Abstract: Embodiments of the invention include delay line circuitry that is integrated with an organic substrate. Organic dielectric material and a plurality of conductive layers form the organic substrate. The delay line circuitry includes a piezoelectric transducer to receive a guided electromagnetic wave signal and to generate an acoustic wave signal to be transmitted with an acoustic transmission medium. An acoustic reflector is communicatively coupled to the acoustic transmission medium. The acoustic reflector receives a plurality of acoustic wave signals from the acoustic transmission medium and reflects acoustic wave signals to the piezoelectric transducer using the acoustic transmission medium. The transducer converts the reflected acoustic signals into electromagnetic waves which are then transmitted back through the antenna and decoded by the reader.

Abstract: Embodiments of the invention include multi-die package and methods of making such multi-die packages. In an embodiment a mold layer has a first surface and a second surface that is opposite from the first surface. One or more first electrical components that each have a solderable terminal that is oriented to face the first surface of the mold layer. The mold layer may also have one or more second electrical components that each have a second type of terminal that is oriented to face the second surface of the mold layer. Embodiments may also include one or more conductive through vias formed between the first surface of the mold layer and the second surface of the mold layer. Accordingly an electrical connection may be made from the second surface of the mold layer to the first electrical components that are oriented to face the first surface of the mold layer.

Abstract: Embodiments of the invention include a waveguide structure that includes a first piezoelectric transducer that is positioned in proximity to a first end of a cavity of an organic substrate. The first piezoelectric transducer receives an input electrical signal and generates an acoustic wave to be transmitted with a transmission medium. A second piezoelectric transducer is positioned in proximity to a second end of the cavity. The second piezoelectric transducer receives the acoustic wave from the transmission medium and generates an output electrical signal.

Abstract: Embodiments of the invention include a switching device that includes an electrode, a piezoelectric material coupled to the electrode, and a movable structure (e.g., cantilever, beam) coupled to the piezoelectric material. The movable structure includes a first end coupled to an anchor of a package substrate having organic layers and a second released end positioned within a cavity of the package substrate.

Abstract: Embodiments of the invention include delay line circuitry that is integrated with an organic substrate. Organic dielectric material and a plurality of conductive layers form the organic substrate. The delay line circuitry includes a piezoelectric transducer to receive a guided electromagnetic wave signal and to generate an acoustic wave signal to be transmitted with an acoustic transmission medium. An acoustic reflector is communicatively coupled to the acoustic transmission medium. The acoustic reflector receives a plurality of acoustic wave signals from the acoustic transmission medium and reflects acoustic wave signals to the piezoelectric transducer using the acoustic transmission medium. The transducer converts the reflected acoustic signals into electromagnetic waves which are then transmitted back through the antenna and decoded by the reader.

Abstract: Embodiments of the invention include a filtering device that includes a first electrode, a piezoelectric material in contact with the first electrode, and a second electrode in contact with the piezoelectric material. The piezoelectric filtering device expands and contracts laterally in a plane of an organic substrate in response to application of an electrical signal between the first and second electrodes.

Abstract: Embodiments of the invention include a piezoelectric package integrated filtering device that includes a film stack. In one example, the film stack includes a first electrode, a piezoelectric material in contact with the first electrode, and a second electrode in contact with the piezoelectric material. The film stack is suspended with respect to a cavity of an organic substrate having organic material and the film stack generates an acoustic wave to be propagated across the film stack in response to an application of an electrical signal between the first and second electrodes.

Abstract: Embodiments of the invention include a tunable radio frequency (RF) communication module that includes a transmitting component having at least one tunable component and a receiving component having at least one tunable component. The tunable RF communication module includes at least one piezoelectric switching device coupled to at least one of the transmitting and receiving components. The at least one piezoelectric switching device is formed within an organic substrate having organic material and is designed to tune at least one tunable component of the tunable RF communication module.

Abstract: Embodiments of the invention include a piezoelectric resonator which includes an input transducer having a first piezoelectric material, a vibrating structure coupled to the input transducer, and an output transducer coupled to the vibrating structure. In one example, the vibrating structure is positioned above a cavity of an organic substrate. The output transducer includes a second piezoelectric material. In operation the input transducer causes an input electrical signal to be converted into mechanical vibrations which propagate across the vibrating structure to the output transducer.

Abstract: Embodiments herein relate to a system in package (SiP). The SiP may have a first layer of one or more first functional components with respective first active sides and first inactive sides opposite the first active sides. The SiP may further include a second layer of one or more second functional components with respective second active sides and second inactive sides opposite the second active sides. In embodiments, one or more of the first active sides are facing and electrically coupled with one or more of the second active sides through a through-mold via or a through-silicon via.

Abstract: Embodiments of the invention include delay line circuitry that is integrated with an organic substrate. Organic dielectric material and a plurality of conductive layers form the organic substrate. The delay line circuitry includes a piezoelectric transducer to receive a guided electromagnetic wave signal and to generate an acoustic wave signal to be transmitted with an acoustic transmission medium. An acoustic reflector is communicatively coupled to the acoustic transmission medium. The acoustic reflector receives a plurality of acoustic wave signals from the acoustic transmission medium and reflects acoustic wave signals to the piezoelectric transducer using the acoustic transmission medium. The transducer converts the reflected acoustic signals into electromagnetic waves which are then transmitted back through the antenna and decoded by the reader.

Abstract: A method apparatus and material are described for radio frequency passives and antennas. In one example, an electronic component has a synthesized magnetic nanocomposite material with aligned magnetic domains, a conductor embedded within the nanocomposite material, and contact pads extending through the nanocomposite material to connect to the conductor.

Abstract: A method apparatus and material are described for radio frequency passives and antennas. In one example, an electronic component has a synthesized magnetic nanocomposite material with aligned magnetic domains, a conductor embedded within the nanocomposite material, and contact pads extending through the nanocomposite material to connect to the conductor.

Abstract: Embodiments of the invention include multi-die package and methods of making such multi-die packages. In an embodiment a mold layer has a first surface and a second surface that is opposite from the first surface. One or more first electrical components that each have a solderable terminal that is oriented to face the first surface of the mold layer. The mold layer may also have one or more second electrical components that each have a second type of terminal that is oriented to face the second surface of the mold layer. Embodiments may also include one or more conductive through vias formed between the first surface of the mold layer and the second surface of the mold layer. Accordingly an electrical connection may be made from the second surface of the mold layer to the first electrical components that are oriented to face the first surface of the mold layer.

Abstract: An electronic package that includes a mold that includes at least one passive component, each of the passive components including electric conductors that are exposed from the mold, and a first conductive layer directly attached to the mold such that the conductive layer touches the mold and the electrical conductors that are exposed from the mold. A method that includes removing a temporary carrier from a mold that includes electronic devices, wherein electric conductors on the electronic devices are exposed once the temporary carrier is removed from the mold, and covering the mold with a first conductive layer such that the first conductive layer covers the mold and is electrically connected to the exposed electric conductors on the electronic devices.

Abstract: A semiconductor device package having reduced form factor and a method for forming said semiconductor device are disclosed. In an embodiment, an active die is embedded within a cavity in the core layer of the package substrate, wherein an in-situ electromagnetic shield is formed on the sidewalls of the cavity. In another embodiment, a crystal oscillator is at least partially embedded within the core layer of the package substrate. In another embodiment, a package having a component embedded in the core layer is mounted on a PCB, and a crystal oscillator generating a clock frequency for the package is mounted on the PCB. By embedding components within the core or removing components from the package to be mounted directly on the PCB, the x, y, and z dimensions of a package may be reduced. In addition, in-situ electromagnetic shield may reduce EM noise emitted from the active die.

Abstract: An apparatus includes a coreless substrate with an embedded die that is integral to the coreless substrate, and at least one device assembled on a surface that is opposite to a ball-grid array disposed on the coreless substrate. The apparatus may include an over-mold layer to protect the at least one device assembled on the surface.

Abstract: A method apparatus and material are described for radio frequency passives and antennas. In one example, an electronic component has a synthesized magnetic nanocomposite material with aligned magnetic domains, a conductor embedded within the nanocomposite material, and contact pads extending through the nanocomposite material to connect to the conductor.

Abstract: Electronic assemblies and their manufacture are described. One assembly includes a coreless substrate comprising a plurality of dielectric layers and electrically conductive pathways, the coreless substrate including a first side and a second side opposite the first side. The assembly includes a first die embedded in the coreless substrate, the first die comprising an RF die, the first die positioned in a dielectric layer that extends to the first side of the coreless substrate. The assembly includes a second die positioned on first side, the second die positioned on the first die. In another aspect, a molding material may be positioned on the die side, wherein the first die and the second die are covered by the molding material. In another aspect, an electrical shielding layer may be positioned over the first side. Other embodiments are described and claimed.

Abstract: A semiconductor device package having reduced form factor and a method for forming said semiconductor device are disclosed. In an embodiment, an active die is embedded within a cavity in the core layer of the package substrate, wherein an in-situ electromagnetic shield is formed on the sidewalls of the cavity. In another embodiment, a crystal oscillator is at least partially embedded within the core layer of the package substrate. In another embodiment, a package having a component embedded in the core layer is mounted on a PCB, and a crystal oscillator generating a clock frequency for the package is mounted on the PCB. By embedding components within the core or removing components from the package to be mounted directly on the PCB, the x, y, and z dimensions of a package may be reduced. In addition, in-situ electromagnetic shield may reduce EM noise emitted from the active die.