KR20080059747A - Device and method of controlling states for system with multiple processor and computer-readable medium having thereon program performing function embodying the same - Google Patents

Abstract

A device and a method for controlling states in a system equipped with a plurality of processors, and a computer-readable recording medium storing a program thereof are provided to minimize power consumption of the system by receiving and analyzing a control signal from a main processor, and changing the state of a sub processor into a normal state when a state control signal is received. A control signal processor(210) receives a control signal from a main processor(100). A state change command generator(230) generates a state change command for a sub processor(150) by analyzing the control signal when the control signal is the state control signal for the sub processor. A state change command transmitter(250) transmits the state change command to the sub processor. The control signal processor receives the control signal from the main processor through a serial communication interface. The control signal processor transmits the control signal to the sub processor when the sub processor is normal state, and transmits the control signal to the state change command generator when the sub processor is a power-down state. The sub processor is power down state.

Description

TECHNICAL DEVICE AND METHOD OF CONTROLLING STATES FOR SYSTEM WITH MULTIPLE PROCESSOR AND COMPUTER-READABLE MEDIUM HAVING THEREON PROGRAM PERFORMING FUNCTION EMBODYING THE SAME}

1 is an exemplary block diagram of a state control apparatus in a system having multiple processing apparatuses in accordance with the present invention.

2 is an exemplary flow chart of a state control method in a system having multiple processing apparatuses in accordance with the present invention;

<Description of the symbols for the main parts of the drawings>

100: main processing unit 150: sub-processing unit

200: state control device 210: control signal processing unit

230: state change command generation unit 250: state change command transmission unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a state control apparatus and a state control method in a system having a plurality of processing apparatuses, and to a computer readable recording medium having recorded thereon a program for realizing the same. Multiple processing that minimizes power consumption of the system by changing the state of the subprocessing unit to the normal state only in the state control signal that receives and interprets the control signal from the main processing unit in the system to perform the operation of the subprocessing unit. A state control apparatus and a state control method in a system having a device, and a computer-readable recording medium having recorded thereon a program for realizing the same.

As information and communication technology develops, a complex product in which many functions are fused is developed and used.

Such a hybrid product performs a mobile communication function and an image processing function at the same time by fusing an RFID reader function to a mobile communication terminal, or a function of image processing to a terminal or a mobile communication terminal that simultaneously performs a mobile communication function and an RFID reader function. For example, the terminal.

In such a complex product, each function is preferably performed in a separate signal processing device.

For example, in the case of a terminal which simultaneously performs a mobile communication function and an RFID reader function, two or more signal processing devices, such as a signal processing device for a mobile communication function and a signal processing device for an RFID reader function, are provided in the terminal to perform a function. Can be.

In addition, a plurality of devices, such as a micro controller unit (MCU) that performs a control function as well as a processing device, may be included.

Hereinafter, in the specification of the present invention, the term “processing device” refers to a semiconductor device such as a central processing unit (CPU) that performs signal processing or a micro controller unit (MCU) that performs a control function, or a programmable signal processing device such as an FPGA. The term "system" refers to a system-on-chip semiconductor device in which a plurality of such semiconductor devices are integrated into one chip by integrating a plurality of semiconductor devices. It is used as a term referring to a terminal, an electronic product, etc. that performs a complex function.

In a system including a plurality of such processing devices, minimization of power consumption is an important factor, particularly in a system configured in the form of a mobile terminal.

For example, a terminal that simultaneously performs the aforementioned mobile communication function and RFID reader function performs an operation based on a built-in battery due to the characteristics of a mobile terminal. Therefore, in order to maximize operating time, it may include a configuration for minimizing power consumption through proper power management.

For example, a mobile terminal is provided with a main processor and a sub processor. The main processing device performs signal processing for, for example, a mobile communication function, and the sub processing device has a signal for, for example, an RFID reader function. Suppose you perform a process.

In this case, the RFID reader function can perform the operation only when the user needs it. In addition, the mobile communication function should always be performed to receive a call.

Thus, for example, the main processing device processing the mobile communication function can be configured to perform state control of the sub processing device processing the RFID function.

That is, the sub-processing device may have the following states with respect to power consumption.

First of all, this is a normal operation state in which a function allocated in the subprocessing apparatus can be normally performed.

In addition, as the idle state, the main core of the subprocessing unit is stopped and only a function such as reception of control signals from the main processing unit or reception of peripheral interrupts is operated. to be.

In addition, as a power down state, all functions of the sub-processing device are stopped and power consumption does not occur.

State control for reducing power consumption in the sub-processing apparatus is as follows.

For example, when the sub processing unit is in an idle state in which power consumption is reduced and receives a state control signal from the main processing unit, the sub processing unit is changed to a normal state for executing a function to perform an RFID reader function.

The state control signal may be generated by the main processing device when receiving a user input through a button of a mobile terminal, for example, and may change the state of the sub processing device from the idle state to the normal state to perform a function assigned to the sub processing device. Control signal to change.

For example, state control is possible by transmitting a state control signal from the main processing unit to the sub processing unit using a serial communication interface such as RS-232 or Intelligent Interface Controller (I2C) or Serial Peripheral Interface (SPI).

The state control of the sub-processing apparatus through such a main processing apparatus has an advantage of reducing power consumption, especially when the sub-processing apparatus is always in a normal state.

However, even in such an idle state, power may be consumed in the subprocessing device. In other words, the sub-processing apparatus must maintain a minimum function for receiving the state control signal from the main processing apparatus, so that the sub-processing apparatus consumes power even in the idle state.

In addition, even when receiving a control signal other than a state control signal from the main processing device, in order to interpret the control signal, the sub-processing device needs to return to a normal state and interpret the control signal.

For example, assume that a control signal transmitted from the main processing unit to the sub processing unit has a format of 12 bytes, and assume that a specific combination represents a state control signal and other combinations represent another control signal.

The subprocessing unit in the idle state is changed to the normal state for the control signal analysis when receiving the control signal transmitted from the main processing unit.

The subprocessing apparatus, once changed to the normal state, analyzes the received control signal. In this case, if the received control signal is the above-described state control signal, it will maintain a normal state and perform a function allocated to a sub-processing device such as an RFID reader function.

However, if the control signal is not the above-described state control signal, the sub-processing apparatus once changed to the normal state and performing the control signal analysis will be changed back to the idle state to minimize power consumption.

In addition, when the control signal is transmitted in units of bytes, in order to check whether the control signal received from the sub-processing unit matches the state control signal, for example, the sub-processing unit receives a 12-byte control signal every byte. For analysis, change to normal state and perform the operation.

As in this case, although the conventional state control method reduces power consumption rather than keeping the sub-processing unit in the idle state and changing the normal state only when necessary to always maintain the normal state by performing the assigned function. In order to interpret the control signal, the sub-processing apparatus is changed to a normal state every time the control signal is received, and thus power consumption occurs.

It is an object of the present invention to bring a state of a sub-processing device into a normal state only in the case of a state control signal which receives a control signal from the main processing device and interprets the control signal from the main processing device in a system having a plurality of processing devices. The present invention provides a state control device and a state control method in a system having a plurality of processing devices that minimize the power consumption of the system.

Another object of the present invention is to provide a computer-readable recording medium having recorded thereon a program for realizing each step of a state control method in a system having a plurality of processing apparatuses described above.

MEANS TO SOLVE THE PROBLEM In order to achieve the said technical subject, this invention is a state control apparatus in the system containing a main processing apparatus and a subprocessing apparatus, Comprising: The control signal processing part which receives the control signal from the said main processing apparatus, And analyzes the said control signal. When the control signal is a state control signal of the sub-processing device, a state change command generation unit for generating a state change command for the sub-processing device, and a state change command for transmitting the state change command to the sub-processing device. Provided are a state control apparatus in a system having a plurality of processing apparatus including a portion.

In a state control apparatus in a system having a plurality of processing apparatuses according to the present invention, the control signal processing unit may receive the control signal from the main processing apparatus via a serial communication interface.

Further, in a state control apparatus in a system having a plurality of processing apparatuses according to the present invention, the control signal processing unit transmits the control signal to the sub processing apparatus when the sub processing apparatus is in a normal operating state, When the processing device is in the power down state, the control signal may be transmitted to the state change command generation unit.

Further, in a state control apparatus in a system having a plurality of processing apparatuses according to the present invention, the control signal processing unit is configured to cause the power down state from the sub processing apparatus before the sub processing apparatus is changed to the power down state. A control signal indicative can be received.

Further, in a state control apparatus in a system having a plurality of processing apparatuses according to the present invention, the sub-processing apparatus is in a power-down state, and the control signal is the state control for waking up the sub-processing apparatus. Signal, and the state change command may be a reset command to the sub-processing device.

Further, in a state control apparatus in a system having a plurality of processing apparatuses according to the present invention, the sub processing apparatus is in a normal state, and the control signal is the state control for changing the sub processing apparatus into a power down or idle state. Signal, and the state change command may be a power down command to the sub-processing device.

Further, in a state control apparatus in a system having a plurality of processing apparatuses according to the present invention, the state change command transmitting unit may transmit the state change command to the subprocessing apparatus through a serial communication interface.

Further, in a state control apparatus in a system having a plurality of processing apparatuses according to the present invention, the state change command transmission unit may transmit the state change command to a state change dedicated pin of the subprocessing apparatus.

Further, in a state control apparatus in a system having a plurality of processing apparatuses according to the present invention, the state control apparatus stops operation when the sub processing apparatus is in a normal state, and when the sub processing apparatus is in a power down state. The state control of the subprocessing apparatus can be performed.

In addition, in a state control apparatus in a system having a plurality of processing apparatuses according to the present invention, the serial communication interface may be any one of RS-232, I2C, or SPI.

The present invention also provides a state control method in a system including a main processing unit and a sub processing unit, the method comprising: (a) receiving a control signal from the main processing unit; and (b) interpreting the control signal to control the control. Generating a state change command for the sub-processing device if the signal is a state control signal of the sub-processing device; and (c) transmitting the state change command to the sub-processing device. It provides a state control method in a system having a.

In a state control method in a system having a plurality of processing apparatuses according to the present invention, the step (a) comprises (a-1) receiving the control signal from the main processing apparatus via a serial communication interface. It may include.

Further, in a state control method in a system having a plurality of processing apparatuses according to the present invention, the step (a) is (a-2) the sub-processing of the control signal when the sub-processing apparatus is in a normal operating state. Transmitting to a device and receiving the control signal when the sub-processing device is in a power down state.

Further, in the state control method in a system having a plurality of processing apparatuses according to the present invention, the step (a) is (a-3) the sub-processing apparatus before the sub-processing apparatus is changed to the power-down state. Receiving from the control signal indicating the power down state.

Further, in a state control method in a system having a plurality of processing apparatuses according to the present invention, the sub processing apparatus is in a power down state, and the control signal is the state control signal for waking up the sub processing apparatus. Step (b) may include (b-1) generating the state change command to perform a reset for the subprocessing device.

Further, in a state control method in a system having a plurality of processing apparatuses according to the present invention, the sub-processing apparatus is in a normal state, and the control signal controls the state to change the sub-processing apparatus to a power down or idle state. Signal, wherein step (b) may include (b-2) generating the state change command to perform power down on the sub-processing device.

Further, in a state control method in a system having a plurality of processing apparatuses according to the present invention, the step (c) includes (c-1) transmitting the state change command to the sub-processing apparatus via a serial communication interface. It may include a step.

Further, in the state control method in a system having a plurality of processing apparatuses according to the present invention, the step (c) is (c-2) to transmit the state change command to the state change-only pin of the sub-processing apparatus. It may include a step.

In addition, in the state control method in a system having a plurality of processing apparatus according to the present invention, the serial communication interface may be any one of RS-232, I2C or SPI.

In addition, the method for controlling a state in a system having a plurality of processing apparatuses according to the present invention may further include (d) checking whether the sub-processing apparatus is in a power-down state before the step (a). have.

The present invention also provides a computer-readable recording medium having recorded thereon a program for realizing each step of a state control method in a system having a plurality of processing apparatuses described above.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, a state control apparatus and a state control method in a system having a plurality of processing apparatuses of the present invention and embodiments of a computer-readable recording medium having recorded thereon a program for realizing the same will be described in more detail with reference to the accompanying drawings. do.

1 is an exemplary block diagram of a state control device in a system having multiple processing devices in accordance with the present invention.

As shown, the state control apparatus 200 in a system having a plurality of processing apparatuses according to the present invention includes a control signal processor 210, a state change command generator 230, and a state change command transmitter 250. It includes.

In addition, as shown, the state control apparatus 200 in a system having a plurality of processing apparatuses according to the present invention is connected between the main processing apparatus 100 and the sub-processing apparatus 150.

As described above, the main processing apparatus 100 transmits a control signal including a state control signal capable of controlling the state of the sub processing apparatus 150 to the sub processing apparatus 150.

As described above, the sub-processing unit 150 receives a state control signal or a separate state control signal from the main processing unit 100 to change the state, and also states in a system having a plurality of processing units according to the present invention. The state may be changed through a state change command from the control device 200.

Examples of the main processing unit 100 and the sub-processing unit 150 may be processing units in charge of the aforementioned mobile communication function and processing units in charge of RFID or image processing.

The state control apparatus 200 in a system having a plurality of processing apparatuses according to the present invention is disposed between the main processing apparatus 100 and the sub-processing apparatus 150 to interpret the state control signals and generate state control commands. And perform the transfer.

Detailed description of the state control apparatus 200 in a system having a plurality of processing apparatuses according to the present invention is as follows.

The control signal processing unit 210 receives a control signal from the main processing apparatus 100.

In this case, the control signal processor 210 may receive a control signal from the main processing apparatus 100 through the serial communication interface.

That is, the control signal can be received through the serial communication interface such as RS-232, I2C or SPI described above.

The control signal processing unit 210 may be configured to receive a control signal from the main processing unit 100 regardless of the state of the sub processing unit 150, but the control signal processing unit 210 may also be configured to receive the sub processing unit 150. The control signal may be configured to receive the control signal from the main processing apparatus 100 or to transmit the control signal to the sub processing apparatus 150 according to the state of.

In other words, when the sub-processing unit 150 is in a normal operating state, the control signal processing unit 210 does not receive the control signal and relays the signal directly to the sub-processing unit 150 to transmit the control signal to the corresponding control signal. Response can be made.

However, when the sub-processing unit 150 is in the power-down state, since the sub-processing unit 150 cannot analyze the control signal, the control signal processing unit 210 receives the control signal, and the received control signal is subsequently The state change command generation unit 230 is transmitted for analysis.

In addition, in such a configuration, the control signal processor 210 may receive a control signal indicating the state of the subprocessing device 150 from the subprocessing device 150.

That is, when the sub-processing device 150 is changed to the power-down state, the sub-processing device 150 can no longer process the control signal. Therefore, in this case, the control signal processor 210 may receive a control signal indicating that the power down state is transmitted from the sub-processing device 150.

When receiving the control signal, the control signal processor 210 may directly receive the control signal from the main processing apparatus 100 without transmitting the control signal to the sub processing apparatus 150.

The control signal processor 210 may be configured by, for example, a signal wire including a switch. Therefore, operation is possible while minimizing power consumption.

The state change command generation unit 230 analyzes a control signal from the main processing unit 100 received by the control signal processing unit 210, and when the control signal is a state control signal of the sub processing unit 150, the sub processing unit ( Generate a state change command for the command 150).

The state control signal is, for example, a signal that wakes up the sub-processing unit 150 in the idle state or the power-down state or changes the sub-processing unit 150 in the normal state to the idle or power-down state. May be a signal.

In the conventional case, the state control signal transmitted from the main processing unit 100 to the subprocessing unit 150 is, for example, the subprocessing unit 150 in the normal state in the idle state or the subprocessing unit 150 in the idle state in the normal state. Only state control signals that change to state are possible.

That is, when the sub-processing device 150 is in the power-down state, the control signal from the main processing device 100 cannot be interpreted, and therefore, the wake-up operation cannot be performed.

However, when the state control apparatus 200 is provided in a system having a plurality of processing apparatuses according to the present invention, even when the sub-processing apparatus 150 is in a power-down state, the control of the control signal may be performed in the state control apparatus 200. Since it can be performed, it is possible to change the subprocessing apparatus 150 to the power-down state.

When the sub-processing apparatus 150 is changed and maintained in the power-down state, power consumption can be reduced than when the sub-processing device 150 is maintained in the idle state.

In addition, although the state control apparatus 200 in the system having a plurality of processing apparatuses according to the present invention performs the operation for the interpretation of the control signal according to the operation for the analysis of the control signal in the state control apparatus 200 The power consumption is much smaller than the case of performing the analysis of the control signal while keeping the sub-processing unit 150 in an idle state.

In addition, in the conventional case, even when the subprocessing unit 150 is maintained in the idle state, when the control signal is received from the main processing unit 150, a wake-up, that is, a normal state is changed to perform the control signal analysis. In this case, even when the control signal is not the state control signal, such control signal analysis is performed, so that the state of the sub-processing device 150 is changed and power consumption is generated accordingly.

However, in the state control apparatus 200 in a system having a plurality of processing apparatuses according to the present invention, the sub-processing apparatus 150 maintains the power-down state and interprets the control signal when it receives the control signal. Only when the state control signal changes the state of the processing unit 150 to a wake-up state, that is, a normal state, a command indicating a state change of the sub-processing unit 150 is generated and transmitted to the sub-processing unit 150 to transmit the command. Change the state of 150 to the normal state.

The state change command indicating the change to the normal state may be, for example, a reset command for resetting the subprocessing device 150.

Therefore, the state change of the unnecessary sub-processing unit 150 can be minimized and power consumption can be reduced.

In addition, as described above, when the sub-processing unit 150 is in the normal operation state, the control signal processing unit 210 does not receive the control signal and directly transmits the sub-processing unit 150 to the corresponding control signal from the sub-processing unit 150. In this case, the control signal processor 210 may receive a control signal and transmit the control signal to the state change command generator 230.

In this case, the control signal may be a state control signal for changing the subprocessing apparatus 150 to a power down or idle state.

The state change command generation unit 230 may generate a power down command for the subprocessing device 150 in response to the state control signal.

That is, in the conventional case, the state control signal transmitted from the main processing apparatus 100 transmits the state control signal to change to the idle state rather than the power down.

Changing to the power-down state requires a direct communication interface separate from the serial communication interface, and since the operation for the bottom of the operating system is required, most main processing apparatuses 100 have a disadvantage in that the realistic support is difficult.

Therefore, in most cases, it is assumed that the state control signal for the sub-processing unit 150 in the normal state is changed to the idle state, but also in the case of power down.

In this case, the state change command generation unit 230 may be configured to generate a power down command for the sub-processing unit 150 in response to both the power down or the idle in response to the state control signal.

That is, in the conventional case, when the sub-processing apparatus 150 is powered down, the control signal analysis is no longer performed, and thus, the control signal may be changed only to the idle state. In the present invention, the control signal may be analyzed through the state control device 200. Therefore, the power down command is generated for the sub-processing device 150 in response to both power down or idle.

The state change command transmitter 250 transmits the state change command generated by the state change command generator 230 to the subprocessing apparatus 150.

The state change command transmitter 250 may transmit the state change command to the subprocessing unit 150 through, for example, a serial communication interface. Such a serial communication interface can be, for example, any one of RS-232, I2C or SPI or similar serial communication interface.

Alternatively, the state change command transmitter 250 may be configured to transmit a state change command directly to a state change dedicated pin of the subprocessing apparatus 150, particularly when the state change command is a reset command.

In addition, the state control apparatus 200 in a system having a plurality of processing apparatuses according to the present invention may determine whether to operate according to the operating state of the sub-processing apparatus 150, for example.

That is, when the sub-processing unit 150 is in the normal state, the operation may be stopped, and when the sub-processing unit 150 is in the power-down state, the state control of the sub-processing unit 150 may be performed.

Such a configuration particularly stops the power supply of the state control apparatus 200 when the subprocessing apparatus 150 operates in the normal state when the conventional subprocessing apparatus 150 having the control signal analysis function is used. Instead, unnecessary power consumption may be further reduced by configuring the state control apparatus 200 to perform an operation only when the sub-processing apparatus 150 is changed to the power-down state.

However, in the case of using the sub-processing device 150 that does not have a control signal analysis function, the state control device 200 should be configured to always supply power to analyze the control signal.

When the operation of the sub-processing unit 150 is not necessary through the state control apparatus in the system having a plurality of processing apparatuses according to the present invention with reference to FIG. 1, the sub-processing unit 150 is completely powered down. By changing to a state, unnecessary power consumption can be reduced.

2 is an exemplary flowchart of a state control method in a system having a plurality of processing apparatuses according to the present invention.

A state control method in a system having a plurality of processing apparatuses according to the present invention is implemented in the state control apparatus 200 connected between the main processing apparatus 100 and the sub-processing apparatus 150 shown in FIG. 1. Assume that

First, a control signal from the main processing apparatus is received (S110).

Receipt of the control signal may be performed via, for example, any one of RS-232, I2C or SPI or similar serial communication interface.

In this case, the control signal may be directly transmitted to the sub-processing device when the sub-processing device is in the normal operating state, and the control signal may be received when the sub-processing device is in the power-down state. In the case where the control signal is directly transmitted or received according to the state of the sub-processing device, preferably, a control signal indicating the power-down state is received from the sub-processing device before the sub-processing device is changed to the power-down state, and The control signal can be received or transmitted on the basis.

Thereafter, the control signal received in step S110 is analyzed to generate a state change command for the sub-processing device when the control signal is a state control signal of the sub-processing device (S120).

In this case, the control signal may be, for example, a signal for waking up the sub-processing device or a state control signal for changing to a power down or idle state.

When the subprocessing device wakes up, a state change command for performing a reset on the subprocessing device may be generated.

When the subprocessing device is changed to a power down or idle state, a state change command for performing a power down on the subprocessing device may be generated.

In other words, the state control method in a system having a plurality of processing apparatuses according to the present invention minimizes power consumption by controlling the power-down state when the operation of the sub-processing apparatus is not required. In the case of a state change, a state change command may be generated to perform a change to a power down state for all.

Thereafter, the state change command generated in step S120 is transmitted to the subprocessing apparatus (S130).

The transmission of such a state change command may be performed via, for example, any one of RS-232, I2C or SPI or similar serial communication interface.

Alternatively, a state change command can be directly sent to the state change pin of the subprocessing device. That is, when the subprocessing apparatus is provided with a state change dedicated pin for resetting, the state change command such as a reset command can be directly transmitted to the pin.

Although not shown, the method may further include checking whether the sub-processing device is in the power-down state before step S110.

That is, the configuration can be performed to minimize power consumption by performing state control only when the sub processing unit is in the power down state.

When the operation of the sub-processing apparatus is not necessary through the state control method in the system having a plurality of processing apparatuses according to the present invention with reference to FIG. 2, the sub-processing apparatus is completely changed to a power-down state, thereby unnecessary power supply. Reduce consumption

The present invention also provides a computer-readable recording medium having recorded thereon a program for realizing each step of a state control method in a system having a plurality of processing apparatuses according to the present invention described above.

A computer readable recording medium refers to any kind of recording device that stores data, that is, data in code or program form, so that it can be read by a computer system. Such computer-readable recording media include, for example, memories such as ROM and RAM, storage media such as CD-ROM and DVD-ROM, magnetic storage media such as magnetic tape and floppy disk, optical data storage devices, and the like. It also includes a case where it is implemented in the form of transmission via. Such computer readable recording media can also be distributed over network coupled computer systems so that the computer readable data is stored and executed in a distributed fashion.

However, a detailed description of such a computer-readable recording medium is omitted because it overlaps with the state control method in the system having a plurality of processing apparatuses according to the present invention described with reference to FIG.

Although the configuration of the present invention has been described in detail, these are merely illustrative of the present invention, and various modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. This will be possible.

Therefore, the embodiments disclosed herein are not intended to limit the present invention but to describe the present invention, and the spirit and scope of the present invention are not limited by these embodiments. It is intended that the scope of the invention be interpreted by the following claims, and that all descriptions within the scope equivalent thereto will be construed as being included in the scope of the present invention.

As described above, according to the present invention, the state of the subprocessing device is only in the case of a state control signal that receives a control signal from the main processing device and interprets the control signal from the main processing device in a system having a plurality of processing devices. Can be changed to normal to minimize power consumption of the system.

Claims (22)

A state control apparatus in a system including a main processing unit and a sub processing unit, A control signal processor that receives a control signal from the main processor; A state change command generation unit for interpreting the control signal and generating a state change command for the sub-processing device when the control signal is a state control signal of the sub-processing device; A state change command transmitter for transmitting the state change command to the sub-processing device State control apparatus in a system having a plurality of processing apparatus comprising a. The method of claim 1, And the control signal processing unit receives the control signal from the main processing unit via a serial communication interface. The method of claim 1, wherein the control signal processing unit, Transmitting the control signal to the sub-processing device when the sub-processing device is in a normal operation state, and transmitting the control signal to the state change command generation unit when the sub-processing device is in a power-down state. The state control device in the system provided. The method of claim 3, wherein the control signal processing unit, And a control signal indicative of the power down state from the sub-processing device before the sub-processing device is changed to the power-down state. The method of claim 1, The sub-processing unit is in a power-down state, The control signal is the state control signal to wake up the sub-processing device, And said state change command is a reset command for said sub-processing device. The method of claim 1, The sub-processing apparatus is in a normal state, The control signal is the state control signal for changing the sub-processing device to a power down or idle state, And the state change command is a power down command to the sub-processing device. The method of claim 1, wherein the state change command transmission unit, And a plurality of processing devices for transmitting the state change command to the sub-processing device via a serial communication interface. The method of claim 1, wherein the state change command transmission unit, And a state processor for transmitting the state change command to a state change dedicated pin of the sub processor. The method of claim 1, The state control device is provided with a plurality of processing devices that stop operation when the sub-processing device is in a normal state and perform the state control on the sub-processing device when the sub-processing device is in a power down state. State control device in The method according to claim 2 or 7, And wherein said serial communication interface is any one of RS-232, I2C, or SPI. As a state control method in a system including a main processing unit and a sub processing unit, (a) receiving a control signal from the main processing apparatus, (b) interpreting the control signal to generate a state change command for the sub-processing device if the control signal is a state control signal of the sub-processing device; (c) transmitting the state change command to the sub-processing device. State control method in a system having a plurality of processing apparatus comprising a. The method of claim 11, The step (a) may include: (a-1) receiving the control signal from the main processing apparatus via a serial communication interface A state control method in a system having a plurality of processing apparatus comprising a. The method of claim 11, wherein step (a) comprises: (a-2) transmitting the control signal to the sub-processing device when the sub-processing device is in a normal operating state and receiving the control signal when the sub-processing device is in a power-down state; A state control method in a system having a plurality of processing apparatus comprising a. The method of claim 13, wherein step (a) comprises: (a-3) receiving a control signal indicating the power down state from the sub processing apparatus before the sub processing apparatus is changed to the power down state A state control method in a system having a plurality of processing apparatus comprising a. The method of claim 11, The sub-processing unit is in a power-down state, The control signal is the state control signal to wake up the sub-processing device, In step (b), (b-1) generating the state change command to perform a reset for the sub-processing device. A state control method in a system having a plurality of processing apparatus comprising a. The method of claim 11, The sub-processing apparatus is in a normal state, The control signal is the state control signal for changing the sub-processing device to a power down or idle state, In step (b), (b-2) generating a state change command for performing power down on the sub-processing device. A state control method in a system having a plurality of processing apparatus comprising a. The method of claim 11, wherein step (c) comprises: (c-1) transmitting the state change command to the sub processing apparatus through a serial communication interface; A state control method in a system having a plurality of processing apparatus comprising a. The method of claim 11, wherein step (c) comprises: (c-2) transmitting the state change command to a state change dedicated pin of the subprocessing device; A state control method in a system having a plurality of processing apparatus comprising a. The method of claim 12, And said serial communication interface is any one of RS-232, I2C or SPI. The method of claim 17, And said serial communication interface is any one of RS-232, I2C or SPI. The method of claim 11, wherein, prior to step (a), (d) confirming that the subprocessing unit is in a power down state The state control method in a system having a plurality of processing apparatus further comprising. A computer-readable recording medium having recorded thereon a program for realizing each step of a state control method in a system having a plurality of processing apparatuses according to any one of claims 11 to 21.

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