An electronic device includes a communication processor including a first communication circuitry, a second communication circuitry, and a temperature measurement sensor. The electronic device further includes an application processor that receives information via the second communication circuitry and determines whether to request the communication processor change modes. The communication processor receives a signal to change modes, release an RRC connection, and control the second communication circuitry to enter a sleep state.

An electronic device includes an extendable support including a first structure and a second structure to receive at least a portion of the first structure and guide relative movement of the first structure with respect to the second structure, a display having compact and expanded positions based on the relative movement of the first structure, a motor to generate an output force to cause the relative movement of the first and second structures, a sensor to detect a posture in which the electronic device is positioned, and a processor to change the output force of the motor based on the posture of the electronic device detected by the sensor.

An electronic device supporting power consumption reduction can be operated in a power saving mode or in an active mode, and the electronic device includes a first processor and a second processor. The first processor is configured to be powered off when the electronic device is in the power saving mode. The second processor is configured to, when the electronic device is in the power saving mode, control peripheral hardware associated with a local bus of the first processor. The peripheral hardware includes at least one of the following: a display unit, an input unit, a BLUETOOTH unit, and a sensing unit.

An electronic device includes: a location measurement circuitry; a rechargeable battery; a memory configured to store instructions; and at least one processor. The at least one processor may be configured to execute the instructions to: monitor a usage pattern of the battery while the electronic device operates in a first power management state; acquire, based on determining that the usage pattern of the battery is different from a reference pattern derived from a model, information on a location in which the battery is estimated to be charged and information on a time at which the battery is estimated to be charged using the model; and switch, partially based on the information on the location and the information on the time, the first power management state to a second power management state based on a second maximum driving frequency lower than the first maximum driving frequency.

A mobile terminal includes a touch screen display, a camera, a power button and an activation button for turning on the touch screen display. The mobile terminal has a first function and a second function to perform in response to user input and provides user settings for configuring at least one of the first and second functions such that the at least one of the first and second functions is performed along with turning on the touch screen display when pressing of the activation button is detected while the touch screen display is turned off. The mobile terminal is configured to perform the first and second functions depending upon length of pressing of the activation button in addition to turning on the touch screen display.

An electronic device has a touch panel configured to detect a touch position; and a controller configured to detect the touch position with greater precision in a first area that includes the touch position than in a second area that is different from the first area.

A method and an apparatus for controlling a sleep mode in a portable terminal having a main controller and a sub-controller operating at low power are provided. The method includes detecting, by the sub-controller, a first sensor signal generated by a first sensor when the main controller is in the sleep mode, extracting a sensed pattern from the detected first sensor signal, determining whether the extracted sensed pattern is substantially identical with a preset wake-up pattern, and cancelling the sleep mode by waking-up the main controller when the extracted sensed pattern is substantially identical with the wake-up pattern.

This application discloses a display control method and an apparatus. The method is applied to a mobile terminal, the mobile terminal includes a display, the mobile terminal is connected to an external device, and the method includes: when the mobile terminal is on a voice call by using the external device, determining that the mobile terminal is in a handheld state or a non-handheld state; and when the mobile terminal is in the handheld state, controlling the display to be in a screen-on state; or when the mobile terminal is in the non-handheld state, controlling the display to be in a screen-off state. When the mobile terminal is on the voice call by using the external device, a display control solution is intelligently selected by determining that the mobile terminal is in the handheld state or the non-handheld state.

Embodiments of this application relate to the field of terminal technologies, and describe a method for displaying a dynamic image and a terminal, which resolve a problem that power consumption of a terminal caused by an existing method in which three-dimensional real-time rendering is used is relatively high. The method may be applied to a terminal, and can includes obtaining, from a video file based on a preset factor, a plurality of pieces of image frame data in a one-to-one correspondence to a plurality of image frames. The method may also include decoding the plurality of pieces of image frame data, to obtain the plurality of image frames. Furthermore, the method can include successively displaying the plurality of image frames obtained through the decoding, to present the dynamic image.

Embodiments relate to a computer system and computer program product for allocating resources and settings in order to optimize application satisfaction in view of hardware resources and adjustable software configurations. As applications are executed on a computing device, usage data is tracked, adjustable settings are identified, and power consumption of each application under different settings is measured. The usage data is then compiled, an optimal configuration setting is assessed for each application, and the setting is conveyed and applied to one or more applications.