A method of manufacturing a package structure is provided, including forming a first wiring layer on a carrier board, forming up plurality of first conductors on the first wiring layer, forming a first insulating layer that encapsulates the first wiring layer and the first conductors, forming a second wiring layer on the first insulating layer, forming a plurality of second conductors on the second wiring layer, forming a second insulating layer that encapsulates the second wiring layer and the second conductors, and forming at least an opening on the second insulating layer for at least one electronic component to be disposed therein. Since the first and second insulating layers are formed before the opening, there is no need of stacking or laminating a substrate that already has an opening, and the electronic component will not be laminated and make a displacement. Therefore, the package structure thus manufactured has a high yield rate. The present invention further provides the package structure.

A mounting structure for an electronic component and a method for mounting the electronic component are provided with a sufficient reinforcing effect for the relatively tall electronic component raised from a substrate. The mounting structure and the mounting method can easily respond to a change of the shape of the electronic component. In a mounting structure 1, a substrate 2 and an electronic component 4 raised on the substrate 2 are joined with bonding metal 3 and a reinforcing resin body 5 is bonded to the substrate 2 and the electronic component 4. The reinforcing resin body 5 includes a plurality of reinforcing resin layers 5a. The reinforcing resin layers 5a constituting the reinforcing resin body 5 are stacked in the height direction of the raised electronic component 4 along a side 4a of the electronic component 4 so as to be raised from the substrate 2.

An electronic part embedded substrate is disclosed. The electronic part embedded substrate includes a first substrate, a second substrate, an electronic part, an electrically connecting member, and a sealing member. A method of producing an electronic part embedded substrate is also disclosed. The method includes mounting an electronic part onto a first substrate, laminating a second substrate on the first substrate through an electrically connecting member; and filling a space between the first substrate and the second substrate with a sealing member to seal the electronic part.

A drive unit for driving a motor has a component assembly including a main circuit board having a component side and a solder side, one or more main circuit conductors formed in at least one layer of the main circuit board, a power component module including one or more power components, the power component module having electrical connection terminals for connecting the power component(s) to the one or more main circuit conductors of the main circuit board and a cooling plate coupled to the power component(s) in a manner enabling transfer of heat from the power component(s) to the cooling plate. The power component module is mounted to the component side of the main circuit board. The component assembly further includes a heat sink mounted on the cooling plate and a fan mounted on the heat sink.

To prevent decrease of the bonding strength of an electronic component and a multilayer substrate, an electronic component-embedded module may include an electronic component having a plurality of pads and a multilayer substrate which includes a plurality of resin layers and a cavity for containing the electronic component. The multilayer substrate may include a first resin layer having a plurality of first pattern conductors and a space, and a second resin layer having a second pattern conductor and a plurality of third pattern conductors. The plurality of third pattern conductors may be in conduction with either of the first pattern conductors or the pads, with the second resin layer being placed over the first resin layer. The second pattern conductor may be arranged around a first pad with a gap, and the second resin layer is present between the second pattern conductor and at least one of the first pads.

An integrated circuit that includes a substrate having a shape memory material (SMM), the SMM is in a first deformed state and has a first crystallography structure and a first configuration, the SMM is able to be deformed from a first configuration to a second configuration, the SMM changes to a second crystallography structure and deforms back to the first configuration upon receiving energy, the SMM returns to the first crystallography structure upon receiving a different amount of energy; and an electronic component attached to substrate. In other forms, the SMM is in a first deformed state and has a first polymeric conformation and a first configuration, the SMM changes from a first polymeric conformation to a second polymeric conformation and be deformed from a first configuration to a second configuration, the SMM changes returns to the first polymeric conformation and deforms back to the first configuration upon receiving energy.

An integrated circuit that includes a substrate having a shape memory material (SMM), the SMM is in a first deformed state and has a first crystallography structure and a first configuration, the SMM is able to be deformed from a first configuration to a second configuration, the SMM changes to a second crystallography structure and deforms back to the first configuration upon receiving energy, the SMM returns to the first crystallography structure upon receiving a different amount of energy; and an electronic component attached to substrate. In other forms, the SMM is in a first deformed state and has a first polymeric conformation and a first configuration, the SMM changes from a first polymeric conformation to a second polymeric conformation and be deformed from a first configuration to a second configuration, the SMM changes returns to the first polymeric conformation and deforms back to the first configuration upon receiving energy.

To prevent decrease of the bonding strength of an electronic component and a multilayer substrate, an electronic component-embedded module may include an electronic component having a plurality of pads and a multilayer substrate which includes a plurality of resin layers and a cavity for containing the electronic component. The multilayer substrate may include a first resin layer having a plurality of first pattern conductors and a space, and a second resin layer having a second pattern conductor and a plurality of third pattern conductors. The plurality of third pattern conductors may be in conduction with either of the first pattern conductors or the pads, with the second resin layer being placed over the first resin layer. The second pattern conductor may be arranged around a first pad with a gap, and the second resin layer is present between the second pattern conductor and at least one of the first pads.

An electronic component module includes a plurality of components having terminals and arranged along a plane, a sealing resin portion that covers and seals these components and has a plane as one plane of an outer surface, and a shield layer that covers the outer surface of the sealing resin portion. Terminals of the plurality of components are exposed in a state of protruding from the plane of the sealing resin portion, and the terminals of these components protruding from the plane of the sealing resin portion are used as mounting terminals of the electronic component module.

Provided are a maleimide resin composition containing (A) one or more selected from the group consisting of a maleimide compound having two or more N-substituted maleimide groups and a derivative thereof, (B) a modified conjugated diene polymer, and (C) a thermoplastic elastomer other than the above component (B), wherein the component (B) is one resulting from modification of (b1) a conjugated diene polymer having a vinyl group in the side chain with (b2) a maleimide compound having two or more N-substituted maleimide groups; and a prepreg, a resin film, a laminated board, a printed wiring board and a semiconductor package, each using the maleimide resin composition.