Abstract: Embodiments of the invention include piezoelectrically driven switches that are used for modifying a background color or light source color in display systems, and methods of forming such devices. In an embodiment, a piezoelectrically actuated switch for modulating a background color in a display may include a photonic crystal that has a plurality of blinds oriented substantially perpendicular to a surface of the display. In an embodiment, the blinds include a black surface and a white surface. The switch may also include an anchor spaced away from an edge of the photonic crystal and a piezoelectric actuator formed on the surface of the anchor and a surface of the photonic crystal. Some embodiments may include a photonic crystal that is a multi-layer polymeric structure or a polymer chain with a plurality of nanoparticles spaced at regular intervals on the polymer chain.

Abstract: Embodiments of the invention include an optical grating switch integrated into an organic substrate and methods of forming such devices. According to an embodiment, the optical grating switch may include a cavity formed into an organic substrate. Additionally, the optical grating switch may include an array of moveable beams anchored to the organic substrate and suspended over the cavity. In an embodiment of the invention, each of the moveable beams in the optical grating switch may include a piezoelectric region formed over end portions of the moveable beam and a top electrode formed over a top surface of each of the piezoelectric regions. In order to reflect or diffract light, embodiments of the invention may include moveable beams that include a reflective surface formed over a central portion of the moveable beam.

Abstract: Embodiments of the invention include a display formed on an organic substrate and methods of forming such a device. According to an embodiment, an array of pixel mirrors may be formed on the organic substrate. For example, each of the pixel mirrors is actuatable about one or more axes out of the plane of the organic substrate. Additionally, embodiments of the invention may include an array of routing mirrors formed on the organic substrate. According to an embodiment, each of the routing mirrors is actuatable about two axes out of the plane of the organic substrate. In embodiments of the invention, a light source may be used for emitting light towards the array of routing mirrors. For example, light emitted from the light source may be reflected to one or more of the pixel mirrors by one of the routing mirrors.

Abstract: Embodiments of the invention include maskless imaging tools and display systems that include piezoelectrically actuated mirrors and methods of forming such devices. According to an embodiment, the maskless imaging tool may include a light source. Additionally, the tool may include one or more piezoelectrically actuated mirrors for receiving light from the light source. In an embodiment, the piezoelectrically actuated mirrors are actuatable about one or more axes to reflect the light from the light source to a workpiece positioned to receive light from the piezoelectrically actuated mirror. Additional embodiments of the invention may include a maskless imaging tool that is a laser direct imaging lithography (LDIL) tool. Other embodiments may include a maskless imaging tool that is a via-drill tool. Embodiments of the invention may also include a piezoelectrically actuated mirror used in a projection system. For example, the projection system may be integrated into a pair of glasses.

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: Embodiments of the present disclosure may relate to a transceiver to transmit and receive concurrently radio frequency (RF) signals via a dielectric waveguide. In embodiments, the transceiver may include a transmitter to transmit to a paired transceiver a channelized radio frequency (RF) transmit signal via the dielectric waveguide. A receiver may receive from the paired transceiver a channelized RF receive signal via the dielectric waveguide. In embodiments, the channelized RF receive signal may include an echo of the channelized RF transmit signal. The transceiver may further include an echo suppression circuit to suppress from the channelized RF receive signal the echo of the channelized RF transmit signal. In some embodiments, the channelized RF transmit signal and the channelized RF receive signal may be within a frequency range of approximately 30 gigahertz (GHz) to approximately 1 terahertz (THz), and the transceiver may provide full-duplex millimeter-wave communication.

Abstract: Various embodiments disclosed relate to a stretchable packaging system. The system includes a first electronic component. The first electronic component includes a first optical emitter. The system further includes a second electronic component. The second electronic component includes a first receiver. An optical interconnect including a first elastomer having a first refractive index connects the first optical emitter to the first receiver. An encapsulate layer including a second elastomer having a second refractive index at least partially encapsulates the first electronic component, the second electronic component, and the optical interconnect.

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 include a microelectronic device having a sensing device and methods of forming the sensing device. In an embodiment, the sensing device includes a mass and a plurality of beams to suspend the mass. Each beam comprises first and second conductive layers and an insulating layer positioned between the first and second conductive layers to electrically isolate the first and second conductive layers. The first conductive layer is associated with drive signals and the second conductive layer is associated with sense signals of the sensing device.

Abstract: Embodiments of the present disclosure may relate to a transmitter to transmit a radio frequency (RF) signal to a receiver via a dielectric waveguide where the transmitter includes a plurality of mixers to generate modulated RF signals and a combiner to combine the modulated RF signals. Embodiments may also include a receiver to receive, from a dielectric waveguide, a RF signal where the receiver includes a splitter to split the RF signal into a plurality of signal paths, a plurality of filters, and a plurality of demodulators. Embodiments may also include a dielectric waveguide communication apparatus that may include the transmitter and the receiver. Other embodiments may be described and/or claimed.

Abstract: Embodiments of the invention include a physiological sensor system. According to an embodiment the sensor system may include a package substrate, a plurality of sensors formed on the substrate, a second electrical component, and an encryption bank formed along a data transmission path between the plurality of sensors and the second electrical component. In an embodiment the encryption bank may include a plurality of portions that each have one or more switches integrated into the package substrate. In an embodiment each sensor transmits data to the second electrical component along different portions of the encryption bank. In some embodiments, the switches may be piezoelectrically actuated. In other embodiments the switches may be actuated by thermal expansion. Additional embodiments may include tri- or bi-stable mechanical switches.

Abstract: Embodiments of the invention include a waveguide structure that includes a lower member, at least one sidewall member coupled to the lower member, and an upper member. The lower member, the at least one sidewall member, and the upper member include at least one conductive layer to form a cavity in a substrate for allowing communications between devices that are coupled or attached to the substrate.

Abstract: Embodiments include devices and methods, including a method for processing a substrate. The method includes providing a substrate including a first portion and a second portion, the first portion including a feature, the feature including an electrically conductive region, the second portion including a dielectric surface region. The method also includes performing self-assembled monolayer (SAM) assisted structuring plating to form a structure comprising a metal on the dielectric surface region, the feature being formed using a process other than the SAM assisted structuring plating used to form the structure, and the structure being formed after the feature. Other embodiments are described and claimed.

Abstract: The present disclosure is directed to systems and methods for communicating between rack mounted devices disposed in the same or different racks separated by distances of less than a meter to a few tens of meters. The system includes a CMOS first mm-wave engine that includes mm-wave transceiver circuitry, mm-wave MODEM circuitry, power distribution and control circuitry, and a mm-wave waveguide connector. The CMOS first mm-wave engine communicably couples to a CMOS second mm-wave engine that also includes mm-wave transceiver circuitry, mm-wave MODEM circuitry, power distribution and control circuitry, and a mm-wave waveguide connector. In some implementations, at least a portion of the mm-wave transceiver circuitry may be fabricated using III-V semiconductor manufacturing methods. The use of mm-wave communication techniques beneficially improves data integrity and increases achievable datarates, and reduces power costs.

Abstract: An apparatus system is provided which comprises: a fabric; a self-assembled monolayer (SAM) material formed on the fabric; and a battery cell formed on the fabric, wherein a current collector of the battery cell is at least in part formed on the SAM material.

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 present disclosure may relate to a transceiver to transmit and receive concurrently radio frequency (RF) signals via a dielectric waveguide. In embodiments, the transceiver may include a transmitter to transmit to a paired transceiver a channelized radio frequency (RF) transmit signal via the dielectric waveguide. A receiver may receive from the paired transceiver a channelized RF receive signal via the dielectric waveguide. In embodiments, the channelized RF receive signal may include an echo of the channelized RF transmit signal. The transceiver may further include an echo suppression circuit to suppress from the channelized RF receive signal the echo of the channelized RF transmit signal. In some embodiments, the channelized RF transmit signal and the channelized RF receive signal may be within a frequency range of approximately 30 gigahertz (GHz) to approximately 1 terahertz (THz), and the transceiver may provide full-duplex millimeter-wave communication.

Abstract: This disclosure relates generally to devices, systems, and methods for making a flexible microelectronic assembly. In an example, a polymer is molded over a microelectronic component, the polymer mold assuming a substantially rigid state following the molding. A routing layer is formed with respect to the microelectronic component and the polymer mold, the routing layer including traces electrically coupled to the microelectronic component. An input is applied to the polymer mold, the polymer mold transitioning from the substantially rigid state to a substantially flexible state upon application of the input.

Abstract: Some forms relate to a stretchable computing device. The stretchable computing device includes a first layer that includes electrical interconnects at a first density wherein the first layer includes a first electronic component; a stretchable second layer electrically connected to the first layer, wherein the stretchable second layer includes electrical interconnects at a second density that is less than the first density, wherein the second layer includes a second electronic component; and a stretchable third layer electrically connected to the stretchable second layer, wherein the stretchable third layer includes electrical interconnects at a third density that is less than the second density.

Abstract: Communication is described between integrated circuit packages using a millimeter-wave wireless radio fabric. In one example a first package has a radio transceiver to communicate with a radio transceiver of a second package. The second package has a radio transceiver to communicate with the radio transceiver of the first package. A switch communicates with the first package and the second package to establish a connection through the respective radio transceivers between the first package and the second package. A system board carries the first package, the second package, and the switch.