A method includes forming a first polymer layer over a plurality of metal pads, and patterning the first polymer layer to forming a plurality of openings in the first polymer layer. The plurality of metal pads are exposed through the plurality of openings. A plurality of conductive vias are formed in the plurality of openings. A plurality of conductive pads are formed over and contacting the plurality of conductive vias. A conductive pad in the plurality of conductive pads is laterally shifted from a conductive via directly underlying, and in physical contact with, the conductive pad. A second polymer layer is formed to cover and in physical contact with the plurality of conductive pads.

A semiconductor device and an amplifier assembly implementing the semiconductor device are disclosed. The semiconductor device, which is a type of Doherty amplifier, includes first transistor elements for a carrier amplifier of the Doherty amplifier and second transistor elements for a peak amplifier. A feature of the Doherty amplifier is that the first transistor elements and the second transistor elements are disposed alternatively on a common semiconductor substrate.

A semiconductor device and an amplifier assembly implementing the semiconductor device are disclosed. The semiconductor device, which is a type of Doherty amplifier, includes first transistor elements for a carrier amplifier of the Doherty amplifier and second transistor elements for a peak amplifier. A feature of the Doherty amplifier is that the first transistor elements and the second transistor elements are disposed alternatively on a common semiconductor substrate.

A semiconductor device includes: a chip; a circuit element formed in the chip; an insulating layer formed over the chip so as to cover the circuit element; a multilayer wiring region formed in the insulating layer and including a plurality of wirings laminated and arranged in a thickness direction of the insulating layer so as to be electrically connected to the circuit element; at least one insulating region which does not include the wirings in an entire region in the thickness direction of the insulating layer and is formed in a region outside the multilayer wiring region in the insulating layer; and at least one terminal electrode disposed over the insulating layer so as to face the chip with the at least one insulating region interposed between the at least one terminal electrode and the chip.

A device includes a first side interconnect structure over a first side of a substrate, wherein active circuits are in the substrate and adjacent to the first side of the substrate, a dielectric layer over a second side of the substrate, a pad embedded in the dielectric layer, the pad comprising an upper portion and a bottom portion formed of two different materials and a passivation layer over the dielectric layer.

A method may include forming a metal pattern in a metal layer of a fabricated integrated circuit device and under a target bump of the fabricated integrated circuit device, wherein the metal pattern has an inner shape and an outer field such that a void space in the metal layer is created between the inner shape and the outer field and approximately centering the void space on an outline of an under-bump metal formed under the target bump with a keepout distance from the inner shape and the outer field on either side of the outline such that the metal minimizes local variations in mechanical stress on underlying structures within the fabricated integrated circuit device.

A display apparatus includes: a substrate; a plurality of sub-pixel circuits on the substrate, each of the plurality of sub-pixel circuits including at least one transistor; a plurality of light-emitting diodes electrically connected to the plurality of sub-pixel circuits, respectively, and defining a display area; a pad at a non-display area outside the display area; a conductive line extending toward a first edge of the substrate; and a conductor electrically connecting the conductive line to the pad. The conductor overlaps with the pad, is interposed between a part of the conductive line and a part of the pad, and has an isolated shape in a plan view.

A semiconductor package includes: a semiconductor chip including a chip pad on a first surface; a first insulating layer arranged on the semiconductor chip and including an insulating hole exposing the chip pad; a redistribution pattern including a redistribution via pattern arranged on an internal surface of the first insulating layer configured to define the first insulating hole and on a surface of the chip pad, and a redistribution line pattern arranged on a surface of the first insulating layer; an under bump metal (UBM) conformally arranged along a surface of the redistribution pattern; and a connection terminal arranged on the UBM, wherein the redistribution line pattern and the UBM provide a dummy space of a shape protruding in a direction toward the first surface of the semiconductor chip, and a portion of the connection terminal fills the dummy space.

A semiconductor package includes: a semiconductor chip including a chip pad on a first surface; a first insulating layer arranged on the semiconductor chip and including an insulating hole exposing the chip pad; a redistribution pattern including a redistribution via pattern arranged on an internal surface of the first insulating layer configured to define the first insulating hole and on a surface of the chip pad, and a redistribution line pattern arranged on a surface of the first insulating layer; an under bump metal (UBM) conformally arranged along a surface of the redistribution pattern; and a connection terminal arranged on the UBM, wherein the redistribution line pattern and the UBM provide a dummy space of a shape protruding in a direction toward the first surface of the semiconductor chip, and a portion of the connection terminal fills the dummy space.

A semiconductor device includes: a chip; a circuit element formed in the chip; an insulating layer formed over the chip so as to cover the circuit element; a multilayer wiring region formed in the insulating layer and including a plurality of wirings laminated and arranged in a thickness direction of the insulating layer so as to be electrically connected to the circuit element; at least one insulating region which does not include the wirings in an entire region in the thickness direction of the insulating layer and is formed in a region outside the multilayer wiring region in the insulating layer; and at least one terminal electrode disposed over the insulating layer so as to face the chip with the at least one insulating region interposed between the at least one terminal electrode and the chip.