When a semiconductor package is stored in a transport tray and when a semiconductor package is transported by a transport tray, the semiconductor package comes into contact with the side wall of the transport tray, so that the end face of the semiconductor package is chipped and dust is generated from the end face of the semiconductor package. Provided is a technology for a semiconductor package that includes a multilayer structure having at least a synthetic resin layer and includes an outermost edge portion such that the end face of the synthetic resin layer protrudes outward compared to the end faces of the other layers constituting the multilayer structure.

A substrate has a front side including an electrical circuit and a rear side including an exposed zone that faces the electrical circuit. In an electrochemical treatment step, an electrical potential is laterally applied at least to the exposed zone of the rear side of the substrate, while the exposed zone is in contact with a chemically reactive substance. The electrical potential causes a lateral flow of electrical current at least in the exposed zone of the substrate. The lateral flow of current and the chemically reactive substance alter the substrate in at least the exposed zone.

An electronic component mounted body includes a substrate, a connection section provided on the substrate, an electronic component having a terminal connected to the connection section, and a solder that fixes the electronic component to the connection section. The connection section has a first region in which the terminal is fixed through the solder, and a second region lower in wettability than the first region, and the second region has an extension region extended to a peripheral edge of the connection section, and a spaced region that projects from the extension region toward the first region and that is provided to be spaced from the peripheral edge.

A high frequency module includes a power amplifier and a substrate on which the power amplifier is mounted. The power amplifier includes a first external terminal and a second external terminal formed on a mounting surface. The substrate includes a first land electrode and a second land electrode formed on one principal surface. The first external terminal is connected to the first land electrode, and the second external terminal is connected to the second land electrode. A distance from the mounting surface to a connection surface of the first external terminal is shorter than a distance from the mounting surface to a connection surface of the second external terminal, and a distance from a connection surface of the first land electrode to the one principal surface is longer than a distance from a connection surface of the second land electrode to the one principal surface.

A radio frequency module includes a first substrate having a first principal surface and a second principal surface on the opposite side to the first principal surface; a signal terminal which is provided on the first principal surface and through which a signal is transmitted to and received from an external circuit; a power supply terminal that is provided on the second principal surface and is supplied with a power supply signal; an antenna; and a radio frequency electronic component that is electrically connected to the signal terminal, the power supply terminal and the antenna, and controls transmission and reception of the antenna based on the signal and the power supply signal.

A power electronics submodule for mounting on a cooling device, has first and second surface sections next to one another, a substrate with a housing and includes a connection element, conductively connected by a contact to a track of the substrate and a connection section, arranged parallel to the substrate, the substrate arranged on the first surface section, the housing has a housing section, with a first main surface, arranged on the second surface section, and a second main surface, situated opposite the first main surface. In a non-mounted state a first main surface of the connection section is a first distance from the second main surface of the housing section in the housing region of a fastening device.

A power electronics submodule for mounting on a cooling device, has first and second surface sections next to one another, a substrate with a housing and includes a connection element, conductively connected by a contact to a track of the substrate and a connection section, arranged parallel to the substrate, the substrate arranged on the first surface section, the housing has a housing section, with a first main surface, arranged on the second surface section, and a second main surface, situated opposite the first main surface. In a non-mounted state a first main surface of the connection section is a first distance from the second main surface of the housing section in the housing region of a fastening device.

A display device includes a plate-like substrate having a first surface and a second surface, pixel units on the first surface, and a power supply voltage feeder on the second surface. The power supply voltage feeder outputs first and second power supply voltages applicable to the pixel units. The second power supply voltage is lower in potential than the first power supply voltage. The display device includes a first wiring conductor electrically connecting the power supply voltage feeder and the pixel units and a second wiring conductor electrically connecting the power supply voltage feeder and the pixel units. At least one of the first or second wiring conductor includes a planar conductive portion covering the first surface. The planar conductive portion includes connectors connected to the power supply voltage feeder on at least two sides of the substrate.

There is provided a method of manufacturing a multilayer wiring board including: alternately stacking wiring layers and insulating layers; stacking a reinforcing sheet having openings on one surface of the resulting multilayer laminate with a soluble adhesive layer therebetween; contacting or infiltrating the soluble adhesive layer with a liquid capable of dissolving the soluble adhesive layer through the openings to thereby dissolve or soften the soluble adhesive layer; and releasing the reinforcing sheet from the multilayer laminate at the position of the soluble adhesive layer. This method enables the multilayer wiring layer to be reinforced so as to generate no large local warpage, thereby improving the reliable connection in the multilayer wiring layer and the flatness (coplanarity) on the surface of the multilayer wiring layer. The reinforcing sheet having finished its role can be released in a significantly short time, while minimizing the stress applied to the multilayer laminate.

There is a method of manufacturing a multilayer wiring board including: alternately stacking wiring layers and insulating layers; stacking a reinforcing sheet on one surface of the resulting multilayer laminate with a soluble adhesive layer therebetween, wherein an unoccupied region without the soluble adhesive layer is provided within a facing area where the reinforcing sheet faces the multilayer laminate; allowing a liquid capable of dissolving the soluble adhesive layer to infiltrate the unoccupied region to dissolve or soften the soluble adhesive layer; and releasing the reinforcing sheet from the multilayer laminate at the soluble adhesive layer. This method enables the multilayer wiring layer to be reinforced to generate no large local warpage, thereby improving the reliable connection and the surface flatness (coplanarity) of the multilayer wiring layer. The used reinforcing sheet can be released in a significantly short time, while minimizing the stress applied to the multilayer laminate.