A patch on interposer (PoINT) package is described with a wireless communications interface. Some examples include an interposer, a main patch attached to the interposer, a main integrated circuit die attached to the patch, a second patch attached to the interposer, and a millimeter wave radio die attached to the second patch and coupled to the main integrated circuit die through the interposer to communicate data between the main die and an external component.

A semiconductor device configured for a radio frequency (RF) application and further configured for passive device integration and/or improved cooling includes a substrate; an active region portion arranged on the substrate, the active region portion includes at least one radio frequency (RF) transistor amplifier; a cavity arranged within the substrate; and one or more radio frequency (RF) devices arranged in the cavity.

A microwave circuit integrated on a common semiconductor substrate, includes: a first-stage amplifier to amplify an input high-frequency signal having a first frequency; a main-system amplification stage to amplify and output one signal having the first frequency branched from an output of the first-stage amplifier; a branch stage to generate a signal having double the frequency of the first frequency; and a sub-system amplification stage to amplify and output the signal having double the frequency. An amplification circuit constituting the first-stage amplifier, an amplification circuit included in the branch stage, an amplification circuit included in the main-system amplification stage, and an amplification circuit included in the sub-system amplification stage are connected in series between a power supply and ground in a DC manner, and each is a current reuse type amplifier including two-stage transistors connected in series between a signal input and a signal output in an AC manner.

A package structure including a first redistribution circuit structure, a semiconductor die, first antennas and second antennas is provided. The semiconductor die is located on and electrically connected to the first redistribution circuit structure. The first antennas and the second antennas are located over the first redistribution circuit structure and electrically connected to the semiconductor die through the first redistribution circuit structure. A first group of the first antennas are located at a first position, a first group of the second antennas are located at a second position, and the first position is different from the second position in a stacking direction of the first redistribution circuit structure and the semiconductor die.

An integrated device package is disclosed. The integrated device package can include an integrated device die, an element, a cavity, and an electrical interconnect. The element can have an antenna structure. The element can be attached to a surface of the integrated device. The cavity can be disposed between the integrated device die and the antenna structure. The electrical interconnect can connect the integrated device die and the antenna structure.

A semiconductor package including a core structure, in which a first and second semiconductor chips and passive components are embedded, a connection structure disposed on a first side of the core structure, and including a redistribution layer electrically connected to the first and second semiconductor chips and the passive components, and a metal pattern layer and a backside wiring layer disposed on a second side of the core structure opposing the first side, and spaced apart from each other. The core structure includes a first metal layer surrounding the first semiconductor chip, a second metal layer surrounding the first semiconductor chip, and the first metal layer, a third metal layer surrounding the second semiconductor chip, and a fourth metal layer surrounding the second semiconductor chip, the passive components, and the third metal layer, and each of the first to fourth metal layers is electrically connected to the metal pattern layer.

On-chip wireless links offer improved network performance due to long distance communication, additional bandwidth, and broadcasting capabilities of antennas. A Through-Silicon Via (TSV)-based antenna design called TSV_A establishes multi-band wireless communication through the silicon substrate medium with only a 3 dB loss over a 30 mm on-chip distance. Simulation results show an improvement in network latency up to ˜13% (average improvement of ˜7%), energy-delay improvements of ˜34% on average, and an improvement in throughput up to ˜34% (average improvement).

A wiring structure includes a conductive structure, a surface structure and at least one through via. The conductive structure includes at least one dielectric layer and at least one circuit layer in contact with the dielectric layer. The surface structure is disposed adjacent to a top surface of the conductive structure. The through via extends through the surface structure and extending into at least a portion of the conductive structure.

A device includes a semiconductor substrate, a source metallization over an active area of the semiconductor substrate, a through-substrate via electrically connected to the source metallization, and an input bond pad formed in the semiconductor substrate and spaced apart from the active area. The input bond pad is electrically connected to a set of gate structures. The device includes a first inductive coil over the semiconductor substrate between a first portion of the source metallization and a second portion of the source metallization and a first capacitor over the semiconductor substrate between the first portion of the source metallization and the second portion of the source metallization. The first inductive coil and the first capacitor are connected in series between the input bond pad and the through-substrate via.

Embodiments may relate to a microelectronic package that includes a substrate signal path and a waveguide. The package may further include dies that are communicatively coupled with one another by the substrate signal path and the waveguide. The substrate signal path may carry a signal with a frequency that is different than the frequency of a signal that is to be carried by the waveguide. Other embodiments may be described or claimed.