Aspects of the present disclosure can receive a hardware Vsync signal from a display, generate a hardware timestamp signal based on the hardware Vsync signal, determine an error for a pulse in the hardware timestamp signal, determine whether the error for the pulse is over a threshold, synchronize a software Vsync signal based on the hardware timestamp signal, wherein the pulse of the hardware timestamp signal is ignored in synchronization based on whether the error is above the threshold, and control rendering and transmission of a frame to the display based on the synchronized software Vsync signal.

Embodiments of this application relate to the field of image processing and display technologies, and provide a method for image processing based on vertical synchronization signals and an electronic device, to shorten a response latency of the electronic device and improve fluency (such as a touch latency) of the electronic device. A specific solution includes: drawing, by the electronic device, one or more first layers in response to a first vertical synchronization signal, and rendering the one or more first layers, and after rendering the one or more first layers, performing layer composing on the rendered one or more first layers to obtain a first image frame; and refreshing and displaying the first image frame in response to a second vertical synchronization signal.

An information handling system includes a timing controller configured to transmit a command for a common voltage of a particular frame rate to a power management circuit. A storage component may store digital information, wherein each digital information is associated with the common voltage of a particular frame rate. The power management circuit supports a variety of common voltage requirements of the liquid crystal display including an ability to select digital information of the digital information that is associated with the common voltage at the particular frame rate stored in the storage component and apply the common voltage at the particular frame rate to the liquid crystal display.

Touch, multi-touch, gesture, flick and stylus pen input may be supported for remoted applications. For example, a touch capable client device may receive touch input for a remoted application executing on a server. In such an instance, the touch input may be transmitted to the server for processing. The server may modify the application display or the application functionality and provide an output to the client device. In some arrangements, the output may correspond to instructions for modifying a display of the application while in other examples, the output may correspond to an image of the changed application display. Additionally or alternatively, determining a functionality associated with touch input may be performed based on user definitions, user preferences, server definitions (e.g., operating system on the server), client definitions (e.g., operating system on the client) and the like and/or combinations thereof. Aspects may also include resolving latency and enhancing user experience.

Touch, multi-touch, gesture, flick and stylus pen input may be supported for remoted applications. For example, a touch capable client device may receive touch input for a remoted application executing on a server. In such an instance, the touch input may be transmitted to the server for processing. The server may modify the application display or the application functionality and provide an output to the client device. In some arrangements, the output may correspond to instructions for modifying a display of the application while in other examples, the output may correspond to an image of the changed application display. Additionally or alternatively, determining a functionality associated with touch input may be performed based on user definitions, user preferences, server definitions (e.g., operating system on the server), client definitions (e.g., operating system on the client) and the like and/or combinations thereof. Aspects may also include resolving latency and enhancing user experience.

Examples are disclosed herein related to controlling a scanning mirror system. One example provides a display device, comprising a light source, a scanning mirror system configured to scan light from the light source in a first direction at a first, higher scan rate, and in a second direction at a second, lower scan rate, and a drive circuit configured to control the scanning mirror system to display video image data by providing a control signal to the scanning mirror system to control scanning in the second direction, and for each video image data frame of at least a subset of video image data frames, combining the control signal with an adjustment signal to adjust the scanning in the second direction, the adjustment signal comprising a low pass filtered signal with a cutoff frequency based on a lowest resonant frequency of the scanning mirror system in the second direction.

PWM-frame rate misalignment is mitigated through implementation of a discrete variable refresh rate (VRR) scheme. A target frame rate is limited to a frame rate selected from only those frame rates that facilitate alignment of each frame period to a specified edge of a PWM cycle of a brightness control signal of a display panel. This alignment results in each frame period at the selected frame rate starting at a same point in a corresponding PWM cycle and ending at a same point in a corresponding PWM cycle to help ensure a constant effective duty cycle across each successive frame period, which in turn mitigates perception of flicker that otherwise would arise. Further, the discrete VRR scheme can employ a compensation mode for compensating for the delay in rendering or otherwise obtaining a frame for display so as to maintain a consistent duty cycle in the brightness control signal.

Even under a situation where an object to be presented has movement, the object can be presented as display information in a more favorable mode. An information processing apparatus includes an acquisition unit (111) that acquires information regarding movement of an object, and a control unit (111) that projects the object in a display region at a projection timing set according to a first period, and corrects display information according to a result of the projection in accordance with a plurality of display timings each set for each second period shorter than the first period, and the control unit controls correction of second display information to maintain continuity according to the movement of the object between first display information displayed according to a first projection result of the object in accordance with a first display timing, and the second display information displayed according to a second projection result of the object in accordance with a second display timing immediately after the first display timing.

The present application discloses a display apparatus and a drive method thereof. The display apparatus includes a display panel, and a panel chive circuit configured to drive the display panel; and a timing controller respectively transmits a signal to source drivers and a gate driver via the bus.

The present application discloses a display apparatus and a drive method thereof. The display apparatus includes a display panel, and a panel chive circuit configured to drive the display panel; and a timing controller respectively transmits a signal to source drivers and a gate driver via the bus.