An apparatus for absorbing electrical noise on cables that includes a housing which contains two partial shells, each partial shell receiving one element which is composed of a material which decreases or absorbs noise. In a closed state, two end sides of the housing each have one opening for a cable to be routed through. The apparatus further includes at least one fixing means for securing the housing to the cable, with the fixing means being arranged on at least one end side of the housing in the region of the opening, and having at least two clips, the limbs of which face one another and can be deformed transverse to the cable and form a slot for receiving the cable in a clamping manner between them. The limbs of the two clips running parallel to one another.

In electronic devices, as a result of miniaturization, the distance between a mounting board and an upper board or a shield case and the like, or the distance between the mounting board and other electronic components mounted adjacent thereto has become smaller. An electronic component is provided with: an element body internally containing a circuit element; and a terminal formed on the element body. The terminal is formed over an end surface of the element body and a surface adjacent to the end surface. An insulating film covering the terminal is formed on the element body. The terminal is exposed from the insulating film at least at a mounting surface of the element body, and a plating film containing tin is formed on a portion of the terminal exposed from the insulating film.

A coil component includes a coil and a composite magnetic material containing magnetic particles. The magnetic particles have an average minor-axis length of more than 5.0 nm and 50 nm or less and an average aspect ratio of 2.0 or more and 10.0 or less. The magnetic particles are orientated substantially perpendicularly to a central axis of the coil and are orientated randomly within a perpendicular plane to the central axis of the coil. The composite magnetic material has a saturation magnetization s of 80.0 emu/g or more.

An element body includes a first function portion including a first material, a second function portion including a second material different from the first material, and an intermediate portion placed between the first function portion and the second function portion. The intermediate portion includes a first component included in the first material, and a second component included in the second material. A side surface of the element body includes surfaces of the first function portion, the second function portion, and the intermediate portion. Each of terminal electrodes includes electrode portion formed on the side surface across the surfaces of the first function portion, the second function portion, and the intermediate portion. An insulating layer is formed on the side surface in such a manner as to be in contact with at least a region exposed from the electrode portions between the electrode portions in the surface of the intermediate portion.

An inductive-capacitive filter includes a first insulating-conductive strip wound around a winding axis, where the first insulating-conductive strip includes a first conductive strip joined with a first insulating strip. An inductive-capacitive filter assembly includes a first and a second insulating-conductive strip concentrically wound around a winding axis, the first insulating-conductive strip including a first conductive strip joined with a first insulating strip, and the second insulating-conductive strip including a second conductive strip joined with a second insulating strip.

A magnetoresistance effect device includes a first port, a second port, a first circuit unit and a second circuit unit which are connected in series between the first port and the second port, a shared reference electric potential terminal or a first reference electric potential terminal and a second reference electric potential terminal, and a shared DC application terminal or a first DC application terminal and a second DC application terminal, wherein the first circuit unit and the second circuit unit include a magnetoresistance effect element and a conductor connected to one end thereof, a first end portion of the conductor is connected to a high-frequency current input side, and a second end portion of the first conductor is connected to the shared reference electric potential terminal, the first reference electric potential terminal or the second reference electric potential terminal.

An inductor according to an embodiment of the present invention comprises: a first magnetic body having a toroidal shape, and including a ferrite; and a second magnetic body disposed on an outer circumferential surface or an inner circumferential surface of the first magnetic body, wherein the second magnetic body includes: resin material and a plurality of layers of metal ribbons wound along the circumferential direction of the first magnetic body, wherein the resin material comprises a first resin material disposed to cover an outer surface of the plurality of layers of metal ribbons, and a second resin material disposed in at least a part of a plurality of layers of interlayer spaces.

An LC composite device includes a capacitor portion, an inductor portion, and a magnetic body portion. The capacitor portion is configured of a first substrate and a thin film capacitance element formed on the first substrate through a thin film process. The inductor portion is configured of a second substrate and a thin film inductance element formed on the second substrate through a thin film process. The magnetic body portion includes a magnetic substrate, and the capacitor portion. The inductor portion and the magnetic body portion are stacked in a positional relationship in which the magnetic body portion and the inductor portion are in contact with each other.

The invention specifies an inductive component for a busbar. The inductive component has two air gaps which are arranged on opposite sides of the component, wherein the air gaps are at a distance from one another in a vertical direction of the component.

An LC composite component includes a magnetic substrate with magnetism, a magnetic layer with magnetism, inductors, capacitors, and core parts with magnetism. The magnetic substrate includes a first surface and a second surface on a side opposite to the first surface. The magnetic layer is disposed to face the first surface of the magnetic substrate. The inductors and the capacitors are disposed between the first surface of the magnetic substrate and the magnetic layer. The core parts are disposed between the first surface of the magnetic substrate and the magnetic layer and connected to the magnetic layer. The thickness of the core part is 1.0 or more times the thickness of the magnetic layer, the thickness of the magnetic substrate is 1.0 or more times the thickness of the magnetic layer.