An electro-optical apparatus includes an electro-optical panel having a first end portion, a first connector that is flexible, and a reinforcement member on the first connector. The first connector has a second end portion and a third end portion opposite to the second end portion. The second end portion is connected to the first end portion. The first connector has a first surface connected to the electro-optical panel, and a second surface opposite to the first surface. The reinforcement member is located on the first surface, and extends from an end surface at the first end portion of the electro-optical panel to the third end portion. The first connector has first and second side edges, at least one of which has a first cutout depressed inward. The first and second side edges connect the second and third end portions to each other.

An electronic device. The electronic device includes a first processor configured to generate a first display signal, and a second processor configured to generate a second display signal and output to a display area. The second processor includes a forwarding module, the first processor is connected to the forwarding module, and the first display signal generated by the first processor is output to the display area through the forwarding module.

A method for controlling a display apparatus includes acquiring a plurality of first images from a plurality of first terminals, displaying the plurality of first images on a first screen via a display device, storing a maximum number of first images to be placed on the first screen in a storage circuit, in response to a signal transmitted from a second terminal that supplies a second image and requesting display of the second image, permitting the second terminal to display a second screen containing only the second image via the display device when the number of first images on the first screen is equal to the maximum number, and in response to the signal transmitted from the second terminal, permitting the second terminal to place the second image on the first screen when the number of first images being placed on the first screen is smaller than the maximum number.

Described herein is a computer implemented method. The method comprises receiving, from a server application, project data defining a plurality of tasks and a plurality of iterations, each iteration having a start time and an end time and displaying, on a display, a timeline graphical user interface including a plurality of task timelines, each task timeline corresponding to one of the plurality of tasks. The method further comprises detecting a first user input, the first user input associated with a particular task and, in response to detecting the first user input, displaying a plurality of available drop zones in the particular task's timeline, each available drop zone corresponding to an available iteration, an available iteration being an iteration that the particular task can be assigned to.

The system may provide a one-stop-shop solution for accepting and integrating with almost any video output from a medical device that is typically used in a healthcare facility and sending the video signal to a streaming platform. The system may be configured as a box with a plurality of different types of video input ports, an output port configured for interfacing with an input port of a video streaming device and a port selector configured to indicate which of the input ports is providing video signals to the output port.

There is provided an information processing device including a voltage detection unit configured to monitor a voltage value of a signal output at a predetermined timing, and a signal control unit configured to stop output of the signal if the voltage value after a predetermined time elapses from when the voltage value detected by the voltage detection unit exceeds a first value does not exceed a second value greater than the first value.

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.

Aspects of the subject technology relate to power consuming processes of electronic devices. For example, an electronic device may create, initiate, and/or modify a power consuming process of the electronic device, based in part on user power consumption information that indicates a typical amount of power consumed by a user of the electronic device. The electronic device may recommend increases in power consumption for low power consumption users and/or decreases in power consumption for high power consumption users. A power consumption process may include a visual arrangement of graphical elements that each display periodically, occasionally, and/or continuously updated information from the application, when a full user interface of the application is not displayed.

This application discloses a configuration update method for an LED display screen, a receiver card, an LED display module, and an LED display screen. The method includes: (S201) when it is detected that a receiver card is powered on, reading storage identity authentication data of the receiver card, and verifying whether the receiver card has been replaced; (S202) when it is determined that the receiver card has been replaced, outputting a configuration parameter stored in a memory to the receiver card, to update a configuration parameter of the receiver card; (S203) when it is detected that an LED display module is powered on, reading display identity authentication data of the LED display module, and verifying whether the LED display module has been replaced; and (S204) when it is determined that the LED display module has been replaced, outputting correction data of the LED display module to the receiver card.

A method for a low voltage drive circuit (LVDC) begins by receiving data from one or more other low voltage drive circuits (LVDCs) using a bus with varying loading at one or more frequencies and continues by sampling one or more data values of the data to produce a sampled digital data value, converting the sampled digital data value to a binary string and writing the binary string to a buffer. The method continues by writing one or more additional binary strings to the buffer to form a digital word, outputting the digital word to a digital converter circuit and formatting the digital word to create a formatted digital word. The method continues by writing the formatted digital word to a second buffer, writing additional formatted digital words to the second buffer to form a data packet and finally, outputting the data packet to a host device.