An antenna module includes a fan-out semiconductor package including an IC, an encapsulant encapsulating at least a portion of the IC, a core member having a first side surface facing the IC or the encapsulant, and a connection member including at least one wiring layer electrically connected to the IC and the core member and at least one insulating layer; and an antenna package including a plurality of first directional antenna members configured to transmit or receive a first RF signal. The fan-out semiconductor package further includes at least one second directional antenna member disposed on a second side surface of the core member opposing the first side surface of the core member, stood up from a position electrically connected to at least one wiring layer, and configured to transmit or receive a second RF signal.

One embodiment is an apparatus comprising a silicon-on-insulator (“SOI”) substrate comprising an insulating layer sandwiched in between a bottom silicon layer and a top silicon layer; a radiating element disposed on a top surface of the SOI substrate; and at least one cavity disposed in the SOI substrate surrounding the radiating element, wherein the at least one cavity extends from a bottom surface of the bottom silicon layer to a bottom surface of the insulating layer.

The present disclosure provides a semiconductor device. The semiconductor device includes a carrier having a first side and a second side adjacent to the first side. The semiconductor device also includes a first antenna adjacent to the first side and configured to operate at a first frequency and a second antenna adjacent to the second side and configured to operate at a second frequency different from the first frequency. An method of manufacturing a semiconductor device is also provided.

This application relates to a device for signal transmission (e.g., radio frequency transmission) and a method for forming the device. For example, the method includes: depositing an insulating layer that includes polybenzobisoxazole (PBO) on a carrier; forming a backside layer including polyimide (PI) over the adhesive layer; forming a die-attach film (DAF) over the backside layer; forming one or more through-insulator via (TIV)-wall structures and one or more TIV-grating structures on the second backside layer; placing a die, such as a radio frequency (RF) integrated circuit (IC) die, on the DAF; encapsulating the die, the one or more TIV-wall structures, and the one or more TIV-grating structures, with a molding compound to form an antenna package including one or more antenna regions; and forming a redistribution layer (RDL) structure on the encapsulated package. The RDL structure can include one or more antenna structures coupled to the die. Each of the one or more antenna structures can be positioned over the one or more antenna regions.

A semiconductor device comprises a first semiconductor chip, a first planar waveguide transmission line arranged within a BEOL metal stack of the first semiconductor chip, wherein the first planar waveguide transmission line comprises line sections situated opposite one another, and a second planar waveguide transmission line arranged over the first semiconductor chip and electrically coupled to the first planar waveguide transmission line, wherein the second planar waveguide transmission line comprises line sections situated opposite one another.

Disclosed herein are structures and assemblies that may be used for thermal management in integrated circuit (IC) packages.

A semiconductor device and a method of manufacturing the same are provided. The semiconductor device includes an antenna zone and a routing zone. The routing zone is disposed on the antenna zone, where the antenna zone includes a first insulation layer and two or more second insulation layer and a thickness of the first insulation layer is different from that of the second insulation layer.

An electronic circuit including a substrate having a first dielectric characteristic. The substrate can include a first side and a second side. An intermediary material can be disposed within the substrate. For instance, the intermediary material can be located between the first side and the second side. The intermediary material can include a second dielectric characteristic, where the second dielectric characteristic is different than the first dielectric characteristic. A first conductive layer can be disposed on the first side, and a second conductive layer can be disposed on the second side. A conductive path can be electrically coupled between the first conductive layer and the second conductive layer. The conductive path can be in contact with at least a portion of the intermediary material.

An antenna-integrated radio frequency (RF) module includes a multilayer substrate disposed between an integrated chip (IC) and patch antennas, signal vias, and ground members. The IC is configured to generate RF signals. The signal vias are configured to connect and transmit/receive the RF signals from each of the patch antennas to the IC. The ground members are disposed on an outer surface layer and intermediate surface layers of the multilayer substrate to surround each of the patch antennas and the signal vias.

The present disclosure is directed to conductive structures that may be utilized in a radio-frequency (RF) switch. The embodiments of the conductive structures of the present disclosure are formed to balance the “on” resistance (R.sub.on) and the “off” capacitance (C.sub.off) such that the R.sub.on.Math.C.sub.off value is optimized such that the conductive structures are relatively efficient as compared to conventional conductive structures within conventional RF switches. For example, the conductive structures include various metallization layers that are stacked on each other and spaced apart in a selected manner to balance the R.sub.on and the C.sub.off as to optimize the R.sub.on.Math.C.sub.off figure of merit as a lower R.sub.on.Math.C.sub.off is preferred.