KR20040062288A - Portable Computer System And Wake-Up Method From S3 Mode To S0 Mode For Portable Computer System - Google Patents

Abstract

PURPOSE: A portable computer system and a method for waking up the same from an S3 mode to an S0 mode are provided to wake up the portable computer system from the S3 mode to the S0 mode by simply opening an LCD(Liquid Crystal Display) panel of the portable computer system without pushing a power button. CONSTITUTION: A lead switch circuit(20) recognizes the opening/closing of the LCD panel by connecting to the first power. A power switch circuit(18) recognizes that the power button is pushed by connecting to the first power. A NOT gate(10) receives the third power applied for the S0 mode by connecting to the second power. A D-flipflop(12) receives a set signal decided by the second power and the NOT gate, a reset signal decided by the first power, an input signal of a D-terminal, and an output signal of the lead switch circuit, and outputs an output signal. An AND gate(14) receives the output signal of the D-flipflop and the output signal of the power switch circuit, and an output terminal of the AND gate is connected to the first power. A microcomputer(16) outputs the power signal by receiving the output signal of the lead switch circuit and the AND gate.

Description

Portable computer system and wake-up method from s3 mode to so0 mode for portable computer system

The present invention relates to a wake-up of a portable computer system and a portable computer system from the S3 mode to the S0 mode. More specifically, the portable computer system can be opened by simply opening the LCD panel of the portable computer system without pressing the power button. A portable computer system for waking up from the S3 mode to the S0 mode and a method for waking up the portable computer system from the S3 mode to the S0 mode.

Generally, computer systems, including portable computer systems, are equipped with a power management function. From the initial power management system (simple power management system) to the advanced power management system (advanced power management system) with improved power management function has been applied to the computer system has been improved. Currently, most computer systems of IBM compatible type have APM function. According to this, unnecessary power consumption of the computer system can be prevented.

On the other hand, the computer system has to go from booting by BIOS to booting by operating system until it can be used by a user. However, as the configuration of the computer system, the operating system and various application programs mounted thereon, the booting time of the computer system is getting longer.

Intel Corporation, Microsoft Corporation, and Toshiba Corporation released "Advanced Configuration and Power Interface Specification Revision 1.0" on December 22, 1996 for better power management and faster computer use. It was. Recently, ACPI (Advanced Configuration and Power Interface) standards have been applied to computer systems. ACPI allows for better power management and faster computer system use.

According to ACPI, the power supply status of computer systems is largely divided into G0 to G3. The G1 state represents a power saving mode, and this G1 is further subdivided into S0 to S5 modes. S0 indicates normal operation mode, S1 ~ S4 mode shows the power consumption of computer system gradually decreased. S1 is standby mode, S2 is suspend mode, S3 is SAVE_TO_RAM mode, S4 is SAVE_TO_DISK mode, and S5 is In SOFT_OFF mode, all power to the computer system is turned off.

Here, ACPI's S3 mode is for fast reuse of computer systems, in which power is supplied to other computer hardware devices other than power management controllers and system memory (RAM), which consists of volatile memory. Is stopped. As the system enters S3 mode, the current state is stored in system memory.

When the system is set to S3 mode, the ACPI function saves the current working state in system memory (RAM) and turns off all power. In the wake-up operation in which the computer system switches from the S3 mode to the S0 mode, the general booting process is not performed, and the system system is quickly reused by calling contents stored in the system memory. Therefore, users will prefer computer systems that support ACPI's S3 mode, which offers greater power savings and enables faster system reuse.

1 is an internal configuration diagram of a portable computer system supporting the conventional ACPI.

As shown in FIG. 1, a conventional portable computer system supporting ACPI includes a power switch circuit unit 118 connected to a P3.3V_Always power source through a resistor and recognizing that a power button (not shown) is pressed. The output of the lead circuit (120) and the power switch circuit (118), which is connected to the P3.3V_AUX power supply via a resistor and recognizes whether the LCD panel (not shown) is opened or closed. And a MICOM 116 for receiving a signal, that is, a power switch signal and an output signal of the reed switch circuit unit 120, that is, a reed switch signal, and outputting a power signal. Here, P3.3V_Always power is always supplied when the portable computer system is in S0 to S5 mode, and P3.3V_AUX power is always supplied when the portable computer system is in S0 to S3 mode.

Referring to FIG. 1, when the output signal of the power switch circuit unit 118, that is, the power switch signal is input to the microcomputer 116 in a low state, the microcomputer 116 recognizes that the power button (not shown) is pressed. The high power signal is output and the portable computer system is turned on. In addition, when the power switch signal is input to the microcomputer 116 in a low state while the power is turned on, that is, when the microcomputer 116 recognizes that the power button (not shown) is pressed, the power is turned off. . On the other hand, when the output signal of the reed switch circuit unit 120, that is, the reed switch signal in the low state is input to the microcomputer 116 in the power-on state, that is, in the S0 mode, the microcomputer (not shown) is closed. 116 recognizes and executes an operation defined in an operating system (OS) (not shown here). In order to turn on the portable computer system again, that is, to wake up the portable computer system from the S3 mode to the S0 mode, open an LCD panel (not shown) and press the power button (not shown) to output the output signal of the power switch circuit unit 118. The power switch signal should be output to the microcomputer 116 in a low state.

However, the role of the reed switch circuit unit 120 of the portable computer system supporting the conventional ACPI only transmits a signal indicating that the LCD panel (not shown) is closed to the microcomputer 116, thereby transferring the portable computer system from the S3 mode to the S0 mode. In order to wake up, there is a problem that you must press the power button (not shown) cumbersomely.

Accordingly, an object of the present invention is to provide a portable computer system and a portable computer system from S3 mode that allow the portable computer system to wake up from S3 mode to S0 mode by simply opening the LCD panel of the portable computer system without pressing the power button. It provides a way to wake up in S0 mode.

1 is an internal configuration diagram of a portable computer system supporting the conventional ACPI,

2 is an internal configuration diagram of a portable computer system supporting ACPI according to the present invention;

3 is an input / output waveform diagram of the D-flip flop when the LCD panel of the portable computer system supporting ACPI according to the present invention is opened up from the S3 mode to the S0 mode.

4 is an input / output waveform diagram of a D-flip flop when the LCD panel of the portable computer system supporting ACPI according to the present invention is opened to wake up from S4 mode to S0 mode.

5 is a flowchart illustrating a method for waking up a portable computer system supporting ACPI from S3 mode to S0 mode according to the present invention.

* Explanation of symbols for the main parts of the drawings

10: sickle gate 12: D-flip flop

14: AND gate 16: micom

18: power switch circuit portion 20: reed switch circuit portion

The above object is, according to the present invention, in a portable computer system that supports ACPI, the lead is connected to the first power supply is always applied when the portable computer system is in the S0 mode to S5 mode to recognize whether the LCD panel opening and closing The portable computer system is connected to a switch circuit unit, a power switch circuit unit connected to the first power source and recognizing that the power button is pressed, and a second power source that is always applied when the portable computer system is in the S0 mode to the S3 mode. A NOT signal gate receiving a third power source applied when the S0 mode is in the S0 mode, a set signal determined by the second power source and the sickle gate connected through a resistor to a set terminal, and the first power source; The reset signal is determined, the input signal of the D terminal, and the output signal of the reed switch circuit part are inputted with a clock pulse, and the output signal corresponding thereto is output. A D-flip flop connected to a first power source, an output signal of the D-flip flop connected to the first power source and an output signal of the power switch circuit unit, and an output terminal of the D-flip flop connected to the first power source; And a microcomputer for receiving the output signal of the reed switch circuit unit and the output signal of the AND gate and outputting a power signal.

Here, the power signal output from the microcomputer is a portable computer system, characterized in that the input to the D terminal of the D-flop flop.

Here, when the LCD panel is opened when the portable computer system is in S3 mode, a clock pulse changed from a low state to a rising-edge state is applied to the D-flip flop; Thereby changing the output signal of the D-flip flop from a high state to a low state; The AND gate outputs an output signal in a low state by an output signal of the D-flip flop in the low state and an output signal of a power switch circuit unit; The microcomputer receives the output signal of the AND gate in the low state and outputs a high power signal so that the portable computer system automatically wakes up from the S3 mode to the S0 mode without pressing the power button. It is preferably a portable computer system.

Meanwhile, according to another aspect of the present invention, in the method for waking up the portable computer system from the S3 mode to the S0 mode when the portable computer system supporting ACPI is in the S3 mode, the first user is in the S3 mode. Opening an LCD panel of the portable computer system at the; When the user opens the LCD panel, the clock pulse applied to the D-flip flop is changed from the low state to the rising-edge state, thereby changing the output signal of the D-flip flop from the high state to the low state; The output signal of the D-flip flop is changed from the high state to the low state so that the output signal of the AND gate, which receives the output signal of the D-flip flop and the output signal of the power switch circuit unit, becomes low; As the output signal of the AND gate goes low, the microcomputer receiving the output signal of the AND gate outputs a high power signal so that the portable computer system automatically switches from S3 mode to S0 mode without pressing the power button. It is also achieved by a method of waking up a portable computer system from S3 mode to S0 mode comprising a wake-up step.

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

2 is an internal configuration diagram of a portable computer system supporting ACPI according to the present invention.

As shown in FIG. 2, the portable computer system supporting ACPI according to the present invention is connected to a P3.3V_Always power source that is always applied when the portable computer system is in the S0 to S5 mode through a resistor (not shown). Reed switch circuit unit 20 for recognizing whether or not to open and close, the power switch circuit unit 18 is connected to the P3.3V_Always power supply through a resistor to recognize that the power button (not shown) is pressed, and the portable computer system is S0 It is connected to the P3.3V_AUX power supply, which is always applied in the S3 mode, from the mode to the NOT gate 10 and the set terminal for receiving the P3.3V power supply when the portable computer system is in S0 mode. A set signal determined by the P3.3V_AUX power supply and the sickle gate 10 connected through the reset signal, a reset signal determined by the P3.3V_Always power supply, an input signal of the D terminal, that is, a power signal output by the microcomputer 16, Clock pulse D-flip flop 12 connected to P3.3V_Always power supply and the Q-terminal connected to P3.3V_Always power supply through the resistor and output the output signal according to the output signal of the switch circuit unit 20, and D-flipflop The output signal of (12) and the output signal of the power switch circuit unit 18 are inputted, and the output terminal is connected to the AND gate 14 connected to the P3.3V_Always power source through a resistor, and the output signal of the reed switch circuit unit 20. The microcomputer 16 receives the output signal of the AND gate 14 and outputs a power signal. Here, the first power source is represented by P3.3V_Always power supply, the second power source is represented by P3.3V_AUX power supply, and the third power source is represented by P3.3V power supply.

Referring to FIG. 2, the difference from FIG. 1 is that the reed switch circuit unit 20 is connected to the P3.3V_Always power source instead of the P3.3V_AUX power source through a resistor, and the power switch signal applied to the microcomputer 16 is a power switch. The output of the AND gate 14 connected to the P3.3V_Always power source, not the output signal of the circuit unit 18, and receiving the output signal of the D-flop flop 12 and the output signal of the power switch circuit unit 18. It becomes a signal. Here, P3.3V_Always power is always supplied when the portable computer system is in S0 mode to S5 mode. Therefore, since the reset stage of the D-flop flop 12 is connected to the P3.3V_Always power supply, the reset signal of the D-flop flop 12 is always high regardless of which mode the portable computer system is in. . The P3.3V_AUX power is always supplied when the portable computer system is in the S0 mode to the S3 mode, and the P3.3V power supply is the power applied when the portable computer system is in the S0 mode.

On the other hand, the characteristics of the D-flip flop 12 included in the portable computer system supporting the ACPI according to the present invention is defined by the following truth table.

<D-Flip Flop Truth Table>

Set signal Reset signal Clock D (power signal) Q (output signal) Case 1 Low High Don't care (X) Don't care (X) High Case 2 High Low Don't care (X) Don't care (X) Low Case 3 Low Low Don't care (X) Don't care (X) High Case 4 High High Rising-edge (R) High High Case 5 High High Rising-edge (R) Low Low Case 6 High High Low Don't care (X) Maintain state (Q0)

FIG. 3 is an input / output waveform diagram of a D-flip flop when the LCD panel of the portable computer system supporting ACPI according to the present invention is opened up from the S3 mode to the S0 mode.

Referring to FIG. 3 with reference to FIG. 2 and <Truth Table of D-Flop Flops>, the portable computer system is in S3 mode before the leftmost LCD panel (not shown) of FIG. 3 is opened. In this case, referring to FIG. 2, the reset terminal of the D-flop flop 12 is connected to the P3.3V_Always power supply so that the reset signal is always kept high regardless of which mode the portable computer system is in. In addition, in the S3 mode, the portable computer system is not supplied with P3.3V power but is supplied with P3.3V_AUX power, so the set signal becomes high. Since the S3 mode means that the LCD panel (not shown) is closed, the clock of the D-flip flop 12 that uses the output signal of the reed switch circuit unit 20 as the clock pulse becomes low. In addition, since the portable computer system is in the S3 mode, the power signal of the microcomputer 16 applied to the D terminal of the D-flop flop 12 goes low. In the case of <Truth Table of D-Flop Flops>, the output signal state of the D-Flip flop 12 becomes high. The states of each of these signals are shown in FIG.

In this case, when the LCD panel (not shown) is opened, the D-flip flop 12 uses the output signal of the reed switch circuit unit 20 as a clock pulse, so that the clock is in a rising edge state. In the case of the flop truth table &gt; 5, the output signal of the D-flop flop 12 is changed to the low state. This state is shown in FIG. Referring to FIG. 2, since the output signal of the D-flip flop 12 is in a low state, the output signal of the AND gate 14 receiving the input signal, that is, the power switch signal, is input to the microcomputer 16 in a low state so that the microcomputer 16 is It recognizes that the power button (not shown) is pressed and outputs a high power signal. This state is shown in FIG. In other words, by opening the LCD panel (not shown) without actually pressing the power button (not shown), the portable computer system supporting the ACPI according to the present invention can be woken up from the S3 mode to the S0 mode. 2, the P3.3V power is input to the sickle gate 10 according to the high power signal output from the microcomputer 16, and the set signal is changed to the low state. This state is shown in FIG. Since the set signal is changed to the low state, the output signal of the D-flop flop 12 is changed to the high state by 1 in the case of the <D-Flip Flop Truth Table>. This state is shown in FIG. After that, even if the LCD panel (not shown) is closed and opened, the output signal of the D-flop flop 12 is kept high by 1 in the case of <Truth table of D-flip flop>. This state is shown in FIG. That is, referring to FIG. 2, since the output signal of the D-flip flop 12 is in a high state, the output signal of the AND gate 14, that is, the state of the power switch signal is determined according to the output signal state of the power switch circuit unit 18. The switch circuit unit 20 only performs the original function of recognizing whether the LCD panel is opened or closed, and does not perform the function of the power switch circuit unit 18.

4 is an input / output waveform diagram of the D-flip flop when the LCD panel of the portable computer system supporting ACPI according to the present invention is opened to wake up from the S4 mode to the S0 mode.

Referring to Fig. 2 and Fig. 2 and <Truth Table of Flip-Flop>, the portable computer system is in S4 mode before the leftmost LCD panel (not shown) of Fig. 4 is opened. In this case, referring to FIG. 2, the reset terminal of the D-flop flop 12 is connected to the P3.3V_Always power supply so that the reset signal is always kept high regardless of which mode the portable computer system is in. The set signal goes low because the portable computer system is not powered by P3.3V and P3.3V_AUX in S4 mode. Since the S4 mode means that the LCD panel (not shown) is closed, the clock of the D-flip flop 12 that uses the output signal of the reed switch circuit unit 20 as the clock pulse becomes low. In addition, since the portable computer system is in the S4 mode, the power signal of the microcomputer 16 applied to the D terminal of the D-flop flop 12 goes low. In the case of <Truth Table of D-Flop Flops>, the output signal state of the D-Flip flop 12 becomes high by 1. The states of each of these signals are shown in FIG.

Here, when the LCD panel (not shown) is opened, the D-flip flop 12 uses the output signal of the reed switch circuit unit 20 as the clock pulse, so that the clock is in the rising edge state and the power button (not shown). When P3.3V_AUX power is applied and referring to FIG. 2, the set signal is changed to high state. This state is shown in FIG. Since the power button (not shown) is pressed, referring to FIG. 2, the output signal of the power switch circuit unit 18 goes low. This state is shown in FIG. Referring to FIG. 2, since the output signal of the power switch circuit unit 18 is in a low state, the output signal of the AND gate 14, which receives the output signal of the power switch circuit unit 18, that is, the power switch signal is in a low state. ), The microcomputer 16 recognizes that the power switch is pressed and outputs a power signal in a high state. This state is shown in FIG. That is, only when the power button (not shown) is pressed, the portable computer system supporting the ACPI according to the present invention can wake up from the S4 mode to the S0 mode, and only by opening the LCD panel (not shown), the ACPI according to the present invention. A portable computer system that supports PC cannot wake up from S4 mode to S0 mode. The P3.3V power is input to the sickle gate 10 according to the high power signal output by the microcomputer 16, and the set signal is changed to the low state. This state is shown in FIG. Since the set signal is turned low, the output signal of the D-flop flop 12 is kept high by 1 in the case of <Truth Table of D-Flip-Flop>. This state is shown in FIG. After that, even if the LCD panel (not shown) is closed and opened, the output signal of the D-flop flop 12 is kept high by 1 in the case of <Truth table of D-flip flop>. This state is shown in FIG. That is, referring to FIG. 2, since the output signal of the D-flip flop 12 is in a high state, the output signal of the AND gate 14, that is, the state of the power switch signal is determined according to the output signal state of the power switch circuit unit 18. The switch circuit unit 20 only performs the original function of recognizing whether the LCD panel is opened or closed, and does not perform the function of the power switch circuit unit 18.

In addition, the description of FIG. 4 described above also applies when the LCD panel of the portable computer system supporting the ACPI is opened to wake up from the S5 mode to the S0 mode. That is, only when the power button (not shown) of the portable computer system supporting the ACPI according to the present invention is pressed, the portable computer system can be woken up from the S5 mode to the S0 mode and only by opening the LCD panel (not shown). A portable computer system supporting ACPI according to the invention cannot wake up from S5 mode to S0 mode.

5 is a flowchart illustrating a method of waking up a portable computer system supporting ACPI from S3 mode to S0 mode according to the present invention.

Referring to FIG. 5, first, an LCD panel (not shown) of a portable computer system supporting ACPI according to the present invention in the S3 mode is opened (S10). The clock pulse applied to the D-flip flop (case 12) where the user opens the LCD panel (not shown) changes from the low state to the rising-edge state so that the output signal of the D-flip flop 12 is low from the high state. The state is changed (S12). Then, since the output signal of the D-flip flop 12 is changed from the high state to the low state, the AND gate 14 receives the output signal of the D-flip flop 12 and the output signal of the power switch circuit unit 18. The output signal goes low (S14). Since the output signal of the AND gate 14 is low, the microcomputer 16 receiving the output signal of the AND gate 14 outputs a high power signal, and the portable computer system automatically switches from the S3 mode to the S0 mode. Wake-up is made (S16).

As described above, according to the present invention, when a portable computer system in S3 mode is to be woken up from the S3 mode to the S0 mode, the portable computer system can be removed from the S3 mode by simply opening the LCD panel without pressing the power button. You can boot up much faster because you can wake up in S0 mode. Also, when the portable computer system is in S3 mode, it can wake up to S0 mode only by opening the LCD panel, and when it is in S4 or S5 mode, it wakes up to S0 mode by pressing the power button. Opening it does not wake-up in S0 mode, which can prevent power consumption or battery life caused by accidentally opening the LCD panel and wake-up in S0 mode. And when the portable computer system is in S0 mode, the output signal of the D-flip flop remains high even when the LCD panel is closed and opened, so that the reed switch circuit part does not perform the function of the power switch circuit part and only the LCD panel is opened and closed. Since it performs the original function of recognizing that there is an advantage that can use the existing hardware structure as it is.

As described above, according to the present invention, the portable computer system and the portable computer system which allow the portable computer system to wake up from the S3 mode to the S0 mode by simply opening the LCD panel of the portable computer system without pressing the power button are provided. A method of wake-up from mode to mode S0 is provided.

Claims (4)

In a portable computer system that supports ACPI, A reed switch circuit unit connected to a first power source that is always applied when the portable computer system is in the S0 mode to the S5 mode and recognizes whether the LCD panel is opened or closed; A power switch circuit unit connected to the first power source and recognizing that a power button is pressed; NOT gate connected to a second power source that is always applied when the portable computer system is in the S0 mode to a S3 mode, and receives a third power source that is applied when the portable computer system is in the S0 mode; A set signal determined by the second power source and the sickle gate connected through a resistor to a set terminal, a reset signal determined by the first power source, an input signal of the D terminal, and a clock pulse; Receiving the output signal and outputting the output signal according to the above, and the D-flop flop with Q terminal connected to the first power source, An output terminal of the D-flip flop and an output signal of the power switch circuit unit, the output terminal being connected to the first power source, and an output terminal of the AND gate connected to the first power source; And a microcomputer receiving the output signal of the reed switch circuit unit and the output signal of the AND gate and outputting a power signal. The method of claim 1, And a power signal output from the microcomputer is input to the D terminal of the D flip-flop. The method of claim 1, When the LCD panel is opened when the portable computer system is in the S3 mode, the clock pulse changed from the low state to the rising edge state is applied to the D-flip flop so that the output signal of the D-flip flop is high. Goes low; The AND gate outputs an output signal in a low state by an output signal of the D-flip flop in the low state and an output signal of a power switch circuit unit; The microcomputer receives the output signal of the AND gate in the low state and outputs a high power signal so that the portable computer system automatically wakes up from the S3 mode to the S0 mode without pressing the power button. Portable computer system. A method of waking up a portable computer system from S3 mode to S0 mode when a portable computer system supporting ACPI is in S3 mode, A user opening an LCD panel of a portable computer system in S3 mode; Changing the clock pulse applied to the D-flip flop from the low state to the rising-edge state when the user opens the LCD panel, thereby changing the output signal of the D-flip flop from the high state to the low state; The output signal of the D-flip flop is changed from the high state to the low state so that the output signal of the AND gate, which receives the output signal of the D-flip flop and the output signal of the power switch circuit unit, becomes low; As the output signal of the AND gate goes low, the microcomputer receiving the output signal of the AND gate outputs a high power signal so that the portable computer system automatically switches from S3 mode to S0 mode without pressing the power button. And wake-up from the S3 mode to the S0 mode.