Abstract: Three-dimensional electromagnetic field analysis is performed for a plurality of positional patterns of a first wiring board internal structure model including one glass cloth on the upper side of differential lines and also for a plurality of positional patterns of a second wiring board internal structure model including one glass cloth on the lower side of differential lines to calculate skews, and the calculated skews are summed relating to a plurality of wiring board patterns configured by combining a plurality of combination patterns obtained by combining the plurality of positional patterns of the first model and a plurality of combination patterns obtained by combining the plurality of positional patterns of the second model to calculate a total skew and then a skew distribution in a wiring board having a certain line length is acquired based on the total skew.

Abstract: A circuit board includes an insulating layer, a capacitor which is provided in the insulating layer and includes a dielectric layer, a first conductor layer provided on a first surface of the dielectric layer and including a first opening part, and a second conductor layer provided on a second surface opposite to the first surface of the dielectric layer and including a second opening part at a position corresponding to the first opening part; a first conductor via provided in the insulating layer, penetrating the dielectric layer, the first opening part and the second opening part, and being smaller than the first opening part and the second opening part in plan view; a second conductor via provided in the insulating layer and making contact with the second conductor layer; and a third conductor layer provided on the insulating layer and electrically coupled to the first and the second conductor vias.

Abstract: A circuit board includes: an insulating layer; a capacitor which is provided in the insulating layer and which includes a dielectric layer, a first conductor layer provided on a first surface of the dielectric layer and including an opening part, and a second conductor layer provided on a second surface opposite to the first surface of the dielectric layer and including a recess part at a position corresponding to the opening part; and a conductor via provided in the insulating layer, penetrating the dielectric layer, the opening part and the recess part, being in contact with the recess part, and being smaller than the opening part in plan view.

Abstract: A wiring board includes: an insulating layer that includes a first surface over which an electronic component is mounted and a second surface opposite to the first surface; a conductive layer that is disposed on the second surface; a via that is provided inside a first through-hole that penetrates a portion between the first surface and the second surface of the insulating layer; an electrode that is disposed on the first surface and connected to the via; and a glass plate that is not contact with the conductive layer and is disposed on the first surface and includes a second through-hole through which the electrode is disposed.

Abstract: A substrate includes: a signal line via, a ground line via, and a power supply line via; a first group of first conductor layers formed at a first wiring layer level and coupled to the signal line via, the ground line via, and the power supply line via; a second conductor layer formed at a second wiring layer level and coupled to the power supply line via; a second group of third conductor layers formed at a third wiring layer level and coupled to the signal line via, the ground line via, and the power supply line via; a first insulating layer; and a second insulating layer, wherein the second insulating layer has an opening with a third insulating layer, a relative dielectric constant of the second insulating layer is higher than the first insulating layer and the third insulating layer, and the opening reaches a conductor pattern.

Abstract: A board includes a plate-shaped member having a first wiring pattern, a first resin layer formed on a first surface of the plate-shaped member, the first surface having the first wiring pattern, a second resin layer stacked on the first resin layer, and a component fixed to the second resin layer in which a second wiring pattern formed on a second surface of the component is buried.

Abstract: A wiring substrate includes: a substrate; an insulator formed in the substrate and having a through hole; an electrode formed in the substrate and provided within the through hole; and a conductor bonded to the electrode and provided within the through hole, wherein the through hole has a shape that is widened toward a direction away from the substrate, and the conductor is configured to cover the entire top surface of the electrode and has a shape that is widened toward the direction away from the substrate.

Abstract: A circuit board includes a substrate, a first ground electrode group, and a first pair of signal electrodes. The first ground electrode group includes a plurality of first ground electrodes, where each of the plurality of the first ground electrodes is disposed at a corresponding one of vertexes of a first rectangular area in a surface of the substrate. the first pair of signal electrodes is disposed in the first rectangular area and is arranged in a first direction parallel to a side of the first rectangular area.

Abstract: A multilayer circuit board with a laminated structure includes an outermost insulating layer provided as an uppermost or bottom layer of the multilayer circuit board and formed of a composite material containing a glass fiber; and a multilayer interconnect lamination provided as an adjacent layer next to the outermost insulating layer, the multilayer interconnect lamination having an interconnect provided in an insulating resin layer that does not contain a glass fiber, and an interlayer via electrically connected to the interconnect.

Abstract: A wiring substrate includes: a substrate; an insulator formed in the substrate and having a through hole; an electrode formed in the substrate and provided within the through hole; and a conductor bonded to the electrode and provided within the through hole, wherein the through hole has a shape that is widened toward a direction away from the substrate, and the conductor is configured to cover the entire top surface of the electrode and has a shape that is widened toward the direction away from the substrate.

Abstract: A semiconductor device manufacturing method includes: a first-process for placing, on a first-substrate on which traces and first-electrodes are formed, each of the first-electrodes being connected to one of traces, a second-substrate in which through-holes corresponding to the first-electrodes and relay-members are disposed, each of the relay-members being formed of solder, penetrating through one of the through-holes, and projecting from both ends of the one of the through-holes, so that the first-electrodes are aligned with the through-holes in a plan view; a second-process for melting the relay-members so that the relay-members are connected to the first-electrodes, after the first-process; and a third-process for placing a semiconductor substrate on which a second-electrodes corresponding to the first-electrodes are formed on a side opposite to the first-substrate across the second-substrate, after the second-process, to connect the first-electrodes and the second-electrodes to each other via the relay-m

Abstract: A semiconductor device manufacturing method includes: a first-process for placing, on a first-substrate on which traces and first-electrodes are formed, each of the first-electrodes being connected to one of traces, a second-substrate in which through-holes corresponding to the first-electrodes and relay-members are disposed, each of the relay-members being formed of solder, penetrating through one of the through-holes, and projecting from both ends of the one of the through-holes, so that the first-electrodes are aligned with the through-holes in a plan view; a second-process for melting the relay-members so that the relay-members are connected to the first-electrodes, after the first-process; and a third-process for placing a semiconductor substrate on which a second-electrodes corresponding to the first-electrodes are formed on a side opposite to the first-substrate across the second-substrate, after the second-process, to connect the first-electrodes and the second-electrodes to each other via the relay-m

Abstract: A wiring board includes a conductor formed on an inner wall of a through hole made in a core board, resin formed inside the conductor in the through hole, and, for example, a land formed over the conductor and the resin. Vias are formed over the land. The vias are connected to a plurality of connection regions of the land extending over the conductor and the resin in the through hole. The land is held by the vias connected to the plurality of connection regions. This controls the thermal expansion of the resin to a land side and therefore prevents a fracture of the land.

Abstract: An electric circuit apparatus includes: a first-circuit board that includes a first-through-hole, and a first-electrode disposed on a front side of the first-circuit-board; a second-circuit-board that is disposed on a back side of the first-circuit-board, the second-circuit-board including on the front side of the second-circuit-board a second-electrode associated with the first-through-hole; a semiconductor device that is disposed on the front side of the first-circuit-board, the semiconductor device including on a back side a third-electrode-associated with the first-electrode, and a fourth-electrode-associated with the second-electrode; a first-bonding-material that bonds the first-electrode and the-third-electrode; a second-bonding-material that bonds the second-electrode and the fourth-electrode while passing through the first-through-hole; and a support body that is disposed between the first-electrode and the second-circuit-board and that supports the first-circuit-board.

Abstract: A semiconductor device manufacturing method includes: a first-process for placing, on a first-substrate on which traces and first-electrodes are formed, each of the first-electrodes being connected to one of traces, a second-substrate in which through-holes corresponding to the first-electrodes and relay-members are disposed, each of the relay-members being formed of solder, penetrating through one of the through-holes, and projecting from both ends of the one of the through-holes, so that the first-electrodes are aligned with the through-holes in a plan view; a second-process for melting the relay-members so that the relay-members are connected to the first-electrodes, after the first-process; and a third-process for placing a semiconductor substrate on which a second-electrodes corresponding to the first-electrodes are formed on a side opposite to the first-substrate across the second-substrate, after the second-process, to connect the first-electrodes and the second-electrodes to each other via the relay-m

Abstract: A semiconductor device includes a first circuit base member including a surface having multiple first electrodes formed thereon, a second circuit base member being provided above the first circuit base member and having first through holes and second through holes formed respectively above the first electrodes, a semiconductor package provided above the second circuit base member, and multiple first bumps provided inside the first through holes and the second through holes to connect the first electrodes to the semiconductor package.

Abstract: There is provided a circuit board to which a solder ball composed of a lead (Pb)-free solder is to be connected, a semiconductor device including an electrode and a solder ball composed of a lead (Pb)-free solder disposed on the electrode, and a method of manufacturing the semiconductor device, in which mounting reliability can be improved by enhancing the bonding strength (adhesion strength) between the solder ball composed of a lead (Pb)-free solder and the electrode.

Abstract: Three-dimensional electromagnetic field analysis is performed for a plurality of positional patterns of a first wiring board internal structure model including one glass cloth on the upper side of differential lines and also for a plurality of positional patterns of a second wiring board internal structure model including one glass cloth on the lower side of differential lines to calculate skews, and the calculated skews are summed relating to a plurality of wiring board patterns configured by combining a plurality of combination patterns obtained by combining the plurality of positional patterns of the first model and a plurality of combination patterns obtained by combining the plurality of positional patterns of the second model to calculate a total skew and then a skew distribution in a wiring board having a certain line length is acquired based on the total skew.

Abstract: A circuit board includes a substrate, a first ground electrode group, and a first pair of signal electrodes. The first ground electrode group includes a plurality of first ground electrodes, where each of the plurality of the first ground electrodes is disposed at a corresponding one of vertexes of a first rectangular area in a surface of the substrate. the first pair of signal electrodes is disposed in the first rectangular area and is arranged in a first direction parallel to a side of the first rectangular area.

Abstract: A semiconductor device manufacturing method includes: a first-process for placing, on a first-substrate on which traces and first-electrodes are formed, each of the first-electrodes being connected to one of traces, a second-substrate in which through-holes corresponding to the first-electrodes and relay-members are disposed, each of the relay-members being formed of solder, penetrating through one of the through-holes, and projecting from both ends of the one of the through-holes, so that the first-electrodes are aligned with the through-holes in a plan view; a second-process for melting the relay-members so that the relay-members are connected to the first-electrodes, after the first-process; and a third-process for placing a semiconductor substrate on which a second-electrodes corresponding to the first-electrodes are formed on a side opposite to the first-substrate across the second-substrate, after the second-process, to connect the first-electrodes and the second-electrodes to each other via the relay-m