KR20070069120A - Computer and control method thereof - Google Patents

Abstract

A computer and a control method thereof are provided to improve power efficiency by adjusting a level of power applied to input of a CPU power generator according to a CPU mode. A system operation power generator(70) transforms source power received from a power source(10) and outputs the transformed power to a system part(80). The CPU power generator(50) outputs operation power needed for operating a CPU(60). A controller(30) selectively applies the source power of the power source or the system power transformed in the system operation power generator to an input terminal of the CPU power generator according to a power mode of the CPU. The power mode of the CPU includes a normal and power-saving mode. If the CPU is operated in the power-saving mode, the controller applies the system power transformed in the system operation power generator to the input terminal of the CPU power generator.

Description

Computer and its control method {COMPUTER AND CONTROL METHOD THEREOF}

1 is a control block diagram of a computer according to a first embodiment of the present invention,

2 is a control block diagram of a computer according to a second embodiment of the present invention,

3A to 3C are graphs showing the efficiency of the CPU driving power generation unit;

4 is a graph showing the efficiency of the system driving power generation unit according to the present invention,

5 is a table comparing the efficiency of the computer and the conventional computer according to the present invention,

6 is a control flowchart of a computer according to the present invention.

Explanation of symbols on the main parts of the drawings

10: power source 30: control unit

31: CPU mode recognition unit 35: the first switching unit

37: second switching unit 39: third switching unit

50: CPU driving power generator 51: PWM generator

57: power output unit 60: CPU

70: system driving power generation unit 80: system unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a computer and a control method thereof, and more particularly, to a computer having improved power efficiency and a control method thereof.

Advanced Configuration and Power Interface (ACPI) is an open industry solution that encompasses computer hardware, operating systems, software and peripheral interfaces. This specification enables communication between the power usage of operating systems, hardware, and peripherals developed by Intel, Microsoft, and Toshiba.

Previously, power management systems in computers were based on BIOS, so devices could not be powered down after a period of inactivity.However, ACPI requires an operating system that supports operating system directed power management (OSPM) to manage all power activities. Manageability ensures that the device is powered only when needed.

The ACPI, released in 1996, defines the operating modes associated with the CPU's power states as C0, C1, C2, and C3 modes. Here, the C0 state is defined as a normal state, the C1 state is a Halt state, C2 is a stop-grant state, and a C3 state is defined as a stop clock state. do.

In the C2 state, the CPU performs minimal activities such as snooping operations to maintain cache association. In C3, which is defined as Deep Sleep Mode, the external clock is not provided to the CPU, so all activity on the processor is stopped except for the ability to maintain data stored in cache memory within the CPU. Therefore, the deep sleep mode further reduces power consumption compared to the C2 state.

Recently, Intel developed Intel Mobile Voltage Positioning II (IMVPII), an improved voltage rectification technology. Power consumption is minimized by significantly lowering the voltage level of the supplied power supply.

A conventional computer includes a power source such as a battery and an adapter, a CPU, and a CPU drive power generation unit that generates a CPU drive power based on the source power output from the power source. The CPU driving power generation unit provided in the conventional computer includes a switching unit to generate a switching loss and a conduction loss according to the switching operation. At this time, since the conduction loss is proportional to the level of the current, the greater the level of the current, the greater the loss. Therefore, when the level of the current is small, the switching loss becomes dominant in the CPU driving power generation unit, and the efficiency is greatly reduced (see FIG. 3A). In addition, the CPU driving power generation unit provided in the conventional computer has a problem in that the power efficiency is lowered by generating the CPU driving power based on a source power source having a high level voltage output from the power source regardless of the current level.

Accordingly, an object of the present invention relates to a computer that improves the efficiency of power by controlling the level of power applied to the CPU driving power generation unit according to the CPU mode, and a control method thereof.

The above object is, according to the present invention, a computer having a CPU and a system unit, including: all elements; A system driving power generation unit converting the source power input from the power source and outputting the converted power to the system unit; A CPU driving power generation unit for outputting driving power for driving the CPU; And a control unit for controlling the source power from the power source and the system power converted from the system driving power generation unit to be selectively applied to an input terminal of the CPU driving power generation unit according to the power mode of the CPU. Is achieved by a computer.

Herein, the power mode of the CPU includes a normal mode and a power saving mode, and the controller is configured to convert the system power converted from the system driving power generation unit to an input terminal of the CPU driving power generation unit when the CPU operates in the power saving mode. It can be controlled to be applied.

The controller may allow the source power output from the power source to be applied to the input terminal of the CPU driving power generator when the CPU operates in the normal mode.

The control unit may further include: a first switching unit intermitting that the source power output from the power source is applied to the CPU driving power generation unit; and the system power output from the system driving power generation unit is the CPU driving power supply. It may include a second switching unit for intermittently being applied to the generator.

The CPU may output a power state signal including information on the power mode, and the controller may further include a CPU mode recognition unit configured to control the first switching unit and the second switching unit according to the power state signal. Can be.

Here, when the CPU operates in the power saving mode, the controller may control the system power to be applied to the CPU driving power generating unit at a level at which the system driving power generating unit depresses the source power output from the power source. Can be.

The power saving mode may include at least one of a deep sleep mode and a deep sleep mode according to an ACPI (Advanced Configuration and Power Interface) protocol.

Here, the power saving mode includes at least two modes, and the controller may allow the system power of different levels to be applied to the CPU driving power generation unit according to a mode.

For example, the power saving mode includes a first power saving mode and a second power saving mode, and the controller is configured to control the system power output from the system driving power generation unit to be applied to the CPU driving power generation unit. A third switching unit, including a second switching unit and a third switching unit so as to be applied to the CPU driving power generation unit in a first power saving mode to the first power saving mode, and The other one of the second switching unit and the third switching unit may be interrupted so that the system driving power of two levels is applied to the CPU driving power generation unit.

The controller may determine that the CPU operates in a power saving mode when the level of the current applied to the CPU is smaller than a predetermined level.

On the other hand, according to the present invention, there is provided a control method of a computer having a CPU and a system unit, comprising: applying a source power output from a power source to a system driving power generation unit; Determining an operation mode of the CPU; And selectively applying the source power from the power source and the system power converted from the system driving power generation unit to the CPU driving power generation unit according to the determined power mode of the CPU. It is achieved by the control method of.

The step of selectively applying the source power and the system power to the CPU driving power generation unit may include converting the source power inputted by the system driving power generation unit to the CPU driving power when the CPU operates in a power saving mode. Outputting to a generation unit and generating driving power of the CPU based on the system power output from the system driving power generation unit.

The step of selectively applying the source power and the system power to the CPU driving power generation unit may include determining that the source power output from the power source is the CPU driving power when the CPU operates in a normal mode. The method may further include applying to the generator.

The step of selectively applying the source power and the system power to the CPU driving power generation unit may include applying the system power at a level at which the system driving power generation unit decompresses the source power output from the power source to the CPU. Output to drive power generator.

In the determining of the operation mode of the CPU, the operation mode of the CPU may be determined based on power state information output from the CPU.

Here, the power saving mode includes at least two modes, and the step of converting the source power inputted by the system driving power generation unit and outputting the input source power to the CPU driving power generation unit may include the system power having a different level according to a mode. Output to the CPU driving power generation unit.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the present invention.

As shown in FIG. 1, a computer according to an embodiment of the present invention includes a power source 10, a CPU 60, a system unit 80, a CPU drive power generation unit 50, and a system drive. It includes a power generator 70 and the controller 30.

The power source 10 includes, for example, an adapter, a battery, and the like, and includes a source power source (voltage level of the source power source) in at least one of the system driving power generation unit 70 and the CPU driving power generation unit 50 which will be described later. Outputs V1).

The CPU 60 is driven by receiving a core voltage (Vcore: Core Voltage) which is a driving power source (voltage level of the driving power source: V5) required for driving from the CPU driving power generation unit 50, which will be described later, to perform calculation or data processing. Perform. Here, the CPU 60 generates a VID (Voltage IDentification) code signal for determining the level of the core voltage Vcore required for its driving, and outputs it to the CPU driving power generation unit 50.

The CPU 60 outputs a VID signal including information on the level of the core voltage through the VID pin, including a VID pin (not shown). For example, the Pentium 4, which is an Intel CPU 60, outputs a 5-bit digital VID code signal output from five VID pins to the CPU driving power generation unit 50, and outputs the output VID code signal. The level of the core voltage of the CPU 60 is determined by this.

The CPU 60 can operate in a normal mode and a power saving mode, and the power saving mode of the CPU 60 is a deep sleep in a C4 state and a dipper sleep mode in a C4 state according to ACPI (Advanced Configuration and Power Interface) protocol. It may include at least one of a (Deep Sleep) mode. Here, the power saving mode of the CPU 60 may also be applied to the power saving mode according to other protocols when the level of the core voltage supplied to the CPU 60 is changed according to the power state of the CPU 60.

The CPU driving power generation unit 50 supplies the driving power V5 required for driving the CPU 60. In other words, the CPU driving power generation unit 50 outputs a driving voltage, for example, a core voltage, at a level required by the CPU 60 based on the VID code provided from the CPU 60.

The CPU driving power generation unit 50 generates a power output unit 57 for outputting a core voltage and a PWM generation for controlling the level of the core voltage output from the power output unit 57 based on the VID code of the CPU 60. The unit 51 is included.

The system unit 80 is a unit of the computer according to the present invention except for the CPU 60, the power source 10, the CPU drive power generation unit 50, the system drive power generation unit 70, the control unit 30 Include.

The system driving power generator 70 converts the source power V1 input from the power source 10 and outputs the converted source power V1 to the system 80. The system driving power generation unit 70 includes a converter, and varies the input source power V1 to a level suitable for each IC in the system unit 80, for example, 1.8V, 3.3V, 5V, 12V, and the like. Can be converted and output to each IC.

The controller 30 may control one of the power output from the power source 10 and the system driving power generation unit 70 to be applied to the CPU driving power generation unit 50 according to the mode of the CPU 60.

The control unit 30 includes a first switching unit 35 for intermittently applying the source power V1 output from the power source 10 to the CPU driving power generation unit 50, and the system driving power generation unit 70. According to the operation mode of the CPU 60 and the second switching unit 37 for intercepting the application of the system power (first voltage level of the system power supply V2) output from the CPU driving power generation unit 50 to CPU mode recognition unit 31 for controlling the switching of the first switching unit 35 and the second switching unit 37.

The CPU mode recognition unit 31 recognizes an operation mode of the CPU 60 and controls the first switching unit 35 and the second switching unit 37. At this time, the CPU mode recognition unit 31 may determine the operation mode of the CPU 60 according to the current level or the PSI signal to be described later as shown in the table.

[table]

PSI signal CPU operation mode electric current One Normal mode i> Preset value 0 Power saving mode i <preset value

The CPU mode recognition unit 31 operates the CPU 60 in the normal mode when the level of the current applied to the CPU 60 is greater than the predetermined level, and operates the power saving mode when the CPU 60 is smaller than the predetermined level. You can judge that.

Alternatively, the CPU mode recognition unit 31 may receive a power status indicator (PSI) corresponding to the operation mode of the CPU 60 to determine whether the operation mode of the CPU 60 is a normal mode or a power saving mode. It may be.

The CPU mode recognition unit 31 controls each switching unit according to the operation mode of the CPU 60. That is, when the CPU 60 operates in the normal mode as a result of the recognition of the CPU mode recognition unit 31, the CPU mode recognition unit 31 turns on the first switching unit 35 to be output from the power source 10. The source power source V1 is input to the CPU driving power generation unit 50. In this case, the voltage of the source power source V1 output from the power source 10 may be, for example, 9 to 19V, or 9 to 12.6V.

As a result of the recognition of the CPU mode recognition unit 31, when the CPU 60 operates in the power saving mode, the CPU mode recognition unit 31 turns off the first switching unit 35 and turns on the second switching unit 37. The system power V2 generated by the system driving power generator 70 is input to the CPU driving power generator 50. In this case, the voltage of the system power source V2 input from the system driving power generation unit 70 may be lower than that of the source power source V1 output from the power source 10. For example, the voltage of the system power source V2 input to the CPU driving power generation unit 50 may be provided at 5V, 3.3V, or the like.

This is because, referring to the graphs of FIGS. 3A to 3C, it is advantageous to apply a low level voltage when operating at a low level current due to the internal efficiency of the CPU driving power generation unit 50.

Here, the CPU mode recognition unit 31 may output power state signals having different logic values when the operation mode of the CPU 60 is switched between the normal mode and the power saving mode. For example, the CPU mode recognition unit 31 outputs a low level power state signal when the CPU 60 is operating in a power saving mode, and a low level power state when the CPU 60 is switched to the normal mode. The signal can be output at the high level.

2 is a control block diagram of a computer according to a second embodiment of the present invention. FIG. 2 uses the same reference numerals for components having the same function as FIG. 1, and description thereof is omitted.

2 shows a power source 10, a CPU 60, a system unit 80, a CPU drive power generation unit 50, and a system drive power generation unit 70, like the computer shown in FIG. 1. ) And a control unit 30.

The control unit 30 according to an embodiment of the present invention includes a CPU mode recognition unit 31, a first switching unit 35, a second switching unit 37, and a third switching unit 39.

The CPU mode recognition unit 31 shown in FIG. 2 controls each switching unit by dividing the power saving mode of the CPU 60 into a first power saving mode and a second power saving mode. Here, the first sleep mode and the second sleep mode will be described as one example including a deep sleep mode (Deep Sleep) and a dipper mode (Deeper Sleep) according to the ACPI (Advanced Configuration and Power Interface).

The CPU mode recognition unit 31 may determine the operation mode of the CPU 60 according to the above-described PSI signal, and the CPU mode recognition unit 31 recognizes a signal such as DPRSLP, DPRSLPVR, etc. from the CPU 60 and the CPU. It may be determined whether the 60 is in the deep sleep mode or the deep sleep mode.

As a result of the recognition of the CPU mode recognition unit 31, when the CPU 60 operates in the normal mode, the CPU mode recognition unit 31 turns on the first switching unit 35 to output the source power output from the power source 10 ( V1), for example, a source power V1 of 12V is applied to the CPU driving power generation unit 50. When the CPU 60 operates in the deep sleep mode as a result of the recognition of the CPU mode recognition unit 31, the CPU mode recognition unit 31 turns on only the second switching unit 37 to generate the system driving power generation unit 70. The system power supply V2 output from the system power source V2, for example, 5V, is applied to the CPU driving power generation unit 50. In addition, when the CPU 60 operates in the deferred sleep mode as a result of the recognition of the CPU mode recognition unit 31, the CPU mode recognition unit 31 turns on only the third switching unit 39 to be output from the power source 10. A system power source (second voltage level V3 of the system power source), for example, 3.3 V system power source V3 may be applied to the CPU driving power generation unit 50.

Then, the CPU driving power generation unit 50 generates and outputs a driving voltage of the level required by the CPU 60 based on the applied level of power.

3A is a graph of voltage vs. efficiency according to a current output from a CPU driving voltage generator.

The CPU driving power generation unit 50 generates a switching loss and a conduction loss. Here, the switching loss is generated by the switch 55 switched according to the PWM signal of the PWM generator 51. Here, the conduction loss is proportional to the square of the current, so the greater the current level, the greater the loss. In addition, the switching loss is proportional to the length of the section in which the current and the voltage simultaneously change when the switch 55 is switched.

Based on this feature, the relationship between voltage vs. efficiency in the CPU driving power generation unit 50 when the core current is 5A is shown in the graph of FIG. 3A, and when the core current is 15A, the CPU driving power generation unit 50 The relationship of voltage vs. efficiency is shown in the graph of FIG. 3B. When the core current is 18A, the relationship of voltage vs. efficiency in the CPU driving power generator 50 is shown in the graph of FIG. 3C. That is, when the core current level is 5A, the voltage applied to the CPU driving power generation unit 50 is about 5V, and when the core current level is 15A, the voltage applied to the CPU driving power generation unit 50 is about 8V. When the level of the core current is 18A, the efficiency of the CPU driving power generation unit 50 is optimized when the voltage applied to the CPU driving power generation unit 50 is about 10V. As the level of the current increases, the efficiency is increased. This optimal voltage level is increased.

4 is a diagram showing the current versus efficiency of the system drive power generation unit 70 according to the present invention. As shown, the system drive power generation unit 70 is optimized for efficiency when a current of about 2.5A flows. The computer according to the present invention also adjusts the level of the current applied to each part to reduce the power consumed by each part when the CPU 60 operates in the power saving mode, the system drive power generation unit 70 also low current Will flow. At this time, the system driving power generation unit 70 according to the present invention flows a current of about 1.5A level higher than the conventional system driving power generation unit 70.

5 is a table comparing the efficiency of a computer according to the present invention and a conventional computer.

The table shows a change in efficiency when the system driving power generation unit 70 is a DCDC converter and the CPU driving power generation unit 50 is a voltage regulation module (VRM) of the CPU 60.

In this case, the currents applied to the DCDC converter are conventionally 0.5A, 1A, but according to the present invention, when the output of the DCDC converter is applied to the input power supply of the VRM of the CPU 60, it is 2A, 2.5A. Therefore, the efficiency of the DCDC converter was 70%, 74%, but 88%, 92% in accordance with the present invention. In addition, when the current applied to the CPU 60 is 5A, 15A, the efficiency of the VRM of the CPU 60 according to the present invention becomes 87% and 89%. In addition, the computer according to the present invention was reduced by 0.8Watt, 0.9Watt compared to the conventional computer, the use time of the battery was increased about 28 minutes, 9 minutes respectively.

6 is a control flowchart of a computer according to the present invention.

As shown in FIG. 6, in the computer according to the present invention, the CPU mode recognition unit 31 determines whether the CPU 60 is in a power saving mode (S11). As a result of determination, when it is determined that the CPU 60 operates in the normal mode instead of the power saving mode, the CPU mode recognition unit 31 determines that the source power V1 output from the power source 10 is the CPU driving power generation unit 50. The first switching unit 35 is controlled to be applied to (S19). The CPU driving power generation unit 50 generates the driving power V5 of the CPU 60 based on the source power V1 applied from the power source 10 (S15), and drives the generated CPU 60. The power supply V5 is output to the CPU 60 (S17).

 As a result of the determination of the CPU mode recognition unit 31 (S11), when it is determined that the CPU 60 operates in the power saving mode, the CPU mode recognition unit 31 is the system power output from the system driving power generation unit 70 ( The second switching unit 37 is controlled so that V2) is applied to the CPU driving power generation unit 50 (S13). The CPU driving power generation unit 50 generates the driving power V5 of the CPU 60 based on the system power V2 applied from the system driving power generation unit 70 (S15), and generates the generated CPU driving power. (V5) is output to the CPU 60 (S17).

In the above-described embodiment, the computer according to the present invention has been described as having one or two power saving modes, but the power saving mode can be subdivided into several stages, and accordingly the system driving power generating unit 70 generates the CPU driving power generating unit. The level (V2, V3) of the system power output to the 50 can be adjusted in various ways.

As described above, the computer according to the present invention applies a voltage having a high level of efficiency to the CPU driving power generator 50 according to the operation mode of the CPU 60, that is, the level of the current applied to the CPU 60. This improved the efficiency of the CPU driving power generation unit 50.

In addition, as the computer according to the present invention improves the efficiency of the CPU driving power generation unit 50, the level of the current applied to the system driving power generation unit 70 is adjusted so that the efficiency of the system driving power generation unit 70 is also increased. Is improved.

Although some embodiments of the invention have been shown and described, it will be apparent to those skilled in the art that modifications may be made to the embodiment without departing from the spirit or spirit of the invention. . It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.

As described above, according to the present invention, there is provided a computer and a method of controlling the same, by adjusting the level of power applied to the input terminal of the CPU driving power generation unit according to the CPU mode to improve the power efficiency.

Claims (16)

In a computer having a CPU and a system unit, A power source; A system driving power generation unit converting the source power input from the power source and outputting the converted power to the system unit; A CPU driving power generation unit for outputting driving power for driving the CPU; And a control unit for controlling the source power from the power source and the system power converted from the system driving power generation unit to be selectively applied to an input terminal of the CPU driving power generation unit according to the power mode of the CPU. computer. The method of claim 1, The power mode of the CPU includes a normal mode and a power saving mode, And the controller controls the system power converted by the system driving power generation unit to be applied to an input terminal of the CPU driving power generation unit when the CPU operates in a power saving mode. The method of claim 2, And the control unit causes the source power output from the power source to be applied to an input terminal of the CPU driving power generation unit when the CPU operates in a normal mode. The method of claim 3, The control unit may include a first switching unit for intermitting that the source power output from the power source is applied to the CPU driving power generation unit, and the system power output from the system driving power generation unit is the CPU driving power generation unit. And a second switching portion for intermittently being applied to the computer. The method of claim 4, wherein The CPU outputs a power state signal including information about the power mode, The control unit further comprises a CPU mode recognition unit for controlling the first switching unit and the second switching unit in accordance with the power state signal. The method of claim 5, When the CPU operates in the power saving mode, the controller controls the system power to be applied to the CPU driving power generation unit at a level where the system driving power generation unit decompresses the source power output from the power source. Computer. The method of claim 6, The power saving mode may include at least one of a deep sleep mode and a deep sleep mode according to an ACPI (Advanced Configuration and Power Interface) protocol. The method of claim 6, The power saving mode includes at least two modes, And the control unit causes the system power of different levels to be applied to the CPU driving power generation unit according to a mode. The method of claim 8, The power saving mode includes a first power saving mode and a second power saving mode, The control unit includes a third switching unit for intermitting that the system power output from the system driving power generation unit is applied to the CPU driving power generation unit, and the system driving power of the first level is set to the first power saving mode. The second switching unit controls the one of the second switching unit and the third switching unit to be applied to the CPU driving power generating unit, and the second switching unit so that the system driving power of the second level is applied to the CPU driving power generating unit in the second power saving mode. And the other interruption of the third switching unit. The method of claim 9, And the controller determines that the CPU operates in a power saving mode when the level of the current applied to the CPU is less than a predetermined level. In the control method of a computer having a CPU and a system unit, Applying a source power output from the power source to the system driving power generation unit; Determining an operation mode of the CPU; And selectively applying the source power from the power source and the system power converted from the system driving power generation unit to the CPU driving power generation unit according to the determined power mode of the CPU. Control method. The method of claim 11, Selectively applying the source power and the system power to the CPU driving power generation unit; Converting the source power inputted by the system driving power generation unit to the CPU driving power generation unit when the CPU operates in a power saving mode; And generating driving power of the CPU based on the system power output from the system driving power generation unit. The method of claim 12, Selectively applying the source power and the system power to the CPU driving power generation unit; And determining that the source power output from the power source is applied to the CPU driving power generation unit when the CPU operates in the normal mode. The method of claim 13, Selectively applying the source power and the system power to the CPU driving power generation unit; And the system driving power generation unit outputs the system power at a level where the source power outputted from the power source is decompressed to the CPU driving power generation unit. The method of claim 14, The determining of the operation mode of the CPU, And determining an operation mode of the CPU based on power state information output from the CPU. The method of claim 15, The power saving mode includes at least two modes, The converting of the source power inputted by the system driving power generation unit and outputting the source power to the CPU driving power generation unit may include outputting the system power having a different level according to a mode to the CPU driving power generation unit. Control method.

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