Abstract: Package-on-package (“PoP”) devices with upper RDLs of WLP (“WLP”) components and methods therefor are disclosed. In a PoP device, a first IC die is surface mount coupled to an upper surface of the package substrate. Conductive lines are coupled to the upper surface of the package substrate in a fan-out region with reference to the first IC. A molding layer is formed over the upper surface of the package substrate. A first and a second WLP microelectronic component is located at a same level above an upper surface of the molding layer respectively surface mount coupled to sets of upper portions of the conductive lines. Each of the first and the second WLP microelectronic components have a second IC die located below a first RDL respectively thereof. A third and a fourth IC die are respectively surface mount coupled over the first and the second WLP microelectronic components.

Abstract: Package-on-package (“PoP”) devices with WLP (“WLP”) components with dual RDLs (“RDLs”) for surface mount dies and methods therefor. In a PoP, a first IC die surface mount coupled to an upper surface of a package substrate. Conductive lines are coupled to the upper surface of the package substrate in a fan-out region. A molding layer is formed over the upper surface of the package substrate. A first and a second WLP microelectronic component are located at a same level above an upper surface of the molding layer respectively surface mount coupled to sets of upper portions of the conductive lines. Each of the first and the second WLP microelectronic components have a second IC die located between a first RDL and a second RDL. A third and a fourth IC die are respectively surface mount coupled over the first and the second WLP microelectronic components.

Abstract: Package-on-package (“PoP”) devices with same level wafer-level packaged (“WLP”) components and methods therefor are disclosed. In a PoP device, a first integrated circuit die is surface mount coupled to an upper surface of a package substrate. Conductive lines are coupled to the upper surface of the package substrate in a fan-out region. The first conductive lines extend away from the upper surface of the package substrate. A molding layer is formed over the upper surface of the package substrate, around sidewall surfaces of the first integrated circuit die, and around bases and shafts of the conductive lines. WLP microelectronic components are located at a same level above an upper surface of the molding layer respectively surface mount coupled to sets of upper portions of the conductive lines.

Abstract: Dies-on-package devices and methods therefor are disclosed. In a dies-on-package device, a first IC die is surface mount coupled to an upper surface of a package substrate. Conductive lines are coupled to the upper surface of the package substrate in a fan-out region with respect to the first IC die. A molding layer is formed over the upper surface of the package substrate, around sidewall surfaces of the first IC die, and around bases and shafts of the conductive lines. A plurality of second IC dies is located at a same level above an upper surface of the molding layer respectively surface mount coupled to sets of upper portions of the conductive lines. The plurality of second IC dies are respectively coupled to the sets of the conductive lines in middle third portions respectively of the plurality of second IC dies for corresponding fan-in regions thereof.

Abstract: Wafer-level packaged components are disclosed. In a wafer-level-packaged, an integrated circuit die has first contacts in an inner third region of a surface of the integrated circuit die. A redistribution layer has second contacts in an inner third region of a first surface of the redistribution layer and third contacts in an outer third region of a second surface of the redistribution layer opposite the first surface thereof. The second contacts of the redistribution layer are coupled for electrical conductivity to the first contacts of the integrated circuit die with the surface of the integrated circuit die face-to-face with the first surface of the redistribution layer. The third contacts are offset from the second contacts for being positioned in a fan-out region for association at least with the outer third region of the second surface of the redistribution layer, the third contacts being surface mount contacts.

Abstract: Hardened fiber optic connectors having a mechanical splice assembly are disclosed. The mechanical splice assembly is attached to a first end of an optical waveguide such as an optical fiber of a fiber optic cable by way of a stub optical fiber, thereby connectorizing the hardened connector. In one embodiment, the hardened connector includes an inner housing having two shells for securing a tensile element of the cable and securing the mechanical splice assembly so that a ferrule assembly may translate. Further assembly of the hardened connector has the inner housing fitting into a shroud of the hardened connector. The shroud aides in mating the hardened connector with a complimentary device and the shroud may have any suitable configuration. The hardened connector may also include features for fiber buckling, sealing, cable strain relief or a pre-assembly for ease of installation.

Abstract: A microelectronic assembly includes a plurality of stacked microelectronic packages, each comprising a dielectric element having a major surface, an interconnect region adjacent an interconnect edge surface which extends away from the major surface, and plurality of package contacts at the interconnect region. A microelectronic element has a front surface with chip contacts thereon coupled to the package contacts, the front surface overlying and parallel to the major surface. The microelectronic packages are stacked with planes defined by the dielectric elements substantially parallel to one another, and the package contacts electrically coupled with panel contacts at a mounting surface of a circuit panel via an electrically conductive material, the planes defined by the dielectric elements being oriented at a substantial angle to the mounting surface.

Abstract: An apparatus including a die including a first side and an opposite second side including a device side with contact points; and a build-up carrier including at least one layer of conductive material disposed on a first side of the die, and a plurality of alternating layers of conductive material and dielectric material disposed on the second side of the die, wherein the at least one layer of conductive material on the first side of the die is coupled to at least one of (1) at least one of the alternating layers of conductive material on the second side of the die and (2) at least one of the contact points of the die. A method including forming a first portion of a build-up carrier adjacent one side of a die, and forming a second portion of the build-up carrier adjacent another side of the die.

Abstract: A clip is used for carrying a chip module to assemble to an electrical connector along a vertical direction. The clip includes a retaining mechanism retaining the chip module and a central opening provided for a part portion of the chip module going through. The clip has an anti-mismating member. When the clip is assembled to the electrical connector by itself disposed in a right-to-left direction perpendicular to the vertical direction or reversely relative to a front-to-back direction perpendicular to the vertical direction, the anti-mismating member stops the clip to be assembled to the electrical connector.

Abstract: Integration of sensor chips with integrated circuit (IC) chips. At least a first sensor chip including a first sensor is affixed to a first side of an interposer to hermetically seal the first sensor within a first cavity. An IC chip is affixed to a second side of the interposer opposite the first sensor, the IC chip is electrically coupled to the first sensor by a through via in the interposer. In embodiments, the first sensor includes a MEMS device and the IC chip comprises a circuit to amplify a signal from the MEMS device. The interposer may be made of glass, with the first sensor chip and the IC chip flip-chip bonded to the interposer by compression or solder. Lateral interconnect traces provide I/O between the devices on the interposer and/or a PCB upon which the interpose is affixed.

Abstract: Integration of sensor chips with integrated circuit (IC) chips. At least a first sensor chip including a first sensor is affixed to a first side of an interposer to hermetically seal the first sensor within a first cavity. An IC chip is affixed to a second side of the interposer opposite the first sensor, the IC chip is electrically coupled to the first sensor by a through via in the interposer. In embodiments, the first sensor includes a MEMS device and the IC chip comprises a circuit to amplify a signal from the MEMS device. The interposer may be made of glass, with the first sensor chip and the IC chip flip-chip bonded to the interposer by compression or solder. Lateral interconnect traces provide I/O between the devices on the interposer and/or a PCB upon which the interpose is affixed.

Abstract: Integration of sensor chips with integrated circuit (IC) chips. At least a first sensor chip including a first sensor is affixed to a first side of an interposer to hermitically seal the first sensor within a first cavity. An IC chip is affixed to a second side of the interposer opposite the first sensor, the IC chip is electrically coupled to the first sensor by a through via in the interposer. In embodiments, the first sensor includes a MEMS device and the IC chip comprises a circuit to amplify a signal from the MEMS device. The interposer may be made of glass, with the first sensor chip and the IC chip flip-chip bonded to the interposer by compression or solder. Lateral interconnect traces provide I/O between the devices on the interposer and/or a PCB upon which the interpose is affixed.

Abstract: A method for making a hydrophilic carbon nanotube film is provided. A reactor, an oxidative acid solution disposed in the reactor, and at least one primary carbon nanotube film are provided. The primary carbon nanotube film is set in the reactor disposed apart from the oxidative acid solution. The oxidative acid solution is then volatilized to form oxidative acid gas and the reactor is filled with the oxidative acid gas.

Abstract: An apparatus including a die including a first side and an opposite second side including a device side with contact points; and a build-up carrier including at least one layer of conductive material disposed on a first side of the die, and a plurality of alternating layers of conductive material and dielectric material disposed on the second side of the die, wherein the at least one layer of conductive material on the first side of the die is coupled to at least one of (1) at least one of the alternating layers of conductive material on the second side of the die and (2) at least one of the contact points of the die. A method including forming a first portion of a build-up carrier adjacent one side of a die, and forming a second portion of the build-up carrier adjacent another side of the die.

Abstract: Integration of sensor chips with integrated circuit (IC) chips. At least a first sensor chip including a first sensor is affixed to a first side of an interposer to hermitically seal the first sensor within a first cavity. An IC chip is affixed to a second side of the interposer opposite the first sensor, the IC chip is electrically coupled to the first sensor by a through via in the interposer. In embodiments, the first sensor includes a MEMS device and the IC chip comprises a circuit to amplify a signal from the MEMS device. The interposer may be made of glass, with the first sensor chip and the IC chip flip-chip bonded to the interposer by compression or solder. Lateral interconnect traces provide I/O between the devices on the interposer and/or a PCB upon which the interpose is affixed.

Abstract: A method for making a hydrophilic carbon nanotube film is provided. A reactor, an oxidative acid solution disposed in the reactor, and at least one primary carbon nanotube film are provided. The primary carbon nanotube film is set in the reactor disposed apart from the oxidative acid solution. The oxidative acid solution is then volatilized to form oxidative acid gas and the reactor is filled with the oxidative acid gas.