A discrete time filter network with an input signal connection and an output signal connection and comprising a capacitor bank with a plurality of history capacitors, and at least one sampling capacitor which operates at a predetermined cycling rate to couple to at least one history capacitor at a time, which history capacitor is selected from the capacitor bank so as to share electrical charge between such selected history capacitor and the sampling capacitor, wherein there is a plurality of sampling capacitors that are provided in the capacitor bank, and the discrete time filter network is provided with at least one switch network comprising a plurality of clock driven switches for making selected cyclical connections between the sampling capacitors and the history capacitors in the capacitor bank at the predetermined cycling rate.

A capacitor component includes a body including a plurality of dielectric layers having a layered structure and a first internal electrode and a second internal electrode alternately disposed with respective dielectric layers of the plurality of dielectric layers disposed therebetween. A first external electrode is disposed on a first surface and a second surface of the body opposing each other, and is connected to the first internal electrode. A second external electrode is disposed on at least one of a third surface and a fourth surface of the body connecting the first surface to the second surface and opposing each other, and is connected to the second internal electrode. The first internal electrode and the second internal electrode provide a plurality of resonance frequencies. In some examples, each of the first internal electrode and the second internal electrode is divided into a plurality of regions spaced apart from each other.

A linear, low noise, high quality factor (Q) and widely tunable notch filter circuit includes one or more first reactive elements coupled between a first filter node and a first node. The notch filter circuit further includes a multi-branch circuit having multiple parallel branches and coupled between the first node and a second node. Each branch of the multi-branch circuit includes at least a switch coupled to a variable capacitor. A notch frequency of the notch filter circuit is tunable by adjusting a capacitance of the variable capacitor.

A filter for both a differential mode and a common mode is provided. A filter for both a differential mode and a common mode according to an embodiment of the present invention comprises: a pair of series inductors having a plurality of coil patterns; two pairs of parallel capacitors connected to opposite ends of the pair of inductors, respectively; and a pair of series capacitors connected to the pair of inductors in parallel. Therefore, the filter can be used in both a common mode and a differential mode, and can remove noise without using an additional filter in an application having a comparatively high data processing speed.

A system that incorporates teachings of the present disclosure may include, for example, a first solid electrode, a second electrode separated into subsections, and a dielectric medium separating the subsections from the first solid electrode, where the subsections of the second electrode include a first group of subsections and a second group of subsections, where the first group of subsections are connectable with a first terminal for receiving an input signal, and where the second group of subsections is connectable with a second terminal for providing an output signal. Other embodiments are disclosed.

A feedthrough subassembly for an active implantable medical device includes a metallic ferrule having a conductive ferrule body, at least one surface disposed on a device side, and a ferrule opening passing through the at least one surface. An insulator body hermetically seals the ferrule opening of the conductive ferrule body by at least one of a first gold braze ceramic seal, a glass seal or a glass-ceramic seal. At least one hermetically sealed conductive pathway is disposed through the insulator body. At least one pocket formed in the at least one surface has a gold pocket pad disposed within. When the first gold braze ceramic seal is present, the first gold braze ceramic seal and the gold pocket pad are not physically touching one another.

Disclosed are apparatus and a method for providing an integrated multi-terminal multilayer ceramic device that has three or more capacitive elements. Two of such capacitive elements may be in series, with a third in parallel. The integrated device may be packaged as an overmolded three leaded component, or can be mounted as SMD (surface mount device). The integrated device may also be combined with a separate varistor in a stacked arrangement of leaded components.

A front-surface-side 3-terminal capacitor and a rear-surface-side 3-terminal capacitor are disposed respectively on a front surface and a rear surface of a circuit substrate at opposing positions. A first outer terminal and a second outer terminal of the front-surface-side 3-terminal capacitor are electrically connected to hot-side conductor patterns and, respectively. Third outer terminals and of the rear-surface-side 3-terminal capacitor are electrically connected to ground-side conductor patterns and, respectively. Third outer terminals and of the front-surface-side 3-terminal capacitor are electrically connected to a first outer terminal and a second outer terminal of the rear-surface-side 3-terminal capacitor by employing vias and, respectively. The front-surface-side 3-terminal capacitor and the rear-surface-side 3-terminal capacitor are thereby electrically connected in series.

A capacitor may include a first capacitor plate having a first length. The capacitor may also include an inorganic capacitor dielectric layer on sidewalls and a surface of the first capacitor plate and a second capacitor plate on the inorganic capacitor dielectric layer. The second capacitor plate may have a second length less than the first length of the first capacitor plate. The capacitor may also include a conductive contact landing directly on the first capacitor plate. The conductive contact may land directly on the first capacitor plate by extending through the inorganic capacitor dielectric layer and an organic interlayer dielectric supported by the inorganic capacitor dielectric layer.

A tunable capacitance circuit comprises a plurality of varactor transistors which are coupled in series. An antenna tuner comprises such a tunable capacitance circuit.