A power supply assembly includes a power supply unit disposed within a housing and an adjustable plate module movably disposed on a floor thereof. The adjustable plate module includes a plate, a shaft, a stopper panel, and a compressible device. The plate has two planar surfaces positioned at different heights with respect to the floor. The shaft is fixedly coupled to and extends outwardly from the plate. The shaft is configured to move between a first position and a second position to transition a connector between the planar surfaces. The stopper panel is disposed adjacent to a distal end of the shaft and has an opening therein for accommodating the shaft. The compressible device is disposed around the shaft such that a displacement of the plate causes the compressible device to compress against the stopper panel and facilitate movement of the shaft from the first position to the second position.

A lens module and a manufacturing method of the lens module are provided. The manufacturing method includes the following steps. Firstly, a circuit substrate is provided. Then, an image sensor chip is placed on a top surface of the circuit substrate. Then, plural electrical connection paths are formed between the image sensor chip and the circuit substrate. Then, plural stacking spacer structures are formed on a top surface of the image sensor chip by a stacking process. Then, plural protective sidewalls are formed to cover the electrical connection paths. Then, a glass substrate is placed over the stacking spacer structures. Then, a lens holder structure is placed on a substrate top surface of the glass substrate directly. The glass substrate is supported by the stacking spacer structures. Consequently, the glass substrate can be maintained at the position over the image sensor chip.

An electronic component is disclosed. The electronic component includes: a capacitor body; first and second external electrodes on a mounting surface of the capacitor body; first and second connection terminals respectively connected to the first and second external electrodes; a first bonding portion between the first external electrode and the first connection terminal, and including a first-2-th region and a first-1-th region, the first-2-th region being adjacent to a center of the capacitor body and including a conductive resin, and the first-1-th region being adjacent to one end of the capacitor body and including a high melting point solder; and a second bonding portion between the second external electrode and the second connection terminal, and including a second-2-th region and a second-1-th region, the second-2-th region being adjacent to the center of the capacitor body and the second-1-th region being adjacent to the other end of the capacitor body.

The present invention provides a sensor mounted wafer, including: a lower case in which a mounting groove is formed; a circuit board on which a plurality of electronic components having different heights are mounted, and placed in the mounting groove; an upper case in which a plurality of insertion grooves having different depths are formed, and bonded together to the lower case so that the plurality of electronic components are inserted into the plurality of insertion grooves; and an adhesive layer placed between the mounting groove and the plurality of insertion grooves, in which the insertion grooves are formed to have different depths according to the heights of the plurality of the electronic components.

The present invention provides various aspects for processing multiple types of substrates within cleanspace fabricators or for processing multiple or single types of substrates in multiple types of cleanspace environments particularly to form hardware based encryption devices and hardware based encryption equipped communication devices and multi-chip modules such as chiplets. In some embodiments, a collocated composite cleanspace fabricator may be capable of processing semiconductor devices into integrated circuits and then performing assembly operations to result in product in packaged form. Customized smart devices, smart phones and touchscreen devices may be fabricated in examples of a cleanspace fabricator. The assembly processing may include steps to form hardware based encryption.

A stretchable mounting substrate that includes: a stretchable wiring substrate, the stretchable wiring substrate including a stretchable base material and a stretchable wiring arranged on the stretchable base material; and a module on a surface of the stretchable wiring substrate, the module including a multilayer substrate, a plurality of electronic components on a principal surface of the multilayer substrate, a plurality of first electrodes and a plurality of second electrodes, and internal wirings inside the multilayer substrate. The module has a first electrode arrangement region where the plurality of first electrodes are arranged and a second electrode arrangement region where the plurality of second electrodes are arranged, and includes a node electrode pair, and the internal wiring of the node electrode pair and the stretchable wiring on the stretchable base material intersect each other in plan view of the stretchable wiring substrate.

The invention relates to a magnetic core (1) of an electronic arrangement, comprising a center region (3), a base (4a), which is formed in the shape of a planar plate, and a cover (4b), wherein the center region (3) is arranged between the base (4a) and the cover (4b), wherein a through-opening (2) with a center line (X) is formed in the center region (3), wherein a first cross-sectional area (9) of the magnetic core (1) in a first section plane (6), which is parallel to the base (4a) and in which the center line (X) is located, is substantially equal to a second cross-sectional area (8) of the magnetic core (1) in a second section plane (7), which is perpendicular to the first section plane (6) and in which the center line (X) is located, and wherein the base (4a) and the cover (4b) protrude beyond the center region (3) in the direction of the center line (X) on at least two mutually opposing sides.

A circuit board according to the embodiment includes a first substrate including a first insulating layer and a first pad disposed on an upper surface of the first insulating layer; a second substrate including a second insulating layer including a via hole and a metal layer formed on upper and lower surfaces of the second insulating layer and an inner wall of the via hole; a third insulating layer disposed between the first substrate and the second substrate and having a first opening in a region overlapping the via hole; a via filling the via hole and disposed on the first pad exposed through the opening of the third insulating layer; and a second pad disposed on the via and the metal layer disposed on an upper surface of the second insulating layer.

A sensor apparatus according to an embodiment of the present technology includes a substrate, one or more first IMU sensors, and one or more second IMU sensors. The substrate has a first surface and a second surface opposite to the first surface. The one or more first IMU sensors are arranged on the first surface. The one or more second IMU sensors are arranged on the second surface. By arranging the IMU sensors on both the first surface and the second surface, it is possible to reduce the size the apparatus and to suppress a deformation of the substrate due to heat. This makes it possible to realize a highly accurate measurement based on a detection result (sensing result) of a plurality of IMU sensors.

A solid-state imaging device according to the present disclosure includes a light-receiving substrate, a circuit board, and a plurality of first connections. The light-receiving substrate includes a plurality of light-receiving circuits provided with photoelectric conversion elements. The circuit board is directly bonded to the light-receiving substrate and includes a plurality of address event detection circuits that detects individual changes in voltages output from the photoelectric conversion elements of the plurality of light-receiving circuits. The plurality of first connections is provided at a joint between the light-receiving substrate and the circuit board to electrically connect the light-receiving circuits and the address event detection circuits corresponding to each other.