KR100617818B1 - Method and device for transmitting data and method and device for receiving data in Broadband wireless communication system - Google Patents

Abstract

The present invention provides a method of transmitting a Medium Access Control (MAC) Protocol Data Unit (PDU) in a broadband wireless communication system, wherein the packing and fragmentation of one MAC PDU are compiled at the same time. Including the information in the Generic MAC Header (GMH), and the header of the last SDU included in the MAC PDU as FSH (Fragmentation Sub-Header) and the FSH Fragment Control (FC) of the SDU (Service Data Unit) Setting to indicate that is the last CSDU or SSDU of the corresponding MAC PDU, and transmitting the MAC PDU.

MAC SDU, MAC PDU

Description

Method and device for transmitting data and method and device for receiving data in Broadband wireless communication system}             

1 is a block diagram illustrating a general broadband wireless communication system;

2 is a diagram illustrating a protocol stack structure of a subscriber station in a general broadband wireless communication system;

3 is a diagram illustrating a structure of a general MAC PDU;

4 is a view showing the structure and contents of GMH proposed in the 802.16REVd / D4 standard;

5A and 5B illustrate a MAC PDU formed according to the prior art,

6 illustrates a MAC PDU according to an embodiment of the present invention;

7 illustrates a transmission apparatus according to an embodiment of the present invention;

8 is a diagram showing a transmission method according to an embodiment of the present invention;

9 is a view showing a receiving apparatus according to an embodiment of the present invention;

10 is a view showing a receiving method according to an embodiment of the present invention;

11A and 11B illustrate the structure of a MAC PDU constructed in accordance with the present invention.

The present invention relates to a data transmission method and apparatus and a data receiving method and apparatus in a broadband wireless communication system.

1 is a diagram illustrating a configuration of a general broadband wireless communication system. Referring to FIG. 1, each Subscriber Station (SS) 10, 12 is generally mobile and is connected to a backbone network 30 via a Base Station (BS) 20, 22, respectively. SS (10, 12) allows the connection between the BS (10, 22) and the subscriber. Base stations (BSs) 20 and 22 provide control, management, and connectivity to SSs 10 and 12.

In addition, the backbone network 30 is connected to an Authentication and Service Authorization Server (ASA) 40 for authentication and service authentication of the SSs 10 and 12. Each SS 10 and 12 has a medium access control (MAC) layer and a physical (PHY) layer. The protocol stack of the SS (10, 12) will be described with reference to FIG.

2 is a diagram illustrating a protocol stack structure of a subscriber station in a general broadband wireless communication system. Referring to FIG. 2, the upper layer 130 transfers a data packet from a service provider, a private IP network, or the like to a service specific convergence sub-layer (CS) 124 of the MAC layer 120. There is a CS Service Access Point (CS SAP) between the upper layer 130 and the CS 124 which is the highest layer of the MAC layer 120.

The CS 124 converts the data packet into a MAC Service Data Unit (SDU) and then transfers it to the MAC Common Part Sub-layer (CPS) 122. The MAC CPS 122 converts the MAC SDU into a MAC protocol data unit (PDU) and transfers the MAC SDU to the PHY layer 110. However, when the MAC SDU is converted into a MAC PDU for transmission, the size may be smaller or larger than the size of the MAC PDU defined to be suitable for transmission. Accordingly, in the process of forming the MAC PDU, a packing or fragmentation process is required.

If the size of each MAC SDU to be transmitted is smaller than the size of the MAC PDU, packing processing is performed to include a plurality of MAC SDUs in one MAC PDU. Packing refers to an operation of collecting a plurality of MAC SUDs in a CPS to form one MAC PDU. In this case, when each MAC SDU has a different size, each MAC SDU packed in the same MAC PDU is prefixed with a PSH (Packing Subheader). In FIG. 2B, the SDUs 150, 152 are packed into one PDU 154.

In addition, when the size of the MAC SDU to be transmitted is larger than the size of the MAC PDU, the fragmentation process is performed such that one MAC SDU is divided into several MAC PDUs. Fragmentation refers to an operation in which one MAC SDU is separated into two or more MAC PDUs and transmitted for efficient use of bandwidth according to QoS requirements in the CPS. The fragmented MAC SDU included in the MAC PDU is prefixed with a fragmentation subheader (FSH). In FIG. 2B, one SDU 160 is fragmented into two PDUs 162 and 164. The two PDUs 162 and 164 each contain a fragment SDU, that is, a segmented SDU, of one SDU 160.

MAC PDUs configured as described above are MAC PDUs having a general MAC header (GMH) and only a bandwidth request header. In the present invention, a MAC PDU that delivers a general MAC management message and user data as its payload is considered. The MAC PDU uses GMH as its MAC header. This MAC PDU is shown in FIG. 3.

3 is a diagram illustrating a structure of a general MAC PDU. Referring to FIG. 3, a generic MAC PDU 170 includes a Generic MAC header (GMH) 172, a payload 174 containing general MAC management messages and user data, and a CRC 176 for error checking. . The MAC PDU 170 does not include the CRC 176 in the case of Non ARQ-enabled connection. GMH 172 is a protocol header of a MAC PDU having a fixed length of 6 bytes. Fields of GMH currently proposed in the 802.16REVd / D4 standard are shown in FIG. 4.

4 is a diagram showing the structure and contents of GMH proposed in the 802.16REVd / D4 standard. As shown in FIG. 4, the transmitting MAC informs the receiving MAC whether a subheader included in the MAC PDU and a payload for a special purpose are present through the Type field 6 of the GMH. Among these subheaders, a packing subheader (PSH) or a fragmentation subheader (FSH) is included in a MAC PDU in which packing or fragmentation is performed. PSH and FSH contain a 2-bit fragment control (FC) field, where the FC bit indicates whether the SDU fragment is the first piece, the last piece, or somewhere in the middle of the MAC SDU. Specifically, if the FC bit is "01", the SDU is the Last MAC SDU fragment of the MAC SDU, "10" indicates that the SDU is the First MAC SDU fragment, and "11" indicates that the SDU is the middle MAC SDU fragment. If the FC bit is 00, it indicates that the MAC SDU is not fragmented.

In addition, unlike the FSH, the PSH includes a length field of 11 bits. In packing, since two or more MAC SDUs are packed in one MAC PDU, the receiving side needs to know the size of each SDU to separate the SDUs. This length field is for indicating the size of the SDU. And, unlike the PSH, the FSH includes a reserved field of 3 bits. Thus, PSH is one byte larger than FSH in size.

As such, since the transmitter performs packing and fragmentation according to circumstances, when MAC SDUs and fragmented MAC SDUs + first fragment of other MAC SDUs are combined or MAC SDUs and fragmented MACs in the same MAC PDU A case where SD + first fragment of other MAC SDUs and other MAC SDUs is combined. The transmitter informs the receiver of the configuration of the MAC PDU through the generic MAC header (GMH) and the MAC subheader.

However, the PSH (packing sub-header) and the fragmentation sub-header (FSH) must be mutually exclusive in the same MAC PDU in the same connection. Therefore, as described above, when the packed SDU and the fragmented SDU are included together in one MAC PDU, the fragmented SDU is also attached to the PSH.

5A and 5B illustrate a MAC PDU formed according to the prior art. In FIG. 5A, a MAC PDU includes several complete SDUs and a first fragment of another fragmented MAC SDU. And in FIG. 5B, the MAC PDU includes the first fragment of the fragmented MAC SDU that is different from the last fragment of one fragmented SDU.

5A and 5B, the PSHs 222, 225 or 232, 234 in one MAC PDU have an 11-bit length field as described above. This length field is used to identify the individual beginning of each Complete SDU / Segmented SDU in one MAC PDU. At this time, the length field in the last PSH in one MAC PDU becomes a problem. The receiver may calculate the size of the last CSDU / SSDU without the length field of the last PSH. However, conventionally, since the PSH and the FSH must be mutually exclusive in one MAC PDU, unnecessary header bit space is wasted.

Accordingly, the present invention provides a method and apparatus for improving traffic data rate by preventing loss of traffic data due to unnecessary header field transmission.

In order to achieve the above object of the present invention, the present invention provides a method of transmitting a medium access control (MAC) protocol data unit (PDU) in a broadband wireless communication system, wherein packing and fragmentation are simultaneously performed on one MAC PDU. If compiled, including the information in the Generic MAC Header (GMH) of the MAC PDU, and the header of the last SDU included in the MAC PDU as FSH (Fragmentation Sub-Header) and the FC of FSH ( And setting the Fragment Control to indicate that the Service Data Unit (SDU) is the last CSDU or SSDU of the MAC PDU, and transmitting the MAC PDU.

In addition, the present invention provides a method for receiving a MAC PDU in a broadband wireless communication system, the packing and fragmentation is compiled at the same time by analyzing the GMH of the received MAC PDU when receiving the MAC PDU (compiled) Determining whether the SDU with PSH is attached to the MAC PDU if the packing and fragmentation are simultaneously edited in the MAC PDU, and using the GMH to determine the last MAC SDU of the MAC PDU. Separating the last SDU by calculating the size.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

6 illustrates a MAC PDU according to an embodiment of the present invention. In the present invention, if packing and fragmentation are allowed within one MAC PDU, the last packing subheader of that MAC PDU is replaced with an appropriate fragmentation subheader. Specifically, when packing and fragmentation are compiled at the same time in one MAC PDU, when the last fragmented MAC SDU and MAC SDUs + first fragment of other MAC SDU are combined in one MAC PDU or last fragmented MAC SDU and MAC SDUs + other MAC SDUs are combined. In this case, the present invention uses the fragmentation subheader in the CSDU or SSD of the payload.

Referring to FIG. 6, according to the present invention, the MAC PDU 300 uses a type field of the GMH 301 to indicate a case in which packing and fragmentation are compiled at the same time in one MAC PDU. Referring to FIG. 4, the first bit from the LSB (Least significant bit) in the GMH type field is a bit indicating the presence or absence of a packing subheader, and the second bit is a bit indicating the presence or absence of a fragmentation subheader. . Therefore, the type field of GMH in the MAC PDU according to the present invention indicates that both the packing subheader and the fragmentation subheader are included. Therefore, the type field of GMH can be "ddd11d" (where d means don't care), where the MAC PDU contains one or more packing subheaders and one fragment for the last CSDU or SSDU. It means to include subheaders at the same time.

In order to find the FSH in the MAC PDU configured according to the present invention, the types of subheaders consecutive to the first PSH according to the FC value of the first PSH and the FC values of the subheaders subsequent thereto are shown in Table 1. .

first PSH FC FC of consecutive subheaders 00 00: This subheader is PSH and not for the last CSDU of that MAC PDU. 10: This subheader is FSH and is for the last SSDU of the MAC PDU. 11: impossible 01: This subheader is FSH and is the last CSDU of the MAC PDU. Basically impossible. 01 00: This subheader is PSH and not for the last CSDU of that MAC PDU. 10: This subheader is FSH and is for the last SSDU of the MAC PDU. 11: impossible 01: This subheader is FSH and is for the last CSDU of the MAC PDU. Basically impossible. 10 (= impossible) No meaningful 11 (= impossible) No meaningful first fragment of other MAC SDU

As shown in Table 1, when packing and fragmentation are compiled at the same time in one MAC PDU, the FC value of the first PSH may have only two states. Specifically, when packing and fragmentation are allowed in one MAC PDU, only MAC SDUs + CSDU or SSDU are combined in one MAC PDU, or only when Last MAC SDU fragment + CSDU or SSDU are combined. . Therefore, the values of the FC of the first PSH may be "00" indicating a CSDU and "01" indicating a Last MAC SDU fragment, and a subsequent PSH value may be 00 or 10 only. That is, if the FC value is "00" in the PSH consecutive to the first PSH, the corresponding SDU is not the last SDU, and if "10" is the first fragment of other MAC SDU, it is also the last SDU of the corresponding PDU.

The MAC PDU 300 also uses the FSH 305 instead of the existing PSH for the last SDU of its payload. And, although the receiver cannot know the value of the length information for the last piece of payload in the PDU, the length information for the last CSDU or the last SSDU 306 of the MAC PDU 300 of FIG. Implicitly specified by the length field of 301. The use of the fragmentation subheader for the last part of the payload is more efficient than using the packing subheader because the fragmentation subheader does not have an 11-bit length field.

Next, a case in which a transmitter generates and transmits a MAC PDU according to the present invention will be described with reference to FIGS. 7 and 8.

7 is a diagram illustrating a transmission apparatus according to an embodiment of the present invention, and FIG. 8 is a diagram illustrating a transmission method according to an embodiment of the present invention.

Referring to FIG. 7, the MAC CPS 122 of the transmission apparatus according to the present invention includes a MAC PDU analyzer 410, a header generator 420, and a MAC PDU component 430.

The MAC PDU analyzer 410 determines whether the CSDU and the SSDU exist simultaneously in one MAC PDU to be configured by analyzing the payload of the MAC PDU to be configured. That is, the MAC PDU analyzer 410 determines whether MAC SDUs + CSDUs or SSDUs are combined or Last MAC SDU fragments + CSDUs or SSDUs are combined within one MAC PDU, and the header generator generates the header. Provided at 420.

When the header generator 420 is informed by the MAC PDU analyzer 410 that CSDU and SSDU exist simultaneously in one MAC PDU to be configured, the header generation unit 420 includes information according to the payload contents of the MAC PDU in the GMH type field. do. That is, the header generation unit 420 sets the type field of the GMH so that the MAC PDU includes both the packing subheader and the fragmentation subheader. That is, the header generation unit 420 sets the GMH type field to "ddd11d" (where d means don't care). The header generator 420 sets the header of the last SDU included in the MAC PDU to FSH and sets the FC of the FSH as shown in Table 1. As described above, if the FC value is "00" in the PSH consecutive to the first PSH, the corresponding SDU is not the last SDU, and if "10" is the first fragment of other MAC SDU, it is also the last SDU of the corresponding PDU. In addition, although "01" is not appropriate value according to the existing standard, in the present invention, this FC value is to indicate that the last CSDU present in the MAC PDU. Subsequently, the MAC PDU configuring unit 430 configures the MAC PDU 430 according to each header from the header generating unit 420 and transmits it to the receiving side.

Subsequently, referring to FIG. 8, in operation 510, the MAC CPS 122 of the transmitting apparatus determines whether there is a request for transmitting a MAC SDU from the CS layer. The MAC CPS 122 then proceeds to step 520 to analyze the payload of the MAC PDU to be configured. The MAC CPS 122 determines whether CSDUs or SSDUs generated from different MAC SDUs exist simultaneously in one MAC PDU to be configured in step 530. In detail, the MAC CPS 122 determines whether a MAC SDUs + CSDU or SSDU is combined or a Last MAC SDU fragment + CSDU or SSDU is combined in one MAC PDU. If there are no CSDUs or SSDUs originating from different MAC SDUs in one MAC PDU at the same time, the MAC CPS 122 proceeds to step 570 to generate the MAC PDU in the conventional manner.                     

When the MAC CPS 122 has CSDUs or SSDUs generated from different MAC SDUs in one MAC PDU to be configured at the same time, the process proceeds to step 540 and includes information according to the payload contents of the MAC PDU in the GMH type field. do. That is, the MAC CPS 122 sets the type field of the GMH to indicate that the MAC PDU includes both a packing subheader and a fragmentation subheader. For example, the type field of GMH may be "ddd11d" (where d means don't care). The MAC CPS 122 then proceeds to step 550 where the header of the last SDU included in the MAC PDU is set to FSH and the FC value of the FSH is set to have a value of "10" or "01".

Finally, the MAC CPS 122 configures and transmits the MAC PDU to the receiver in step 560.

Next, a case in which a receiving side receives a MAC PDU according to the present invention will be described with reference to FIGS. 9 and 10.

9 is a diagram illustrating a receiving apparatus according to an embodiment of the present invention, and FIG. 10 is a diagram illustrating a receiving method according to an embodiment of the present invention.

9, a reception apparatus according to an embodiment of the present invention includes a header analyzer 610, an SDU size calculator 620, and a MAC PDU separator 630.

When the header analyzer 610 receives the MAC PDU from the PHY layer 110, the header analyzer 610 analyzes the GMH type field of the received MAC PDU to determine whether CSDUs or SSDUs generated from different MAC SDUs exist simultaneously in one MAC PDU. . That is, the header analyzer 610 determines whether the GMH type field is “ddd11d” and provides the result to the SDU size calculator 620 and the MAC PDU separator 630.

The SDU size calculator 620 calculates the size of the last CSDU or SSDU when CSDUs or SSDUs generated from different MAC SDUs exist in one MAC PDU at the same time. That is, the GMH of the MAC PDU has its full length information, and the SDU with the PSH has its length information. Therefore, the SDU size calculator 620 calculates the size of the last CSDU or SSDU when subtracting the size of the GMH and the length of the SDU having the PSH from the total length, and provides the result to the MAC PDU separator 630. .

When the MAC PDU separation unit 630 simultaneously exists CSDUs or SSDUs generated from different MAC SDUs in one MAC PDU, the MAC PDU separator 630 first separates the SDUs to which the PSH is attached. That is, the MAC PDU separation unit 630 can separate the SDUs before the last SDU through the PSH attached to their MAC SDUs.

The MAC PDU separator 630 separates the last SDU according to the size of the last CSDU or SSDU provided from the SDU size calculator 620.

Subsequently, referring to FIG. 10, the MAC CPS 122 of the reception apparatus according to an embodiment of the present invention determines whether the MAC PDU is received from the PHY layer 110 in step 710. MAC CPS 122, when the MAC PDU is received, analyzes the GMH type field of the received MAC PDU.

In operation 720 and 730, the MAC CPS 122 determines whether CSDUs or SSDUs generated from different MAC SDUs exist simultaneously in the received MAC PDU. That is, the MAC CPS 122 determines whether the MAC PDU is set to include both the packing subheader and the fragmentation subheader in the GMH type field. If CSDUs or SSDUs generated from different MAC SDUs do not exist in one MAC PDU at the same time, the MAC CPS 122 proceeds to step 760 and processes the MAC PDUs according to the conventional method.

If the MAC CPS 122 has CSDUs or SSDUs generated from different MAC SDUs simultaneously in one MAC PDU, the process proceeds to step 740 to separate the SDUs with PSH. That is, the MAC CPS 122 can be separated by the PSH attached to the front of their MAC SDU for the SDU before the last CSDU or SSDU. MAC CPS 122 then separates the last CSDU or SSDU at step 750 via the "LEN" field present in the Generic MAC header. That is, the MAC CPS 122 calculates the size of the last MAC SDU to separate the last SDU.

A method of calculating the size of the last SDU will be described with reference to FIG. 11.

11A and 11B illustrate a structure of a MAC PDU configured according to the present invention. Referring to FIG. 11A, since the value of the LEN field present in the Generic MAC header indicates the size of the MAC PDU including the MAC header in bytes, LEN = K, MAC_SDU_1 length = a, MAC_SDU_2 length = b, and MAC_SDU_3 length = d If the length of the last CSDU or SSDU is the last CSDU or SSDU length = K-((2 + a) + (2 + b) + (2 + d) + even if there is no field in FSH indicating the size of that last CSDU or SSDU MAC header size + CRC size).

Referring to FIG. 11B, the size of the MAC SDU 333 is identified as the Length = a + 2 field in the PSH, and the size of the MAC SDU 335 is the size of the MAC SDU 335 when LEN = K in the GHM. It can be obtained through length = K-(MAC header size + (2 + a) + CRC size).

In the above description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be defined by the described embodiments, but should be determined by the equivalent of claims and claims.

Conventionally, when the MAC PDU 300 is packed and fragmented in one MAC PDU simultaneously, the MAC PDU 300 notifies the receiver of the size of the CSDU or SSDU forming the last part of the MAC PDU. Use PSH.

However, the present invention uses FSH instead of PSH by obtaining the size of the CSDU or SSDU at the end of the MAC PDU. That is, according to the present invention, by using FSH instead of PSH, the overhead is reduced by 8 bits and more data can be allocated to the payload.

In addition, the present invention refers to the possibility of coexistence of the fragmentation / packing subheader in the existing P802.16REVd / D4 standard, thereby applying the table6-type encodings of the standard as it is, and applying it to a transmitter / receiver. There is an advantage that the present invention can be implemented with only a slight modification. This invention is applicable to both ARQ-enable and Non-ARQ.

Claims (8)

In the method for transmitting a medium access control (MAC) protocol data unit (PDU) in a broadband wireless communication system, Including the information in a generic MAC header (GMH) of the MAC PDU when packing and fragmentation are compiled at the same time in one MAC PDU; Setting the header of the last SDU included in the MAC PDU as a fragmentation sub-header (FSH) and setting the fragment control (FC) of the FSH to indicate that the service data unit (SDU) is the last CSDU or SSDU of the MAC PDU. Wow, Transmitting the MAC PDU. 2. The method of claim 1, wherein packing and fragmentation are simultaneously edited in one MAC PDU in the type field of the GMH. The method of claim 1, wherein the first PSH of the MAC PDU has one of an FC value indicating that the SDU is a last MAC SDU fragment and an FC value indicating that the SDU is a complete SDU. Way. An apparatus for transmitting a medium access control (MAC) protocol data unit (PDU) in a broadband wireless communication system, A MAC PDU analysis unit for determining a case in which packing and fragmentation are compiled at the same time in one MAC PDU and outputting the result; If packing and fragmentation are compiled at the same time in one MAC PDU, the information is included in the Generic MAC Header (GMH) of the MAC PDU, and the subheader of the last SDU included in the MAC PDU is FSH ( A header generation unit that sets a fragment control sub-header (FC) and sets the FSH FC (fragment control) to indicate that the service data unit (SDU) is the last CSDU or SSDU of the corresponding MAC PDU; And a MAC PDU configuration unit configured to receive the header information from the header generator and to configure and transmit a MAC PDU. In the method for receiving a Medium Access Control (MAC) Protocol Data Unit (PDU) in a broadband wireless communication system, When receiving the MAC PDU, determining whether packing and fragmentation are compiled at the same time by analyzing a Generic MAC Header (GMH) of the received MAC PDU; Separating a service data unit (SDU) having PSH from the MAC PDU if packing and fragmentation are simultaneously edited in the one MAC PDU; Separating the last SDU by calculating the size of the last MAC SDU of the MAC PDU using the GMH. 6. The method of claim 5, wherein packing and fragmentation are simultaneously edited in one MAC PDU in the type field of the GMH. 6. The method of claim 5, wherein the length field of the GHM is used when calculating the size of the last MAC SDU of the MAC PDU. An apparatus for receiving a medium access control (MAC) protocol data unit (PDU) in a broadband wireless communication system, When receiving the MAC PDU, by analyzing the type field of the GMH (Generic MAC Header) of the received MAC PDU to determine whether the packing and the fragmentation was compiled at the same time (compiled) in one MAC PDU and the header analysis unit for outputting the result Wow, An SDU size calculator configured to calculate a size of a last MAC Service Data Unit (SDU) using a GMH length field of the MAC PDU; And a MAC SDU separation unit for separating the SDU with PSH attached from the MAC PDU and separating the last SDU according to last MAC SDU size information from the SDU size calculation unit.

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