KR100705442B1 - Sleep Mode Method and Mobile Station Using Thereof - Google Patents

Abstract

The present invention relates to a mobile communication terminal using a sleep mode method and a sleep mode method.

According to the present invention, by generating a final sleep window component used to determine the sleep interval period according to the battery power state of the mobile communication terminal, sending the final sleep window component to the base station, and receives sleep window data from the base station The duration of the sleep interval can be adjusted to reduce battery power consumption.

Mobile communication terminal, sleep mode, battery, sleep interval, listening interval

Description

Sleep mode method and mobile station using thereof

1 is a diagram illustrating a sleep mode operation of a mobile communication terminal according to the prior art.

2 is a schematic diagram of a mobile communication service system according to an embodiment of the present invention.

3 is a flowchart illustrating a sleep mode setting process when receiving packet data according to an embodiment of the present invention.

4 is a diagram illustrating an example of a sleep mode operation of a mobile communication terminal according to an embodiment of the present invention.

5 is a diagram illustrating an example of setting a sleep mode of a mobile communication terminal according to an embodiment of the present invention.

The present invention relates to a mobile communication terminal using a sleep mode method and a sleep mode method.

Recently, with the development of mobile communication technology, not only voice calls but also data communication are available through mobile communication terminals. In general, data communication divides data into a certain size, packetizes, and transmits and receives.

Traffic for packet transmission and reception in the mobile communication terminal is not generated continuously for a long time but is concentrated for a short period due to the characteristics of packet traffic.

At this time, since the mobile communication terminal that transmits and receives the data always monitors the radio channel receiving the packet data, it consumes a lot of battery power of the mobile communication terminal. It is good to watch. However, it is theoretically impossible to predict the arrival of packet data to the mobile communication terminal in advance, and a method of periodically monitoring the radio channel has been used in a suboptimal manner. Preferably, when the packet data arrives frequently to the mobile terminal, the mobile terminal frequently monitors the radio channel. On the contrary, when the packet data does not arrive to the mobile terminal frequently, the wireless channel is occasionally monitored. .

The mobile communication terminal uses the following sleep mode for efficient use of battery power. The sleep mode is configured by alternately repeating a sleep interval, which is a section in which a mobile communication terminal monitors a wireless channel, and a sleep interval, which is a section in which a wireless channel is not monitored. The mobile communication terminal operates in a low power state during the sleep interval, and packet data transmission and reception are impossible. Then, the packet data arriving at the base station in the sleep interval period is buffered.

The packet data reception operation in the sleep mode of the mobile communication terminal will be described in detail with reference to FIG. Referring to FIG. 1, when the packet data arrives at the listening interval and the base station at the first time point 10, the packet data is not immediately transmitted to the mobile communication terminal, but is buffered and stored in the base station. The mobile terminal wakes up at a second time point 20 in a listening interval state and transitions to a state capable of receiving a message transmitted from the base station, and the base station includes the address of the mobile communication terminal to the mobile communication terminal. Send a traffic arrival message.

When the traffic arrival message includes its own terminal address, the mobile communication terminal stays in a state where it can continue to receive the message without transitioning to the sleep interval at the third time point 30 when the listening interval state ends. Receive packet data buffered at the base station. Here, if the terminal does not include the terminal address in the traffic arrival message, the terminal transitions to a sleep interval in which the power saving state cannot receive the packet data again.

In this way, the packet data is received by the mobile communication terminal at the fourth time 40. Here, the packet data arrives at the base station at the first time 10, but the time at which the packet data actually arrives at the mobile communication terminal is the fourth time 40, from the first time 10 to the fourth time (40). Is the packet arrival delay time.

As described above, when the sleep interval period is short, battery power of the mobile communication terminal is consumed a lot, and when the sleep interval period is long, battery power of the mobile communication terminal is consumed less.

 SUMMARY OF THE INVENTION The present invention has been made in an effort to provide a mobile communication terminal using a sleep mode method and a sleep mode method for reducing battery power consumption by adjusting a period of a sleep interval according to a battery power state of a mobile communication terminal.

In the sleep mode method of a mobile communication terminal according to a feature of the present invention for achieving the above object, in the sleep mode method comprising a sleep interval and a listening interval of the mobile communication terminal for transmitting and receiving packet data,

a) measuring a state of battery power; And

b) operating a sleep mode by adjusting at least one of the length of the sleep interval and the length of the listening interval according to the measured state of battery power.

Mobile communication terminal according to another feature of the present invention,

A battery check unit checking a battery power state;

A data generator generating data on the battery power state; And

And a sleep mode setting unit configured to transmit data on the generated power state to a base station, and set a sleep interval period and a listening interval period allowed by the base station.

Mobile communication terminal according to another feature of the present invention,

A battery check unit checking a battery power state;

A data generator configured to generate a final sleep interval length determined according to the battery power state; And

And a sleep mode setting unit configured to transmit the final sleep interval length to a base station, and set a sleep interval period and a listening interval period allowed by the base station.

DETAILED DESCRIPTION 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. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention.

First, a mobile communication system according to an embodiment of the present invention will be described in detail with reference to FIG. 2.

As shown in FIG. 2, the mobile communication system according to the embodiment of the present invention includes a home agent 200, a packet access router 210, and a base station 220 for accessing the mobile communication terminal 100.

The home agent 200 is connected to the packet access router 210 through the internet network to perform a mobile IP service function. The mobile IP is a protocol that detects the movement of the mobile communication terminal 100 and enables communication after the movement in the same manner as before the movement. The mobile IP service function is different from the home network of the mobile communication terminal 100. This is a feature that allows you to use the Internet using your existing IP address. The server in communication with the mobile communication terminal 100 can also communicate by establishing a connection only with an existing IP address of the mobile communication terminal 100 without having to recognize where the mobile communication terminal 100 is located.

The packet access router 210 is connected to at least one base station 220 and the Internet network to perform packet access routing, mobile IP, handoff, and quality of service (QoS) control.

The base station 220 performs initial access, handoff, and QoS control functions of the mobile communication terminal 100. In addition, the base station 220 receives the packet data from the mobile communication terminal 100 and transmits the packet data to the packet access router 210 or, conversely, various packet data received from the packet access router 210 to the mobile communication terminal 100. Perform the function of passing. In addition, when the base station receives the sleep request message from the mobile communication terminal 100, the base station transmits a sleep response message to the mobile communication terminal 100 to determine the length of the sleep interval accordingly.

The mobile communication terminal 100 functions as a mobile internet terminal, performs a wireless channel transmission and reception function and a medium access control (MAC) protocol processing function according to a wireless access standard of the mobile internet, and accesses the packet data by accessing the base station 220. Send and receive.

The mobile communication terminal 100 periodically sends a sleep request message including information related to the sleep interval and the listening interval to the base station 220 to operate in the sleep mode. In this case, the sleep request message includes an initial sleep window, a final sleep window base, a final sleep window exponent, and a listening window data.

Upon receiving the sleep request message, the base station 220 transmits a sleep response message including information on a sleep interval and a listening interval to the mobile communication terminal 100 so that the mobile communication terminal 100 sleeps. Allows you to operate in mode.

Here, the listening window is data for setting a listening interval period, the initial sleep window is data for setting an initial sleep interval period, and the final sleep window base and final sleep window component values represent a last sleep interval period. This value is used to calculate the final sleep window value to be set.

The final slip window is calculated by Equation 1 below.

Final Sleep Window = Final Sleep Window Base × 2 ^{(Final Sleep Window Component)}

In this case, a value of the final sleep window component for determining the length of the sleep interval may be a real-time service, a non-real-time service, or a best-effort service. It may be determined to have different values according to the type of service included and the requested quality of service (QoS).

In this case, the sleep interval length or the listening interval length is operated in a window manner, and the characteristics of the corresponding window are determined according to the window component value.

The mobile communication terminal 100 according to an exemplary embodiment of the present invention includes a battery check unit 110, a data generator 120, and a sleep mode setting unit 130.

The battery check unit 110 checks the battery power state of the mobile communication terminal.

The data generator 120 generates a final sleep window component value of the sleep request message according to the battery power state checked by the battery checker 110.

The data generator 120 divides the remaining amount of battery power into a predetermined section and sets a final sleep window component value so that the length of the sleep interval is increased in inverse proportion to the remaining amount of the battery.

The sleep mode setting unit 130 includes the final sleep window component value generated by the data generator 120 in the sleep request message and sends the sleep request message to the base station 220, and the sleep window data or listening window is transmitted from the base station 220. A sleep response period including data is received to set a sleep interval period and a listening interval period.

When the battery is sufficiently charged, the mobile communication terminal 100 decreases the final sleep window component value and increases the final sleep window component value to the base station 220 as the battery is discharged. Accordingly, the sleep mode can be used to reduce battery consumption.

In the present embodiment, the base station 220 determines the length of the sleep interval or the length of the listening interval. Alternatively, the mobile communication terminal 100 may determine the length of the sleep interval or the listening interval.

In addition, although the mobile communication terminal 100 determines the window component value for setting the sleep interval period or the listening interval length according to the power state of the battery, in the present embodiment, the mobile communication terminal 100 is different. Transmits data about a battery power state to a base station and sets a sleep interval period and a listening interval period allowed by the base station.

Alternatively, the mobile communication terminal 100 may transmit the final sleep interval length to the base station according to the power state of the battery, and set the sleep interval period and the listening interval period allowed by the base station.

A sleep mode setting process of a mobile communication terminal according to an embodiment of the present invention will be described with reference to FIGS. 3 to 5.

In the sleep mode setting process of the mobile communication terminal according to the embodiment of the present invention shown in FIG. 3, the mobile communication terminal 100 first checks the power state of the current battery, and determines the length of the sleep interval according to the battery power state. The sleep request message including the final sleep window component value that can be determined is transmitted to the base station 220 (S100).

The base station 220 receives the sleep request message from the mobile communication terminal 100 and transmits sleep window data or listening window data corresponding thereto to the mobile communication terminal 100.

The terminal 100 operates a sleep mode based on the sleep fairy message received from the base station 220.

4 is a sleep mode of a mobile communication terminal according to an embodiment of the present invention.

In the sleep mode for transmitting and receiving the data, the mobile communication terminal checks the traffic arrival message at the listening interval after the first sleep interval Sl1, and if the address of the mobile communication terminal is included in the message, sleeps after receiving the packet data. The mode is initialized to start the first sleep interval S1 again.

However, if the traffic arrival message is examined at the listening interval after the first sleep interval Sl1 and the address of the mobile communication terminal is not included in the message, the length of the next second sleep interval Sl2 is determined by the first sleep interval. It is set to twice the length of the interval Sl1.

In addition, when the traffic arrival message is examined at the listening interval after the second sleep interval Sl2 and the address of the corresponding mobile communication terminal is not included in the message, the length of the next third sleep interval Sl3 is determined by the second sleep. It is set to twice the length of the interval Sl2. Similarly, the next fourth slip interval Sl4 is twice the length of the third slip interval Sl3. However, when the number of sleep intervals is more than a predetermined number, the length of the sleep interval is no longer increased.

5 shows an example of setting a sleep mode of a mobile communication terminal according to an embodiment of the present invention.

The listening interval of the mobile communication terminal is a fixed value during the sleep mode, and the sleep interval has a value that is twice the previous sleep interval. Here, the delay time of packet traffic is determined by the final sleep window component (hereinafter, referred to as Kmax) value of Equation (1).

That is, the final sleep interval length is determined according to the final sleep window component value, and the length of the sleep interval in the sleep mode is determined according to the final sleep interval length, thereby determining the packet traffic propagation delay time.

Therefore, the average packet traffic propagation delay time can be adjusted by adjusting the Kmax value. In other words, if the Kmax value is small, the average delay time decreases. If the Kmax value is large, the average delay time increases. However, if the Kmax value is small, the listening interval occurs frequently, which increases the power consumption of the battery.

The sleep mode of the mobile communication terminal according to the present invention adjusts the Kmax value according to the remaining amount of battery power. In other words, when the battery power is large, setting the Kmax value to reduce the packet traffic transmission delay time, and when the battery power is low, setting the Kmax value to reduce the battery power consumption of the mobile communication terminal.

Here, the remaining amount of battery power is divided into N sections, and an appropriate Kmax value is assigned to each of them, and these contents are stored in the memory of the mobile communication terminal. Accordingly, the mobile communication terminal periodically checks the remaining amount of battery power, sends a Kmax value corresponding to a section to which the remaining amount of battery power belongs, and receives a final sleep window value corresponding thereto.

The N intervals are 0 to 100 / N (%), 100 / N to 100 × 2/100 (%), 100 × 2/100 to 100 × 3/100 (%), respectively. … , Divided into intervals of 100 to 100 × (N-1) / 100 (%), whereby the Kmax values are K ₀ , K ₁ , K ₂ ,. … , K _N-1 value. (K ₀ ≥ K ₁ ≥ K ₂ ≥ K _N-1 )

That is, the mobile communication terminal 100 divides the remaining amount of battery power into a predetermined section and sets a final sleep window component value so that the length of the sleep interval is increased in inverse proportion to the remaining amount of the battery power.

In such a sleep mode, if the battery of the mobile communication terminal is sufficiently charged, the final sleep window component value is adjusted to decrease the average packet traffic delay time, and inversely proportional to the final amount as the battery is discharged and the remaining amount is reduced. Adjust the sleep window component to increase its value to reduce battery power consumption.

In this case, a value of the final sleep window component for determining the length of the sleep interval may be a real-time service, a non-real-time service, or a best-effort service. It may be determined to have different values according to the type of service included and the requested quality of service (QoS).

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

 As described above, according to the present invention, the final sleep window component value may be adjusted according to the battery power state of the mobile communication terminal, thereby reducing the power consumption of the battery by adjusting the duration of the sleep interval.

Claims (14)

A sleep mode method comprising a sleep interval and a listening interval of a mobile communication terminal for transmitting and receiving packet data, a) measuring a state of battery power; And b) operating a sleep mode by adjusting at least one of a length of the sleep interval and a length of a listening interval according to the measured state of battery power. The method of claim 1, In the step b) the sleep mode operation, And when the remaining amount of the measured battery power becomes less than a predetermined capacity, operating the sleep mode to reduce battery consumption. delete The method according to claim 1 or 2, And determining at least one of the length of the sleep interval and the length of the listening interval is determined by a terminal operating the sleep mode method. The method according to claim 1 or 2, And determining at least one of the length of the sleep interval and the length of the listening interval is determined by a base station communicating with a terminal operating the sleep mode method.        The method of claim 5, Determining at least one of the sleep interval length and the listening interval length, Sending, by the terminal, a sleep request message for determining at least one of the sleep interval length and the listening interval length to a base station; Receiving a response message corresponding to the sleep request message from the base station. The method according to claim 1 or 2, In step b), The first sleep interval length is determined when the remaining amount of the battery exceeds a predetermined capacity by measuring a state of the battery power, and when the remaining amount of the battery is less than the predetermined capacity, Sleep mode method characterized in that determining. The method according to claim 1 or 2, In step b), And dividing the remaining amount of the battery into predetermined sections, and determining the sleep interval length according to a section corresponding to the remaining amount of the battery. The method of claim 8, And the sleep interval length set according to the remaining amount of the battery divided into the predetermined sections increases in inverse proportion as the remaining amount of the battery decreases. The method according to claim 1 or 2, The sleep interval length or the listening interval length is operated in a window manner, and the characteristic of the window is determined according to the window component value. The method according to claim 1 or 2, The value of the final sleep window component for determining the length of the sleep interval includes a real-time service, a non-real-time service, and a best-effort service. And determining different values according to the type of service and the requested quality of service. A battery check unit checking a battery power state; A data generator generating data on the battery power state; And And a sleep mode setting unit configured to transmit data about the generated power state to a base station, and set a sleep interval period and a listening interval period allowed by the base station. A battery check unit checking a battery power state; A data generator configured to generate a final sleep interval length determined according to the battery power state; And And a sleep mode setting unit configured to transmit the final sleep interval length to a base station, and set a sleep interval period and a listening interval period allowed by the base station. The method of claim 13, The data generator, And dividing the remaining amount of the battery into predetermined sections and increasing the sleep interval length as the remaining amount of the battery decreases.

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