Abstract: The disclosure provides a method for optimizing remote display at a client device in communication with a remote desktop. The method generally includes receiving one or more frames for display at the client device, determining that a frame rate of the received one or more frames is less than an expected frame rate and/or a resolution of the received one or more frames is less than an expected resolution, determining that at least one of a local central processing unit (CPU) usage at the client device is less than a CPU usage threshold or a local graphics processing unit (GPU) usage at the client device is less than a GPU usage threshold, applying one or more enhancement techniques to the received one or more frames to produce one or more optimized frames while continuously monitoring the local CPU usage and/or the local GPU usage at the client device, and rendering the one or more optimized frames for display at the client device.

Abstract: The disclosure provides a method for optimizing remote display at a client device in communication with a remote desktop. The method generally includes receiving one or more frames for display at the client device, determining that a frame rate of the received one or more frames is less than an expected frame rate and/or a resolution of the received one or more frames is less than an expected resolution, determining that at least one of a local central processing unit (CPU) usage at the client device is less than a CPU usage threshold or a local graphics processing unit (GPU) usage at the client device is less than a GPU usage threshold, applying one or more enhancement techniques to the received one or more frames to produce one or more optimized frames while continuously monitoring the local CPU usage and/or the local GPU usage at the client device, and rendering the one or more optimized frames for display at the client device.

Abstract: A logon screen and a user interface (UI) element used in connection with a remote desktop are resized, by presenting the logon screen and UI element in a connection/viewing window having a size that has been reduced to be smaller than the topology of a display screen of a user device. After the logon process is completed, a window of the remote desktop and/or a window of an application installed on the remote desktop can be sized/resized to a larger size for use by the user.

Abstract: A system is described for scaling display content on a computing device based on user-to-device distance. A measurement is taken of the distance between the user and the device and a scaling setting is determined using a predefined rule based on the measured distance. The scaling setting is applied to scale content on the display based on the user-to-device distance by changing settings in the operating system or changing scaling in an application. Embodiments include virtual desktop/application and localized implementations.

Abstract: A system is described for scaling display content on a computing device based on user-to-device distance. A measurement is taken of the distance between the user and the device and a scaling setting is determined using a predefined rule based on the measured distance. The scaling setting is applied to scale content on the display based on the user-to-device distance by changing settings in the operating system or changing scaling in an application. Embodiments include virtual desktop/application and localized implementations.

Abstract: Hybrid elements that enable coupling effects between SPH particles and FEM solid are disclosed. According to one aspect of the present invention, hybrid elements are configured to facilitate coupling effect of solid element based on finite element method (FEM) and one or more corresponding particles based on smoothed particle hydrodynamics (SPH). Hybrid elements are defined in a computer aided engineering (CAE) grid model as a buffer or interface between the SPH particles and FEM solids. For example, a portion of the grid model comprises SPH particles because the likelihood of enduring large deformation, while the rest of the model comprises FEM solid elements. Hybrid elements are placed between the solids and the particles. Each hybrid element comprises two layers: solid layer and particle layer.

Abstract: Hybrid elements that enable coupling effects between SPH particles and FEM solid are disclosed. According to one aspect of the present invention, hybrid elements are configured to facilitate coupling effect of solid element based on finite element method (FEM) and one or more corresponding particles based on smoothed particle hydrodynamics (SPH). Hybrid elements are defined in a computer aided engineering (CAE) grid model as a buffer or interface between the SPH particles and FEM solids. For example, a portion of the grid model comprises SPH particles because the likelihood of enduring large deformation, while the rest of the model comprises FEM solid elements. Hybrid elements are placed between the solids and the particles. Each hybrid element comprises two layers: solid layer and particle layer.