KR100563324B1 - Power saving mode cancle method of most network - Google Patents

Abstract

The present invention relates to a last network, and more particularly, to a method of canceling a power saving mode of a most network for canceling entry of a power saving mode of a most network. The present invention adds a retry count limit and entry cancellation function in the existing power saving mode entry procedure. Accordingly, the present invention is characterized in that when the devices on the most network enter the power saving mode, the power saving mode entry cancellation according to the limit of the number of retries of the power master and the power saving mode entry cancellation by the device request are performed.

Most network, power mode, cancel,

Description

Power saving mode cancle method of most network

1 is a last network according to the prior art;

2 is an operation control flow diagram for entering the power saving mode of the most network according to the prior art.

3 is an embodiment of an operation control flowchart for canceling entry of a power saving mode of a most network according to the present invention;

Figure 4 is another embodiment of the operation control flow diagram for canceling the power saving mode entry of the most network in accordance with the present invention.

            Explanation of symbols on the main parts of the drawings

50: Most Network 100: Powermaster

110 ~ 130: Power Slave

The present invention relates to a most network, and more particularly to a method of canceling a most network power saving mode for canceling the most network enters the power mode.

Most network technology is a vehicle multimedia ring network technology in Europe. It supports a bandwidth of 25 Mbps and transmits and receives data through an optical cable between devices in the vehicle.

Hereinafter, a method of canceling a power network and a power saving mode of a most network according to the prior art will be described.

1 is a last network according to the prior art.

The conventional most network 50 is comprised by the power master 100 and many power slaves. The power master 100 is a device that is in charge of power management on the most network 50 and leads the entry into the power saving mode. The power slaves 110, 120, and 130 are devices on the most network 50 and have a power management function under the control of the power master 100.

The 'power saving mode' refers to a state in which devices on a network enter a minimum power consumption mode while maintaining a minimum function or a waking function, wherein the devices on the network do not emit light output.

The power saving mode entry request message is a message for inquiring whether the power master 100 may enter the power saving mode from the power slaves. The power slaves 110 that have received the power saving mode entry request message have received the power saving mode entry request message. 120 and 130 enter the power saving mode entry standby mode and cannot perform other general operations.

The power saving mode execution message is a message in which the power master 100 instructs the power slaves 110, 120, and 130 to enter the power saving mode.

The "power saving mode delay message" is a message that the power slave requests the power master 100 to delay entering the power saving mode for a specified time.

Looking at the operation of the control configuration as follows.

2 is an operation control flow chart for entering the power saving mode of the most network according to the prior art.

In order to control the power master 100 and each of the power slaves 110, 120, and 130 to be switched to the power saving mode on the most network 50, the power master 100 sends a message requesting the entry of the power saving mode. Output to the power slave (step 200). That is, when the power saving mode entry request message is output from the optical output terminal of the power master 100, the power saving mode entry request message is input to the optical input terminal of the first power slave 110. At the same time, the power master 100 waits for the response of the first power slave 110. At this time, the time for waiting for a response is made for a preset time.

After step 200, the state of the power slave is checked (step 210) to determine whether to enter the power slave power saving mode, and to determine whether to enter the power saving mode according to the determined result.

That is, in step 210, when the state of the first power slave 110 is in the standby state ready to enter the power saving mode (step 220), the first power slave 110 is the power master 100 Rather than responding to the message, it performs only the tasks necessary to be controlled in power saving mode.

On the other hand, if it is determined in step 210 that the first power slave 110 cannot enter the power saving mode, the first power slave 110 transmits a 'power saving mode entry delay message' to the power master 100. (Step 270).

As a result of step 220 and step 270, the power master 100 determines whether a 'power saving mode delay message' has been received from the first power slave 110 (step 230).

In step 230, when the power master 100 receives the 'power saving mode delay message' from the first power slave 110, the first power slave 110 returns to step 200 while maintaining a standby state.

In a situation where the power saving mode should not be entered, the power saving mode delay message is outputted from the power slave, so that the steps 200 to 230 are repeatedly performed repeatedly. As a result, the state of the most network is stopped.

On the other hand, if the power master 100 has not received the 'power saving mode delay message' from the first power slave 110 as a result of the determination in step 230, the power master 100 receives the 'power saving mode execution message'. Output to the first power slave 110 (240).

Accordingly, the first, second, and third power slaves 110, 120, and 130 sequentially enter the power saving mode (250). That is, the first power slave 110 receiving the 'power saving mode execution message' of the power master 100 through the optical input terminal determines the corresponding message and then receives the optical input terminal of the second power slave 120 through the optical output terminal. Will print The first power slave 110 is switched to the power saving mode. Meanwhile, the second power slave 120 recognizes the 'power saving mode execution message' input through the optical input terminal, and outputs the corresponding signal to the optical input terminal of the third power slave 130 through the optical output terminal. The second power slave 120 is switched to the power saving mode. Meanwhile, the third power slave 130 recognizes the 'power saving mode execution message' input through the optical input terminal, and outputs the corresponding signal to the optical input terminal of the power master 100 through the optical output terminal. The third power slave 130 is switched to the power saving mode. The power master 100 also switches to the power saving mode (step 260).

In this manner, after all the power slaves on the most network 50 enter the power saving mode, the power network 100 also enters the power saving mode, and the most network 50 is in the power saving mode.

If the power slave cannot enter the power saving mode by any condition in the flow, it requests the power master to postpone the power saving mode. At this time, after receiving the power saving mode delay message, the power master waits for a predetermined time and then attempts to enter the power saving mode while outputting a message requesting entry into the power saving mode again.

However, such a prior art may continuously retry when the power saving mode should not be entered as mentioned above, resulting in a problem that the network is stopped. There was also no way to specify how devices would cancel the request to enter power saving mode.

Accordingly, an object of the present invention is to provide a method of canceling a power saving mode of a most network for canceling a time point when the most network enters the power saving mode.

Another object of the present invention is to provide a method of canceling a last network power saving mode which limits the number of retries in an entry procedure due to power saving.

According to an aspect of the present invention, there is provided a method for canceling a power saving mode of a most network, comprising: a power master having a light input / output stage and controlling power management; In a most network including a plurality of power slaves having a light input and output stage, and limiting the light input and output according to the power control signal of the power master: A power master outputs a power saving mode entry request signal to the power slave A first step; A second step of determining whether to enter the power saving mode according to the signal output by the first step; A third step of receiving, from the second step, the power master by receiving a status signal of the power slave, and determining whether to cancel the power saving mode according to the received signal; According to the third step, a fourth step of controlling to cancel the power saving mode in the most network consisting of the power master and the power slave.

In the second step, a standby step in which the power slave waits to prepare for entry into a power saving mode; If the power slave is not in the power saving mode entry state, the power saving mode is configured to further include a request for requesting a postponement.

The third step may further include a counting step of counting the number of power saving mode delay requests transmitted from the power slave when the signal received by the power master is a power saving mode delay request signal.

If the number of power saving mode delay requests in the counting step is more than a predetermined number, the power master further includes a cancellation request step for requesting cancellation of the power saving mode.

If the power slave is in a standby state, the power master outputs a signal for executing a power saving mode; By the signal, the most network is configured to further control the power saving mode.

According to an aspect of the present invention, there is provided a method for canceling a power saving mode of a most network, comprising: a power master having a light input / output stage and controlling power management; In a most network comprising a plurality of power slaves having a light input and output stage, and limiting the light input and output according to the power control signal of the power master: the power master outputs a power saving mode request signal to the power slave Steps; A determination step of receiving a request signal of the output step and determining a state of a power slave; In the first determination step, the power slave comprises: a state output step of outputting a corresponding state to the power master; In the state output step, if the power slave requests to cancel the power saving mode, it comprises a first control step of controlling to cancel the power saving mode.

In the state output state, if the power slave waits in the power saving mode, the power master requests a request to execute the power saving mode; The requesting step further includes a second control step in which the most network is controlled in a power saving mode.

The most recent network 50 of the present invention is composed of a power master 100 and a plurality of power slaves. The power master 100 is a device that is in charge of power management on the most network 50 and leads the entry into the power saving mode. The power slave is present on the most network 50 and has a power management function.

The 'power saving mode' refers to a state in which devices on a network enter a minimum power consumption mode while maintaining a minimum function or a waking function, wherein the devices on the network do not emit light output.

The power saving mode entry request message is a message for inquiring whether the power master 100 may enter the power saving mode from the power slaves 110, 120, and 130, and the power slave receiving the power saving mode inquiry message. The fields 110, 120, and 130 enter the power saving mode entry standby mode and do not perform other general operations.

The power saving mode execution message is a message in which the power master 100 instructs the power slaves 110, 120, and 130 to enter the power saving mode.

The "power saving mode delay message" is a message that the power slave requests the power master 100 to delay entering the power saving mode for a specified time.

The power saving mode entry cancellation request message is a message requesting the power master 100 to cancel entering the power saving mode when it is impossible to enter the power saving mode due to the situation of the power slaves 110, 120, and 130.

The power saving mode entry cancel message is a message for the power master 100 to minimize the waiting for entry to the power slaves waiting to enter the power saving mode on the network at the request of the power slave and return to the normal operation state.

Hereinafter, an operation control process for canceling a power mode of a most network according to the present invention will be described with reference to the control configuration of FIG. 1.

3 is an embodiment of an operation control flowchart for canceling a power mode of a most network according to the present invention.

In order to allow the power master 100 and the power slaves configured on the most network 50 to enter the power saving mode, the power master 100 outputs a 'power saving mode entry request message' through the optical output terminal ( Step 300). Then, the power master 100 waits for a predetermined time (predetermined time is set in advance by specifying a suitable time) from the output time. The power saving mode entry request message output through the optical output terminal of the power master 100 is input to the optical input terminal of the first power slave 110. The first power slave 110 determines whether to enter the power saving mode according to the input 'power saving mode entry request message' (step 310).

In step 310, when it is determined that the first power slave 110 is ready to enter the power saving mode, the first power slave 110 does not respond to the message of the power master 100, and enters the power saving mode. Only operations necessary to be controlled are performed (step 320).

On the other hand, if it is determined in step 310 that the first power slave 110 cannot enter the power saving mode, the first power slave 110 transmits a 'power saving mode delay message' to the power master 100. (Step 330).

As a result of steps 320 and 330, the power master 100 determines whether a 'power saving mode delay message' has been received from the first power slave 110 (step 340).

In step 340, when the power master 100 receives the 'power saving mode delay message' from the first power slave 110, the first power slave 110 maintains its standby state, and thus, steps 300 to 340. Repeat. At this time, the number of retries is less than the specified number of times (step 350). At this time, the number of retries and the number of designations are set in advance. The value to be set may vary as needed.

However, in step 350, if the number of retries from step 300 to step 340 exceeds the specified number of times, the power master 100 outputs a 'power saving mode entry cancellation message' (step 390). The power saving mode entry cancellation message of the power master 100 is input to the optical input terminal of the first power slave 110 through the optical output terminal. Accordingly, the first power slave 110 confirms that entering of the power saving mode has been canceled (step 395). All devices on the network then wake up and perform normal operations.

Meanwhile, in step 340, if the power master 100 does not receive a 'power saving mode delay message' from the first power slave 110, the power master 100 receives a 'power saving mode execution message' as the first power. Output to the slave 110 (360).

Accordingly, the first, second and third power slaves sequentially enter the power saving mode (step 370). That is, the first power slave 110 receiving the 'power saving mode execution message' of the power master 100 through the optical input terminal determines the corresponding message and then receives the optical input terminal of the second power slave 120 through the optical output terminal. Will print The first power slave 110 is switched to the power saving mode. At the same time, the optical input terminal and the optical output terminal of the first power slave 110 cannot transmit or receive optical signals. Meanwhile, the second power slave 120 recognizes the 'power saving mode execution message' input through the optical input terminal, and outputs the corresponding signal to the optical input terminal of the third power slave 130 through the optical output terminal. The second power slave 120 is switched to the power saving mode. At the same time, the optical input terminal and the optical output terminal of the second power slave 120 cannot transmit or receive optical signals. Meanwhile, the 'power saving mode execution message' outputted through the second power slave 120 is input through the optical input terminal of the third power slave 130, and the third power slave 130 that recognizes the corresponding signal is optical. Through the output terminal transmits a 'power saving mode execution message' to the optical input terminal of the power master (100). In addition, the third power slave 130 is switched to the power saving mode and at the same time, the optical input / output terminal of the third power slave 130 cannot transmit or receive the optical signal. The power master 100 is also switched to a power saving mode (step 380).

4 is another embodiment of an operation control flowchart for canceling a power mode of a most network according to the present invention.

In order to allow the power master 100 and the power slaves configured on the most network to enter the power saving mode, the power master 100 outputs a 'power saving mode entry request message' through the optical output terminal (step 400). ). Then, the power master 100 waits for a predetermined time (predetermined time is set in advance by specifying a suitable time) from the output time. The power saving mode entry request message output through the optical output terminal of the power master 100 is input to the optical input terminal of the first power slave 110. The first power slave 110 determines whether to enter the power saving mode according to the input 'power saving mode entry request message' (step 410).

In step 410, if it is determined that the first power slave 110 is ready to enter the power saving mode (step 420), the first power slave 110 does not respond to the message of the power master 100. In this case, only the tasks necessary to be controlled by the power saving mode are performed.

On the other hand, if it is determined in step 410 that the first power slave 110 cannot enter the power saving mode, the first power slave 110 sends a 'power saving mode entry cancellation request message' to the power master 100. In step 430, the process is transmitted.

As a result of steps 420 and 430, the power master 100 determines whether a 'power saving mode entry cancellation request message' has been received from the first power slave 110 (step 440).

In step 440, when the power master 100 receives the 'power saving mode entry cancellation request message' from the first power slave 110, the power master 100 outputs a 'power saving mode entry cancellation message' ( Step 480). The power saving mode entry cancellation message of the power master 100 is input to the optical input terminal of the first power slave 110 through the optical output terminal. Accordingly, the first power slave 110 confirms that the entry of the power saving mode has been canceled (step 490). And all the devices on the network get out of standby and perform normal operations.

On the other hand, in step 440, if the power master 100 does not receive the 'power saving mode entry cancellation request message' from the first power slave 110, the power master 100 is the 'power saving mode execution message' 1 outputs to the power slave 110 (step 450).

Accordingly, the first, second and third power slaves sequentially enter the power saving mode (step 460). That is, the first power slave 110 receiving the 'power saving mode execution message' of the power master 100 through the optical input terminal determines the corresponding message and then receives the optical input terminal of the second power slave 120 through the optical output terminal. Will print The first power slave 110 is switched to the power saving mode. At the same time, the optical input terminal and the optical output terminal of the first power slave 110 cannot transmit or receive optical signals. Meanwhile, the second power slave 120 recognizes the 'power saving mode execution message' input through the optical input terminal, and outputs the corresponding signal to the optical input terminal of the third power slave 130 through the optical output terminal. The second power slave 120 is switched to the power saving mode. At the same time, the optical input terminal and the optical output terminal of the second power slave 120 cannot transmit or receive optical signals. Meanwhile, the 'power saving mode execution message' outputted through the second power slave 120 is input through the optical input terminal of the third power slave 130, and the third power slave 130 that recognizes the corresponding signal is optical. Through the output terminal transmits a 'power saving mode execution message' to the optical input terminal of the power master (100). In addition, the third power slave 130 is switched to the power saving mode and at the same time, the optical input / output terminal of the third power slave 130 cannot transmit or receive the optical signal. The power master 100 is also switched to a power saving mode (step 470).

As described above, the present invention has a basic technical concept of selectively canceling the power saving mode or limiting the number of retries in the entry procedure of the power saving mode.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

Therefore, the following effects can be expected due to the power mode cancellation method of the most network according to the present invention.

Currently, the procedure for entering into the power saving mode according to the most network specification has not been prepared for the situation where entry is impossible. Therefore, if the procedure for canceling the power saving mode entry cancellation according to the present invention is applied, it is possible to prevent the network stop situation caused by infinite retry to enter the power saving mode, and to flexibly cope with the power saving mode as necessary. Allow to selectively cancel the entry of.

Claims (7)

A power master having a light input / output stage and controlling power management; In a most network comprising a plurality of power slaves having a light input and output stage, and limiting the light input and output according to the power control signal of the power master: A first step of the power master outputting a power saving mode entry request signal to the power slave; A second step of determining whether to enter the power saving mode according to the signal output by the first step; A third step of receiving, from the second step, the power master by receiving a status signal of the power slave, and determining whether to cancel the power saving mode according to the received signal; And a fourth step of controlling the power saving mode to be canceled in the most network composed of the power master and the power slave according to the third step. The method of claim 1, In the second step, A standby step in which the power slave waits for preparation for entering the power saving mode; If the power slave is not in the power saving mode entry state, further comprising a request for delaying the power saving mode delay is configured to cancel the most network power saving mode. The method of claim 1, The third step, If the signal received by the power master is the power saving mode delay request signal, And a counting step of counting the number of power saving mode delay requests transmitted from the power slaves. The method of claim 3, wherein And canceling the power saving mode delay request of the counting step, the power master further comprising a cancel request step of requesting cancellation of the power saving mode. The method of claim 2, If the power slave is in standby state, The power master outputs a signal for executing a power saving mode; And canceling, by the signal, the most network in a power saving mode. A power master having a light input / output stage and controlling power management; In a most network comprising a plurality of power slaves having a light input and output stage, and limiting the light input and output according to the power control signal of the power master: The power master outputs a power saving mode request signal to a power slave; A determination step of receiving a request signal of the output step and determining a state of a power slave; In the first determination step, the power slave comprises: a state output step of outputting a corresponding state to the power master; And a first control step of controlling the power saving mode to be canceled when the power slave requests the power saving mode cancellation in the state output step. The method of claim 6, In the state output state, if the power slave waits in the power saving mode, the power master requests a request to execute the power saving mode; And, by the requesting step, further comprising a second control step in which the most network is controlled in a power saving mode.

Images