KR101402986B1 - Apparatus and method for managing sleep mode in wideband wireless access system - Google Patents

Abstract

The present invention relates to an apparatus and method for managing a sleep mode of a broadband wireless access system.

The sleep mode management method and apparatus according to the present invention manages a sleep mode of a subscriber terminal by changing a sleep period and a listening period according to characteristics (pattern or cycle) of downlink traffic.

The sleep mode management device and the management method have an advantage of preventing the subscriber terminal from unnecessarily switching to the weather mode, thereby enhancing the power saving effect. In addition, there is an effect of preventing a transmission delay of downlink data that may occur due to an unnecessary sleep interval, thereby preventing deterioration of service quality.

Sleep Mode, Power Saving Rating, Quality of Service, Listening Period, Sleep Duration

Description

[0001] The present invention relates to a sleep mode management apparatus and a method for managing a sleep mode in a broadband wireless access system,

1 is a signal flow diagram illustrating a sleep mode management operation in a general broadband wireless access system.

FIG. 2A shows a power saving class 1 sleep period and listening period belonging to the power saving class type I in one subscriber terminal operating in the sleep mode.

FIG. 2B shows sleep periods and listening periods of power saving class 2 belonging to the power saving class II in one subscriber terminal operating in the sleep mode.

3 is a signal flow diagram illustrating a sleep mode management operation in a broadband wireless access system according to an embodiment of the present invention.

4 is a flowchart illustrating a method of a BS managing a sleep mode of a subscriber station according to an embodiment of the present invention.

5 is a flowchart illustrating a sleep mode management method of a subscriber station according to an embodiment of the present invention.

FIG. 6 is a block diagram illustrating a sleep mode management apparatus of a broadband wireless access system according to an embodiment of the present invention. Referring to FIG.

7 is a configuration diagram illustrating a sleep mode management unit according to an embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power saving method for a wideband radio access system and more particularly to a power saving mode or a sleep mode in a broadband wireless access system Quot; mode "). ≪ / RTI >

A broadband wireless access system refers to a next generation communication method that further supports mobility in a short distance data communication method using a fixed access point such as a conventional wireless LAN.

Various standards have been proposed for such a broadband wireless access system, and an international standardization of a broadband wireless access system is actively underway in IEEE 802.16e.

A conventional wireless LAN scheme such as IEEE 802.11 provides a data communication scheme capable of wireless communication within a short distance around a fixed access point. However, it does not provide mobility of a subscriber station, It has a limit to support data communication.

On the other hand, a broadband wireless access system such as IEEE 802.16e provides a data communication service by ensuring mobility even when a subscriber terminal moves from a cell managed by a base station to another cell managed by another base station.

Accordingly, in the above-described broadband wireless access system, a battery is mainly used as a power supply means of a subscriber terminal. Therefore, in the above-described broadband wireless access system, the battery use time of the subscriber terminal becomes a large limiting factor of the service use time.

Accordingly, in the broadband wireless access system, in order to minimize the power consumption of the terminal, if there is no uplink traffic, all devices in the terminal support a sleep mode in which the operation stops to save power.

Meanwhile, in the broadband wireless access system, the quality of service (QoS) required for the wireless channels established between the terminal and the base station varies depending on the traffic characteristics of the wireless channels. Accordingly, the IEEE 802.16e standard introduces a power saving class for efficient sleep mode management, and manages the sleep period separately according to the power saving class. For example, a wireless channel in which data is generated every two seconds and a wireless channel in which data is generated every three seconds are associated with different power saving classes, and a listening period is set at different periods during a sleep mode for each wireless channel to determine whether data is generated do.

According to the IEEE 802.16e standard, the power saving class is classified into three types according to the required QoS, and the method of updating the listening period and the sleeping period according to the power saving class type and the data receiving operation in the listening period are different.

The power saving grade Type I is a rating that targets the Best Effort (BE), which is characteristic of existing Internet traffic, or the non-real-time Variable Rate (nrt-VR) The parameters defining the power saving class type I include an initial-sleep window, a final-sleep window base, a final-sleep window exponent, a listening window ), And the start frame number for the sleep window.

The power saving class type II is a class that targets real-time variable rate (rt-VR) which is real-time traffic in which VoIP or transmission rate is changed, and parameters defining the power saving class type II include an initial sleep window, , And the initial frame number of the sleep window.

The power saving class Type III is a multicast transmission or a management message in which a UE in a sleep mode periodically transmits, such as a DCD / UCD (Downlink Channel Descriptor / Uplink Channel Descriptor) and a MOB_NBR-ADV The parameters defining the power saving class Type III are the final sleep window basis, the final sleep window exponent, and the initial frame number of the sleep window.

Wireless channels in a subscriber terminal may be defined as multiple power saving classes, where all power saving classes belong to one of the three power saving types described above.

A sleep mode management method of a subscriber terminal in a broadband wireless access system according to the related art and a sleep period management method in a power saving class type I and a power saving class type II will be described below.

Since the case of the power saving class III is a special case and is not related to the contents of the present invention, the description of the power saving class III is omitted below.

1 is a signal flow diagram illustrating a sleep mode management operation in a general broadband wireless access system.

The subscriber terminal 10 operating in the awake mode needs to be approved by the base station 20 to enter the sleep mode. The subscriber terminal 10 which intends to enter the sleep mode transmits a sleep mode request message (SLP-REQ) to the base station 20 to perform a sleep mode request (S10).

If there is a sleep mode request as described above, the base station 20 sends a sleep mode response message (SLP-RSP) to the subscriber terminal 10 to make a sleep mode approval (S11).

If the sleep mode is approved by the base station 20, the subscriber terminal 10 enters a sleep mode state in which no data is received from the sleep mode entering time (S12). When the initial sleep period has elapsed, the subscriber terminal 10 switches to the listening mode and confirms whether there is data waiting for transmission during the sleep period from the base station 20 (S13).

Herein, the sleeping period refers to a period during which the subscriber terminal 10 is operating in the sleep mode, and the listening period refers to a period during which the subscriber terminal 10 operates in the listening mode.

At this time, if there is no data waiting for transmission during the first sleeping period, the base station 20 sets a message indicating the existence of data traffic to 0 and transmits it to the subscriber terminal 10 (S14).

Upon confirming that there is no data traffic transmitted during the listening mode, the subscriber terminal 10 enters the sleep mode again (S15). At this time, the sleeping period may be equal to or larger than the initial sleeping period depending on the setting, and may be different according to the power saving class described above.

Meanwhile, if there is downlink data waiting for transmission to the subscriber station 10 during the second sleep period, the base station 20 may buffer the downlink data (S17). The buffered data is notified when the subscriber terminal 10 is operating in the listening mode (S18).

In the listening mode step S16, when the subscriber terminal 10 confirms that there is downlink data to be transmitted to the subscriber terminal 10, the subscriber terminal 10 ends the sleep mode, enters the awake mode, And then performs data communication with the base station 20. [

If there is no downlink data to be transmitted to the subscriber station by the sleep mode operation as described above, the subscriber station maintains the sleep mode continuously to prevent unnecessary power consumption.

Meanwhile, another sleep mode management method in a broadband wireless access system is a method of managing whether or not buffered downlink data can be transmitted within a listening period of a corresponding terminal when buffered downlink data is generated while the terminal is operating in a sleep mode . Accordingly, if it is determined that transmission is possible within the listening period, transmission of the downlink data is terminated within the listening period and the sleep mode of the subscriber terminal is maintained.

In order to transmit the downlink data even during the listening mode, there is a special promise between the base station and the subscriber station. This is because the traffic triggering of the sleep mode request message SLP-REQ and the sleep mode response message SLP- And setting a wake flag (traffic_triggered_wakening_flag).

2A and 2B show sleep periods and listening periods of a power saving class 1 belonging to the above-mentioned power saving class I and a power saving class 2 belonging to the power saving class II in one subscriber terminal operating in a sleep mode It is.

Referring to FIG. 2A, when the subscriber terminal maintains the sleep mode, the power saving class 1 continuously increases the sleep period to an exponent of 2 and determines that data transmission is necessary in the listening mode or data transmission is impossible in the listening period In this case, it immediately instructs the end of the sleep mode. On the other hand, as shown in FIG. 2B, the power saving class 2 is composed of a fixed length listening period and a sleeping period irrespective of data transmission / reception within the listening period.

In the case of managing the sleep mode as described above, in the case of the power saving class type II, it is possible to continuously transmit the fixed pattern data traffic and the periodically transmitted data traffic by maintaining the fixed length listening period and the sleeping period. However, if the data traffic pattern to be transmitted to the terminal is changed or the data traffic period is changed, if the terminal enters the sleep mode, the terminal must be switched to the weather mode or the terminal must wait until the terminal enters the next listening interval . In such a case, there arises a problem that QoS required can not be guaranteed due to delayed transmission of data traffic.

Disclosure of Invention Technical Problem [8] The present invention provides a sleep mode management method and apparatus capable of continuously reducing data transmission delay time in a broadband wireless access system, in particular, an IEEE 802.16e system.

According to an aspect of the present invention, there is provided a method for managing a sleep mode of a base station in a broadband wireless access system supporting a sleep mode for power saving of a terminal,

a) determining whether the characteristics of the downlink traffic have changed if downlink traffic corresponding to the terminal operating in the sleep mode occurs; b) if the characteristics of the downlink traffic are changed, setting the listening period of the terminal differently according to the characteristics of the downlink traffic; And c) transmitting information corresponding to the set listening period to the terminal.

According to another aspect of the present invention, there is provided a method of managing a sleep mode in a broadband wireless access system supporting sleep mode for power saving of a terminal,

a) receiving downlink data corresponding to a first listening period of fixed length; b) receiving a message including information corresponding to a second listening period from the base station; And c) receiving downlink data corresponding to the second listening period.

According to another aspect of the present invention, there is provided a sleep mode management apparatus for managing a sleep mode in a broadband wireless access system supporting a sleep mode for power saving of a terminal,

A sleep mode manager for setting different listening periods according to the changed characteristics when the characteristics of the downlink traffic corresponding to the terminals operating in the sleep mode are changed; A sleep mode message transmitter for transmitting a message including the listening period received from the sleep mode manager to the terminal; And a traffic transmission management unit for transmitting the downlink data to the terminal in response to the listening period received from the sleep mode management unit.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

Hereinafter, a sleep mode management method of a broadband wireless access system according to an embodiment of the present invention will be described in detail with reference to the drawings.

In particular, a sleep mode management method in a broadband wireless access system that provides downlink traffic corresponding to the power saving class Type II will be described.

In the following, description will be omitted of the operation in which the subscriber station awakes from the sleep mode when uplink data to be transmitted to the base station is generated while the subscriber station is operating in the sleep mode. Since the method of operating the sleep mode in such a case is already well known, a detailed description thereof will be omitted and will be easily understood by those skilled in the art.

3 is a signal flow diagram illustrating a sleep mode management operation in a broadband wireless access system according to an embodiment of the present invention.

As shown in FIG. 3, the subscriber terminal 10 needs to be approved by the base station 20 to enter the sleep mode. The subscriber terminal 10 which intends to enter the sleep mode transmits a sleep mode request message (SLP-REQ) to the base station 20 to perform a sleep mode request (S20).

When the subscriber terminal 10 requests the sleep mode as described above, the base station 20 transmits a sleep mode response message (SLP-RSP) to the subscriber terminal 10 to make a sleep mode approval (S21).

If the sleep mode is approved, the subscriber terminal 10 enters a sleep mode state in which no data is received from the sleep mode entry point (S22).

At this time, the power saving class belonging to the power saving class type II is set to the sleep period of the subscriber terminal 10 through the initial sleep window, the listening window, and the initial frame number of the sleep window included in the sleep mode request and sleep mode response message, Set the listening period. In addition, the controller controls the sections (S23, S27) in which the terminal operates in the sleep mode and the sections (S25, S29) operating in the listening mode according to the sleeping period and the listening period.

In the case where the subscriber terminal 10 does not request the sleep mode but the subscriber terminal 10 enters the sleep mode of the subscriber terminal 10 in the sleep mode entering process of the subscriber terminal 10, The sleep mode request step S20 of the subscriber terminal 10 is omitted and the subscriber terminal 10 can enter the sleep mode only by the sleep mode response S21 of the base station.

When downlink traffic to the subscriber station 10 occurs when the subscriber station 10 is operating in the sleep mode, the base station 20 buffers the traffic (S24) and transmits the downlink data to the next listening interval S25 Quot;) < / RTI >

If it is determined that the downlink data transmission can be completed within the listening period of the subscriber terminal 10, the base station 20 transmits the downlink data to the subscriber terminal 10 when the subscriber terminal 10 enters the listening mode (S26). Upon receiving the downlink data from the base station 20, the subscriber terminal 10 enters the sleep mode again at the end of the listening interval (S27).

At this time, the listening mode and the sleep mode of the subscriber terminal 10 are managed corresponding to the first listening period and the first sleep period set in the initial sleep mode request and response process.

On the other hand, when downlink traffic with a changed pattern or period is generated, the base station 20 buffers the downlink traffic (S28), and generates a new listening period (listening period 2) and a sleep period (second sleep period) corresponding to the changed pattern or period .

Thereafter, when the subscriber terminal 10 is switched from the sleep mode S27 to the listening mode (S29), the base station 20 transmits the buffered downlink data (S30), and transmits a sleeping face including the changed listening period and the sleeping period And transmits the mode response message to the subscriber terminal 10.

At this time, even if the buffered downlink data can not be transmitted within the listening period of the subscriber station, the base station 20 controls the subscriber terminal 10 to receive the next listening period (S33) without switching to the weather mode.

Subsequently, the subscriber terminal 10 manages the sleep mode (S32, S36) and the listening mode (S33) in response to the sleep period and the listening period calculated by receiving the sleep mode response message.

4 is a flowchart illustrating a method of managing a sleep mode of a subscriber station by the base station 20 according to an embodiment of the present invention.

Referring to FIG. 4, when downlink traffic to be transmitted to the subscriber station 10 occurs (S100), the base station 20 determines whether there is a downlink traffic period or pattern change (S110).

If the characteristics of the downlink traffic are changed, the base station 20 calculates a new listening period and a sleeping period of the subscriber terminal 10 in response to the change of the pattern or period of the downlink traffic (S120).

When the subscriber terminal 10 switches to the listening mode, the base station 20, which has calculated the new listening period and the sleep period, transmits a sleep mode response message including information on the listening period and the sleep period to the subscriber terminal (S130).

Thereafter, when the downlink data to be transmitted to the subscriber terminal 10 is generated, the base station 20 transmits the downlink data to the subscriber terminal 10 in response to the changed listening period and sleep period.

5 is a flowchart illustrating a sleep mode management method of the subscriber terminal 10 according to an embodiment of the present invention.

5, when the subscriber station is operating in the listening mode (S200) and receives the sleep mode response message from the base station 20 (S210), the subscriber station calculates the changed sleep period and listening period in the sleep mode response message (S220). At this time, the sleep mode response message includes an initial sleep window corresponding to the sleep period and a listening window corresponding to the listening period.

Thereafter, the subscriber terminal 10 manages the sleep mode corresponding to the changed listening period and the sleep period (S230).

Hereinafter, an apparatus 200 for managing a sleep mode of a broadband wireless access system according to an embodiment of the present invention will be described in detail with reference to the drawings.

6 is a sleep mode management apparatus 200 of a base station 20 of a broadband wireless access system according to an embodiment of the present invention.

The sleeping mode management apparatus 200 may be implemented in a base station that manages subscriber terminals and may utilize a component that operates a sleep mode of an existing broadband wireless access system.

The sleep mode management apparatus 200 includes a sleep mode message receiving unit 210, a message analyzing unit 220, a subscriber terminal identifying unit 230, a sleep mode managing unit 240, a traffic receiving unit 250, a memory 260, A transmission management unit 270 and a sleep mode message transmission unit 280.

The sleep mode message receiving unit 210 receives a sleep mode request message (SLP-REQ) from the subscriber terminal. The sleep mode request message (SLP-REQ) includes a subscriber terminal identifier and sleep mode definition parameters for setting a sleep period and a listening period of the corresponding terminal.

The message analyzer 220 analyzes the sleep request message SLP-REQ received from the sleep mode message receiver 210 and extracts the subscriber terminal identifier and the sleep mode definition parameter to analyze the sleep mode manager 240 and the subscriber terminal identification (230).

The subscriber terminal identification unit 230 analyzes the received subscriber terminal identifier and transmits the identification information corresponding to the subscriber terminal to the sleep mode management unit 240.

The sleep mode manager 240 receives the subscriber terminal identifier and the sleep mode definition parameters from the message analyzer 220 and sets the sleep mode entry point of the corresponding terminal to the sleep mode message transmitter 280.

That is, when the subscriber terminal enters the sleep mode by the sleep mode manager 240, the sleep mode manager 240 informs the sleep mode message transmitter 280, and when the sleep mode message transmitter 280 receives the sleep mode entry point And transmits the sleep mode response message to the subscriber terminal. Accordingly, the sleep mode message transmitting unit 280 transmits a sleep mode request to the subscriber terminal by sending a MAC message (for example, an SLP-RSP message) including a sleep mode defining parameter and a sleep mode entering time.

In addition, the sleep mode manager 240 classifies the sleep mode definition parameters according to the power saving class in the terminal and stores the classified sleep mode definition parameters in the memory 260. Thereafter, the sleep mode management unit 240 determines whether or not the sleep mode definition parameter (or sleep mode definition parameter) corresponding to the listening period and the sleep period that are optimal for the pattern or period is generated, Lt; / RTI > The changed sleep mode definition parameter is included in the sleep mode response message and is transmitted within the listening interval of the subscriber terminal 10. [

Also, the traffic transmission management unit 270 transmits the downlink data to the subscriber terminal 10 in response to the changed listening period and sleep period.

Meanwhile, the traffic receiver 250 receives the downlink data through the network, identifies the subscriber terminal to which the data is to be transmitted, and transmits the downlink data and the terminal identification information to the traffic transmission management unit 270.

The traffic transmission management unit 270 transmits the downlink data to the terminal in response to the listening period and the sleeping period. That is, when the terminal enters the sleeping period, the traffic transmission management unit 270 temporarily stores the downlink data in the buffer, and when the terminal enters the listening period or switches to the weather mode, the traffic transmission management unit 270 transmits the stored downlink data to the corresponding terminal .

FIG. 7 is a block diagram illustrating a sleep mode management unit 240 according to an embodiment of the present invention.

7, the sleep mode management unit 240 includes a determination unit 241 and a period changing unit 242. [

When the downlink traffic occurs, the determination unit 241 determines whether the characteristics such as the periodicity or the pattern are changed in response to the downlink traffic that occurred in the past. When it is determined that it is necessary to change the listening period and the sleep period of the subscriber terminal 10 to receive the traffic due to the change of the characteristics of the downlink traffic, the determination unit 241 outputs a control signal and notifies the changing unit 242 thereof do.

The changing unit 242 changes the listening period and the sleeping period of the subscriber terminal 10 in response to the control signal output from the determination unit 241. [ At this time, the changing unit 242 prevents the subscriber terminal 10 from unnecessarily waking up by setting the listening period of the subscriber terminal 10 to be long if the amount of generated data of the downlink traffic increases or the generation period becomes faster, To reduce the transmission delay of the downlink data, thereby maintaining the QoS. On the other hand, if the downlink traffic generation data amount increases or the data generation period becomes long, unnecessary power consumption is reduced by setting the listening period of the subscriber terminal 10 to be short and the sleep period to be long.

The sleep mode management method and apparatus adaptively change the listening period and the sleep period of the subscriber terminal in response to a change in the pattern or cycle of the downlink traffic, thereby preventing the terminal from unnecessarily entering the awake mode, It is possible to maintain service quality while maximizing consumption.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

A sleep mode management method and apparatus for managing a sleep mode of a subscriber terminal by changing sleep periods and listening periods according to characteristics (patterns or periods) of downlink traffic according to an embodiment of the present invention includes: It is advantageous in that the power saving effect is improved.

In addition, there is an effect of preventing a transmission delay of downlink data that may occur due to an unnecessary sleep interval, thereby preventing deterioration of service quality.

Claims (18)

A method of managing a sleep mode in a base station in a broadband wireless access system supporting a sleep mode for power saving of a terminal, Transmitting a sleep mode response message to the terminal, the sleep mode response message including a first parameter for setting a sleep period and a listening period of the sleep mode; and A second parameter for setting a new sleep period and a listening period to a terminal operating in a sleep mode according to the sleep period and the listening period set by the first parameter when at least one of the sleep period and the listening period needs to be changed, Transmitting a sleep mode response message including the sleep mode response message Gt; delete delete delete delete delete delete delete delete A method for managing a sleep mode in a broadband wireless access system supporting sleep mode for power saving of a terminal, Receiving a sleep mode response message from a base station, the sleep mode response message including a first parameter for setting a sleep period and a listening period of the sleep mode; Entering the sleep mode according to the sleep period and the listening period set by the first parameter, and Receiving from the base station a sleep mode response message including a second sleep mode and a second parameter for setting a listening period if at least one of the sleep period and the listening period is required during operation in the sleep mode Gt; delete delete A sleep mode management apparatus for managing a sleep mode in a broadband wireless access system supporting a sleep mode for power saving of a terminal, A sleep mode manager for managing a plurality of parameters for setting a sleep period and a listening period of the sleep mode, and A sleep mode response message including a first parameter for setting a sleep period of an initial sleep mode and a listening period is transmitted to the terminal, and when at least one of the sleep period and the listening period is required, And a second parameter for setting a new sleep period and a listening period to the terminal operating in the sleep mode according to the sleep period and the listening period set by the sleep mode message transmitter And the sleep mode management device. delete delete delete delete delete

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