Abstract: Discussed generally herein are methods and devices including or providing a magnetic, detachable, conductive connector to provide an electrical and mechanical connection between parts. A device can include a first substrate, at least one electric component on or at least partially in a first surface of the first substrate, an adhesive on the first surface of the first substrate to temporarily attached the device to skin of a user, a contact pad electrically coupled to an electric component of the at least one electric component, the contact pad on or at least partially in a second surface of the substrate, the first surface opposite the second surface, and a conductive magnetic connector electrically and mechanically connected to the contact pad through a first conductive adhesive.

Abstract: Discussed generally herein are methods and devices including or providing a patch system that can help in diagnosing a medical condition and/or provide therapy to a user. A body-area network can include a plurality of communicatively coupled patches that communicate with an intermediate device. The intermediate device can provide data representative of a biological parameter monitored by the patches to proper personnel, such as for diagnosis and/or response.

Abstract: Embodiment of the present disclosure describe integrated circuit package assemblies that allow for relatively short connections between devices such as a processor and memory. In one embodiment, a package assembly includes a die embedded in a subpackage directly coupled to another die attached to the subpackage. In some embodiments the subpackage may also contain power management devices. In some embodiments the die embedded in the subpackage and/or the power management device may overlap, or be located in, a region defined by the die coupled to the subpackage such that they are located between the die coupled to the subpackage and a substrate underlying the subpackage. Other embodiments may be described and/or claimed.

Abstract: Embodiments of the invention include a resonant sensing system comprising driving circuitry to generate a drive signal during excitation time periods, a first switch coupled to the driving circuitry, and a sensing device coupled to the driving circuitry via the first switch during the excitation time periods. The sensing device includes beams to receive the drive signal during a first excitation time period that causes the beams to mechanically oscillate and generate a first induced electromotive force (emf) in response to the drive signal. The first switch decouples the sensing device and the driving circuitry during measurement time periods for measurement of the induced emf.

Abstract: Embodiments of the invention include a sensing device that includes a base structure having a proof mass that is positioned in proximity to a cavity of an organic substrate, a piezoelectric material in contact with a first electrode of the base structure, and a second electrode in contact with the piezoelectric material. The proof mass deflects in response to application of an external force or acceleration and this deflection causes a stress in the piezoelectric material which generates a voltage differential between the first and second electrodes.

Abstract: Embodiments of the invention include a temperature sensing device that includes a base structure that is positioned in proximity to a cavity of an organic substrate, an input transducer coupled to the base structure, and an output transducer coupled to the base structure. The input transducer includes a first piezoelectric material to generate vibrations which are transmitted on the base structure in response to input signals being applied to the input transducer. The output transducer includes a second piezoelectric material to receive the vibrations and to generate output signals which are used to determine a change in ambient temperature.

Abstract: Embodiments of the invention include a piezoelectric package integrated jet device. In one example, the jet device includes a vibrating membrane positioned between first and second cavities of an organic substrate, a piezoelectric material coupled to the vibrating membrane which acts as a first electrode, and a second electrode in contact with the piezoelectric material. The vibrating membrane generates fluid flow through an orifice in response to application of an electrical signal between the first and second electrodes.

Abstract: Embodiments of the invention include an acoustic sensing device having a piezoelectric transmit transducer to receive input electrical signals and to generate a surface acoustic wave to be transmitted along a surface of the sensing device which is integrated with an organic substrate. The sensing device also includes a piezoelectric receive transducer to receive the surface acoustic wave and to generate output electrical signals and an input region integrated with the organic substrate. The input region is capable of receiving input which changes an acoustic amplitude of the surface acoustic wave.

Abstract: Embodiments of the invention include a chemical species-sensitive device that includes an input transducer to receive input signals, a base structure that is coupled to the input transducer and positioned in proximity to a cavity of an organic substrate, a chemically sensitive functionalization material attached to the base structure, and an output transducer to generate output signals. For a chemical sensing functionality, a desired chemical species attaches to the chemically sensitive functionalization material which causes a change in mass of the base structure and this change in mass causes a change in a mechanical resonant frequency of the chemical species-sensitive device.

Abstract: A microelectronic package of the present description may comprises a first microelectronic device having at least one row of connection structures electrically connected thereto and a second microelectronic device having at least one row of connection structures electrically connected thereto, wherein the connection structures within the at least one first microelectronic device row are aligned with corresponding connection structures within the at least one second microelectronic device row in an x-direction.

Abstract: Magnet placement is described for integrated circuit packages. In one example, a terminal is applied to a magnet. The magnet is then placed on a top layer of a substrate with solder between the terminal and the top layer, and the solder is reflowed to attach the magnet to the substrate.

Abstract: Electrical cable technology is disclosed. In one example, an electrical cable can include a transmission line conductor, a ground conductor, and a dielectric material. The dielectric material can have at least a portion with a thickness separating the transmission line conductor and the ground conductor that is variable along a length of the electrical cable. Such a non-uniform cable (e.g., a cable having components or features that vary in size and/or geometry along the length of the cable) can provide high IO density with acceptable conductive losses and cross-talk while maintaining a desired impedance.

Abstract: Discussed generally herein are methods and devices including or providing a patch system that can help in diagnosing a medical condition and/or provide therapy to a user. A body-area network can include a plurality of communicatively coupled patches that communicate with an intermediate device. The intermediate device can provide data representative of a biological parameter monitored by the patches to proper personnel, such as for diagnosis and/or response.

Abstract: An embodiment includes a package comprising: a cavity formed in a dielectric material; a beam in the cavity; an interconnect to couple the beam to a current source; a magnet coupled to the cavity; and a polymer, on the beam, having an affinity to an analyte; wherein (a) a vertical axis intersects the magnet, the cavity, and the beam; (b) in a first state the beam and the polymer, which is not coupled to the analyte, collectively have a first mass and resonate at a first resonant frequency when the beam conducts a first current; and (c) in a second state the beam and the polymer, which is coupled to the analyte, collectively have a second mass that is greater than the first mass and resonate at a second resonant frequency when the beam conducts a second current. Other embodiments are described herein.

Abstract: Embodiments of the invention may include a packaged device that includes thermally stable radio frequency integrated circuits (RFICs). In one embodiment the packaged device may include an integrated circuit chip mounted to a package substrate. According to an embodiment, the package substrate may have conductive lines that communicatively couple the integrated circuit chip to one or more external components. One of the external components may be an RFIC module. The RFIC module may comprise an RFIC and an antenna. Additional embodiments may also include a packaged device that includes a plurality of cooling spots formed into the package substrate. In an embodiment the cooling spots may be formed proximate to interconnect lines the communicatively couple the integrated circuit chip to the RFIC.

Abstract: Embodiments of the invention describe hermetic encapsulation for MEMS devices, and processes to create the hermetic encapsulation structure. Embodiments comprise a MEMS substrate stack that further includes a magnet, a first laminate organic dielectric film, a first hermetic coating disposed over the magnet, a second laminate organic dielectric film disposed on the hermetic coating, a MEMS device layer disposed over the magnet, and a plurality of metal interconnects surrounding the MEMS device layer. A hermetic plate is subsequently bonded to the MEMS substrate stack and disposed over the formed MEMS device layer to at least partially form a hermetically encapsulated cavity surrounding the MEMS device layer. In various embodiments, the hermetically encapsulated cavity is further formed from the first hermetic coating, and at least one of the set of metal interconnects, or a second hermetic coating deposited onto the set of metal interconnects.

Abstract: An apparatus including a substrate including a first side and an opposite second side; at least one first circuit device on the first side of the substrate, at least one second device on the second side of the substrate; and a support on the second side of the substrate, the support including interconnections connected to the at least one first and second circuit device, the support having a thickness dimension operable to define a dimension from the substrate greater than a thickness dimension of the at least one second circuit device. A method including disposing at least one first circuit component on a first side of a substrate; disposing at least one second circuit component on a second side of the substrate; and coupling a support to the substrate, the substrate defining a dimension from the substrate greater than a thickness dimension of the at least one second circuit component.

Abstract: Methods of forming sensor integrated package devices and structures formed thereby are described. An embodiment includes providing a substrate core, wherein a first conductive trace structure and a second conductive trace structure are disposed on the substrate core, forming a cavity between the first conductive trace structure and the second conductive trace structure, and placing a magnet on a resist material disposed on a portion of each of the first and second conductive trace structures, wherein the resist material does not extend over the cavity.

Abstract: A pressure sensor is integrated into an integrated circuit fabrication and packaging flow. In one example, a releasable layer is formed over a removable core. A first dielectric layer is formed. A metal layer is patterned to form conductive metal paths and to form a diaphragm with the metal. A second dielectric layer is formed over the metal layer and the diaphragm. A second metal layer is formed to connect with formed vias and to form a metal mesh layer over the diaphragm. The first dielectric layer is etched under the diaphragm to form a cavity and the cavity is covered to form a chamber adjoining the diaphragm.

Abstract: A microelectronic package of the present description may comprises a first microelectronic device having at least one row of connection structures electrically connected thereto and a second microelectronic device having at least one row of connection structures electrically connected thereto, wherein the connection structures within the at least one first microelectronic device row are aligned with corresponding connection structures within the at least one second microelectronic device row in an x-direction.