KR20110080123A - Method and apparatus of transmitting and receiving system information in a wireless system - Google Patents

Abstract

PURPOSE: A system information transceiving method and apparatus in a wireless communication system are provided to efficiently receive system information in a terminal which operates in a sleep mode. CONSTITUTION: A terminal receives an S-SFH(Secondary-Super Frame Header) change period from a BS(Base Station)(S210). The terminal receives a P-SFH IE(Primary-Super Frame Header Information Element) including an S-SFH change frequency field(S220). The terminal receives and updates an S-SFH SP IE(Secondary-Super Frame Header SubPacket Information Element)(S230). The terminal applies contents included in the changed S-SFH SP IE from a specific point of time(S240).

Description

METHOD AND APPARATUS OF TRANSMITTING AND RECEIVING SYSTEM INFORMATION IN A WIRELESS SYSTEM}

The present invention relates to a wireless communication system, and more particularly, to a method and apparatus for transmitting and receiving system information in a wireless communication system.

First, a super-frame header (SFH) will be described.

The base station delivers system information to the terminals through the SHF. The SFH is located in the first subframe within one superframe. The SFH is divided into a primary superframe header (primary SFH, P-SFH) and a secondary superframe header (secondary SFH, S-SFH).

Table 1 shows the format of the P-SFH information element (IE).

The P-SFH IE is transmitted every super frame and includes 4-bit least significant bit (LSB) information of a super frame number (SFN) and information related to the S-SFH IE. Information related to the S-SFH IE includes an S-SFH change count indicating the S-SFH version currently transmitted, and any secondary super frame header subpacket information element in the corresponding superframe. element, S-SFH scheduling information indicating whether the S-SFH SP IE is transmitted, S-SFH size indicating the number of LRUs allocated for S-SFH transmission, S-SFH size, S S-SFH number of repetitions indicating the transmission format of the SFH, and an S-SFH SP change bitmap indicating which S-SFH SP IE has been changed. The size of the S-SFH SP change bitmap field is equal to the total number of S-SFH SP IEs.

Table 2 shows the format of the S-SFH IE. S-SFH delivers actual system information, and system parameters and system configuration information transmitted through S-SFH are classified into S-SFH SP1 IE, S-SFH SP2 IE, and S-SFH SP3 IE. S-SFH SP1 IE includes information for network reentry, S-SFH SP2 IE includes information for initial network entry and network discovery, S-SFH SP3 IE contains the rest of the necessary system information for network (re) entry.

Each of the S-SFH SP1 IE, S-SFH SP2 IE, and S-SFH SP3 IE is transmitted at different times with different periods. Table 3 shows the transmission periods of the S-SFH SP1 IE, the S-SFH SP2 IE, and the S-SFH SP3 IE, and the transmission periods of the S-SFH SP1 IE, the S-SFH SP2 IE, and the S-SFH SP3 IE are S-SFH. It is sent via SP3 IE.

Next, a method of updating information of a secondary super frame header subpacket information element (S-SFH SP IE) by a terminal will be described.

The terminal receives the P-SFH IE and checks the S-SFH change count field. The base station increments the value of the S-SFH change count field by 1 each time the S-SFH IE information is updated (changed).

If the S-SFH change count is different from its own value, the UE determines that the S-SFH SP IE has been updated (changed), and checks the S-SFH SP change bitmap of the P-SFH IE to determine which S-SFH SP. Check if is updated (changed).

In addition, the S-SFH scheduling information is checked in the P-SFH IE to determine which S-SFH SP IE is transmitted in the current superframe. If the S-SFH SP IE to be updated (saved and updated) is transmitted in the current SFH, the corresponding S-SFH SP IE is checked and updated (saved and updated). If the S-SFH SP IE to be updated (saved and updated) is not transmitted in the current SFH, the S-SFH SP IE is received and updated in the next cycle in which the S-SFH SP IE to be updated (saved and updated) is transmitted. (Save and update).

According to the prior art, since the UE decodes the P-SFH every superframe to check the S-SFH change count to check whether the S-SFH SP IEs are changed, there is a problem in that the power consumption of the UE increases.

Next, a sleep mode operation according to the prior art will be described with reference to FIG. 1. When the mobile station communicates with the base station in the normal mode or the active mode and there is no more traffic to send and receive with the base station, a sleep request (hereinafter referred to as "AAI_SLP-REQ") message It transmits to the base station to request a transition to the sleep mode (sleep mode). The base station transmits a sleep response (hereinafter referred to as "AAI_SLP-RSP") message to the terminal in response, the terminal receiving the AAI_SLP-RSP message, the sleep cycle included in the AAI_SLP-RSP message, listening Transition to sleep mode by applying sleep parameters such as a listening window. In addition, the base station may transmit an unsolicited AAI_SLP-RSP message to the terminal to allow the terminal to transition to the sleep mode.

1 is a diagram illustrating a sleep mode operation of a terminal according to the prior art. As shown in FIG. 1, after the UE transitions from the normal mode to the sleep mode, the terminal operates in the sleep mode by applying an initial sleep cycle. After transitioning to sleep mode, the first sleep cycle includes only sleep windows.

After the first sleep cycle is finished, the second sleep cycle starts, the terminal operates the slim mode by applying the sleep cycle including the listening interval and the sleep interval. When the UE receives a traffic indication (TRF-IND) message including a negative indication during the listening interval, it determines that there is no traffic transmitted in the downlink and doubles the current sleep cycle. Let's do it. After the doubled sleep cycle ends, the terminal resets the current sleep cycle to the initial sleep cycle upon receiving a TRF-IND message containing a positive indication during the listening interval of the next sleep cycle.

The terminal in the sleep mode should have the latest system information transmitted through the SFH for smooth communication with the base station. However, when the frame in which the P-SFH is transmitted exists within the sleep period of the UE, there is a problem in that the P-SFH cannot be received.

As described above, according to the related art, since the UE needs to decode the P-SFH every superframe to check whether the S-SFH SP IEs are changed, there is a problem in that power consumption of the UE increases. In the case of the UE operating in the sleep mode, there is a problem in that the P-SFH cannot be received if the frame in which the P-SFH is transmitted exists within the sleep period of the UE.

An object of the present invention is to provide a method for transmitting and receiving system information that can reduce the power consumption of the terminal.

Another object of the present invention is to provide a system information transmission / reception method for allowing a terminal operating in a sleep mode to efficiently receive system information.

Technical problems to be achieved in the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned above will be clearly understood by those skilled in the art from the following description. Could be.

In order to achieve the above object, in the method of receiving system information in a terminal of a wireless communication system according to an aspect of the present invention, the terminal receives a secondary superframe header (secondary SFH, S-SFH) change period from the base station, a plurality of Primary SFH information element (P-SFH) including a first field indicating the number of changes of the secondary super frame header subpacket information element (S-SFH SP IE) IE), and each of the plurality of S-SFH SP IEs does not change during one or more S-SFH change cycle periods once changed.

In this case, the value of the first field may be changed only in a superframe in which a remainder obtained by dividing a superframe number (SFN) by the S-SFH change period is a predetermined number.

In addition, the S-SFH change period may be transmitted through one of the plurality of S-SFH SP IEs.

The terminal may receive and update at least one S-SFH SP IE among the plurality of S-SFH SP IEs when the value of the first field is different from the number of S-SFH changes stored by the terminal. have.

In addition, if the difference between the value of the first field and the number of S-SFH changes stored by the UE is 1, the UE changes the S-SFH SP change bitmap included in the P-SFH SP IE (S-SFH SP). Only the S-SFH SP IE having a bit of change bitmap) may be received and updated, and the S-SFH SP change bitmap may indicate whether each of the plurality of P-SFH SP IEs is changed.

In addition, the terminal may receive and update all of the plurality of S-SFH SP IEs when the difference between the value of the first field and the number of S-SFH changes stored by the terminal is greater than one.

In addition, the terminal is the latest of the next superframe immediately after each of the at least one S-SFH SP IE is regularly scheduled and transmitted a predetermined number of times for each of the at least one S-SFH SP IE Information included in the at least one S-SFH SP IE may be simultaneously applied in a superframe.

In addition, the P-SFH IE may further include a second field indicating S-SFH SP IEs applied in a superframe in which the P-SFH IE is transmitted.

In order to achieve the above object, in a method of transmitting system information in a base station of a wireless communication system according to another aspect of the present invention, the base station transmits a secondary superframe header (secondary SFH, S-SFH) change period to the terminal, A primary SFH information element (primary SFH information element) including a first field indicating a number of changes of a plurality of secondary super frame header subpacket information elements (S-SFH SP IE) to the UE; P-SFH IE), and each of the plurality of S-SFH SP IEs is not changed for one or more S-SFH change cycle periods once changed.

In order to achieve the above object, a terminal of a wireless communication system according to another aspect of the present invention is a secondary superframe header (secondary SFH, S-SFH) change period from the base station and a plurality of secondary superframe header subpacket information element (secondary) a receiving module for receiving a primary SFH information element (P-SFH IE) including a first field indicating a number of changes of a super frame header subpacket information element (S-SFH SP IE), Each of the plurality of S-SFH SP IEs does not change during one or more S-SFH change periods once changed.

In order to achieve the above object, a base station according to another aspect of the present invention is a secondary super frame header (secondary SFH, S-SFH) change period and a plurality of secondary super frame header subpacket information element to the terminal a transport module for transmitting a primary SFH information element (P-SFH IE) including a first field indicating a number of changes of an information element, S-SFH SP IEs, and the plurality of S Each of the SFH SP IEs is changed once and does not change during one or more S-SFH change cycle periods.

In order to achieve the above object, a terminal according to another aspect of the present invention is a central processing unit (CPU) for controlling the operation of the terminal, a memory for storing information related to communication with the base station and the base station and A communication module for controlling communication of a second superframe header (S-SFH) change period and a plurality of secondary super frame header subpacket information elements from the base station; element, a receiving module for receiving a primary SFH information element (P-SFH IE) including a first field indicating a number of changes of S-SFH SP IEs, and the plurality of S- Each of the SFH SP IEs does not change for one or more S-SFH change periods once changed.

In order to achieve the above object, a base station according to another aspect of the present invention is a central processing unit (CPU) for controlling the operation of the base station, a memory for storing information related to communication and a communication module for controlling communication The communication module may include a secondary SFH (S-SFH) change period and a plurality of secondary super frame header subpacket information elements (S-SFH SP IE) to the UE. And a transmitting module for transmitting a primary SFH information element (P-SFH IE) including a first field indicating a number of changes of the P-SFH IE, wherein each of the plurality of S-SFH SP IEs is once If changed, it does not change during one or more S-SFH change cycles.

According to the embodiments of the present invention, each of the plurality of S-SFH SP IEs are not changed during one or more S-SFH change cycle periods once changed, so that the UE is only required to check the validity of the S-SFH SP IEs. It is possible to reduce the power consumption of the UE by decoding the SFH IE and checking whether the S-SFH SP IEs are changed.

The effects obtainable in the present invention are not limited to the above-mentioned effects, and other effects not mentioned above may be clearly understood by those skilled in the art from the following description. will be.

1 is a diagram illustrating a sleep mode operation of a terminal according to the prior art.
2 is a flowchart illustrating a method of receiving system information of a terminal according to an embodiment of the present invention.
3 is a diagram illustrating an application time point when one S-SFH SP IE is changed in one transmission period.
4 is a diagram illustrating an application time point when a plurality of S-SFH SP IEs are changed in one transmission period.
5 is a view showing an application time point according to the second method.
6 is a diagram illustrating an example of an application time point according to a third method.
7 is a diagram illustrating another example of an application time point according to a third method.
8 illustrates an application time point according to a fourth method.
9 illustrates an example of an application time point according to the fifth method, and FIG. 10 illustrates another example of an application time point according to the fifth method.
11 is a flowchart illustrating an operation of a terminal according to a sixth method.
12 illustrates an example of an application time point according to a sixth method.
13 is a diagram illustrating another example of an application time point according to a sixth method.
14 shows another example of an application time point according to a sixth method.
15 is a diagram illustrating that an S-SFH SP2 IE is transmitted irregularly.
16 is a diagram illustrating a configuration of a mobile station and a base station in which embodiments of the present invention can be implemented.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The following detailed description, together with the accompanying drawings, is intended to illustrate exemplary embodiments of the invention and is not intended to represent the only embodiments in which the invention may be practiced. The following detailed description includes specific details in order to provide a thorough understanding of the present invention. However, one of ordinary skill in the art appreciates that the present invention may be practiced without these specific details. For example, the following detailed description will be described in detail on the assumption that the mobile communication system is a 3GPP2 802.16 system, but can be applied to any other mobile communication system except for the specific matters of the 3GPP2 802.16 system.

In some instances, well-known structures and devices may be omitted or shown in block diagram form centering on the core functions of the structures and devices in order to avoid obscuring the concepts of the present invention. In addition, the same components will be described with the same reference numerals throughout the present specification.

In the following description, it is assumed that the UE collectively refers to a mobile stationary or stationary user equipment such as a UE (User Equipment) and an MS (Mobile Station). In addition, it is assumed that the base station collectively refers to any node of the network side that communicates with the terminal, such as Node B, eNode B, Base Station.

A method of transmitting and receiving system information according to an embodiment of the present invention will be described with reference to the drawings.

According to an embodiment of the present invention, the terminal considers the S-SFH change cycle (S-SFH change cycle), the secondary super frame header subpacket information element (S-SFH) stored by the terminal Whenever validation of the SP IEs is required, the primary super frame header information element (P-SFH IE) is decoded to check whether the S-SFH SP IEs are changed.

2 is a flowchart illustrating a method of receiving system information of a terminal according to an embodiment of the present invention.

As shown in Figure 2, the terminal receives the S-SFH change period from the base station (S210). In this case, the terminal may receive the S-SFH change cycle through the S-SFH SP3 IE.

The S-SFH change period means the minimum interval where the S-SFH is not changed. Each of the plurality of S-SFH SP IEs may be changed only once during the S-SFH change period. That is, each of the plurality of S-SFH SP IEs are not changed for one or more S-SFH change periods once changed. The S-SFH change period may be set for all of the plurality of S-SFH SP IEs or may be set for each of the plurality of S-SFH SP IEs.

The S-SFH change period may be expressed in time units (eg, ms) or in superframe units. In addition, when the S-SFH change period is set for each of the plurality of S-SFH SP IEs, the S-SFH SP IE may be expressed as the total number of transmissions of the corresponding S-SFH SP IE.

When the S-SFH change period is set for all of the plurality of S-SFH SP IEs, S-SFH indicating the version of the S-SFH included in the primary superframe header information element (P-SFH IE). The S-SFH change count may increase only once during the S-SFH change period. In this case, the number of S-SFH changes may be increased only in specific superframes determined according to the change period and the superframe number (SFN). For example, when the S-SFH change cycle is set in units of superframes, the number of S-SFH changes may increase only in a superframe having SFNs in which a 'SFN modulo S-SFH change cycle' satisfies a specific number. The specific number can be zero. Then, if the S-SFH change period is 32, the number of S-SFH change can be increased only in the superframe whose SFN is a multiple of 32.

The changed S-SFH SP IE transmits through superframes scheduled for the changed S-SFH SP IE, among the superframes with the changed number of S-SFH changes and the superframes after the changed number of S-SFH changes. do.

Next, when the S-SFH change period is set for each of the plurality of S-SFH SP IEs, the base station uses the S-SFH change period and SFN for each of the plurality of S-SFH SP IEs. The S-SFH SP IE may be changed at the determined time point. That is, the S-SFH SP IE may be changed in a superframe that satisfies 'f (SFN, S-SFH change cycle) = x'. In this case, x may be predefined as a specific number or may be delivered through S-SFH. And, x should be less than (transmission period of the corresponding S-SFH SP IE / interval of one superframe). For example, if the transmission period of the S-SFH SP1 IE is 40ms, and the interval of one superframe is 20ms, x should be less than 2. In the following description, it is assumed that the interval of one superframe is 20ms.

If the S-SFH change cycle is expressed as the total number of S-SFH SP IEs transmitted during the S-SFH change cycle, then 'SFN mod (S-SFH change cycle * S-SFH SP IE transmission cycle / 20)' S-SFH SP IE may be changed only in a superframe having SFNs satisfying a specific number. For example, S-SFH SP1 IE transmits 40ms, change period is 3, and S- every superframe satisfies SFN mod (S-SFH change period * S-SFH SP IE transmission period / 20ms) = 1 If the SFH SP1 IE can be changed, the S-SFH SP1 IE can be changed in a superframe with SFNs of 1, 7, 13, and 19, and the like.

When the S-SFH change cycle is expressed in time units (ms), the S-SFH SP IE can be changed only in superframes with SFNs where 'SFN mod (S-SFH change cycle / 20 ms)' satisfies a specific number. have. At this time, the S-SFH change period should be an integer multiple of the transmission period of the S-SFH SP IE. For example, if the change cycle of the S-SFH SP1 IE is 80 ms and the S-SFH SP1 IE can be changed for each superframe that satisfies 'SFN mod (S-SFH change cycle / 20 ms) = 1', -SFH SP1 IE can be changed in a superframe with SFNs of 1, 5, 9, 13, and the like.

When the S-SFH change cycle is expressed in units of superframes, the S-SFH SP IE may be changed only in a superframe having SFNs in which the 'SFN mod S-SFH change cycle' satisfies a specific number. At this time, the S-SFH change period should be an integer multiple of the value expressed by the number of superframes the transmission period of the S-SFH SP IE. For example, if the S-SFH change cycle of the S-SFH SP1 IE is 4 and the S-SFH SP1 IE can be changed for each superframe that satisfies the 'SFN mod S-SFH change cycle = 1', the S-SFH The SP1 IE may be changed in a superframe with SFNs of 1, 5, 9, and 13, and the like.

Referring back to FIG. 2, the terminal receives the P-SFH IE including the S-SFH change count field (S220). The S-SFH change count field indicates a change count, that is, a version, of S-SFH SP IEs transmitted in the current S-SFH change period. If at least one of the S-SFH SP IEs is changed, the number of S-SFH changes is increased.

At this time, since the UE knows the S-SFH change cycle, whenever the validity check of the S-SFH SP IEs stored by the UE is decoded, the P-SFH IE is decoded to determine the S-SFH change count field of the P-SFH SP IE. The value and the number of S-SFH modifications stored by the terminal can be compared.

If the number of S-SFH changes can be changed only in specific superframes determined according to the change period and SFN, the UE can calculate a superframe in which the number of S-SFH changes can be changed using the SFN and the S-SFH change period. have.

The UE operating in the normal mode may determine whether the S-SFH SP IEs are changed by decoding the P-SFH IE in the calculated superframe.

The UE operating in the sleep mode transmits the P-SFH including the number of S-SFH changes immediately before the listening window when the calculated superframe is included in the sleep window. Wake up at a superframe and receive a P-SFH IE. For example, if there are superframes z and z + n in which the number of S-SFH changes can be changed in the sleep period, the UE does not occur in superframe z but wakes up in superframe z + n to receive the P-SFH IE. can do. If the calculated superframe is not included in the sleep window, it does not need to occur. This is because the base station can change the S-SFH IE only once within the aforementioned change period. That is, it means that the S-SFH IE has not been changed while the terminal is in the sleep period.

The terminal receives and updates the S-SFH SP IE (S230).

If the value of the S-SFH change count field of the P-SFH SP IE and the S-SFH change count stored by the UE are different, the UE receives and updates at least one of the S-SFH SP IEs, and the P-SFH SP IE If the value of the S-SFH change count field of the S-SFH change count stored in the terminal is the same, the terminal does not decode the S-SFH SP IE until the value of the S-SFH change count is changed.

If the difference between the value of the S-SFH change count field of the P-SFH SP IE and the S-SFH change count stored by the UE is 1, the UE determines the S-SFH SP change bitmap (S-SFH) of the P-SFH SP IE. Receive and update only the S-SFH SP IE with bit of SP change bitmap). The S-SFH SP change bitmap indicates whether each of the plurality of S-SFH SP IEs is changed. That is, if the S-SFH SP change bitmap field is 'XYZ', Z indicates whether the S-SFH SP1 is changed, Y indicates whether the S-SFH SP2 is changed, and X indicates whether the S-SFH SP3 is changed. Can be represented. For example, if Z is 1, S-SFH SP1 is changed, 0 is S-SFH SP1 is not changed, Y is 1 is S-SFH SP2 is changed, and 0 is S-SFH SP2 is changed. 1 indicates that S-SFH SP3 has changed and 0 indicates that S-SFH SP3 has not changed.

If the difference between the S-SFH change count field of the P-SFH SP IE and the S-SFH change count stored by the UE is greater than 1, the UE receives and updates all S-SFH SP IEs.

The terminal applies the content included in the changed S-SFH SP IE from a specific time point (S240).

When the S-SFH SP IE is changed, the base station and the terminal apply the content included in the changed S-SFH SP IE from a specific time point.

In the embodiment of the present invention, six methods for determining a specific time point for applying the content included in the changed S-SFH SP IE are proposed.

First, a first method of determining a specific time point to apply the content included in the changed S-SFH SP IE will be described. According to the first method, the content included in the changed S-SFH SP IE is applied from the specific superframe determined by the superframe in which the S-SFH SP IE is changed. That is, after a predetermined number of regularly scheduled transmissions of the changed S-SFH SP IE from the superframe determined by the above-mentioned calculation formula, the content included in the changed S-SFH SP IE in the immediately following superframe may be applied. have. This is to ensure the time for which UEs can receive the changed S-SFH SP IE. In this case, the predetermined number of times may be predefined as a fixed value, or may be dynamically determined by the base station.

For example, if the S-SFH SP1 IE is changed, after two regularly scheduled transmissions of the changed S-SFH SP1 IE from after the S-SFH change count field is increased by one in the superframe determined by the above-mentioned calculation formula. In the immediately following superframe, the content included in the changed S-SFH SP IE may be applied. If the S-SFH SP2 IE is changed, the next time after the two regularly scheduled transmissions of the changed S-SFH SP2 IE from the S-SFH change count field is increased by one in the superframe determined by the above-mentioned calculation formula. Content included in the S-SFH SP IE changed in the superframe may be applied. When the S-SFH SP3 IE is changed, the next time after one regularly scheduled transmission of the changed S-SFH SP3 IE, since the S-SFH change count field is increased by one in the superframe determined by the above-mentioned calculation formula. Content included in the S-SFH SP IE changed in the superframe may be applied.

In addition, when a plurality of S-SFH SP IEs are changed in one S-SFH change period, the information included in the changed S-SFH SP IEs is determined as described above for each of the plurality of S-SFH SP IEs. It is applied simultaneously in the later superframe. That is, after each of the plurality of S-SFH SP IEs are regularly scheduled and transmitted a predetermined number of times for each of the plurality of S-SFH SP IEs, The information contained in the S-SFH SP IE is applied simultaneously.

In addition, the base station may transmit an S-SFH application hold indicator to the UE by including the S-SFH application hold indicator in the P-SFH. The S-SFH application indicator indicates which S-SFH SP IE contents related to the number of S-SFH changes in the current superframe are applied. That is, when the S-SFH application indicator is set to 0, it indicates that the contents of the S-SFH SP IEs related to the number of S-SFH changes included in the P-SFH transmitted in the current superframe are applied in the current superframe, and the S-SFH If the application indicator is set to 1, it may indicate that the contents of the S-SFH SP IEs related to (the number of S-SFH changes included in the P-SFH transmitted in the current superframe-1) are applied in the current superframe.

3 is a diagram illustrating an application time point when one S-SFH SP IE is changed in one transmission period.

3 shows that the S-SFH change period is 16, the S-SFH SP1 IE is changed, and the changed S-SFH SP1 IE is changed after the S-SFH change count field is increased by one in the superframe determined by the above-mentioned calculation formula. This is a case where the content included in the changed S-SFH SP1 IE is applied to the next superframe after being transmitted twice.

In FIG. 3, CC indicates the number of S-SFH changes, CB indicates the S-SFH SP change bitmap, SI indicates S-SFH scheduling information, and Flag indicates an S-SFH application indicator, and is included in the P-SFH IE and transmitted. In addition, the S-SFH count being applied indicates the number of S-SFH changes related to the S-SFH SP IEs applied in the corresponding superframe, and is not included in the P-SFH IE.

In FIG. 3, the number of S-SFH changes is changed from 0 to 1 in the superframe with SFN 16 determined by the above-mentioned calculation formula, and the S-SFH SP change bitmap is set to '001' to S-SFH SP1. Indicates that the IE has changed. The modified S-SFH SP1 IE is transmitted in superframes having SFNs of 17 and 19. The changed content of the S-SFH SP1 IE is applied from the superframe having the SFN of 20.

4 is a diagram illustrating an application time point when a plurality of S-SFH SP IEs are changed in one S-SFH change cycle.

4 shows that the S-SFH change period is 16, and the S-SFH SP1 IE and the S-SFH SP2 IE are changed and changed after the S-SFH change count field is increased by 1 in the superframe determined by the above-mentioned calculation formula. The next superframe and the changed S-SFH SP2 IE immediately after the transmission of the S-SFH SP1 IE twice. Indicates that the included content is applied at the same time.

In FIG. 4, the number of S-SFH change times is changed from 0 to 1 in a superframe with SFN 16 determined by the above-mentioned calculation formula, and the S-SFH SP change bitmap is set to '011' so that S-SFH SP1 Indicates that the IE and S-SFH SP2 IE have changed. The modified S-SFH SP1 IE is transmitted in superframes with SFNs 17 and 19, and the modified S-SFH SP2 IE is transmitted in superframes with 18 and 22 SFNs. Therefore, the next superframe after the transmission of the modified S-SFH SP1 IE twice is a superframe with 20 SFNs, and the next superframe after the transmission of the modified S-SFH SP2 IE 2 times is a superframe with 23 SFNs. to be. Accordingly, the contents of the modified S-SFH SP1 IE and S-SFH SP2 IE are applied from the superframe with SFN of 23 and the superframe with SFN of 23 with the SFN of 23.

Next, a second method of determining a specific time point to apply the content included in the changed S-SFH SP IE will be described. According to the second method, the base station informs UEs of a change in S-SFH SP IEs to a specific reference point, and informs application time using a flag. And, the modified S-SFH SP1 IEs are simultaneously applied at the application time indicated through the flag.

The specific reference point may be superframes satisfying 'SFN mod x = 0'. In this case, when the S-SFH change period is expressed in time units (ms), x is an S-SFH change period / 20 ms, and the S-SFH SP IE is transmitted during the S-SFH change period. When expressed as the total number, x is the transmission period / 20 of the S-SFH change period * S-SFH SP IE, and when the S-SFH change period is expressed in units of superframes, x is the S-SFH change period.

Table 4 shows a flag according to the second method when the S-SFH change cycle is expressed as the total number of S-SFH SP IEs transmitted during the S-SFH change cycle.

Flag Description 00 Apply at current superframe 01 Applied from the point {(change cycle * transmission cycle of S-SFH SP1 IE / 20ms) / 4} away from a specific reference point 10 Applied from the point {(change cycle * transmission cycle of S-SFH SP1 IE / 20ms) / 2} away from a specific reference point 11 Applied from the point {(change cycle * transmission cycle of S-SFH SP1 IE / 20ms)-1} away from a specific reference point

5 is a view showing an application time point according to the second method.

5 shows a case where the S-SFH change cycle is 32 superframes.

In FIG. 5, specific reference points are superframes with SFNs of 32 and 64, the number of S-SFH changes is changed to 1 in a superframe with SFNs of 32, and the S-SFH SP change bitmap is set to 011 to S- Indicates that the SFH SP1 IE and the S-SFH SP2 IE have been changed. In addition, since the flag is 10, the contents of the S-SFH SP1 IE and the S-SFH SP2 IE whose SFNs, which are 16 superframes apart from the specific reference point, are changed from the 48th superframe.

In the superframe with SFN 64, the S-SFH change count is changed to 2, and the S-SFH SP change bitmap is set to 001 to indicate that the S-SFH SP1 IE is changed. In addition, since the flag is 01, the content of the S-SFH SP1 IE whose SFN, which is a point separated by 8 superframes from a specific reference point from the 72-day superframe, is applied.

When the terminal having the S-SFH change count stored 0 receives the S-SFH change count 1 through the P-SFH, the UE may know that the S-SFH SP IE has been changed. Since the difference between the number of S-SFH changes stored by the UE and the number of S-SFH changes received through the P-SFH is 1, the UE checks the S-SFH change bitmap and checks the S-SFH SP1 IE and the S-SFH SP2 IE. You can see that has changed. Accordingly, the terminal receives the changed S-SFH SP1 IE and the S-SFH SP2 IE when the S-SFH SP1 IE and the S-SFH SP2 IE are transmitted. In addition, the flag can be checked to find out when the modified S-SFH SP1 IE and the S-SFH SP2 IE are applied.

When the terminal having the S-SFH change count stored 0 receives the S-SFH change count 2 through the P-SFH, the UE may know that the S-SFH SP IE has been changed. The UE must receive all S-SFH SP IEs because the difference between the number of S-SFH changes stored in the terminal and the number of S-SFH changes received through the P-SFH is two. In addition, the UE checks the S-SFH change bitmap and recognizes that the S-SFH SP IE changed in the corresponding S-SFH change period is the S-SFH SP1 IE. In addition, the flag confirms the application time of the changed S-SFH SP1 IE, and it can be seen that the S-SFH SP2 IE and the S-SFH SP3 IE are already applied.

Next, a third method of determining a specific time point to apply the content included in the changed S-SFH SP IE will be described. According to the third method, the base station informs the terminals of the change of each of the S-SFH SP IEs within the S-SFH change period, and informs the application time using a flag. And, the modified S-SFH SP IEs are applied simultaneously at the application time indicated through the flag. In this case, whether to change each of the S-SFH SP IEs may inform the UEs in the superframe in which each S-SFH SP IE changed within the S-SFH change period is transmitted first.

The specific reference point is determined in the same manner as described in the second method, and the meaning of the flag is the same as in Table 4.

6 is a diagram illustrating an example of an application time point according to a third method.

6 shows a case where the S-SFH change cycle is 32 superframes.

In FIG. 6, specific reference points are superframes with SFNs 32 and 64, and the S-SFH change in a superframe with SFN 33, which is a superframe in which the changed S-SFH SP1 IE is transmitted first within the S-SFH change period. The number of times was changed to 1 and the S-SFH SP change bitmap is set to 001 to indicate that the S-SFH SP1 IE has been changed. The number of S-SFH changes is changed to 2 and the S-SFH SP change bitmap is 010 in a superframe in which SFN is 34, the first superframe to which the changed S-SFH SP2 IE is transmitted within the S-SFH change period. It is set to indicate that the S-SFH SP2 IE has been changed. Since the flag is 10, the changed contents of the S-SFH SP1 IE and the S-SFH SP2 IE are applied from a point separated by 16 superframes from the specific reference point.

The terminal operating in the sleep mode has a listening section where the S-SFH SP1 IE, S-SFH SP2 IE and S-SFH SP3 IE are transmitted first in the section before the S-SFH SP1 IE and S-SFH SP2. You can find out whether IE 2 and S-SFH SP3 IE have changed. For example, a UE having a listening period at a point having a superframe number of 43 is a change in S-SFH SP3 IE in superframe 32, a change in S-SFH SP1 IE in superframe 33, and a S in superframe 34. -You can check the change of SFH SP2 IE. The UE may know that the S-SFH SP1 IE and the S-SFH SP2 IE 2 have been changed, and the contents of the changed S-SFH SP1 IE and the S-SFH SP2 IE are applied from a point separated by 16 superframes from a specific reference point. have.

7 is a diagram illustrating another example of an application time point according to a third method.

7 illustrates a case where an S-SFH change cycle is 32 superframes.

In FIG. 7, when the number of S-SFH changes is increased for the first time within one S-SFH change period, only the bit corresponding to the changed S-SFH SP IE of the S-SFH SP change bitmap is set to 1. If the number of S-SFH changes increases in the corresponding S-SFH change period, the bit corresponding to the currently changed S-SFH SP IE of the S-SFH SP change bitmap is additionally set to 1.

In FIG. 7, if the S-SFH SP1 IE is changed in a superframe having an SFN of 5, the S-SFH SP change bitmap is set to 001. In addition, if the S-SFH SP2 IE is changed in a superframe having an SFN of 10, the S-SFH SP change bitmap is set to 011.

Next, a fourth method of determining a specific time point to apply the content included in the changed S-SFH SP IE will be described. According to the fourth method, a flag may be interpreted in different meanings according to superframes. The contents included in the changed S-SFH SP IE are simultaneously applied according to the corresponding flag value.

Table 5 shows the meaning of the flags according to the fourth method.

Flag Flag semantics in superframes where no changed SP is transmitted Flag semantics in superframe in which modified SP is transmitted 00 S-SFH count is applied in the current superframe Apply to current superframe 01 S-SFH count-1 is applied in the current superframe Applied from the point where {change cycle * SP1 periodic information / 20ms) / 4} is separated from a specific reference point 10 S-SFH count-2 is applied in the current superframe Applied from the point where {change cycle * SP1 periodic information / 20ms) / 2} is separated from a specific reference point 11 S-SFH count-3 is applied in the current superframe Applied from the point away from the specific reference point by {change cycle * SP1 periodic information / 20ms)-1}

When the number of S-SFH change is increased for the first time within one S-SFH change period, only the bit corresponding to the changed S-SFH SP IE of the S-SFH SP change bitmap is set to one. If the number of S-SFH changes increases in the corresponding S-SFH change period, the bit corresponding to the currently changed S-SFH SP IE of the S-SFH SP change bitmap is additionally set to 1.

8 illustrates an application time point according to a fourth method.

8 shows a case where an S-SFH change cycle is 32 superframes.

In FIG. 8, if the S-SFH SP1 IE is changed in a superframe having an SFN of 5, the S-SFH SP change bitmap is set to 001. In addition, if the S-SFH SP2 IE is changed in a superframe having an SFN of 10, the S-SFH SP change bitmap is set to 011. Since the flag is 10, the changed contents of the S-SFH SP1 IE and the S-SFH SP2 IE are applied from a point separated by 16 superframes from the specific reference point.

If the SFN of the current superframe is larger than the SFN of the application time indicated by the flag, it means that the changed S-SFH SP IE is already applied.

The flag of the superframe in which the S-SFH SP IE is transmitted, which causes the increase in the number of S-SFH changes within one S-SFH change period, indicates the application time of the changed S-SFH SP IE. In addition, a flag of a superframe in which the remaining S-SFH SP IEs and a superframe in which the S-SFH SP IE is not transmitted indicates the number of S-SFH changes related to the S-SFH SP IEs currently applied in the superframe. .

In FIG. 8, the hatched portion represents a superframe in which the flag indicates the number of S-SFH changes associated with the S-SFH SP IEs currently being applied in the superframe.

And, if the S-SFH change cycle interval is different, the flag indicates the number of S-SFH changes associated with the S-SFH SP IEs currently applied in the superframe until the number of S-SFH changes is increased.

Next, a fifth method of determining a specific time point to apply the content included in the changed S-SFH SP IE will be described. According to the fifth method, a flag may be interpreted in a different meaning according to a superframe, and the base station transmits whether each changed S-SFH SP IE is transmitted within the S-SFH change period whether or not each of the S-SFH SP IEs is changed. UEs are informed in the superframe, and the application time is informed using a flag. Each of the modified S-SFH SP IEs is applied independently at the application time indicated through each flag value.

In the fifth method, specific reference points are determined in the same way as described in the second method.

When the number of S-SFH change is increased for the first time within one S-SFH change period, only the bit corresponding to the changed S-SFH SP IE of the S-SFH SP change bitmap is set to one. If the number of S-SFH changes increases in the corresponding S-SFH change period, the bit corresponding to the currently changed S-SFH SP IE of the S-SFH SP change bitmap is additionally set to 1.

9 is a diagram illustrating an example of an application time point according to a fifth method, and the meaning of the flag is referred to Table 5 below. FIG. 10 is a diagram illustrating another example of an application time point according to a fifth method, and refer to Table 6 for a meaning of flags.

Table 6 shows the meaning of the flags used in FIG. 10 of the fifth method.

Flag Flag semantics in superframes where no changed SP is transmitted Flag semantics in superframe in which modified SP is transmitted 00 S-SFH count is applied in the current superframe All changed SPs apply to the current superframe 01 S-SFH count-1 is applied in the current superframe Applied from the point where {change cycle * SP1 periodic information / 20ms) / 4} is separated from a specific reference point 10 S-SFH count-2 is applied in the current superframe Applied from the point where {change cycle * SP1 periodic information / 20ms) / 2} is separated from a specific reference point 11 S-SFH count-3 is applied in the current superframe Applied from the point away from the specific reference point by {change cycle * SP1 periodic information / 20ms)-1}

9 and 10 show a case where the S-SFH change cycle is 32 superframes.

9 and 10, if the S-SFH SP1 IE is changed in the superframe with SFN 5, the S-SFH SP change bitmap is set to 001. In addition, if the S-SFH SP2 IE is changed in a superframe having an SFN of 10, the S-SFH SP change bitmap is set to 011.

If the SFN of the current superframe is larger than the SFN of the application time indicated by the flag, it means that the changed S-SFH SP IE is already applied.

The flag of the superframe in which the S-SFH SP IE is transmitted, which causes the increase in the number of S-SFH changes within one S-SFH change period, indicates the application time of each changed S-SFH SP IE. In addition, a flag of a superframe in which the remaining S-SFH SP IEs and a superframe in which the S-SFH SP IE is not transmitted indicates the number of S-SFH changes related to the S-SFH SP IEs currently applied in the superframe. .

In FIG. 9, the hatched portion represents a superframe in which the flag indicates the number of S-SFH changes associated with the S-SFH SP IEs currently being applied in the superframe.

In FIG. 10, after each changed S-SFH SP IE is applied, a flag indicates the number of S-SFH changes associated with S-SFH SP IEs currently applied to a superframe. That is, in FIG. 10, the flag is set to 0 from the superframe in which the contents of the S-SFH SP1 IE have been applied since SFN 8 and the S-SFH SP1 IE has been transmitted from the SFN. Since all the changed S-SFH IEs are applied by applying the changed S-SFH SP2 IE contents in the superframe with SFN 16, all flags are set to 0 from the superframe with SFN 16.

And, if the S-SFH change cycle interval is different, the flag indicates the number of S-SFH changes associated with the S-SFH SP IEs currently applied in the superframe until the number of S-SFH changes is increased.

When the difference between the number of S-SFH changes stored by the UE and the number of S-SFH changes of the received P-SFH is 1, the UE receives only the S-SFH SP IE in which the bit of the S-SFH changed bitmap is set to 1. If the difference between the number of S-SFH changes stored by the terminal and the number of S-SFH changes of the received P-SFH is greater than 1, the terminal receives and updates all S-SFH SP IEs.

The UE can know when the changed S-SFH SP1 IE is applied through the flag of the superframe in which the S-SFH SP1 IE is applied, and the S-SFH SP2 IE is changed through the flag of the superframe in which the S-SFH SP2 IE is transmitted. It can be seen when is applied. In addition, S-SFH SP IEs related to the number of S-SFH changes in the corresponding superframe are applied through the flag of the superframe in which the S-SFH SP3 IE is transmitted and the superframe in which the S-SFH SP IE is not transmitted. Able to know.

9 and 10, since the flag of the superframe through which the changed S-SFH SP1 IE is transmitted is 01, the content of the changed S-SFH SP1 IE is applied from the superframe with 8 SFNs separated by 8 superframes from a specific reference point. Since the flag of the superframe through which the S-SFH SP2 IE is transmitted is 10, the changed content of the S-SFH SP2 IE is applied from the superframe with 16 SFNs separated by 16 superframes from a specific reference point.

Since the S-SFH SP1 IE and the S-SFH SP2 IE include permutation information and are related to them, the number of S-SFH changes that the terminal stores and the S-SFH change of the received P-SFH In the case where the difference in the number of times is greater than 1, the terminal should communicate with the base station after confirming the application time of the S-SFH SP1 IE and the S-SFH SP2 IE. That is, the terminal should wait to confirm the S-SFH SP2 IE even if it receives the transmitted S-SFH SP1 IE and knows that it has already been applied.

Next, a sixth method of determining a specific time point to apply the content included in the changed S-SFH SP IE will be described. In the sixth method, it is assumed that each of the S-SFH SP IEs has a different S-SFH change cycle.

According to the sixth method, each time the S-SFH SP IE is changed, the base station increments the number of S-SFH changes by 1 and sets the bit corresponding to the changed S-SFH SP IE of the S-SFH SP change bitmap to 1. Set to. The bit of the S-SFH SP change bitmap corresponding to the S-SFH SP IE applied in the corresponding superframe is set to 0.

11 is a flowchart illustrating an operation of a terminal according to a sixth method.

As shown in FIG. 11, the terminal receives the P-SFH and compares the number of S-SFH changes that the terminal stores with the number of S-SFH changes of the received P-SFH. If the number of S-SFH changes stored by the UE and the number of S-SFH changes of the received P-SFH are the same, the UE does not need to decode the S-SFH SP IEs and the number of S-SFH changes stored by the UE If the number of S-SFH changes in the received P-SFH is different, the UE should decode and update the S-SFH SP IEs.

If the difference between the number of S-SFH changes stored by the UE and the number of S-SFH changes of the received P-SFH is equal to the number of bits set to 1 in the S-SFH SP change bitmap of the P-SFH, The S-SFH SP IE corresponding to the bit set to 1 of the SFH SP change bitmap may be decoded and updated. If the difference between the number of S-SFH changes stored by the UE and the number of S-SFH changes of the received P-SFH is different from the number of bits set to 1 in the S-SFH SP change bitmap of the P-SFH, the UE Receive and update all S-SFH SP IEs. In this case, when the UE can implicitly identify the changed S-SFH SP IE using the change cycle, the S-SFH SP IE corresponding to the bit set to 1 of the S-SFH SP change bitmap and the S-SFH implicitly identified. You can also decode and update only the SP IE.

The UE may know the number of S-SFH changes related to the S-SFH SP IEs currently applied using the number of S-SFH changes and the number of bits set to 1 in the S-SFH SP change bitmap. If the UE has S-SFH SP IEs being applied, it can perform normal communication with the base station, and if it does not have S-SFH SP IEs being applied, it is normal to the base station after receiving and updating the S-SFH SP IEs. Communication can be performed.

12 illustrates an example of an application time point according to a sixth method.

In FIG. 12, the base station is applying the contents of the S-SFH SP IEs related to the S-SFH change count 25 in the first superframe. The number of S-SFH changes applied in the corresponding superframe may be obtained by 'number of S-SFH changes-the number of bits set to 1 in the S-SFH SP change bitmap'. That is, the number of S-SFH modifications applied in the first superframe of FIG. 12 is 25 (25-0).

If the S-SFH SP1 IE is changed in the second superframe, the base station increases the number of S-SFH changes to 26 and sets the S-SFH SP change bitmap to 001. Therefore, the number of S-SFH modifications applied in the second, third, and fourth superframes is 25 (26-1).

In FIG. 12, the content of the changed S-SFH SP1 IE is applied from the next superframe immediately after the changed S-SFH SP1 IE is transmitted twice. This is to apply the contents of the changed S-SFH SP1 IE after the changed S-SFH SP IE is transmitted a predetermined number of times in order to ensure the time for the terminals to receive the changed S-SFH SP IE. In this case, the predetermined number of times may be defined as a predetermined value or may be dynamically determined by the base station. Therefore, the content of the S-SFH SP1 IE changed in the fifth superframe is applied.

In addition, since the base station sets a bit corresponding to the changed S-SFH SP IE of the S-SFH SP change bitmap to 0 at the time when the changed S-SFH SP IE is applied, the S-SFH SP change bitmap is the fifth super. It is set to 000 in the frame.

In FIG. 12, it is assumed that the number of S-SFH changes stored by the UE in the first superframe is 25. The UE determines the number of S-SFH changes applied in the first superframe using the number of S-SFH changes in the first superframe and the number of bits set to 1 in the S-SFH SP change bitmap.

The UE determines that the S-SFH SP IEs have not changed since the UE compares the number of S-SFH changes received in the first superframe with the number of S-SFH changes stored by the UE. Since the number of S-SFH changes is 25 and the number of bits set to 1 in the S-SFH SP change bitmap is 0, it can be seen that the number of S-SFH changes applied in the first superframe is 25.

In the second superframe, the UE knows that the difference between the number of S-SFH changes received and the number of S-SFH changes stored by the UE is 1, and it is known that the S-SFH SP IE is changed. The S-SFH SP change bitmap indicates that the S-SFH SP1 IE has been changed, and the number of S-SFH changes applied is 25 (26-1).

In the fifth superframe, the UE may know that the applied count is 26 (26-0).

13 is a diagram illustrating another example of an application time point according to a sixth method.

In the first superframe, the base station sets the S-SFH change count to 26, which is increased by 1 to change the S-SFH SP1 IE, and the S-SFH SP change bitmap is set to 001. The number of S-SFH modifications applied in the first superframe is 25 (26-1).

If the S-SFH SP2 IE is changed in the second superframe, the base station sets the S-SFH change count to 27, which is increased by 1, and the S-SFH SP change bitmap is set to 011. The number of S-SFH changes applied to the second, third, and fourth superframes is 25 (27-2).

When simultaneously applying the contents of the changed S-SFH SP1 IE and S-SFH SP2 IE, the base station sets the S-SFH SP change bitmap to 000 in the fifth superframe. Accordingly, the number of S-SFH changes applied in the fifth superframe is 27 (27-0).

Alternatively, the base station may apply the contents of the modified S-SFH SP1 IE and the S-SFH SP2 IE at different times.

14 shows another example of an application time point according to a sixth method.

In the first superframe, the base station sets the S-SFH change count to 27, which is increased by 2 to change the S-SFH SP1 IE and the S-SFH SP2 IE, and the S-SFH SP change bitmap is set to 011. The number of S-SFH modifications applied to the first superframe is 25 (27-2).

When simultaneously applying the contents of the changed S-SFH SP1 IE and S-SFH SP2 IE, the base station sets the S-SFH SP change bitmap to 000 in the fifth superframe. Accordingly, the number of S-SFH changes applied in the fifth superframe is 27 (27-0).

In the above, the case where S-SFH SP IEs are transmitted in a regularly scheduled transmission period is described. However, S-SFH SP IEs may be transmitted additionally irregularly in addition to the regularly scheduled transmission period.

15 is a diagram illustrating that an S-SFH SP2 IE is transmitted irregularly.

In this case, the S-SFH SP IE that is irregularly transmitted may be limited to the changed S-SFH SP IE. In addition, when a plurality of S-SFH SP IEs are changed at the same time, the S-SFH SP IE that is transmitted irregularly may be an S-SFH SP IE having the longest transmission period among the plurality of S-SFH SP IEs.

However, the UE may not know that the irregular transmission of the S-SFH SP IE is an irregular transmission.

If the UE does not receive the transmission cycle information through the S-SFH SP3 IE, it can implicitly determine the transmission period from the point of irregular reception of the S-SFH SP IE to the next receiving point of the S-SFH SP IE. have. Then, the terminal may incorrectly determine the transmission cycle of the S-SFH SP IE.

When the UE receives the transmission period information through the S-SFH SP3 IE, it is determined that the S-SFH SP IE will be transmitted a point separated by the transmission period from the time of the irregular reception of the S-SFH SP IE. Therefore, a problem may occur in which the terminal incorrectly determines the transmission time of the S-SFH SP IE.

Therefore, in the embodiment of the present invention, four methods are proposed to prevent the UE from incorrectly determining the transmission period of the S-SFH SP IE or the transmission time of the S-SFH SP IE due to the irregular transmission of the S-SFH SP IE. .

According to the first method, the UE checks the P-SFH until the UE receives S-SFH SP IEs having the same transmission period.

According to the second method, the base station explicitly informs whether the S-SFH is regularly transmitted or irregular through the P-SFH.

According to the third method, the base station explicitly informs whether the S-SFH SP IE is regularly transmitted or irregular through each S-SFH SP IE.

According to the fourth method, a specific value (0b1111) is used to indicate that an irregular transmission is made among transmission period information of each S-SFH SP IE. At this time, the specific value is predefined or the base station needs to inform the terminals in advance.

According to the fifth method, a specific value (0b1111) is used to indicate that an irregular transmission is made among the S-SFH SP scheduling information transmitted through the P-SFH.

Two or more of the five methods described above may be applied simultaneously.

The modified S-SFH SP IE may be applied immediately after being transmitted N times in a regular period. At this time, the irregular transmission is not included in N transmissions.

If the difference between the number of S-SFH changes that the terminal has and the number of S-SFH changes delivered through the P-SFH is 2 or more and the changed S-SFH SP IE is the S-SFH SP3 IE, the terminal is applied with the changed information. The timing should be clear. That is, since the transmission period may be changed in the changed S-SFH SP3 IE, the terminal should monitor the P-SFH until the application time information transmitted through the P-SFH is applied.

FIG. 16 is a diagram illustrating the configuration of a mobile station and a base station in which embodiments of the present invention described above can be implemented as another embodiment of the present invention.

The mobile station (AMS) and the base station (ABS) are an antenna capable of transmitting and receiving information, data, signals, and / or messages, a transmitting module for controlling a antenna and transmitting a message, and a receiving module for controlling a antenna and receiving a message. And a communication module 520 and 530, memory 560 and 570 for storing information related to communication, and a central processing unit (CPU) 540 and 550 for controlling the communication module and the memory, respectively. .

The CPUs 540 and 550 typically control the overall operation of the mobile terminal or base station. In particular, the CPU performs a control function for performing the above-described embodiments of the present invention, a medium access control (MAC) frame variable control function, a handover function, an authentication and encryption function, etc. according to service characteristics and a propagation environment. Can be done. In addition, the processors 540 and 550 may further include an encryption module for controlling encryption of various messages and a timer module for controlling transmission and reception of various messages, respectively.

The CPU 550 of the terminal receives at least one S-SFH SP IE among the plurality of S-SFH SP IEs when the number of S-SFH changes of the P-SFH IE is different from the number of S-SFH changes stored by the terminal. To update.

The transmission module may perform a predetermined coding and modulation on the signal and / or data scheduled from the processor and transmitted to the outside, and then may transmit the signal to the antenna. The receiving module may decode and demodulate the radio signal received through the antenna from the outside, restore the original data, and transmit the decoded module to the CPU.

The transmitting module of the base station transmits the P-SFH IE including the first field indicating the S-SFH change cycle and the number of changes of the plurality of S-SFH SP IEs to the terminal.

The receiving module of the terminal receives from the base station a P-SFH IE including a S-SFH change cycle and a first field indicating the number of changes of the plurality of S-SFH SP IEs.

The memory 560, 570 may store a program for processing and controlling the processor, and input / output data (in the case of a mobile station, an uplink grant (UL grant), system information, and station identifier allocated from a base station) STID), flow identifier (FID), action time (Action Time), area allocation information, frame offset information, etc.) may be temporarily stored.

In addition, the memory may be a flash memory type, a hard disk type, a multimedia card micro type, a card type memory (for example, SD or XD memory), RAM Random Access Memory (RAM), Static Random Access Memory (SRAM), Read-Only Memory (ROM), Electrically Erasable Programmable Read-Only Memory (EEPROM), Programmable Read-Only Memory (PROM), Magnetic Memory, Magnetic It may include a storage medium of at least one type of disk, optical disk.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The foregoing description of the preferred embodiments of the invention disclosed herein has been presented to enable any person skilled in the art to make and use the present invention. While the present invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. For example, those skilled in the art can utilize each of the configurations described in the above-described embodiments in a manner of mutually combining them.

Accordingly, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (25)

In the method of receiving system information at a terminal of a wireless communication system,
Receiving a secondary SFH (S-SFH) change period from a base station; And
A primary SFH information element including a first field indicating a number of changes of a plurality of secondary super frame header subpacket information elements (S-SFH SP IEs) from the base station; Receiving a P-SFH IE),
And each of the plurality of S-SFH SP IEs is not changed during one or more S-SFH change periods once changed. The method of claim 1,
The value of the first field may be changed only in a superframe in which a remainder obtained by dividing a superframe number (SFN) by the S-SFH change period is a predetermined number. The method of claim 1,
And the S-SFH change period is transmitted through one of the plurality of S-SFH SP IEs. The method of claim 1,
Receiving and updating at least one S-SFH SP IE among the plurality of S-SFH SP IEs if the value of the first field and the number of S-SFH changes stored by the terminal are different; How to receive information. The method of claim 4, wherein
The updating may include: S-SFH SP change bitmap included in the P-SFH SP IE when the difference between the value of the first field and the number of S-SFH changes stored by the UE is 1; change and receive only the S-SFH SP IE having a bit of 1) and update it,
And the S-SFH SP change bitmap indicates whether each of the plurality of P-SFH SP IEs is changed. The method of claim 4, wherein
The updating may include receiving and updating all of the plurality of S-SFH SP IEs when the difference between the value of the first field and the number of S-SFH changes stored by the terminal is greater than one. How to receive information. The method of claim 4, wherein
Each of the at least one S-SFH SP IE is regularly scheduled for a predetermined number of times for each of the at least one S-SFH SP IE, and then at least in the latest superframe of the next superframes immediately after the transmission. And simultaneously applying information included in one S-SFH SP IE. The method of claim 1,
The P-SFH IE further includes a second field indicating S-SFH SP IEs applied in a superframe in which the P-SFH IE is transmitted. In the method of transmitting system information in a base station of a wireless communication system,
Transmitting a secondary superframe header (secondary SFH, S-SFH) change cycle to the terminal; And
A primary SFH information element including a first field indicating a number of changes of a plurality of secondary super frame header subpacket information elements (S-SFH SP IEs) to the terminal; , P-SFH IE),
And each of the plurality of S-SFH SP IEs is not changed during one or more S-SFH change periods once changed. 10. The method of claim 9,
The value of the first field may be changed only in a superframe in which a remainder obtained by dividing a superframe number (SFN) by the S-SFH change period is a predetermined number. 10. The method of claim 9,
The S-SFH change period is transmitted via one of the plurality of S-SFH SP IEs. 10. The method of claim 9,
The terminal, if the value of the first field and the number of S-SFH changes stored by the terminal are different, transmits system information for receiving and updating at least one S-SFH SP IE among the plurality of S-SFH SP IEs. Way. The method of claim 12,
If the difference between the value of the first field and the number of S-SFH changes stored by the terminal is 1, the terminal includes an S-SFH SP change bitmap included in the P-SFH SP IE. System information transmission method, characterized in that for receiving and updating only the S-SFH SP IE bit 1). The method of claim 12,
The terminal receives and updates all of the plurality of S-SFH SP IEs when the difference between the value of the first field and the number of S-SFH changes stored by the terminal is greater than one. Way. 10. The method of claim 9,
The P-SFH IE further includes a second field indicating S-SFH SP IEs applied in a superframe in which the P-SFH IE is transmitted. In a terminal of a wireless communication system,
A first field indicating a number of changes of a secondary SFH (S-SFH) change period and a plurality of secondary super frame header subpacket information elements (S-SFH SP IEs) from the base station; Receiving module for receiving a primary SFH information element (P-SFH IE) including a,
Wherein each of the plurality of S-SFH SP IEs is not changed during one or more S-SFH change periods once changed. The method of claim 16,
The value of the first field may be changed only in a superframe in which a remainder obtained by dividing a superframe number (SFN) by the S-SFH change period is a predetermined number. The method of claim 16,
The S-SFH change period is characterized in that the terminal is transmitted through one of the plurality of S-SFH SP IEs. The method of claim 16,
Central processing unit for receiving and updating at least one S-SFH SP IE among the plurality of S-SFH SP IEs when the value of the first field is different from the number of S-SFH changes stored by the terminal; unit, CPU) further comprising. The method of claim 19,
The CPU is the latest superframe of the next superframes immediately after each of the at least one S-SFH SP IE is regularly scheduled and transmitted a predetermined number of times for each of the at least one S-SFH SP IE. The terminal characterized in that to simultaneously apply the information contained in the at least one S-SFH SP IE. In a base station of a wireless communication system,
First field indicating a change cycle of secondary SFH (S-SFH) and a plurality of secondary super frame header subpacket information elements (S-SFH SP IE) A transport module for transmitting a primary superframe header information element (P-SFH IE) including a,
And wherein each of the plurality of S-SFH SP IEs is not changed during one or more S-SFH change periods once changed. The method of claim 21,
And the value of the first field may be changed only in a superframe in which a remainder obtained by dividing a superframe number (SFN) by the S-SFH change period is a predetermined number. The method of claim 21,
The S-SFH change period is transmitted via one of the plurality of S-SFH SP IEs. In a terminal of a wireless communication system,
A central processing unit (CPU) for controlling the operation of the terminal;
A memory that stores information related to communication with a base station; And
A communication module for controlling communication with the base station,
The communication module may change a secondary SFH (S-SFH) change cycle and a plurality of secondary super frame header subpacket information elements (S-SFH SP IEs) from the base station. A receiving module for receiving a primary SFH information element (P-SFH IE) including a first field indicating a, wherein each of the plurality of S-SFH SP IEs is changed once Terminal which is not changed during the above S-SFH change cycle period. In a base station of a wireless communication system,
A central processing unit (CPU) for controlling the operation of the base station;
A memory for storing information related to the communication; And
A communication module for controlling communication,
The communication module informs the terminal of the number of changes of secondary superframe header (S-SFH) and a plurality of secondary super frame header subpacket information elements (S-SFH SP IE). A transport module for transmitting a primary SFH information element (P-SFH IE) including a first field indicating, wherein each of the plurality of S-SFH SP IEs is changed one or more times; The base station, which is not changed during the S-SFH change period period.

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