Abstract: The present disclosure relates to a semiconductor package and method of making the same. The semiconductor package includes an encapsulation layer, a component within the encapsulation layer, a first dielectric layer, a second dielectric layer, a first patterned conductive layer, and a second patterned conductive layer. The component includes pads on a front surface of the component. The first dielectric layer is disposed on a surface of the encapsulation layer. The second dielectric layer is disposed on a surface of the first dielectric layer. The first and second dielectric layers define via holes extending from the second dielectric layer to respective ones of the pads. The first patterned conductive layer is disposed within the first dielectric layer and surrounds the via holes. The second patterned conductive layer is disposed within the second dielectric layer and surrounds the via holes.

Abstract: Providing for improved sensing of non-volatile resistive memory to achieve higher sensing margins, is described herein. The sensing can leverage current-voltage characteristics of a volatile selector device within the resistive memory. A disclosed sensing process can comprise activating the selector device with an activation voltage, and then lowering the activation voltage to a holding voltage at which the selector device deactivates for an off-state memory cell, but remains active for an on-state memory cell. Accordingly, very high on-off ratio characteristics of the selector device can be employed for sensing the resistive memory, providing sensing margins not previously achievable for non-volatile memory.

Abstract: A method of a cross-region multilevel band broadcast structure includes: selecting a main band for broadcasting in a full region; selecting a first secondary band for broadcasting in a first region within the full region; and selecting a second secondary band for broadcasting in a second region within the full region. The main band, the first secondary band and the second secondary band are different bands.

Abstract: A method includes performing a first strike process to strike a metal bump of a first package component against a metal pad of a second package component. A first one of the metal bump and the metal pad includes copper. A second one of the metal bump and the metal pad includes aluminum. The method further includes performing a second strike process to strike the metal bump against the metal pad. An annealing is performed to bond the metal bump on the metal pad.

Abstract: A complementary metal oxide semiconductor (CMOS) device is disclosed. The CMOS device includes a substrate with a first device region and a second device region formed thereon. A first isolation structure is formed in the first device region, and includes a first trench filled with a first material. A second isolation structure is formed in the second device region and includes a second trench filled with a second material. The first material and the second material have different stresses. A first gate structure is disposed atop the first material and completely covering the first trench. A second gate structure is disposed atop the second material and completely covering the second trench.

Abstract: Providing for a configuration cells for junction nodes of a field programmable gate array (FPGA) is described herein. By way of example, a configuration cell can comprise non-volatile resistive switching memory to facilitate programmable storage of data as an input to a control circuit of a junction node. The control circuit can activate or deactivate a junction node of the FPGA in response to a value of the data stored in the non-volatile resistive switching memory. The control circuit can comprise an SRAM circuit for fast operation of the junction node. Moreover, the non-volatile memory of the configuration cell facilitates fast power-up of the control circuit utilizing data stored in the resistive switching memory, and minimizes power consumption associated with storing the data.

Abstract: An integrated module having an antenna comprises a module substrate, a camera module and the antenna disposed on the module substrate. The antenna comprises a grounding portion connected to ground plane, a low-frequency radiating arm, a high-frequency radiating arm, a feed-in line and a shorting portion. A connection portion of the low-frequency radiating arm and a connection portion of the high-frequency radiating arm are connected to the grounding portion. A free-end portion of the high-frequency radiating arm and a free-end portion of the low-frequency radiating arm are back-to-back and extend towards opposite directions. The feed-in line is perpendicular to an edge of the ground plane and extends away from the ground plane. The feed-in line crosses and connects the high-frequency radiating arm to provide a second feeding-point. The end of the feed-in line is connected to the connection portion of the low-frequency radiating arm to provide a first feeding-point.

Abstract: Providing for improved sensing of non-volatile resistive memory to achieve higher sensing margins, is described herein. The sensing can leverage current-voltage characteristics of a volatile selector device within the resistive memory. A disclosed sensing process can comprise activating the selector device with an activation voltage, and then lowering the activation voltage to a holding voltage at which the selector device deactivates for an off-state memory cell, but remains active for an on-state memory cell. Accordingly, very high on-off ratio characteristics of the selector device can be employed for sensing the resistive memory, providing sensing margins not previously achievable for non-volatile memory.

Abstract: A system of integrated module with antenna used for an electronic device comprises a circuit board, at least one antenna exciting unit, a wireless module, a module grounding plane, a grounding metal, a camera module and a digital signal line. The antenna exciting unit is used to couple with an antenna. The wireless module and the camera module are disposed on the circuit board to couple with the module grounding plane. The wireless module is electrically connected to the antenna exciting unit. The grounding metal is electrically connected to the module grounding plane and a system grounding plane. The digital signal line is electrically connected to the wireless module and the camera module is a digital transmission media. The wireless module, the camera module and the circuit board constitute an integrated module for disposing at an up-side of a screen of the electronic device.

Abstract: The present disclosure relates to a semiconductor package and method of making the same. The semiconductor package includes an encapsulation layer, a dielectric layer, a component, and a first patterned conductive layer. The encapsulation layer has a first surface. The component is within the encapsulation layer and has a front surface and a plurality of pads on the front surface. The dielectric layer is on the first surface of the encapsulation layer, and defines a plurality of via holes; wherein the plurality of pads of the component are against the dielectric layer; and wherein the dielectric layer has a second surface opposite the first surface of the encapsulation layer. Each of plurality of via holes extends from the second surface of the dielectric layer to a respective one of the plurality of the pads. The first patterned conductive layer is within the dielectric layer and surrounds the via holes.

Abstract: A method includes performing a first strike process to strike a metal bump of a first package component against a metal pad of a second package component. A first one of the metal bump and the metal pad includes copper. A second one of the metal bump and the metal pad includes aluminum. The method further includes performing a second strike process to strike the metal bump against the metal pad. An annealing is performed to bond the metal bump on the metal pad.

Abstract: A non-volatile programmable circuit configurable to perform logic functions, is provided. The programmable circuit can employ two-terminal non-volatile memory devices to store information, thereby mitigating or avoiding disturbance of programmed data in the absence of external power. Two-terminal resistive switching memory devices having high current on/off ratios and fast switching times can also be employed for high performance, and facilitating a high density array. For look-up table applications, input/output response times can be several nanoseconds or less, facilitating much faster response times than a memory array access for retrieving stored data.

Abstract: Providing for improved sensing of non-volatile resistive memory to achieve higher sensing margins, is described herein. The sensing can leverage current-voltage characteristics of a volatile selector device within the resistive memory. A disclosed sensing process can comprise activating the selector device with an activation voltage, and then lowering the activation voltage to a holding voltage at which the selector device deactivates for an off-state memory cell, but remains active for an on-state memory cell. Accordingly, very high on-off ratio characteristics of the selector device can be employed for sensing the resistive memory, providing sensing margins not previously achievable for non-volatile memory.

Abstract: A method includes performing a first strike process to strike a metal bump of a first package component against a metal pad of a second package component. A first one of the metal bump and the metal pad includes copper. A second one of the metal bump and the metal pad includes aluminum. The method further includes performing a second strike process to strike the metal bump against the metal pad. An annealing is performed to bond the metal bump on the metal pad.

Abstract: A method for forming a pattern includes steps of forming a patterned core layer on a substrate, conformally forming a spacer layer on the patterned core layer to form first concave portions, performing an etch back process to expose the patterned core layer, removing the exposed patterned core layer to form second concave portions, filling up the first concave portions and the second concave portions with a directed self-assembly material, and activating a directed self-assembly process, so that the directed self-assembly material is diffused to the perimeter of the concave portions to form a hole surrounding by the directed self-assembly material in each concave portions.

Abstract: A method for forming a pattern includes steps of forming a patterned core layer on a substrate, conformally forming a spacer layer on the patterned core layer to form first concave portions, performing an etch back process to expose the patterned core layer, removing the exposed patterned core layer to form second concave portions, filling up the first concave portions and the second concave portions with a directed self-assembly material, and activating a directed self-assembly process, so that the directed self-assembly material is diffused to the perimeter of the concave portions to form a hole surrounding by the directed self-assembly material in each concave portions.

Abstract: Integrated circuits with memory elements are provided. An integrated circuit may include logic circuitry formed in a first portion having complementary metal-oxide-semiconductor (CMOS) devices and may include at least a portion of the memory elements and associated memory circuitry formed in a second portion having nano-electromechanical (NEM) relay devices. The NEM and CMOS devices may be interconnected through vias in a dielectric stack. Devices in the first and second portions may receive respective power supply voltages. In one suitable arrangement, the memory elements may include two relay switches that provide nonvolatile storage characteristics and soft error upset (SEU) immunity. In another suitable arrangement, the memory elements may include first and second cross-coupled inverting circuits. The first inverting circuit may include relay switches, whereas the second inverting circuit includes only CMOS transistors.

Abstract: A gate oxide formation process includes the following steps. A first gate oxide layer is formed on a substrate. The first gate oxide layer is thinned to a first predetermined thickness. The first gate oxide layer is then thickened to a second predetermined thickness, to thereby form a second gate oxide layer.

Abstract: A method of fabricating a spatial semiconductor structure includes steps as follows. Firstly, a semiconductor substrate is provided. Then, a first mask layer is formed above the semiconductor substrate. Then, at least a first opening is formed in the first mask layer and exposes a portion of a surface of the semiconductor substrate. Then, a first semiconductor pattern is formed in the first opening. Then, a second mask layer is formed over the first semiconductor pattern and the first mask layer. Then, at least a second opening is formed through the second mask layer to the first mask layer and exposes another portion of the surface of the semiconductor substrate. And, a second semiconductor pattern is formed in the second opening.