KR100620012B1 - Mobile communication station and method for controlling a power saving in wireless mobile internet system - Google Patents

Abstract

The present invention relates to a mobile communication terminal for controlling power consumption in a wireless portable Internet system and a method thereof. The present invention stores a timer value according to a power saving type for power control in a wireless portable Internet system, counts the timer value according to the preset timer value according to the power saving type in a sleep mode operation, and then returns to the corresponding timer value. When the counting expires, the sleep mode ends and the idle mode operation is performed.

Mobile internet, power saving, sleep mode, idle mode.

Description

MOBILE COMMUNICATION STATION AND METHOD FOR CONTROLLING A POWER SAVING IN WIRELESS MOBILE INTERNET SYSTEM}

1 is a block diagram showing a general wireless portable Internet system,

2 is a flowchart illustrating a sleep mode operation in a typical wireless portable Internet system;

3 is an internal configuration diagram of a mobile communication terminal for power control according to an embodiment of the present invention;

4 is a flow chart for controlling power in a mobile communication terminal according to an embodiment of the present invention.

The present invention relates to a mobile communication terminal for power control and a method thereof, and more particularly, to a mobile communication terminal and method for controlling to reduce power consumption in a wireless portable Internet system.

The wireless portable Internet is a next-generation communication method that further supports mobility in a short-range data communication method using a fixed access point like a conventional wireless LAN.

Various standards have been proposed for the wireless mobile Internet, and international standardization of the mobile internet is currently progressing around the IEEE 802.16e.

1 is a block diagram showing a general portable Internet system.

The wireless portable Internet system basically includes a subscriber station 10, base stations 20 and 21 performing wireless communication with the subscriber station, routers 30 and 31 connected via the base station and a gateway, an internet network 50, and End node 40 is included.

Conventional wireless LAN methods such as IEEE 802.11 provide a data communication method capable of wireless communication within a short distance around a fixed access point, but this provides mobility of a subscriber station (hereinafter referred to as SS). Rather, it was limited to supporting short-range data communications over wireless rather than wired.

On the other hand, the wireless portable Internet system promoted by the IEEE 802.16 group and the like ensures the mobility even when the subscriber station 10 shown in FIG. It will provide an uninterrupted data communication service.

IEEE 802.16e is basically a standard that supports metropolitan area network (MAN), and means an information communication network covering an intermediate area between a local area network (LAN) and a wide area network (WAN).

Accordingly, the wireless portable Internet system supports handover of the subscriber station 10 like the mobile communication service, and performs dynamic IP address allocation according to the movement of the subscriber station.

In the wireless portable Internet system configured as described above, a sleep mode and an idle mode are used as modes for reducing power consumption.

First, the sleep mode will be described with reference to the flowchart of FIG. 2. 2 is a flowchart illustrating a sleep mode operation in a typical wireless portable Internet system.

In order for the subscriber station 10 to enter the sleep mode, the base station 20 needs to be approved. The subscriber station 10 to enter the sleep mode sets a sleep period and performs a sleep mode request to the base station 20 (S10). If there is the sleep mode request, the base station designates a sleep period to grant the sleep mode to the subscriber station (S11).

If the sleep mode is granted, the subscriber station enters a sleep mode that does not receive data from the sleep mode entry point (M) (S12). When the initial sleep cycle has elapsed, the subscriber station switches to the listening mode and checks whether there is data waiting to be transmitted during the sleep cycle from the base station 20 (S13).

At this time, if there is no data waiting to be transmitted during the first sleep period, the base station 20 transmits a message indicating the presence of data traffic to the subscriber station (S14). After confirming that there is no data traffic transmitted during the listening mode, the subscriber station enters the sleep mode again (S15). In this case, the sleep cycle may be greater than or equal to the initial sleep cycle, depending on the setting.

On the other hand, if there is data waiting to be transmitted to the subscriber station 10 during the second sleep period, the base station may buffer the data traffic (S17). The buffered data is notified of its existence in the listening mode of the subscriber station 10 (S18).

In the listening mode step S16, when the subscriber station 10 confirms that there is data traffic to be transmitted to it, the subscriber station 10 exits the sleep mode, enters the awake mode, and buffers the data. Receives traffic and performs data communication with the base station 20.

If there is no data to be transmitted by the sleep mode operation, the subscriber station 10 continues to sleep, thereby preventing unnecessary power consumption.

This sleep mode has three power saving types. Each type has a sleep period and a listening period, which vary depending on the connection method. However, if no special event occurs, the sleep mode continues to operate. It is a way of saving.

According to each type of power saving, a first power saving type for setting the maximum window size while increasing the sleep window size by an exponential multiple of 2 and preventing the window size from increasing beyond that, and keeping the sleep window size constant There is a second power saving type and a third power saving type that automatically increases the sleep window size by an exponential multiple of 2 each time the sleep interval continues, and automatically terminates after a predetermined time.

In addition, the idle mode, which is a mode for reducing power consumption in a wireless portable Internet system, is to reduce power consumption by eliminating air interface and network handover traffic. Since the idle mode is not registered in the base station (Deregistration) is a mode that can further reduce the power consumption than the sleep mode.

However, when there is no traffic among the modes for reducing power consumption in the wireless portable Internet system as described above, the idle mode may further reduce power consumption compared to the sleep mode. Therefore, there is a demand for a method of using the sleep mode and the idle mode together when there is no traffic.

Accordingly, an object of the present invention is to provide a mobile communication terminal and a method for interlocking a sleep mode and an idle mode to control power consumption in a wireless portable Internet system.

SUMMARY OF THE INVENTION An object of the present invention is to provide a mobile communication terminal and a method for operating in an idle mode when a sleep mode of a predetermined time is maintained to control power consumption in a wireless portable Internet system.

According to an aspect of the present invention, there is provided a mobile communication terminal for power control, comprising: a memory unit for storing different timer values according to one or more power saving types, a timer for counting according to a control signal, and a sleep mode operation; And a control unit configured to control the timer to operate the timer with a corresponding timer value according to the power saving type, and to perform an idle mode operation after ending the sleep mode when the timer expires.

According to an aspect of the present invention, there is provided a method for controlling power in a wireless portable Internet system, comprising: a first process of storing different timer values according to one or more power saving types; And a second step of counting the set timer value and a third step of performing an idle mode operation after ending the sleep mode when the counting time expires.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. It should be noted that the same elements among the figures are denoted by the same reference numerals and symbols as long as they function even though they are shown in different figures. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Next, the configuration and operation of the mobile communication terminal according to the present invention will be described with reference to FIG. 3. 3 is an internal configuration diagram of a mobile communication terminal for power control according to an embodiment of the present invention.

The controller 300 controls the overall operation of the mobile communication terminal. In particular, in the present invention, the control unit 300 drives the timer 310 to a predetermined timer value according to the power saving type during the sleep mode operation, and when the timer 310 expires, the idle mode operation after ending the sleep mode. Control to perform the process for. In particular, when the power saving type is the first power saving type, the control unit 300 performs the sleep mode until the sleep window size reaches a preset maximum window size while increasing the sleep window size by an exponential multiple of 2. Control to drive the timer (310). In addition, when the power saving type is the second power saving type to the third power saving type, the controller 300 performs a sleep mode and controls the timer 310 to be driven by the T1 timer value.

The operation of the controller 300 will be described in more detail with reference to the flowchart of FIG. 4.

The message receiving unit 302 receives a message transmitted from the base station. In the present invention, the message receiver 302 receives a sleep mode response message including a minimum sleep cycle, a maximum sleep cycle, and a sleep mode entry time point, and transmits the message to the message analyzer 304. In addition, the message receiver 302 receives the idle mode response message and transmits the message to the message analyzer 304.

The message analyzer 304 analyzes the information included in the sleep mode and idle mode response messages and transmits the analyzed result to the controller 300.

The message transmitter 306 transmits a message to the base station. In the present invention, the message transmitter 306 transmits a sleep mode request message, an idle mode request message, and the like to the base station under the control of the controller 300.

The memory unit 308 is composed of a ROM, a RAM, and the like. The ROM stores a control program for performing various control functions and data necessary for control. In particular, in the present invention, the memory unit 308 stores a timer value according to the power saving type. For example, the memory unit 308 may determine a maximum value of the window size while increasing the sleep window size by an exponential multiple of two, and then operate the timer in the case of the first power saving type that prevents the window size from being increased. Corresponds to the T2 timer value and stores it. In addition, the memory unit 308 includes a second power saving type that maintains a constant sleep window size, and a program that automatically increases the sleep window size by an exponent of 2 each time the sleep interval continues, and automatically terminates after a predetermined time. 3 In the case of the power saving type, the T1 timer value, which is a value for driving the timer, is stored in correspondence.

The timer 310 is used to count according to the control signal of the controller 300.

Next, a process for controlling power in the mobile communication terminal configured as shown in FIG. 3 will now be described with reference to FIG. 4. 4 is a flowchart for controlling power in a mobile communication terminal according to an exemplary embodiment of the present invention.

In operation 400, when the operation mode becomes the sleep mode, the controller 300 checks the power saving type. In this case, the power saving type proceeds to step 408 in the case of the first power saving type in which the power saving type increases the sleep window size by an exponential multiple of two and sets the maximum value of the window size so that the window size cannot be increased beyond that. In the case of the second power saving type that maintains the sleep window size constant and the third power saving type that automatically increases the sleep window size by an exponential multiple of 2 each time the sleep interval continues, and automatically terminates after a certain time, 404. Proceed to step.

First, when the power saving type is the first power saving type, the control unit 300 performs the sleep mode by increasing the sleep window size by an exponential multiple of 2 in step 408. In operation 410, the controller 300 determines whether the sleep window size is the preset maximum window size. If the sleep window size is the preset maximum window size, the controller 300 proceeds to step 412; otherwise, proceeds to step 408. Subsequently, the sleep mode is performed while increasing the sleep window size by an exponent of 2.

In step 410 to step 412, the control unit 300 drives the timer 310 to the T2 timer value. In step 413, the controller 300 checks whether there is traffic, and if there is traffic, the control unit 300 proceeds to step 416 to operate in a listen mode.

If there is no traffic in step 413, the controller 300 proceeds to step 415 and determines whether the T2 timer expires. If the T2 timer expires, the process proceeds to step 417. Otherwise, the process proceeds to step 414 to maintain the sleep mode, and then proceeds to step 413.

Meanwhile, when the power saving type is the second power saving type or the third power saving type in step 402, the controller 300 performs a sleep mode and drives the timer 310 with a T1 timer value in step 404. Thereafter, the controller 300 proceeds to step 405 and checks whether there is traffic. If there is traffic, the controller 300 proceeds to step 416 to perform a listening mode.

However, if there is no traffic in step 405, the control unit 300 proceeds to step 406 and checks whether the T1 timer expires. At this time, if the T1 timer expires, the process proceeds to step 417, otherwise the process proceeds to step 407 and proceeds to step 405 while maintaining the sleep mode.

Then, in step 417 proceeds to step 406 and step 415, the control unit 300 performs an operation for ending the sleep mode and proceeds to step 418 to perform a process for operating in the idle mode.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the scope of the following claims, but also by the equivalents of the claims.

As described above, the present invention allows the portable Internet power usage time to be maximized by operating in the idle mode when the sleep mode of the predetermined time is continued.

Claims (8)

In the mobile communication terminal for power control, A memory unit for storing different timer values according to one or more power saving types; A timer for counting according to the control signal, And a controller configured to control the timer to operate according to the power saving type according to the power saving type and to perform an idle mode operation after ending the sleep mode when the timer expires. Mobile communication terminal for power control in the Internet system. The method of claim 1, wherein the memory unit, In the case of the first power saving type that increases the sleep window size by an exponential multiple of 2 and prevents the window size from increasing beyond that, the first timer value is set and stored, and the sleep window size is fixed. In the case of the second power saving type which continuously maintains the power saving type and the sleep period continues continuously, the third power saving type which continuously increases the sleep window size by an exponent multiple of 2 and automatically terminates after a predetermined time is the second power saving value. A mobile communication terminal for power control in a wireless portable Internet system, characterized in that it further comprises means for setting and storing as a timer value. The method of claim 2, wherein the control unit, When the power saving type is the first power saving type, the timer is driven with a first timer value after performing a sleep mode until the sleep window size reaches a preset maximum window size while increasing the sleep window size by an exponential multiple of 2. And means for controlling to control the power of the mobile communication terminal in a wireless portable Internet system. The method of claim 2, wherein the control unit, And a means for performing a sleep mode when the power saving type is the second power saving type to the third power saving type, and controlling the device to drive the timer with the second timer value. Mobile communication terminal for power control in the Internet system. In the method for power control in a wireless portable Internet system, A first process of storing different timer values according to one or more power saving types; Counting a timer value set according to the power saving type during a sleep mode operation; And a third process of performing an idle mode operation after ending the sleep mode when the counting expires. The method of claim 5, wherein the first process, In the case of the first power saving type that increases the sleep window size by an exponential multiple of 2 and prevents the window size from increasing beyond that, the first timer value is set and stored, and the sleep window size is fixed. Whenever the second power saving type and the sleep interval are continuously maintained, the sleep window size is continuously increased by an exponent of 2, and in the case of the third power saving type which automatically shuts down after a certain time, it is set as the second timer value and stored. A method for power control in a wireless portable Internet system, characterized in that the process. The method of claim 6, wherein the second process, When the power saving type is the first power saving type, a process of counting the first timer value after performing a sleep mode until the sleep window size reaches a preset maximum window size while increasing the sleep window size by an exponential multiple of 2 is performed. A method for power control in a wireless portable internet system characterized by the above. The method of claim 6, wherein the second process, And when the power saving type is a second power saving type to a third power saving type, performing a sleep mode and counting the second timer value at the same time.

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