An electronic device module includes a first board including a first side and a second side facing in opposite directions, the first side of the first board being configured to have a first electronic device mounted thereon; a second board adhered to the second side of the first board, and including a device accommodating portion that is a space formed by removing a central portion of the second board; a second electronic device disposed in the device accommodating portion and mounted on the second side of the first board so that the second electronic device is adjacent to an internal edge side of the second board defining a boundary of the device accommodating portion; and a bonding layer disposed in a gap between the first board and the second board and extending into a gap between the second side of the first board and the second electronic device, the bonding layer bonding the second board and the second electronic device to the first board.

A radio frequency (RF) chip package includes: an RF die; a first peripheral circuit chip; a second peripheral circuit chip; a substrate having a -shaped step formed on a portion thereof so that the RF die is mounted on top of the step of the substrate and the first peripheral circuit chip and the second peripheral circuit chip are mounted on top of the substrate where no step is formed; a first mutual inductance controller for controlling the dimension of the mutual inductance between the first peripheral circuit chip and the RF die; and a second mutual inductance controller for controlling the dimension of the mutual inductance between the second peripheral circuit chip and the RF die.

An integrated radio frequency (RF) circuit structure may include an active device on a first surface of an isolation layer. The integrated RF circuit structure may also include a back-bias metallization on a second surface opposite the first surface of the isolation layer. A body of the active device is biased by the back-bias metallization. The integrated RF circuit structure may further include a handle substrate on a front-side dielectric layer on the active device.

A semiconductor package structure is provided. The structure includes a package substrate having a first surface and a second surface opposite to the first surface and including a ground layer embedded therein. A semiconductor die is formed on the first surface of the package substrate and an antenna pattern layer is formed on the second surface of the package substrate and electrically coupled to the semiconductor die. The structure also includes a first connector and a second connector formed on the second surface of the package substrate and arranged adjacent to the antenna pattern layer. The first connector is electrically coupled to the semiconductor die and electrically isolated to the ground layer, and the second connector is electrically coupled to the ground layer. A wireless communication device including the semiconductor package structure is also provided.

Millimeter wave (mmWave) technology, apparatuses, and methods that relate to transceivers, receivers, and antenna structures for wireless communications are described. The various aspects include co-located millimeter wave (mmWave) and near-field communication (NFC) antennas, scalable phased array radio transceiver architecture (SPARTA), phased array distributed communication system with MIMO support and phase noise synchronization over a single coax cable, communicating RF signals over cable (RFoC) in a distributed phased array communication system, clock noise leakage reduction, IF-to-RF companion chip for backwards and forwards compatibility and modularity, on-package matching networks, 5G scalable receiver (Rx) architecture, among others.

Provided is an integrated antenna package structure including a chip, a circuit structure, a shielding body, an encapsulant, a first antenna layer, a dielectric body, and a second antenna layer. The circuit structure is electrically connected to the chip. The shielding body is disposed on the circuit structure and has an accommodating space. The chip is disposed in the accommodating space of the shielding body. The encapsulant is disposed on the circuit structure and covers the chip. The first antenna layer is disposed on the circuit structure and is electrically connected to the circuit structure. The dielectric body is disposed on the encapsulant. The second antenna layer is disposed on the dielectric body. A manufacturing method of the integrated antenna package structure is also provided.

An antenna substrate includes: a first insulating layer surrounding a cavity; a second insulating layer of which at least a portion is disposed in the cavity and containing an insulating material different from an insulating material of the first insulating layer; a first patch antenna having one surface facing the first insulating layer by an amount greater than half of an area of the first patch antenna; and a second patch antenna having one surface facing the cavity by an amount greater than half of an area of the second patch antenna.

A package structure and the method thereof are provided. The package structure includes a conductive plate, a semiconductor die, a molding compound, and antenna elements. The conductive plate has a first surface, a second surface and a sidewall connecting the first surface and the second surface. The semiconductor die is located on the second surface of the conductive plate. The molding compound laterally encapsulates the semiconductor die and covers the sidewall and a portion of the second surface exposed by the semiconductor die, wherein the first surface of the conductive plate is coplanar with a surface of the molding compound. The antenna elements are located over the first surface of the conductive plate.

A semiconductor device package that incorporates a combination of ceramic, organic, and metallic materials that are coupled using silver is provided. The silver is applied in the form of fine particles under pressure and a low temperature. After application, the silver forms a solid that has a typical melting point of silver, and therefore the finished package can withstand temperatures significantly higher than the manufacturing temperature. Further, since the silver is an interfacial material between the various combined materials, the effect of differing material properties between ceramic, organic, and metallic components, such as coefficient of thermal expansion, is reduced due to low temperature of bonding and the ductility of the silver.

Radio frequency (RF) packages containing substrates having coefficient of thermal expansion (CTE) matched mount pads are disclosed, as are methods for fabricating RF packages and substrates. In embodiments, the RF package contains a high thermal performance substrate including a metallic base structure, which has a frontside facing a first RF power die and a first die attach region on the frontside of the base structure. A first CTE matched mount pad is bonded to the metallic base structure and covers the first die attach region. The first CTE mount pad has a CTE greater than the CTE of RF power die and less than the CTE of the metallic base structure. An electrically-conductive bonding material attaches the RF power die to the first CTE matched mount pad, while RF circuitry integrated into first RF power die is electrically coupled to the metallic base structure through the mount pad.