In an embodiment, a package structure including an electro-optical circuit board, a fanout package disposed over the electro-optical circuit board is provided. The electro-optical circuit board includes an optical waveguide. The fanout package includes a first optical input/output portion, a second optical input/output portion and a plurality of electrical input/output terminals electrically connected to the electro-optical circuit board. The first optical input/output portion is optically coupled to the second optical input/output portion through the optical waveguide of the electro-optical circuit board.

In various embodiments, a chip card module for a chip card is provided. The chip card module may include a carrier with a first side and an opposite second side, a chip arranged over the first side of the carrier, an antenna arranged over the carrier. The antenna may be electrically conductively coupled to the chip and configured to inductively couple to a second antenna formed on a chip card body of the chip card. The chip card module may further include a capacitor electrically conductively coupled to the chip, the capacitor including a first electrode arranged over the first side of the carrier, and a second electrode arranged over the second side of the carrier.

The present disclosure is related to electronic modules for electronic components and methods for manufacturing the same. In one embodiment, an electronic module is formed using a first substrate having a first component area and a second substrate having a second component area. One or more electronic components may be attached to both the first component area and the second component area. The second substrate is mounted over the first substrate such that the second component area faces the first component area. An overmold covers the first component area and the second component area so as to cover the electronic components on both the first component area and the second component area. In this manner, the number of electronic components within the electronic module that can be mounted on an area of a printed circuit board (PCB) is increased.

A semiconductor package includes a first substrate, a first conductive layer, a first surface mount device (SMD) and a first bonding wire. The first substrate has a first top surface. The first conductive layer is formed on the first top surface and has a first conductive element and a second conductive element separated from each other. The first SMD is mounted on the first top surface, overlapping with but electrically isolated from the first conductive element. The first bonding wire electrically connects the first SMD with the first conductive layer.

Structures, methods and devices are disclosed, related to improved stack structures in electronic devices. In some embodiments, a stack structure includes a pad implemented on a substrate, the pad including a polymer layer having a side that forms an interface with another layer of the pad, the pad further including an upper metal layer over the interface, the upper metal layer having an upper surface. In some embodiments, the stack structure also includes a passivation layer implemented over the upper metal layer, the passivation layer including a pattern configured to provide a compressive force on the upper metal layer to thereby reduce the likelihood of delamination at the interface, the pattern defining a plurality of openings to expose the upper surface of the upper metal layer.

Aspects of this disclosure relate to selectively shielded radio frequency modules. A radio frequency module can include a package substrate, a radio frequency component on the package substrate, a multi-layer antenna, a radio frequency shielding structure configured to provide shielding between the multi-layer antenna and the radio frequency component. The radio frequency shielding structure can include a shielding layer providing a shield over the radio frequency component and leaving the radio frequency module unshielded over the antenna.

A packaged module for use in a wireless communication device has a substrate supporting an integrated circuit die that includes at least a microprocessor and radio frequency receiver circuitry and a stacked filter assembly configured as a filter circuit that is in communication with the radio frequency receiver circuitry. The stacked filter assembly includes a plurality of passive components, where each passive component is packaged as a surface mount device. At least one passive component is in direct communication with the substrate and at least another passive component is supported above the substrate by the at least one passive component that is in the direct communication with the substrate.

An integrated circuit (IC) structure for radio frequency (RF) circuits having a multi-point selectably grounded die seal and multi-point selectably grounded signal paths. Embodiments include switch-coupled grounding pads that can selectively electrically couple an internal grounding pad within the die seal of an IC die to a connection point on the die seal and/or on a signal path. When the IC die is embedded in a grounded system, the die seal and/or signal path can be locally grounded at selected connection points, and thus an IC die may be “tuned” to mitigate the effects of parasitic coupling and/or to selective repurpose such parasitic coupling to generate a notch filter effect. Another aspect is selective grounding of inactive signal paths to improve isolation between signal ports.

A biological information detecting apparatus includes: an LC resonant pressure sensor including a resonant circuit including a capacitor and an inductor, and having a resonant frequency that changes depending on a change in external pressure applied to the capacitor; and an integrated circuit (IC) chip package including a coil type antenna radiating a radio frequency (RF) signal within a preset frequency band, wherein a change in the resonant frequency results in a change in a power transmission rate depending on a inductive coupling between the resonant frequency and a frequency of the RF signal. The IC chip package includes the coil type antenna disposed in a region overlapping the LC resonant pressure sensor in a plan view of the IC chip package.

Various methods and devices that involve EMI shields for radio frequency layer transferred devices are disclosed. One method comprises forming a radio frequency field effect transistor in an active layer of a semiconductor on insulator wafer. The semiconductor on insulator wafer has a buried insulator side and an active layer side. The method further comprises bonding a second wafer to the active layer side of the semiconductor on insulator wafer. The method further comprises forming a shield layer for the semiconductor device. The shield layer comprises an electrically conductive material. The method further comprises coupling the radio frequency field effect transistor to a circuit comprising a radio frequency component. The method further comprises singulating the radio frequency field effect transistor, radio frequency component, and the shield layer into a die. The shield layer is located between a substrate of the radio frequency component and the radio frequency field effect transistor.