One object of the present invention is to provide a compact coil component with superior characteristics. An electronic component according one embodiment includes an insulator and a coil portion. The insulator is formed of a non-magnetic material. The insulator includes a width direction in a first axial direction, a length direction in a second axial direction, and a height direction in a third axial direction. The coil portion includes a circumference section. The circumference section is wound around the first axial direction. The coil portion is arranged inside the insulator. The first ratio of a height to a length of the insulator is 1.5 times or less of a second ratio of a height between first inner peripheral portions of the circumference section along the third axial direction with respect to a length between second inner peripheral portions of the circumference section along the second axial direction.

A multilayer inductor component includes an element body that is an insulator and a coil in which a plurality of coil conductor layers that extend along planes in the element body are electrically connected to each other. Also, each of the coil conductor layers includes metal part and glass part, and the glass part include internal glass portion that is entirely included in the metal part.

In a multilayer coil component, a plurality of coil conductors are stacked in a coil axis direction. A connecting conductor connects the coil conductors adjacent to each other in the coil axis direction. First, second, and third coil conductors are arranged in order in the coil axis direction. A main body portion extends in a circumferential direction of the coil axis. Pad portions are connected to the main body portion, are connected to the first coil conductor via the connecting conductor, overhang from the third coil conductor in a direction away from the coil axis when viewed from the coil axis direction, and are inclined with respect to a virtual plane orthogonal to the coil axis direction.

There are provided a thin film coil and an electronic device having the same, the thin film coil including a substrate; and a coil pattern including a first coil strand and a second coil strand formed on both surfaces of the substrate, respectively, wherein the first coil strand formed on one surface of the substrate includes at least one gyration path that passes through the other surface of the substrate and gyrates.

A passive chip device includes a chip body, a conductive coil and a surface-mount contact unit. The chip body is in the form of a single piece, and has two opposite end faces and a first surface which is between the end faces. The conductive coil is deposited on and surrounding the chip body. The surface-mount contact unit includes two spaced apart conductive terminal contacts. Each of the terminal contacts extends from a respective one of the end faces to the first surface and connects to a respective one of end portions of the coil. The method of making the passive chip device is also disclosed.

An electronic package comprises an integrated circuit (IC) configured to receive a power input signal and to deliver a regulated power output signal. A multilayer electrical routing structure is attached to the IC and is configured to couple the electronic package to an external circuit. The multilayer routing structure has one or more electrical conductors on each of at least two layers which are configured to route the power input signal from the external circuit to the IC and to route the regulated power output signal from the IC to the external circuit. The one or more electrical conductors form an integrated inductive device having a respective portion disposed on each of the at least two layers and the power output signal is coupled to the external circuit through the integrated inductive device.

An electronic component according one embodiment of the disclosure includes an insulator, an internal conductor, and an external electrode. The insulator may be formed of a material that contains resin. The internal conductor is provided inside the insulator and includes a conductive main body and an outer coating film that is provided on at least a part of a peripheral surface of the conductive main body and has a resistivity higher than the conductive main body. The external electrode is disposed on the insulator and electrically coupled to the internal conductor.

In a stepwise structure formed in a multilayer coil component, a difference occurs in a shrinkage amount between a maximum film thickness portion in which the number of layers is large and a minimum film thickness portion in which the number of layers is small due to portions different in the number of layers of coil parts (that is, upper coil part, lower coil part, and connecting part) adjacent to each other like the maximum film thickness portion and the minimum film thickness portion, readily causing a crack by an inner stress due to the difference in the shrinkage amount. In a multilayer coil component according to the present disclosure, a stress relaxation part overlapping with a maximum film thickness portion whose shrinkage amount is large is provided to relax inner stress in a stepwise structure, resulting in prevention of a crack.

An electronic component module that includes a substrate, an inductor element, a single-sided functional component, a sealing resin, and an electromagnetic shield. The inductor element is mounted on the substrate. The single-sided functional component is mounted on a base ground conductor and a base signal conductor that are disposed on a side of the inductor element opposite to the substrate. The sealing resin has an insulating property and covers the inductor element, the base ground conductor, the base signal conductor, and the single-sided functional component. The electromagnetic shield covers the sealing resin, and a ground surface of the single-sided functional component.

A band pass filter includes a first filter circuit, a second filter circuit, a first intermediate circuit, a second intermediate circuit, and a ninth capacitor. The first intermediate circuit includes a seventh inductor connected between a fifth capacitor and a sixth capacitor. The second intermediate circuit includes an eighth inductor connected between a seventh capacitor and an eighth capacitor. The ninth capacitor is connected between the first intermediate circuit and the second intermediate circuit.