KR102211900B1 - Method for Saving Power by Using Video Driver - Google Patents

Abstract

Disclosed is a method for saving power consumption using a video driver. An embodiment of the present invention provides a method for saving power consumption using a video driver to disable an unused register while checking CPU and GPU usage rate and maintenance time of a computer to save video power according to a window outputted on a display for reducing power used for a video driver consumed in the computer.

Description

Method for Saving Power by Using Video Driver}

An embodiment of the present invention relates to a power consumption saving method using a video driver.

The contents described below merely provide background information related to the present embodiment and do not constitute the prior art.

In a conventional computer power supply, a power supply such as a switched mode power supply (SMPS) is connected to a super input/output (SIO) of a main board, and one of them is used to apply a standby voltage. When the user presses the power button on the PC case, the power button sends a signal to the SIO. The SIO activates the power-on signal line with the power supply. The power supply transmits a power signal signal to the CPU and chipset, and then supplies power to the main board.

Standby power is applied between the power supply and the main board even when it is not in operation, and standby power is required for recognition of the start button and remote start. Therefore, energy is unnecessarily consumed due to standby power in the computer system. In order to solve the problem of unnecessary energy consumption due to standby power in a computer system, it is necessary to use an outlet having a switch that completely cuts off the power at the power outlet itself and makes standby power zero. If the user does not turn off the power-off switch of the outlet, power is wasted, and there is a problem in that it is expensive to attach a separate device to prevent consumption of standby power in the computer.

In this embodiment, in order to reduce the power used by the video driver consumed in the computer, the usage rate and retention time of the CPU and GPU of the computer are checked, and video power is saved according to the window output on the display, and unused registers are disabled. An object of the present invention is to provide a method of saving power consumption using a video driver that operates to be performed.

According to an aspect of this embodiment, the process of checking a CPU usage rate using a management application in a VGA driver; Checking whether the CPU usage rate is less than or equal to a preset first threshold usage rate in the VGA driver; When the CPU usage rate is less than the preset first threshold usage rate, checking whether the CPU usage rate is maintained for the preset first threshold time in the VGA driver; When the CPU usage rate in the VGA driver operates for the preset first threshold time below the preset first threshold usage rate, the topmost window T1 and the moving window T2 among a plurality of windows output on the screen are displayed. After extracting and generating the rest of the screen capture image (T3) excluding the top window (T1) and the moving window (T2) among the plurality of windows output on the screen, the top window (T1), Combining and displaying the moving window (T2) and the screen capture image (T3); Performing video power saving on a screen in which the topmost window (T1), the moving window (T2), and the screen capture image (T3) are combined in the VGA driver; Selecting and inactivating a register not in use for more than the first threshold time among registers operating in an operating system (OS) by the VGA driver; And when the system shutdown signal is received by the VGA driver, the standby power supplied from the SMPS (Switched Mode Power Supply) is controlled by controlling the program IC after checking the standby power blocking signal included in the system shutdown signal. It provides a power consumption saving method using a video driver, characterized in that it includes a process of controlling to block.

As described above, according to the present embodiment, in order to save power used by the video driver consumed in the computer, video power is saved according to the window output on the display by checking the usage rate and maintenance time of the computer's CPU and GPU. At the same time, there is an effect of saving power consumption of the video driver operating to disable unused registers.

1 is a diagram showing a computer power supply system according to the present embodiment.
2A and 2B are diagrams showing images output on the screen according to the present embodiment.
3 is a diagram showing a method of saving power consumption of a video driver according to a CPU usage rate according to the present embodiment.
4 is a diagram showing a method of deactivating a register according to a CPU usage rate according to the present embodiment.
5 is a diagram illustrating a method of saving power consumption of a video driver according to an output screen according to the present embodiment.
6 is a diagram illustrating a method of saving power consumption of a video driver according to a CPU addition confirmation according to the present embodiment.
7 is a diagram illustrating a method of saving power consumption of a video driver according to an additional confirmation of a GPU according to the present embodiment.

Hereinafter, this embodiment will be described in detail with reference to the accompanying drawings.

1 is a diagram showing a computer power supply system according to the present embodiment.

The computer power supply system 100 according to the present embodiment includes a processor 110, a VGA driver 120, an OS 130, a VGA memory manager 142, and a window task manager 144. Components included in the computer power supply system are not necessarily limited thereto, and a main board including a computer power supply system processor, chipset, PCI, SPI flash, SIO, system memory and memory power supply controller, OS and DDI, etc. It includes an SMPS connected to the main board using an auxiliary connector and a main connector. It includes a standby power supply including a PIC and a standby power switching element and a power stage regulator between the main board and the power supply (SMPS). The standby power supply unit controls the supply of standby power to the main board.

The VGA driver 120 is connected between the processor 110 and the OS 130. The OS 130 processes keyboard input and mouse input, and calls the window task manager 144 together with the VGA driver 120. The VGA driver 120 calls the window task manager 144 using the OS to check the current processor and memory usage.

The VGA driver 120 captures the snapshot image T3 using the VGA memory manager 142 and then stores or outputs the current state. In other words, the VGA driver 120 activates only some layers as an execution screen in the short term idle mode according to CPU usage. The VGA driver 120 outputs the captured image by capturing the remaining lower layers as a snapshot. In the long-term idle mode, the VGA driver 120 captures a snapshot while overlapping all layers and outputs only the captured image.

In the short term idle mode, the VGA driver 120 outputs only the upper layer as an actual execution screen. The VGA driver 120 captures the state in which the remaining lower layers are overlapped, creates a background image, and outputs it. In the long term idle mode, the VGA driver 120 partially activates the layers according to CPU usage, such as capturing all layers in a superimposed state and generating and outputting the background screen, so that data usage is significantly reduced, and the consumption of the computer. You can save the power consumption of the graphics card, which takes up part of the power.

The processor 110 communicates with the VGA driver 120 using a digital display interface (DDI). The processor 110 performs Suspended To RAM (STR) in a sleep mode using a system memory, a memory power supply control unit, and a PCI.

The SMPS (Switched Mode Power Supply) shown in FIG. 1 supplies standby power. SMPS includes AUX and Main Converter. SMPS receives 5VSB (5V standby) power from the AUX included inside. SMPS always receives 5VSB power as standby power when the computer is powered off. The switch element cuts off or supplies standby power applied from the SMPS under the control of a program IC.

The program IC controls standby power according to the control of the chipset, CPU, processor 110, VGA driver 120, and the like. The program IC may detect power off as an SLP signal with a signal input from a chipset, CPU, processor 110, VGA driver 120, and the like. Program IC can be omitted depending on the number of spare GPIO (general purpose input/output ports) ports such as chipset or SUPER IO.

2A and 2B are diagrams showing images output on a screen according to the present embodiment.

The VGA driver 120 extracts the topmost window T1 and the moving window T2 from among a plurality of windows output on the screen. The VGA driver 120 generates the rest of the screen capture image (Snap Shot Image) (T3) excluding the topmost window (T1) and the moving window (T2) among a plurality of windows output on the screen. After creating the remaining screen capture image (T3), the VGA driver 120 backs up all information on the existing screen to memory, and displays the top window (T1), the moving window (T2), and the screen capture image (T3). do.

The VGA driver 120 extracts only the moving window T2 from among a plurality of windows output on the screen. The VGA driver 120 generates the remaining screen capture image T3 except for the moving window T2 among a plurality of windows output on the screen. After generating the remaining screen capture image T3, the VGA driver 120 backs up all of the information on the existing screen to memory, and displays a moving window T2 and a screen capture image T3.

The VGA driver 120 extracts only moving blocks T4 from among a plurality of windows output on the screen. Here, the moving blocks T4 may be a clock in the lower right corner and an Internet specific window, as shown in FIG. 2B. The VGA driver 120 generates the remaining screen capture image T3 except for the moving blocks T4 among a plurality of windows output on the screen. After generating the remaining screen capture image T3, the VGA driver 120 backs up all information on the existing screen to memory, displays the screen capture image T3, and overlays the moving blocks T4. ) Format.

3 is a diagram showing a method of saving power consumption of a video driver according to a CPU usage rate according to the present embodiment.

The VGA driver 120 loads a GPU management application (GPUM) (S310). The VGA driver 120 checks the CPU usage rate using a GPU management application (GPUM). The VGA driver 120 checks whether the CPU usage rate is less than or equal to a preset first threshold usage rate (eg, 15%) (S312).

As a result of checking in step S312, if the CPU usage rate is less than or equal to the preset first threshold usage rate, the VGA driver 120 checks whether the CPU usage rate is maintained for a preset first threshold time (eg, for 60 seconds) below the preset first threshold usage rate. It is checked whether or not (S314).

As a result of checking in step S314, when the CPU usage rate is maintained for a preset first threshold time (eg, for 60 seconds) below the preset first threshold usage rate, the VGA driver 120 is at the top of the plurality of windows output on the screen. The window (T1) and the moving window (T2) are extracted. The VGA driver 120 generates the rest of the screen capture image (Snap Shot Image) (T3) excluding the topmost window (T1) and the moving window (T2) among a plurality of windows output on the screen. After generating the remaining screen capture image T3, the VGA driver 120 backs up all information on the existing screen to memory. The VGA driver 120 combines and displays the topmost window T1, the moving window T2, and the screen capture image T3 (S316).

In step S316, the VGA driver 120 performs additional video power saving. In other words, the VGA driver 120 saves video power for a screen in which the topmost window T1, the moving window T2, and the screen capture image T3 are combined.

In step S316, when performing video power saving, the VGA driver 120 operates the PLL (Phase Locked Loop) and the transceiver in a sleep mode in the VGA driver, and the lane of the Express Bus. (Lane) is reduced by the first reduced lane (e.g., 4x) in the entire lane (e.g., 16x).

In step S316, the VGA driver 120 restores a display image in a specific area (eg, E820 area) of the system memory (S317). When step S317 is performed, the VGA driver 120 then performs step S324.

The VGA driver 120 disables a register that is not used for a predetermined time among the registers operating in the OS (S318). In step S318, the VGA driver 120 selects and disables a register that is not in use for more than a first threshold time among registers operating in an operating system (OS).

In step S318, when the VGA driver 120 selects and disables the registers, the VGA driver is an OS update register, a vaccine register, a security register, a disk defragmentation register, a scheduler register, an alarm register, and a Bluetooth device. ) Disable at least one of the registers.

The VGA driver 120 checks the CPU usage rate using a GPU management application (GPUM). The VGA driver 120 checks whether the CPU usage rate exceeds a preset first threshold usage rate (eg, 15%) (S320).

As a result of checking in step S320, if the CPU usage rate does not exceed the preset first threshold usage rate, the VGA driver 120 checks whether a device call command or a register call command is input. (S322).

As a result of checking in step S322, if a device call command or a register call command is not input, the VGA driver 120 performs step ⓐ thereafter.

As a result of checking in step S320, when the CPU usage rate exceeds the preset first threshold usage rate, the VGA driver 120 initializes the screen (VGA_INIT# (DPI NVS, DPI Reclaim, DPI Table)) (S324). In step S324, the VGA driver 120 initializes the screen when the CPU usage rate exceeds a preset first threshold usage rate (eg, 15%).

In step S324, when the CPU usage rate exceeds a preset first threshold usage rate (eg, 15%), the VGA driver 120 wakes up and outputs an original screen instead of an imaged screen.

As a result of checking in step S322, when a device call command or a register call command is input, the VGA driver 120 wakes up the device corresponding to the device call command or register call command. A register corresponding to is called (S324). In step S324, when a device call command or a register call command is input, the VGA driver 120 wakes up a device corresponding to the device call command or responds to the register call command. Call the register.

In FIG. 3, it is described that steps S310 to S324 are sequentially executed, but the present invention is not limited thereto. In other words, since it is possible to change and execute the steps illustrated in FIG. 3 or execute one or more steps in parallel, FIG. 3 is not limited to a time series order.

As described above, the method for saving power consumption of the video driver according to the CPU usage rate according to the present embodiment illustrated in FIG. 3 may be implemented as a program and recorded on a computer-readable recording medium. A program for implementing a method for saving power consumption of a video driver according to the CPU usage rate according to the present embodiment is recorded, and the computer-readable recording medium is any type of recording device in which data that can be read by a computer system is stored. Includes.

4 is a diagram illustrating a method of deactivating a register according to a CPU usage rate according to the present embodiment.

The VGA driver 120 checks whether or not the CPU usage rate is maintained below a preset first threshold usage rate (eg, 15%) for a preset second threshold time (eg, for 120 seconds) (S410).

The VGA driver 120 extracts only the moving window T2 from among a plurality of windows output on the screen. The VGA driver 120 generates the rest of the screen capture image (Snap Shot Image) (T3) excluding the moving window (T2) among the plurality of windows output on the screen. After generating the remaining screen capture image T3, the VGA driver 120 backs up all information on the existing screen to memory. After that, the VGA driver 120 combines and displays the moving window T2 and the screen capture image T3 (S412).

In step S412, the VGA driver 120 performs additional video power saving. The VGA driver 120 further reduces (eg, from 4x to 1x) a lane of an Express Bus to save video power. The VGA driver 120 turns off some functions (eg, output) of the BIOS to save video power.

In other words, the VGA driver 120 reduces the lane of the Express Bus to the first reduction lane (for example, in order to save video power for the screen in which the moving window T2 and the screen capture image T3) are combined. 4x) is reduced by the second reduction lane (eg, 1x), and the output function of the BIOS is turned off.

The VGA driver 120 additionally disables a register that is not used for a predetermined specific time among the registers operating in the OS (S414). In step S414, the VGA driver 120 deactivates at least one or more of a network service management register and a network device register.

The VGA driver 120 checks whether there is a running program using the GPU management application (GPUM) (S416).

As a result of checking in step S416, if there is a running program, the VGA driver 120 initializes the screen (VGA_INIT# (DPI NVS, DPI Reclaim, DPI Table)) and activates the inactive register (for example, the network register ( LAN_WAKE_EN=1) wakes up (S418). In step S418, if there is a running program, the VGA driver 120 initializes the screen and wakes up an additionally inactive register. In step S418, if there is a running program, the VGA driver 120 initializes the screen and wakes up an additionally inactive register to output an original screen instead of an imaged screen.

As a result of checking in step S416, if there is no program being executed, the VGA driver 120 performs video port power saving (S420).

In step S420, when performing video port power saving, the VGA driver 120 operates the PLL (Phase Locked Loop) and the transceiver in a sleep mode in the VGA driver, and the Express Bus The Lane is reduced from the entire lane (eg, 16x) to the second reduced lane (eg, 4x). The VGA driver 120 turns off some functions (eg, output) of the BIOS to save video power.

In other words, the VGA driver 120 changes the VGA power saving state from D0 (0 stage power saving) to D2 (2 stage power saving) by operating the PLL, transceiver sleep, and some BIOS functions off. Here, the VGA power saving state may be divided into D0 (0 stage power saving) to D3 (maximum power saving).

The VGA driver 120 reduces the Express Bus from the entire lane (eg, 16x) to the second reduced lane (eg, 4x), and thus changes the 16x PCIex bus to 1x. The VGA driver 120 sets the maximum power to the minimum power in the graphic power usage setting of the registry.

In FIG. 4, steps S410 to S418 are described as sequentially executing, but are not limited thereto. In other words, since the steps described in FIG. 4 may be changed and executed or one or more steps may be executed in parallel, FIG. 4 is not limited to a time series order.

As described above, the register deactivation method according to the CPU usage rate according to the present embodiment illustrated in FIG. 4 may be implemented as a program and recorded in a computer-readable recording medium. A program for implementing the method of deactivating a register according to the CPU usage rate according to the present embodiment is recorded and the computer-readable recording medium includes all types of recording devices in which data that can be read by a computer system is stored.

5 is a diagram illustrating a method of saving power consumption of a video driver according to an output screen according to the present embodiment.

The VGA driver 120 checks whether there is a keyboard input or a mouse input for a predetermined specific time (T sec) (S510).

As a result of checking in step S510, when there is no keyboard input or mouse input for a predetermined time (T sec), the VGA driver 120 extracts only moving blocks T4 from among a plurality of windows output on the screen. . The VGA driver 120 generates the rest of the screen capture image (Snap Shot Image) (T3) excluding the moving blocks (T4) among the plurality of windows output on the screen. After generating the remaining screen capture image T3, the VGA driver 120 backs up all information on the existing screen to memory, displays the screen capture image T3, and overlays the moving blocks T4. ) Format (S520).

The VGA driver 120 checks whether or not it is in the Suspend To Ram (STR) mode in which power is supplied to only the main power supply (power = Power) and the memory (RAM) (S530).

As a result of checking in step S530, if it is confirmed that the operation is in the STR mode, the VGA driver 120 maintains the STR mode (S540). In step S530, the VGA driver 120 maintains the Suspend To Ram (STR) mode operation in a state in which power is supplied to the main power supply device and the memory (RAM).

As a result of checking in step S530, if the STR mode does not operate, the VGA driver 120 returns to step S416.

The VGA driver 120 checks whether a standby power cutoff signal is included in the system termination signal (S550). In step S550, the VGA driver 120 checks whether the SLP signal is S4. That is, the VGA driver 120 checks whether a standby power cutoff signal is included in the system termination signal.

As a result of checking in step S550, if the standby power blocking signal is included in the system shutdown signal, the VGA driver 120 transmits a control signal to cut off standby power while shutting down the system (power off) via the processor 110. Transfer to the program IC.

In step S550, when the SLP signal is S4, the VGA driver 120 transmits a control signal for shutting off standby power and terminating the system while shutting down the system (power off) via the processor 110 to the program IC.

When receiving a control signal from the VGA driver 120 via the processor 110, the program IC shuts down the system (power off) using a switch and cuts off standby power (S560). In step S560, the program IC controls the switch to turn off standby power (5VSB) supplied from the SMPS.

In FIG. 5, steps S510 to S560 are described as sequentially executing, but the present invention is not limited thereto. In other words, since the steps described in FIG. 5 may be changed and executed or one or more steps may be executed in parallel, FIG. 5 is not limited to a time series order.

As described above, the method of saving power consumption of the video driver according to the output screen according to the present embodiment illustrated in FIG. 5 may be implemented as a program and recorded in a computer-readable recording medium. A program for implementing a method of saving power consumption of a video driver according to the output screen according to the present embodiment is recorded, and the computer-readable recording medium is any type of recording device in which data that can be read by a computer system is stored. Includes.

6 is a diagram illustrating a method of saving power consumption of a video driver according to a CPU addition confirmation according to the present embodiment.

The VGA driver 120 loads a GPU management application (GPUM) (S610). The VGA driver 120 checks the CPU usage rate using a GPU management application (GPUM). The VGA driver 120 checks whether the CPU usage rate is less than or equal to a preset first threshold usage rate (eg, 15%) (S612).

The VGA driver 120 checks the type of CPU and checks whether the CPU is a predetermined specific manufacturer's CPU (eg, AMD) (S614). As a result of checking in step S614, if the CPU is a predetermined specific manufacturer CPU (eg, AMD), the VGA driver 120 calls a power slide function corresponding to the specific manufacturer CPU (S616).

The VGA driver 120 operates in a normal power saving mode based on a power slide function when a specific manufacturer's CPU usage rate is less than a preset first threshold usage rate (eg, 15%) (S618). In step S618, when the CPU usage rate is less than or equal to a preset first threshold usage rate, and the CPU is a preset specific manufacturer's CPU (eg, AMD), the power slide function corresponding to the specific manufacturer's CPU ), and operates in a normal power saving mode based on the power slide function.

The VGA driver 120 checks whether or not the specific manufacturer's CPU usage rate is less than or equal to a preset second threshold usage rate (eg, 10%) (S620). As a result of checking in step S620, when the CPU usage rate of a specific manufacturer is less than or equal to the preset second threshold usage rate, the VGA driver 120 operates in the maximum power saving mode based on the power slide function (S622). In step S622, the VGA driver 120 operates the power mode to the maximum power saving mode, as shown in FIG. 7.

In step S622, the VGA driver 120 is a CPU of a specific manufacturer CPU (e.g., AMD) set in advance, and the CPU usage rate is a preset second threshold usage rate (eg, 10%) or less. 10%), it operates by switching from hibernation mode to normal power saving mode based on the power slide function.

The VGA driver 120 checks whether the specific manufacturer's CPU usage rate exceeds a preset second threshold usage rate (eg, 10%) (S624).

As a result of checking in step S624, when the CPU usage rate of a specific manufacturer exceeds a preset second threshold usage rate (eg, 10%), the power saving mode is switched to the general power saving mode based on the power slide function (S626).

In step S626, when the CPU is a specific manufacturer's CPU (eg, AMD) and the CPU usage rate is less than or equal to a preset second threshold usage rate (eg, 10%), the VGA driver 120 is in hibernation mode based on the power slide function. Works as

In FIG. 6, it is described that steps S610 to S626 are sequentially performed, but the present invention is not limited thereto. In other words, since the steps shown in FIG. 6 may be changed and executed or one or more steps may be executed in parallel, FIG. 6 is not limited to a time-series order.

As described above, the method of saving power consumption of the video driver according to the additional confirmation of the CPU according to the present embodiment illustrated in FIG. 6 may be implemented as a program and recorded on a computer-readable recording medium. In accordance with the additional confirmation of the CPU according to the present embodiment, a program for implementing a method of saving power consumption of a video driver is recorded, and the computer-readable recording medium is all types of recording data that can be read by a computer system. Including the device.

7 is a diagram illustrating a method of saving power consumption of a video driver according to an additional confirmation of a GPU according to the present embodiment.

The VGA driver 120 loads a GPU management application (GPUM) (S710). The VGA driver 120 checks the GPU usage rate using a GPU management application (GPUM). The VGA driver 120 checks whether the GPU usage rate is less than or equal to a preset first threshold usage rate (eg, 15%) (S712).

The VGA driver 120 checks the type of GPU and checks whether the GPU is a preset specific manufacturer's GPU (eg, NVIDIA) (S714). As a result of checking in step S714, when the GPU is a preset specific manufacturer's GPU (eg, NVIDIA), the VGA driver 120 checks whether a 3D application program using a specific manufacturer's GPU is running (S716).

In step S716, the VGA driver 120 checks the GPU usage rate using a management application, the GPU usage rate is less than a preset first threshold usage rate, the GPU is a preset specific manufacturer's GPU (eg, NVIDA), and the specific manufacturer's GPU Check whether or not a 3D application program using is running.

As a result of checking in step S716, if a 3D application program using a specific manufacturer's GPU is not running, the VGA driver 120 calls a 3D power management tool corresponding to the specific manufacturer's GPU, and enters the adaptive mode using the 3D power management tool. It operates (S718). In step S718, when a 3D application program using a specific manufacturer's GPU is not running, the VGA driver 120 calls a 3D power management tool corresponding to the specific manufacturer's GPU, and operates in an adaptive mode using the 3D power management tool. .

The VGA driver 120 checks whether the specific manufacturer's GPU usage rate is less than or equal to a preset second threshold usage rate (eg, 10%) (S720). As a result of checking in step S720, if the GPU usage rate of a specific manufacturer is less than the preset second threshold usage rate, the VGA driver 120 operates in the optimal power mode using the 3D power management tool (S722).

In step S722, the VGA driver 120 operates in an optimal power mode using a 3D power management tool when the GPU usage rate of a specific manufacturer is less than or equal to a preset second threshold usage rate (eg, 10%).

The VGA driver 120 checks whether a 3D application program using a specific manufacturer's GPU is running (S724). As a result of checking in step S724, when a 3D application program using a specific manufacturer's GPU is running, the VGA driver 120 operates in the highest performance mode using the 3D power management tool (S726). In step S726, the VGA driver 120 operates the power mode in the highest performance mode.

In step S726, when a 3D application program using a specific manufacturer's GPU is running, the VGA driver 120 calls a 3D power management tool corresponding to the specific manufacturer's GPU, and operates in the highest performance mode using the 3D power management tool. .

In FIG. 7, it is described that steps S710 to S726 are sequentially executed, but the present invention is not limited thereto. In other words, since the steps described in FIG. 7 may be changed and executed or one or more steps may be executed in parallel, FIG. 7 is not limited to a time-series order.

As described above, the method of saving power consumption of the video driver according to the additional confirmation of the GPU according to the present embodiment illustrated in FIG. 7 may be implemented as a program and recorded in a computer-readable recording medium. In accordance with the additional confirmation of the GPU according to the present embodiment, a program for implementing a method of saving power consumption of a video driver is recorded, and the computer-readable recording medium stores all types of data that can be read by the computer system Including the device.

The above description is merely illustrative of the technical idea of the present embodiment, and those of ordinary skill in the technical field to which the present embodiment belongs will be able to make various modifications and variations without departing from the essential characteristics of the present embodiment. Accordingly, the present exemplary embodiments are not intended to limit the technical idea of the present exemplary embodiment, but are illustrative, and the scope of the technical idea of the present exemplary embodiment is not limited by these exemplary embodiments. The scope of protection of this embodiment should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present embodiment.

100: computer power supply system
110: processor
120: VGA driver 130: OS
142: VGA memory manager 144: Window task manager

Claims (5)

Checking the CPU usage rate using the management application in the VGA driver;
Checking whether the CPU usage rate is less than or equal to a preset first threshold usage rate in the VGA driver;
When the CPU usage rate is less than the preset first threshold usage rate, checking whether the CPU usage rate is maintained for the preset first threshold time in the VGA driver;
When the CPU usage rate in the VGA driver operates for the preset first threshold time below the preset first threshold usage rate, the topmost window T1 and the moving window T2 among a plurality of windows output on the screen are displayed. After extracting and generating the rest of the screen capture image (T3) excluding the top window (T1) and the moving window (T2) among the plurality of windows output on the screen, the top window (T1), Combining and displaying the moving window T2 and the screen capture image T3;
Performing video power saving on a screen in which the topmost window (T1), the moving window (T2), and the screen capture image (T3) are combined in the VGA driver;
Selecting and inactivating a register not in use for more than the first threshold time among registers operating in an operating system (OS) by the VGA driver;
Checking whether the CPU usage rate in the VGA driver is maintained below the first threshold usage rate for a preset second threshold time period;
In the case where the CPU usage rate in the VGA driver is maintained below the preset first threshold usage rate for a preset second threshold time, only the moving window T2 is extracted from a plurality of windows output on the screen, and Generating the remaining screen capture image (T3) excluding the moving window (T2) among the plurality of output windows, and then combining and displaying the moving window (T2) and the screen capture image (T3);
In the VGA driver, in order to reduce video power for a screen in which the moving window T2 and the screen capture image T3 are combined, the lane of the Express Bus is changed from the first reduction lane to the second reduction lane. Reducing and turning off the output function of the BIOS;
Checking whether or not there is a running program, if there is a running program, initializing a screen in the VGA driver and waking up an additionally inactive network register;
If the running program does not exist, Video Port Power Saving is performed to operate the PLL (Phase Locked Loop) and the transceiver in Sleep mode, and the Express Bus Reducing a lane by the second reduction lane in all lanes and turning off an output function of a BIOS to save video power, thereby changing a VGA power saving state to a high power saving step;
When there is no keyboard input or mouse input for a predetermined time (T sec), only moving blocks (T4) are extracted from the plurality of windows output on the screen by the VGA driver, and After generating the remaining screen capture image T3 excluding the moving blocks T4 from the window, displaying the remaining screen capture image T3 and outputting the moving blocks T4 in an overlay form. process;
Operating a Suspend To Ram (STR) mode in which power is supplied to a main power supply and a memory (RAM) in the VGA driver; And
When receiving the system shutdown signal from the VGA driver, control the program IC after checking the standby power blocking signal included in the system shutdown signal to shut down the system and block standby power supplied from the switched mode power supply (SMPS). Control process
Power consumption saving method using a video driver comprising a. The method of claim 1,
When performing the video power saving, the VGA driver operates the PLL (Phase Locked Loop) and the transceiver in a sleep mode, and the lane of the Express Bus is controlled from all lanes. Power consumption saving method using a video driver, characterized in that the number is reduced by one reduction lane. The method of claim 2,
When selecting and deactivating the register, the VGA driver sets at least one or more of an OS update register, a vaccine register, a security register, a disk defragmentation register, a scheduler register, an alarm register, and a Bluetooth device register. Power consumption saving method using a video driver, characterized in that to disable. The method of claim 3,
When the CPU usage rate exceeds the preset first threshold usage rate, the VGA driver initializes a screen and outputs an original screen instead of an imaged screen. The method of claim 4,
When a Device Call command or Register Call command is input, the VGA driver wakes up the device corresponding to the device call command or calls the register corresponding to the register call command. Power consumption saving method using a video driver, characterized in that.

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