A multilayer ceramic capacitor includes a capacitor main body including a multilayer body including dielectric layers and internal electrode layers alternately laminated, and external electrodes at two end surfaces of the multilayer body and connected to the internal electrode layers, and two interposers on a surface of the capacitor main body, and opposed and spaced apart from each other. The two interposers each include a first surface at or adjacent to the capacitor main body, and a second surface opposite to the first surface, the first and second surfaces being parallel or substantially parallel with each other, and the first surface is sloped with respect to the surface of the capacitor main body at a predetermined angle to be spaced from the surface of the capacitor main body toward a side at which the two interposers face each other.

A composite electronic component includes a composite body including a multilayer ceramic capacitor including a first ceramic body in which dielectric layers and internal electrodes disposed to oppose each other with a respective one of the dielectric layers interposed therebetween are layered, and first and second external electrodes disposed on both ends of the first ceramic body; and a ceramic chip disposed below the multilayer ceramic capacitor and including a second ceramic body including ceramic, and first and second terminal electrodes disposed on both ends of the second ceramic body and respectively connected to the first and second external electrodes. A ratio (G1/M1) of a spacing distance (G1) between the first ceramic body and the second ceramic body in a thickness direction to a length (M1) of a margin portion between the internal electrode and a lower surface of the first ceramic body satisfies 1.0 to 2.5.

An electronic component includes a multilayer capacitor and an interposer. First and second internal electrodes of the multilayer capacitor are such that 0.95≤{(Wm1+Wm2)/Wa}/{(Lm1+Lm2)/La}≤4.93, in which Lm2 is a distance between a first internal electrode and a fourth surface of a capacitor body, Lm1 is a distance between a second internal electrode and a third surface of the capacitor body opposite the fourth surface in a first direction, Wm1 is a distance between the first or second internal electrode and a second surface of the capacitor body, Wm2 is a distance between the first or second internal electrode and a first surface of the capacitor body opposite the second surface in a third direction, La is a length in the first direction of a region of overlap of the first and second internal electrodes, and Wa is a length in the third direction of the region of overlap.

An electronic component and a board having the same mounted thereon are provided. The electronic component includes a capacitor body, a pair of external electrodes, respectively disposed on end portions of the capacitor body, a pair of metal frames, respectively disposed to be connected the pair of external electrodes, and a conductive bonding layer disposed between the external electrode and the metal frame and having a discontinuous region.

A multilayer ceramic capacitor includes an interposer including, on a side in a length direction, a first through conductive portion that penetrates the interposer in a stacking direction, and provides electrical conduction between a first joining electrode and a first mounting electrode. The interposer includes, on the other side in the length direction, a second through conductive portion that penetrates the interposer in the stacking direction, and provides electrical conduction between a second joining electrode and a second mounting electrode. The first mounting electrode includes a first portion that covers a portion of a first interposer end surface on the one side in the length direction of the interposer. The second mounting electrode includes a second portion that covers a portion of a second interposer end surface on the other side in the length direction of the interposer.

In a multilayer ceramic capacitor, an interposer includes, on a side of a first external electrode in a length direction, a first through hole that penetrates the interposer in a stacking direction, and provides electrical conduction between a first joining electrode and a first mounting electrode. The first through hole further includes a first metal film provided on an inner wall thereof. The interposer includes, on a side of a second external electrode in the length direction, a second through hole that penetrates the interposer in the stacking direction, and provides electrical conduction between a second joining electrode and a second mounting electrode. The second through hole further includes a second metal film provided on an inner wall thereof. A first uncovered portion is provided, which is not covered by the first metal film, on a first surface of the inner wall of the first through hole, and a second uncovered portion is provided which is not covered by a second metal film on the first surface of the inner wall of the second through hole.

In a multilayer ceramic capacitor, an interposer includes, on a side of a first external electrode in a length direction, a first through conductive portion that penetrates the interposer in a stacking direction, and provides electrical conduction between a first joining electrode and a first mounting electrode. The interposer includes, on a side of a second external electrode in the length direction, a second through conductive portion that penetrates the interposer in the stacking direction, and provides electrical conduction between a second joining electrode and a second mounting electrode. The first joining electrode includes a first portion that covers a portion of a first interposer end surface on the one side in the length direction of the interposer. The second joining electrode includes a second portion that covers a portion of a second interposer end surface on the other side in the length direction of the interposer.

A vibration isolator and method of assembly utilize “flex circuits” to provide both vibration/shock isolation and integrated electrically isolated conductive paths to support lightweight devices (<100 grams) such as crystal oscillators, IC chips, MEMs devices and the like. Each flex circuit includes a least one polymer layer and at least one of the flex circuits includes at least one patterned conductive layer. The isolator may be integrally formed from a stack of polymer layers and patterned conductive layers to provide the plurality of flex circuits, platform and connectors. Most typically, flex circuits are Type 4 in which the multiple polymer layers have a loose leaf or bonded configuration. Flex circuits are easy to produce in large quantities at low cost with standardized and repeatable performance characteristics.

A shock resistant fuselage system includes first and second fuselage side walls, each of the first and second fuselage side walls having a plurality of guide posts, and a printed circuit board (PCB) rigidly attached to at least one of the first and second fuselage side walls, the PCB having a plurality of guide slots, each of the plurality of guide posts slideably seated in a respective one of the plurality of guide slots so that elastic deformation of the PCB is guided by the guide slots between the first and second fuselage side walls.

Printed circuit board assembly (PCBA) technology is disclosed. A PCBA can include a printed circuit board (PCB). The PCBA can also include a capacitor operably mounted on a side of the PCB. In addition, the PCBA can include a damper material coupled to the PCB and operable to dissipate kinetic energy generated by the capacitor during operation. An electronic system including a capacitor and damping material, and a method for minimizing acoustic vibration in an electronic system are also disclosed.