Shielded radio-frequency (RF) module having reduced area. In some embodiments, a method for fabricating a radio-frequency module includes forming or providing a packaging substrate configured to receive a plurality of components. The method may include mounting one or more devices on the packaging substrate such that the packaging substrate includes a first area associated with mounting of each of the one or more devices. In some embodiments, the method further includes forming a plurality of shielding wirebonds on the packaging substrate to provide RF shielding functionality for one or more regions on the packaging substrate, such that the packaging substrate includes a second area associated with formation of each shielding wirebond, the mounting of each device implemented with respect to a corresponding shielding wirebond such that a portion of the first area associated with the device overlaps at least partially with a portion of the second area associated with the corresponding shielding wirebond.

The present invention relates to an improved electronic circuit, as well as an improved substrate with electronic circuits, with an identification pattern. The invention makes it possible to make them identifiable and amongst other things to retrace the circuit(s) in this way through the production process. Furthermore, the invention relates to an improved production method for circuits and substrates according to the invention.

A method is provided. The method includes one or more of extracting a die from an original packaged integrated circuit, modifying the extracted die, reconditioning the modified extracted die, placing the reconditioned die into a cavity of a hermetic package base, bonding a plurality of bond wires between reconditioned die pads of the reconditioned die to leads of the hermetic package base or downbonds to create an assembled hermetic package base, and sealing a hermetic package lid to the assembled hermetic package base to create a new packaged integrated circuit. Modifying the extracted die includes removing the one or more ball bonds on the one or more die pads. Reconditioning the modified extracted die includes adding a sequence of metallic layers to bare die pads of the modified extracted die. The extracted die is a fully functional semiconductor die with one or more ball bonds on one or more die pads of the extracted die.

A method is provided. The method includes one or more of extracting a die from an original packaged integrated circuit, modifying the extracted die, reconditioning the modified extracted die, placing the reconditioned die into a cavity of a hermetic package base, bonding a plurality of bond wires between reconditioned die pads of the reconditioned die to leads of the hermetic package base or downbonds to create an assembled hermetic package base, and sealing a hermetic package lid to the assembled hermetic package base to create a new packaged integrated circuit. Modifying the extracted die includes removing the one or more ball bonds on the one or more die pads. Reconditioning the modified extracted die includes adding a sequence of metallic layers to bare die pads of the modified extracted die. The extracted die is a fully functional semiconductor die with one or more ball bonds on one or more die pads of the extracted die.

According to one embodiment, a magnetic memory device includes a magnetic memory chip having a magnetoresistive element, a magnetic layer having first and second portions spacing out each other, the first portion covering a first main surface of the magnetic memory chip, the second portion covering a second main surface facing the first main surface of the magnetic memory chip, a circuit board on which the magnetic layer is mounted, and a bonding wire connecting between the magnetic memory chip and the circuit board in a first direction parallel to the first and second main surfaces.

According to one embodiment, a magnetic memory device includes a magnetic memory chip having a magnetoresistive element, a magnetic layer having first and second portions spacing out each other, the first portion covering a first main surface of the magnetic memory chip, the second portion covering a second main surface facing the first main surface of the magnetic memory chip, a circuit board on which the magnetic layer is mounted, and a bonding wire connecting between the magnetic memory chip and the circuit board in a first direction parallel to the first and second main surfaces.

A packaged semiconductor structure includes an interconnect layer and a first microelectronic device on a first major surface of the interconnect layer. The structure also includes a substrate having a cavity, wherein the cavity is defined by a vertical portion and a horizontal portion, wherein the vertical portion surrounds the first device, the horizontal portion is over the first device, and the first device is between the horizontal portion and the first major surface of the interconnect layer such that the first device is in the cavity. The structure further includes a second microelectronic device attached to the horizontal portion of the substrate, and encapsulant on the interconnect layer and surrounding the first device, the substrate, and the second device, such that the substrate is embedded in the encapsulant.

A package carrier including a flexible substrate, a first build-up structure and a second build-up structure is provided. The flexible substrate has a first surface and a second surface opposite to each other, and has a first opening connected between the first surface and the second surface. The first build-up structure is disposed on the first surface and covers the first opening. The second build-up structure is disposed on the second surface and has a second opening, and the first opening and the second opening are connected to each other to form a chip accommodating cavity together. In addition, a manufacturing method of the package carrier and a chip package structure having the package carrier are also provided.

An electronic device includes a substrate including an upper surface, a clock output pad formed in a control device mounting area of the upper surface, a command/address output pad formed in the control device mounting area, a clock signal main wiring connected to the clock output pad, a command/address signal main wiring connected to the command/address output pad, a first clock signal branch wiring branched from the clock signal main wiring at a first branch point of the clock signal main wiring, and a second clock signal branch wiring branched from the clock signal main wiring at a second branch point of the clock signal main wiring, which is located at a downstream side of the clock signal main wiring than the first branch point of the clock signal main wiring.

A PoP semiconductor device has a top semiconductor package disposed over a bottom semiconductor package. The top semiconductor package has a substrate and a first semiconductor die disposed over the substrate. First and second encapsulants are deposited over the first semiconductor die and substrate. A first build-up interconnect structure is formed over the substrate after depositing the second encapsulant. The top package is disposed over the bottom package. The bottom package has a second semiconductor die and modular interconnect units disposed around the second semiconductor die. A second build-up interconnect structure is formed over the second semiconductor die and modular interconnect unit. The modular interconnect units include a plurality of conductive vias and a plurality of contact pads electrically connected to the conductive vias. The I/O pattern of the build-up interconnect structure on the top semiconductor package is designed to coincide with the I/O pattern of the modular interconnect units.