Abstract: Systems and methods for docking portable electronic devices. A master device may be docked to a slave device to control the operation of the slave device. The slave device may have a form factor different than that of the master device. For example, the slave device may be a tablet and the master device may be a handheld device such as a smart phone. The slave device may include a retention mechanism to retain the master device in a docked position with respect to the slave device. When in the docked position, the master device may be in operative communication with one or more hardware components of the slave device to control the operation thereof. The slave device may lack the ability to exploit the full functionality of the one or more hardware components of the slave device without communication with the master device.

Abstract: Methods and devices for selectively presenting a user interface or “desktop” across two devices are provided. More particularly, a unified desktop is presented across a device and a computer system that comprise a unified system. The unified desktop acts as a single user interface that presents data and receives user interaction in a seamless environment that emulates a personal computing environment. To function within the personal computing environment, the unified desktop includes a process for docking and undocking the device with the computer system. The unified desktop presents a new user interface to allow access to functions of the unified desktop.

Abstract: Methods and devices for selectively presenting a user interface or “desktop” across two devices are provided. More particularly, a unified desktop is presented across a device and a computer system that comprise a unified system. The unified desktop acts as a single user interface that presents data and receives user interaction in a seamless environment that emulates a personal computing environment. To function within the personal computing environment, the unified desktop includes a process for docking and undocking the device with the computer system. The unified desktop presents desktops or windows based on the displays that were pre-existing before docking or undocking.

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. A seamless cross-environment workflow is provided in a multi-operating system computing environment. 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 (i.e., Internet-based application, browser).

Abstract: Systems and methods related to the user interface of docking portable electronic devices. A master device may be docked with a slave device to control operation of the slave device. The master device may be operable to display a user interface. The user interface of the master device may be adapted to be used with the slave device that may include different display and/or input devices than that of the master device. In one embodiment, the master device may be a handheld device such as a smart phone and the slave device may be a tablet device.

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 shared kernel of a mobile computing device. User interaction support includes handling input events initially received in the shared kernel by accepting the input events in the desktop operating system and translating, mapping, and/or passing the input events through a virtual input device to the mobile operating system such that applications of the mobile operating system receive the input events as if coming from a user interaction space of the mobile 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 associated with a first user environment and a desktop operating system associated with a second user environment running concurrently and independently on a mobile computing device. User interaction support includes handling input events initially received in the shared kernel by accepting the input events in the desktop operating system and translating, mapping, and/or passing the input events through a virtual input device to the mobile operating system such that applications of the mobile operating system receive the input events as if coming from a user interaction space of the mobile 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: 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: 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 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.