One object of the present invention is to enable identification of the direction of an electronic component, while suppressing increase in cost. The present invention provides an electronic component comprising: an insulator portion having a plurality of surfaces (e.g., a top surface, a bottom surface, end surfaces, and side surfaces), the insulator portion including a plurality of regions having different transmissivities of a light beam entering one of the plurality of surfaces (e.g., a top surface, a bottom surface, end surfaces, and side surfaces); an internal conductor portion provided in the insulator portion; and external electrodes provided on the insulator portion and electrically connected to the internal conductor portion.

A thin film capacitor includes a body including a dielectric layer, a first internal electrode layer and a second internal electrode layer, a melting point of a material included in the first internal electrode layer being lower than a melting point of a material included in the second internal electrode layer, and a first external electrode and a second external electrode disposed on an upper surface of the body, the second internal electrode layer being disposed on an upper surface of the first internal electrode layer and a lower surface of the first internal electrode layer opposing the upper surface of the first internal electrode layer.

A thin film capacitor includes a body including a dielectric layer, a first internal electrode layer and a second internal electrode layer, a melting point of a material included in the first internal electrode layer being lower than a melting point of a material included in the second internal electrode layer, and a first external electrode and a second external electrode disposed on an upper surface of the body, the second internal electrode layer being disposed on an upper surface of the first internal electrode layer and a lower surface of the first internal electrode layer opposing the upper surface of the first internal electrode layer.

A capacitor that includes a substrate having a first main surface and a second main surface that are opposite to each other, and a plurality of trench portions on the first main surface; a dielectric film adjacent the first main surface of the substrate and extending into interiors of the plurality of trench portions; a conductor film on the dielectric film and extending into the interiors of the plurality of trench portions; and a bonding pad electrically connected to the conductor film. In a plan view from a direction normal to the first main surface of the substrate, the plurality of trench portions are arranged in second regions disposed along a second direction and not in first regions disposed along a first direction in which a bonding wire electrically connected to the bonding pad extends.

Certain aspects of the present disclosure provide a metal-on-metal (MoM) capacitor with metal layers, each layer having two different electrical conductors with orthogonally-arranged conductive arteries and orthogonally-oriented conductive fingers. One exemplary MoM capacitor generally includes a plurality of metal layers, wherein a first metal layer in the plurality of metal layers comprises a first electrical conductor providing a first node of the MoM capacitor and a second electrical conductor providing a second node of the MoM capacitor. According to aspects, the first electrical conductor comprises a first plurality of conductive fingers and the second electrical conductor comprises a second plurality of conductive fingers. Further, conductive fingers of the first plurality of conductive fingers are interdigitated with conductive fingers of the second plurality of conductive fingers. Additionally, the first electrical conductor in the first metal layer is oriented orthogonal to the second electrical conductor in the first metal layer.

Certain aspects of the present disclosure provide a metal-on-metal (MoM) capacitor with metal layers, each layer having two different electrical conductors with orthogonally-arranged conductive arteries and orthogonally-oriented conductive fingers. One exemplary MoM capacitor generally includes a plurality of metal layers, wherein a first metal layer in the plurality of metal layers comprises a first electrical conductor providing a first node of the MoM capacitor and a second electrical conductor providing a second node of the MoM capacitor. According to aspects, the first electrical conductor comprises a first plurality of conductive fingers and the second electrical conductor comprises a second plurality of conductive fingers. Further, conductive fingers of the first plurality of conductive fingers are interdigitated with conductive fingers of the second plurality of conductive fingers. Additionally, the first electrical conductor in the first metal layer is oriented orthogonal to the second electrical conductor in the first metal layer.

There is provided a multilayered ceramic capacitor, including: a ceramic body; an active layer including a plurality of first and second internal electrodes; an upper cover layer; a lower cover layer formed below the active layer, the lower cover layer being thicker than the upper cover layer; first and second external electrodes; at least one pair of first and second internal electrodes repeatedly formed inside the lower cover layer, wherein, when A is defined as of an overall thickness of the ceramic body, B is defined as a thickness of the lower cover layer, C is defined as of an overall thickness of the active layer, and D is defined as a thickness of the upper cover layer, a ratio of deviation between a center of the active layer and a center of the ceramic body, (B+C)/A, satisfies 1.063(B+C)/A1.745.

A composite electronic component includes: a composite body in which a multilayer ceramic capacitor and a ceramic chip are coupled to each other. The multilayer ceramic capacitor includes a first ceramic body, and first and second external electrodes disposed on both end portions of the first ceramic body. The ceramic chip includes a second ceramic body disposed on a lower portion of the multilayer ceramic capacitor, and first and second terminal electrodes disposed on both end portions of the second ceramic body and connected to the first and second external electrodes. A width of first regions of the second ceramic body in which the first and second terminal electrodes are disposed is wider than a width of a second region of the second ceramic body between the first regions.

A film capacitor includes a wound body in which a dielectric film and an electrode film are wound; and a pair of external electrodes provided respectively on a pair of end faces positioned in an axial direction of the wound body. The dielectric film includes an electrode-free portion provided on one end side in a width direction, continuously in a longitudinal direction of the dielectric film. The electrode film has a first projection portion on a surface on the other end side in the width direction, and the first projection portion has a string shape extending in the width direction.

A film capacitor includes a wound body in which a dielectric film and an electrode film are wound; and a pair of external electrodes provided respectively on a pair of end faces positioned in an axial direction of the wound body. The dielectric film includes an electrode-free portion provided on one end side in a width direction, continuously in a longitudinal direction of the dielectric film. The electrode film has a first projection portion on a surface on the other end side in the width direction, and the first projection portion has a string shape extending in the width direction.