provide current multiplication at an essentially fixed conversion ratio, K, in the semiconductor package, receiving AC power at a relatively high voltage and delivering DC power at a relatively low voltage to the die. The output circuits may be connected in series or parallel as needed. A driver circuit may be provided outside the semiconductor package for receiving power from a source and driving the transformer in the output circuit(s), preferably with sinusoidal currents. The driver circuit may drive a plurality of output circuits. The semiconductor package may require far fewer interface connections for supplying power to the die.

In accordance with disclosed embodiments, there are provided methods, systems, and apparatuses for implementing a magnetic particle embedded flexible substrate, a printed flexible substrate for a magnetic tray, or an electro-magnetic carrier for magnetized or ferromagnetic flexible substrates. For instance, in accordance with one embodiment, there are means disclosed for fabricating a flexible substrate having one or more electrical interconnects to couple with leads of an electrical device; integrating magnetic particles or ferromagnetic particles into the flexible substrate; supporting the flexible substrate with a carrier plate during one or more manufacturing processes for the flexible substrate, in which the flexible substrate is held flat against the carrier plate by an attractive magnetic force between the magnetic particles or ferromagnetic particles integrated with the flexible substrate and a complementary magnetic attraction of the carrier plate; and removing the flexible substrate from the carrier plate subsequent to completion of the one or more manufacturing processes for the flexible substrate. Other related embodiments are disclosed.

A contactless connector includes: a circuit board; a light emitter arranged on the circuit board and capable of converting electrical signals into optical signals; a light emitter control chip arranged on the circuit board for controlling the operation of the light emitter; and a light-transmitting member at least partially covering the circuit board, the light emitter, and the light emitter control chip.

A security device in an electronic device which protects against unauthorized disassembly includes light sources, a plurality of photosensitive elements, a detection unit, a storage unit, a processor, and light guiding devices. Light conducting channels are provided between the light sources and the induction elements. Barrier objects that block light are installed at certain first light guiding channels of the light guiding channels, and are removed from the first light conducting channels when the electronic device is disassembled, so that induction signals output by the photosensitive elements are changed from the model or original digitally-recorded signals.

The present invention discloses several means for combining together electrically and physically a single or multi-pole discrete magnetic device structure into an external main power-processing assembly or structure, which contains power semiconductor components and other power components. The point of interface and electrical connection mainly consists of winding terminations, power semiconductors and capacitors and creating the most optimum path for high frequency current flow and distribution in that region. This invention discloses several optimum methods for combining the two structures not previously done in prior art. In addition, the disclosure resolves how to optimize the high frequency current distribution at the point of connection or interface of the two discrete assemblies. It does so by creating interleaving layers of countervailing current flow and parallel paths of current flow on each layer at the interface or connection point of the two discrete assemblies.

A power module is disclosed and includes an upper surface for receiving multiple input signals, a lower surface for outputting multiple output signals, a top layer circuit board, a bottom layer circuit board and a middle layer. The top layer circuit board includes a first surface and a second surface disposed opposite to each other, and multiple electronic devices. The first surface forms the upper surface, and multiple first signal connection parts are disposed on the first surface for receiving the multiple input signals. The bottom layer circuit board includes a third surface and a fourth surface disposed oppositely. The fourth surface forms the lower surface, and multiple second signal connection parts are disposed on the fourth surface for outputting the multiple output signals. The middle layer is disposed between the top layer circuit board and the bottom layer circuit board.

In accordance with disclosed embodiments, there are provided methods, systems, and apparatuses for implementing a magnetic particle embedded flexible substrate, a printed flexible substrate for a magnetic tray, or an electro-magnetic carrier for magnetized or ferromagnetic flexible substrates. For instance, in accordance with one embodiment, there are means disclosed for fabricating a flexible substrate having one or more electrical interconnects to couple with leads of an electrical device; integrating magnetic particles or ferromagnetic particles into the flexible substrate; supporting the flexible substrate with a carrier plate during one or more manufacturing processes for the flexible substrate, in which the flexible substrate is held flat against the carrier plate by an attractive magnetic force between the magnetic particles or ferromagnetic particles integrated with the flexible substrate and a complementary magnetic attraction of the carrier plate; and removing the flexible substrate from the carrier plate subsequent to completion of the one or more manufacturing processes for the flexible substrate. Other related embodiments are disclosed.

An electrical connection device includes a mother board and a daughter board. The mother board includes a first board body with at least one cavity and a first electrical contact printed on the first board body. The daughter board includes a second board body and a second electrical contact printed on the second board body. At least one of the daughter board and the mother board includes at least one contour feature integrally formed with at least one of the first board body and the second board body. When the second board body is inserted into the at least one cavity of the first board body, the second electrical contact is electrically connected to the first electrical contact, and the daughter board is positioned in the mother board through the at least one contour feature.

A manufacturing method for a conductive substrate with a filtering function includes preparing a core layer and forming first and second conductive holes in the core layer, forming a sacrificial copper layer on the first conductive hole and on the core layer, forming a metal layer on the second conductive hole, forming a metal post in the first conductive hole, forming a lower insulating layer on the core layer, forming a lower insulative post in the second conductive hole, forming a magnet wrapping around the metal post to obtain a first conductive post, forming an upper insulating layer on the core layer, forming an upper insulative post in the second conductive hole to obtain a second conductive post, removing the upper insulating layer, the lower insulating layer, and the remaining sacrificial copper post layer, followed by flattening.