Abstract: A seamless cross-environment workflow is provided in a multi-operating system computing environment. The multi-operating system computing environment may include a mobile operating system and a desktop operating system running concurrently and independently on a mobile computing device. Two or more application programs, running in independent operating systems, share user interaction state information including user data, user settings, and/or application context information. Interaction state information may be shared for applications that are used primarily to access and edit local user content as well as applications that communicate to a remote server or access and navigate other remote content (e.g., Internet-based application, browser, etc.). The mobile computing device may be a smartphone running the Android mobile operating system and a full desktop Linux distribution on a modified Android kernel.

Abstract: Cross-environment rendering and user interaction support provide a seamless computing experience in a multi-operating system computing environment. The multi-operating system computing environment may include a mobile operating system and a desktop operating system running concurrently and independently on a mobile computing device. The seamless computing experience includes mirroring the active user interaction space of the mobile operating system to a display of a user environment associated with the desktop operating system. The user interface is rendered by the desktop operating system by accessing surface information of the active user interaction space directly from shared memory. The mobile computing device may be a smartphone running the Android mobile operating system and a full desktop Linux distribution on a modified Android kernel.

Abstract: A mobile computing device with a mobile operating system and desktop operating system running concurrently and independently on a shared kernel without virtualization. The mobile operating system provides a user experience for the mobile computing device that suits the mobile environment. The desktop operating system provides a full desktop user experience when the mobile computing device is docked to a secondary terminal environment. The desktop operating system may be suspended when the mobile computing device is not docked with a secondary terminal environment and resumed when the mobile computing device is docked with a secondary terminal environment that provides a desktop computing experience. The mobile computing device may be a smartphone running the Android mobile OS and a full desktop Linux OS distribution on a modified Android kernel.

Abstract: A mobile computing device with a mobile operating system and desktop operating system running concurrently and independently on a shared kernel without virtualization. The mobile operating system provides a user experience for the mobile computing device that suits the mobile environment. The desktop operating system provides a full desktop user experience when the mobile computing device is docked to a secondary terminal environment. The mobile computing device configures the mobile operating system and/or the desktop operating system to take advantage of a docked secondary terminal environment. The mobile computing device may be a smartphone running the Android mobile OS and a full desktop Linux OS distribution on a modified Android kernel.

Abstract: A mobile computing device with a mobile operating system and desktop operating system running concurrently and independently on a shared kernel without virtualization. The mobile operating system provides a user experience for the mobile computing device that suits the mobile environment. The desktop operating system provides a full desktop user experience when the mobile computing device is docked to a second user environment. Cross-environment rendering and user interaction support provide a seamless computing experience in a multi-operating system computing environment. The seamless computing experience includes mirroring the active user interaction space of the mobile operating system to a display of a user environment associated with the desktop operating system. The mobile computing device may be a smartphone running the Android mobile operating system and a full desktop Linux distribution on a modified Android kernel.

Abstract: Cross-environment rendering and user interaction support provide a seamless computing experience in a multi-operating system computing environment. The multi-operating system computing environment may include a mobile operating system and a desktop operating system running concurrently and independently on a mobile computing device. Full user interaction support is provided for redirected and/or mirrored applications that are rendered using an extended graphics context. An extended input queue handles input events from virtual input devices for remotely displayed applications. Remotely displayed applications are mapped to separate motion spaces within the input queue. The mobile computing device may be a smartphone running the Android mobile operating system and a full desktop Linux distribution on a modified Android kernel.

Abstract: A mobile computing device with a mobile operating system and desktop operating system running concurrently and independently on a shared kernel without virtualization. The mobile operating system provides a user experience for the mobile computing device that suits the mobile environment. The desktop operating system provides a full desktop user experience when the mobile computing device is docked to a secondary terminal environment. The mobile computing device may be a smartphone running the Android mobile OS and a full desktop Linux distribution on a modified Android kernel.

Abstract: A method of tagging a location using a mobile device entails obtaining position data for a current location of the mobile device, detecting a proximity of another device using a short-range wireless interface, and automatically storing the position data for the current location of the mobile device in response to the detecting of the proximity of the other device. The proximity detector may comprise a near field communication (NFC) interface, a Bluetooth® transceiver or another short-range wireless technology that may be employed to detect the proximity of another device. This technology enables two devices to store a current location to facilitate a subsequent rendezvous back at that same location.

Abstract: A fiber optic splice tray that has an increased fiber capacity and maximizes bend radius. The fiber optic splice tray has multiple manifolds that are stacked on top of each other to form manifold stacks. Also, the fiber optic splice tray has two sets of manifold stacks.

Abstract: The described embodiments relate generally to systems and methods for providing direct and indirect navigation modes on mobile devices comprising a touch screen display based on a determined characteristic of the mobile device. In example embodiments, upon detecting a first characteristic, touch screen input is interpreted as direct navigation input. Upon detecting that the characteristic of the mobile device has changed, touch screen input may be interpreted as indirect navigation input. The touch screen display of the mobile device may also be reconfigured as a result of determining the change in the characteristic of the mobile device.

Abstract: A process is provided for the preparation of a compound of formula (1) wherein R and R? represent optionally substituted hydrocarbyl groups and X represents a hydrocarbyl linking group. The process comprises either the stereoselective reduction of the keto group in a dihydroxy keto precursor followed by selective esterification of a primary hydroxy, or selective esterification of a primary hydroxy of a dihydroxy keto precursor followed by stereoselective reduction of the keto group.

Abstract: In embodiments of the invention, bundles of carbon nanotubes are separated from individual nanotubes via interfacial trapping of bundled carbon nanotube bundles at an emulsion interface between suspension-phase and a solution-phase. The separation method comprises dispersing a mixture of individual and bundled carbon nanotubes in a solution comprising surfactant; adding at least one solvent to the surfactant solution to form a two-phase mixture; agitating the two-phase mixture to form an emulsion interface between the solution-phase and a suspension-phase, where nanotube bundles selectively segregate to the emulsion interface. Single-walled carbon nanotube suspensions exhibit strong fluorescence, which can be used to assess the degree of separation and determine if a repeated extraction of any remaining bundled carbon nanotubes remaining in the suspension-phase is desired. In another embodiment of the invention, separation of carbon nanotubes by type is carried out by interfacial trapping.

Abstract: A process is provided for the preparation of a compound of formula (1) wherein R and R? represent optionally substituted hydrocarbyl groups and X represents a hydrocarbyl linking group. The process comprises either the stereoselective reduction of the keto group in a dihydroxy keto precursor followed by selective esterification of a primary hydroxy, or selective esterification of a primary hydroxy of a dihydroxy keto precursor followed by stereoselective reduction of the keto group.

Abstract: A process is provided for the preparation of a compound of formula (1) wherein R and R? represent optionally substituted hydrocarbyl groups and X represents a hydrocarbyl linking group. The process comprises either the stereoselective reduction of the keto group in a dihydroxy keto precursor followed by selective esterification of a primary hydroxy, or selective esterification of a primary hydroxy of a dihydroxy keto precursor followed by stereoselective reduction of the keto group.

Abstract: Compounds of formula (I) and their use in therapy, particularly for the treatment of a disorder mediated by CB1 receptors wherein R1 is a radical of formula -(Alk1)m-(NH)p-(Alk2)n-Q wherein m, n and p are independently 0 or 1, Alk1 and Alk2 are straight or branched chain divalent C1-C6 alkylene or C2-C6 alkenylene radicals, and Q is (i) hydrogen, except in the case where m, n and p are each 0, or (ii) an optionally substituted carbocyclic or heterocyclic group; R2 is hydrogen, C1-C3 alkyl, cyclopropyl, or —CF3; Ring A is a phenyl or 5- or 6-membered heteroaryl ring either of which is optionally substituted; Ar is a phenyl or 5- or 6-membered heteroaryl ring either of which is optionally substituted; L is —CH2—, —C(?O)—, —NH—, —O—, —S—, —SO—, —SO2—, —(CH2)2—, —CH?CH—, —OCH2—, —CH(CH3)—, or —NH—CH2—; s is 1 and W is an optionally substituted N-containing heterocyclic ring of 5 to 7 ring atoms; or s is 0 and W is an optionally substituted N-containing saturated heterocyclic ring of 5 to 7 ring atoms, or an N-con

Abstract: A radio base station performs reverse link rate control in a wireless communication network by “stealing” bits on a forward common power control channel. The forward common power control channel is divided into a plurality of frames, with each frame including a plurality of power control groups and each power control group including a plurality of power control slots. The radio base station may dynamically select power control slots depending on user demand to be used for reverse link rate control.

Abstract: A process is provided for the preparation of a compound of formula (1) wherein R and R? represent optionally substituted hydrocarbyl groups and X represents a hydrocarbyl linking group. The process comprises either the stereoselective reduction of the keto group in a dihydroxy keto precursor followed by selective esterification of a primary hydroxy, or selective esterification of a primary hydroxy of a dihydroxy keto precursor followed by stereoselective reduction of the keto group.

Abstract: There is provided an aqueous liquid domestic composition comprising (i) one or more active component selected from the group consisting of (A) 3% to 50% by weight, based on the total solids weight of said domestic composition, one or more softening agent, (B) 2% to 90% by weight, based on the total solids weight of said domestic composition, one or more anionic surfactant, and (C) a mixture consisting of (I) 1% to 25% by weight, based on the total solids weight of said domestic composition, one or more softening agent, and (II) 5% to 75% by weight, based on the total solids weight of said domestic composition, one or more anionic surfactant, and (D) 0.1% to 30% by weight, based on the total solids weight of said domestic composition, one or more amphoteric compound; and(ii) one or more cationic polymer latex comprising (I) 0.5% to 6% by weight, based on the dry weight of said polymer, one or more cationic monomer, (II) 30% to 99.

Abstract: A process is provided for the preparation of a compound of formula (1) wherein R and R? represent optionally substituted hydrocarbyl groups and X represents a hydrocarbyl linking group. The process comprises either the stereoselective reduction of the keto group in a dihydroxy keto precursor followed by selective esterification of a primary hydroxy, or selective esterification of a primary hydroxy of a dihydroxy keto precursor followed by stereoselective reduction of the keto group.

Abstract: An apparatus and method provide MAC logic enabling the use of two or more reverse link rate controls at the same time in one or more sectors of a radio base station. That enables the base station to control reverse link loading via reverse link rate control, while assigning mobile stations to the type of reverse link rate control best suited to their needs. For example, the base station MAC logic may implement both a common rate controller that generates per-sector rate control commands, and a dedicated rate controller that generates per-user rate control commands and assign mobile stations having relatively lax reverse link service needs to the common rate controller, while assigning mobile stations having more demanding reverse link service requirements to the dedicated rate control. More than two rate controls can be implemented, and exemplary choices include per-user, per-sector, per-group, and scheduled rate control in any combination.