An integrated circuit (IC) device according to the present disclosure includes a substrate including a first surface and a second surface opposing the first surface, a redistribution layer disposed over the first surface and including a conductive feature, a passivation structure disposed over the redistribution layer, a metal-insulator-metal (MIM) capacitor embedded in the passivation structure, a dummy MIM feature embedded in the passivation structure and including an opening, a top contact pad over the passivation structure, a contact via extending between the conductive feature and the top contact pad, and a through via extending through the passivation structure and the substrate. The dummy MIM feature is spaced away from the MIM capacitor and the through via extends through the opening of the dummy MIM feature without contacting the dummy MIM feature.

A wiring board includes an insulating layer, a thin film capacitor laminated on the insulating layer, an interconnect layer electrically connected to the thin film capacitor, and an encapsulating resin layer laminated on the thin film capacitor. The interconnect layer includes a pad protruding from the thin film capacitor. The encapsulating resin layer is a mold resin having a non-photosensitive thermosetting resin as a main component thereof. The encapsulating resin layer exposes a top surface of the pad, and covers at least a portion of a side surface of the pad.

A leadwire for physiological patient monitoring is provided that transfers potentials received at a chest electrode to a data acquisition device. The leadwire includes an electrode end connectable to the chest electrode and a first conductive layer extending from the electrode end. The leadwire also has a device end connectable to a data acquisition device and a second conductive layer extending from the device end. The first conductive layer is galvanically isolated from the second conductive layer such that the first conductive layer and the second conductive layer form a capacitor.

A multilayer substrate module includes a first substrate portion including a first substrate portion body including first insulator layers stacked in a vertical direction and a first conductor layer and/or a first interlayer connection conductor provided at the first substrate portion body. A second substrate portion includes a second substrate portion body including second insulator layers stacked in the vertical direction and a second conductor layer and a second interlayer connection conductor provided at the second substrate portion body, and is mounted on an upper surface of the first substrate portion. A mount device is mounted on an upper surface or a lower surface of the second substrate portion. At least a portion of an inductance component is defined by the first conductor layer and the first interlayer connection conductor.

Embodiments described herein may be related to apparatuses, processes, and techniques directed to embedding capacitors in through glass vias within a glass core of a substrate. In embodiments, the through glass vias may extend entirely from a first side of the glass core to a second side of the glass core opposite the first side. Layers of electrically conductive material and dielectric material may then be deposited within the through glass via to form a capacitor. the capacitor may then be electrically coupled with electrical routings on buildup layers on either side of the glass core. Other embodiments may be described and/or claimed.

A circuit board having excellent reliability of connection between layers while being capable of achieving a compact and low-profile electronic device. In the circuit board has an LC circuit built therein with the use of a glass core having a through hole, a conductor layer formed in the through hole is connected to a wiring pattern formed on one surface of the glass core, and connected to a wiring pattern formed on the other surface of the glass core, with the conduction layer projected from the surface of the glass core. Thus, the area of contact between the conduction layer and the through hole is increased, thus making it possible to prevent the reliability of connection between layers in the through hole from being decreased, even when the glass core is reduced in thickness for achieving a low-profile device.

A surface mountable laser driver circuit package is configured to mount on a host printed circuit board (PCB). A surface mount circuit package includes a lead-frame. A plurality of laser driver circuit components is mounted on and in electrical communication with the lead-frame of the surface mount circuit package. A dielectric layer is located between the lead-frame and the host PCB and includes portals through the dielectric layer each arranged to accommodate an electrical connection between the lead-frame and the host PCB. The lead-frame and the dielectric layer are arranged such that a first lead-frame portion and a first dielectric layer portal align with a first end of a host PCB trace configured to provide a current return path for the surface mount laser driver, and a second lead-frame portion and a second dielectric layer portal align with a second end of the host PCB trace.

An electronic component comprising a glass body containing a photosensitizer; a conductor as at least a part of an electric element, arranged on the glass body; a terminal electrode as a terminal of the electric element, arranged above an outer surface of the glass body, with the terminal electrode being electrically connected to the conductor; and an insulating film arranged above the outer surface of the glass body. The insulating film reflects or absorbs light in a photosensitive wavelength range of the photosensitizer contained in the glass body.

A surface mount transmission line capacitor can have excellent high frequency performance characteristics. The surface mount transmission line capacitor can include a monolithic substrate having a surface, a first electrode formed over the surface, a second electrode arranged over the first electrode, a dielectric layer arranged between the first electrode and second electrode, a first terminal layer exposed along the surface of the substrate and electrically connected with the first electrode, and a second terminal layer exposed along the surface of the substrate and electrically connected with the second electrode. The first terminal layer and the second terminal layer can be contained within a perimeter of the surface of the monolithic substrate.

There is provided an electric toothbrush including a toothbrush head, a toothbrush handle and a force sensing array. The force sensing array is arranged on the toothbrush head and/or the toothbrush handle. When the force sensing array is arranged on the toothbrush head, it is able to detect the force uniformity of brush hairs. When the force sensing array is arranged on the toothbrush handle, it is able to control the vibration strength of the brush hairs and detect the pressing force of the brush hairs.