KR20080113525A - Embedded system and power management method thereof - Google Patents

Abstract

An embedded system and a power management method thereof are provided to minimize unnecessary power consumption by operating in a power saving mode when the embedded system is not used and prevent malfunction of the embedded system due to motion noise. An embedded system for minimizing power consumption comprises a motion detecting unit(10), an operating mode determining unit(20), a processing unit(30), and a power supply unit(40). The motion detecting unit detects physical motion of the system to generate a motion signal. The operating mode determining unit analyzes a motion signal according to an effective motion condition and effective time of the motion signal to check whether the system is used. The operating mode determining unit generates a control signal for setting or requesting a power saving mode. The processing unit sets and releases the power saving mode according to the control signal. The power supply unit supplies power to the motion detecting unit, the operating mode determining unit and the processing unit.

Description

Embedded system and power management method

1 is a view showing the configuration of an embedded system according to an embodiment of the present invention;

2 is a view for explaining in more detail the operation of the operation mode determiner according to an embodiment of the present invention; and

3 is a flowchart illustrating a power management method of an embedded system according to an exemplary embodiment of the present invention.

The present invention relates to an embedded system (embedded system), and more particularly to an embedded system and its power management method for minimizing unnecessary power consumption.

In general, an embedded system performs special functions only by embedding software for operating a system in hardware. Unlike a personal computer, an embedded system has specific requirements and performs only predefined tasks.

Embedded systems are often implemented as handheld devices such as remote controls, computer mice, or wearable biosignal measurement devices.

In this case, since the embedded system is supplied with a power source using a portable battery, the power consumption is a factor in determining the usable time of the embedded system. Therefore, it is necessary to minimize unnecessary power consumption.

However, the conventional embedded system always operates in a normal state regardless of whether the user uses it, and it can be seen that unnecessary power consumption occurs.

For example, if the embedded system is implemented as a portable device such as a remote control or a computer mouse in which a user only touches and performs a task when necessary, the system performs a set task only when the system is moved by the user.

In other words, it is necessary to perform the set operation only when it is physically moved by the user. However, the conventional remote control or the computer mouse is always activated and ready to perform the set operation regardless of the unnecessary power consumption. It can be seen.

In addition, when the embedded system is implemented as a portable device that is always in contact with the user's human body, there is a risk that a malfunction due to a meaningless movement of the user is performed even if the system is not used by the user.

In other words, not only unnecessary power consumption may increase due to meaningless movement, but also a problem of malfunctioning may be generated by recognizing and processing as motion noise input data.

An object of the present invention for solving the above problems is to detect the suspended state through the occurrence of the movement of the embedded system to minimize unnecessary power consumption and at the same time to prevent the malfunction due to meaningless movement in advance And a power management method thereof.

In order to achieve the object of the present invention as described above, the embedded system of the present invention, the motion detection unit for detecting the physical movement of the system to generate a motion signal; An operation mode determination unit which analyzes the motion signal according to an effective motion condition and an effective time to determine whether to use the system, and generates a control signal for requesting to set or release a power saving mode; A processing unit configured to set or release a power saving mode according to the control signal; And a power supply unit supplying power to the motion detector, the operation mode determiner, and the processing unit.

In order to achieve the object of the present invention as described above, the power management method of the embedded system of the present invention, the step of detecting the physical movement of the system through a motion sensor; Setting a power saving mode if it does not detect a motion that satisfies the valid motion condition so that the valid time elapses; And canceling the power saving mode when detecting a motion satisfying the effective motion condition during the power saving mode.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. However, in describing in detail the operating principle of the preferred embodiment of the present invention, if it is determined that the detailed description of the related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

In addition, the same reference numerals are used for parts having similar functions and functions throughout the drawings.

1 is a diagram showing the configuration of an embedded system according to an embodiment of the present invention.

Referring to FIG. 1, the power management apparatus of the present invention includes a motion detector 10, an operation mode determiner 20, a processor 30, and a power supply 40.

The motion detector 10 may be implemented as any type of sensor capable of detecting motion, such as an acceleration sensor, a gyro sensor, and a vibration sensor, and generates a motion signal by detecting physical movement of a corresponding system.

In this case, the motion signal may be implemented as both an analog signal and a digital signal.

The operation mode determiner 20 sets a valid motion condition and an effective time in advance, and analyzes the motion signal transmitted from the motion detector 10 to generate an interrupt signal for changing the operation mode of the corresponding system. .

That is, if a motion signal that satisfies the valid motion condition is not inputted so that the valid time elapses, the system determines that the system is in a disabled state and generates an interrupt signal for setting the power saving mode. On the other hand, when a motion signal that satisfies the valid motion condition is received, it is determined that the user has started using the system again, and generates an interrupt signal for canceling the power saving mode.

In this case, the effective motion condition and the valid time may be arbitrarily set and changed by a user or a developer of the corresponding system according to a field and an operating environment to which the system is applied. In particular, by arbitrarily setting and changing the effective motion condition, the system can detect whether or not the motion occurs in all cases of the wearable portable device and the non-wearable portable device.

The processing unit 30 performs a task required by the user using the power supplied from the power supply unit 40 in the normal mode, but maintains a low power state in the power saving mode.

The power supply unit 40 allows the portable battery to be mounted and detached, and supplies power of the portable battery to the internal power of the motion sensing unit 10, the operation mode determiner 20, and the processing unit 30.

The peripheral power supply unit 50 is a power regulator for supplying power to various peripheral devices (for example, analog devices, LCDs, sensors, etc.) connected to the processing unit 30. Power is supplied from the power supply to the peripheral device 60 by increasing and decreasing the pressure.

The peripheral device power supply unit 50 of the present invention sets a power saving mode (off state) in response to a control signal output from the operation mode determination unit 20, and provides the peripheral device 60 to the peripheral device in the power saving mode. Cut off power to reduce power consumption.

In the above embodiment, the operation mode determination unit 20 and the processing unit 30 are configured separately, but if necessary, the processing unit 30 includes the operation mode determination unit 20 to configure the operation mode determination unit 20. ) Can be performed.

2 is a view for explaining in more detail the operation of the operation mode determiner according to an embodiment of the present invention.

In FIG. 2, (a) shows a motion signal when the embedded system of the present invention is implemented as a non-wearable portable device, and (b) shows a motion signal when the human body is equipped with a wearable portable device.

As described above, the embedded system of the present invention can be implemented as a wearable portable device as well as a non-wearable portable device, and are set and changed according to the application field and the operating environment of the corresponding system.

When the embedded system of the present invention is implemented as a non-wearable portable device, a movement signal having a certain signal value is physically moved by the user when using the system as shown in (a). It can be seen that no motion signal is generated.

Even when implemented as a human body wearable portable device, as shown in (b), it can be seen that the motion signal has a constant signal level when in use, but has a value that is relatively much larger or smaller than the signal value when in use. .

Therefore, the effective motion condition may be limited to a constant signal value (or signal level range).

Accordingly, as shown in (a), when the embedded system of the present invention is implemented as a non-wearable portable device, the operation mode determiner 21 does not input a motion signal that satisfies the valid motion condition so that the valid time elapses. If not, it is easily recognized that the system is in use.

That is, by analyzing the motion signal according to the effective motion conditions, it is possible to easily determine whether the corresponding system is used and change the operation mode.

In addition, even when the embedded system of the present invention is implemented as a wearable portable device, as shown in (b), the operation mode determiner 21 analyzes a motion signal according to an effective motion condition to determine whether the system is used or not. You can easily grasp and change the operation mode.

3 is a flowchart illustrating a power management method of an embedded system according to an exemplary embodiment of the present invention.

First, by continuously detecting the physical movement of the system, a motion signal reflecting the detection result is generated (S11).

If the motion signal generated through the step S11 does not satisfy the valid motion condition (S12), it is checked once more whether this motion signal is continuously generated during the valid time (S13).

As a result of the check, if a motion signal that does not satisfy the effective motion condition is continuously generated during the effective time, the user determines that the user is not using the system and operates in a power saving mode to prevent unnecessary power consumption (S14). .

On the other hand, if the motion signal satisfies the valid motion condition, it is confirmed that the corresponding system is in use by the user, and it is checked once more whether the current operation mode is the power saving mode (S15).

If the current operation mode is the power saving mode, the power saving mode is immediately canceled and the normal mode is set (S16, S17). If it is already operating in the normal mode, the operation continues to the normal mode (S17).

In some cases, the power saving mode may be set and released according to conditions opposite to the above. 4 is a flowchart showing an operation in this case.

First, by continuously detecting the physical movement of the system, a motion signal reflecting the detection result is generated (S21).

When the motion signal generated through the step S21 satisfies the valid motion condition (S22), it is checked once more whether this motion signal is continuously generated during the valid time (S23).

As a result of the check, if a motion signal that satisfies the valid motion condition is generated continuously during the valid time, it operates in the power saving mode (S24).

On the other hand, if a motion signal that does not satisfy the effective motion condition is generated continuously, the current operation mode is checked once more (S25).

If the current operation mode is the power saving mode, the power saving mode is immediately canceled and the normal mode is set (S26, S27). If it is already operating in the normal mode, the operation continues to the normal mode (S27).

As described above, the present invention can set power saving mode setting conditions in various forms.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and it is common in the art that various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be apparent to those skilled in the art.

As described above, the embedded system and the power management method of the present invention detect the physical movement of the corresponding system, determine the use of the embedded system, and set an operation mode of the corresponding system.

Therefore, when the embedded system is in an inactive state, it is operated in a power saving mode, which minimizes unnecessary power consumption and also blocks the possibility of malfunction of the embedded system, which may be caused by motion noise.

Claims (10)

A motion detector for detecting a physical motion of the system and generating a motion signal; An operation mode determination unit which analyzes the motion signal according to an effective motion condition and an effective time to determine whether to use the system, and generates a control signal for requesting to set or release a power saving mode; A processing unit configured to set or release a power saving mode according to the control signal; And And a power supply unit configured to supply power to the motion detector, the operation mode determiner, and the processor. The method of claim 1, wherein the motion detector An embedded system for minimizing power consumption, which is implemented by at least one of an acceleration sensor, a gyro sensor, and a vibration sensor. The method of claim 1, wherein the operation mode determiner If only the motion signal that does not satisfy the effective motion condition is input so that the valid time elapses, the power saving mode is set, and then the power saving mode is released when the motion signal that satisfies the valid motion condition is received. An embedded system for minimizing power consumption. The method of claim 1, wherein the operation mode determiner Setting the power saving mode when the motion signal satisfying the effective motion condition is input so that the valid time elapses, and then canceling the power saving mode when the motion signal not satisfying the valid motion condition is received; Embedded system to minimize power consumption. The method of claim 1, wherein the valid motion condition and valid time are Embedded system, characterized in that can be set and changed according to the application field and the operating environment of the embedded system. The method of claim 1, wherein the processing unit Embedded power for minimizing power consumption characterized in that the power is turned off when the power saving mode is set, the power is turned on when the power saving mode is released. The method of claim 1, An embedded system for supplying power to a peripheral device, further comprising a peripheral power supply for supplying power to the peripheral device in response to the control signal output from the operation mode determiner. . Detecting physical movement of the system through a motion sensor; Setting a power saving mode if it does not detect a motion that satisfies the valid motion condition so that the valid time elapses; And And detecting the movement satisfying the effective movement condition in the power saving mode, and releasing the power saving mode. The method of claim 8, wherein the motion detection sensor And at least one of an acceleration sensor, a gyro sensor, and a vibration sensor. The method of claim 8, wherein the valid motion condition and valid time are: The power management method of the embedded system, characterized in that the setting and change according to the application field and the operating environment of the embedded system.

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