KR100678144B1 - Method and apparatus for efficiently transmitting data in a wireless potable internet system - Google Patents

Abstract

According to an embodiment of the present invention, when a base station simultaneously allocates data bursts to terminals capable of receiving only normal bursts and terminals capable of receiving H-ARQ bursts, the base station sends frames and H-ARQ bursts when sending normal bursts. Configure the frame of time differently. In other words, the base station does not send an H-ARQ burst and does not use an H-ARQ map when sending a normal burst. In addition, the base station may be configured to send only the H-ARQ burst except for the normal burst for the terminal that does not support H-ARQ when sending the H-ARQ burst.

HARQ burst, normal burst

Description

TECHNICAL AND APPARATUS FOR EFFICIENTLY TRANSMITTING DATA IN A WIRELESS POTABLE INTERNET SYSTEM

1 is a diagram showing the configuration of a typical wireless mobile Internet system;

2 is a diagram showing the configuration of a frame transmitted by a base station to a terminal;

3 is a view showing the configuration of an H-ARQ map,

4 is a block diagram of a base station according to an embodiment of the present invention;

5 is a diagram illustrating a frame to which a normal burst is allocated according to an embodiment of the present invention;

6 illustrates a frame to which an HARQ burst is allocated according to an embodiment of the present invention;

7 is a control flowchart when a transmission frame is configured in a base station according to an embodiment of the present invention.

The present invention relates to a method and apparatus for efficient message transmission in a wireless portable Internet system.

1 is a diagram illustrating a configuration of a general wireless portable Internet system. Referring to FIG. 1, each mobile subscriber station (MSS) 10, 12 is generally mobile and is connected to a backbone network 30 through a base station (BS) 20, 22, respectively. The terminals 10 and 12 allow access between the base stations 20 and 22 and subscribers. Base stations 20 and 22 provide control, management, and connectivity to terminals 10 and 12. The backbone network 30 is connected to an authentication and service authorization server (ASA) 40 for authentication and service authentication of the terminals 10 and 12.

The wireless portable Internet system configured as described above may adopt a hybrid automatic request (HARQ) scheme to ensure data transmission between the base stations 20 and 22 and the terminals 10 and 12. The HARQ scheme is an optional function of a MAC or PHY supporting a wireless portable Internet system and may be performed on a per-terminal basis. The HARQ scheme is a data transmission scheme proposed to have a stronger error correction capability for a data transmission channel by adding forward error correction (FEC) to the conventional automatic repeat request (ARQ) scheme. The HARQ scheme is a mixture of the ARQ scheme for transmitting ACK for data reception and the FEC scheme for inserting an error correction code into the transmitted data, which enables reliable data transmission and is not sensitive to channel conditions. Has Hereinafter, a data burst to which the H-ARQ is not applied is called a normal burst, and a burst to which the H-ARQ method is applied is referred to as an H-ARQ burst. However, in the wireless portable Internet system, there may be a terminal that does not support H-ARQ and a terminal that supports HARQ. That is, a terminal that does not support H-ARQ may process only a normal burst, and a terminal that supports H-ARQ may process both an H-ARQ and a normal burst. Therefore, HARQ bursts are not allocated and transmitted to UEs that do not support H-ARQ.

The order of data transmission on a frame in a wireless portable Internet system is determined by the base station. Specifically, the BS (base station) informs various terminals of the location of the data burst on the frame together with the CID of each terminal, and each terminal finds and reads data burst information indicated by its CID in a map. Know the location of the burst sent to you. The location information of the downlink data burst sent by the BS is indicated in DL (Downlink) -map in case of normal burst and in H-ARQ map in case of position information of H-ARQ burst. In addition, the position of the normal burst may be indicated by temporarily disabling H-ARQ in the H-ARQ map.

The location information of the data burst in the DL-map transmitted from the BS in the wireless portable Internet system is informed to each terminal of the OFDMA symbol offset, subchannel offset, and number of OFDMA symbols. , Two-dimensional allocation of the number of subchannels. 2 shows a configuration of a frame transmitted by a base station to a terminal. As illustrated in FIG. 2, the terminal may know the number of subchannels from the start position and the subchannel start position in the subchannel and the number of symbols from the start position and the start position in the symbol. Therefore, in the DL-map, each terminal can receive the data burst sent to each terminal by finding the location information of the data burst indicated by its CID.

On the other hand, in the H-ARQ map, unlike the DL-map tells the size in one dimension. 3 shows the configuration of the H-ARQ map. As shown in FIG. 3, since only CID and HARQ bursts are informed for each UE, each UE needs to know all data before data burst information indicated by its CID in the H-ARQ map in order to find the location of its HARQ burst. You must know the size of the bursts. For example, if the BS sends a data burst as shown in FIG. 3, the terminal needs to know the size of the H-ARQ bust # 1 to find the H-ARQ burst # 2, and the H to find the H-ARQ burst # 3. You must know the data burst size of ARQ burst # 1 and H-ARQ burst # 2.

However, when the base station supports a terminal capable of receiving only a normal burst and a terminal capable of receiving an H-ARQ burst simultaneously in the same frame, the position of the normal burst indicated by the DL-map is displayed in two dimensions, so that the terminal is normal. Bursts are easy to find.

However, in the case of a terminal receiving a location of a HARQ burst to be received by the H-ARQ-map, as shown in FIG. 2, in order to find the location of its HARQ burst, it is difficult to consider the location or size of the normal burst indicated by the DL map. There is this. For example, in FIG. 2, the UE needs to know the positions of the normal bursts # 1, # 2, and # 3 as well as the sizes of the H-ARQ bursts # 1 and # 2 for the H-ARQ burst # 3. Find # 3. In other words, it is necessary to know the location of the data burst in every DL-map to find the H-ARQ burst. This is complicated in the terminal looking for data burst, but also very complicated in scheduling in the base station carrying the data burst. In addition, terminals using H-ARQ must perform a complex procedure to locate the H-ARQ burst.

Accordingly, the present invention provides a method and apparatus for efficiently allocating HARQ bursts and normal bursts in a wireless portable Internet system.

According to an embodiment of the present invention, in a method for efficient data transmission in a base station of a wireless portable Internet system, determining whether a normal burst and a HARQ burst are mixed in a data burst to be transmitted when a transmission frame is configured, and the normal burst and HARQ If bursts are mixed, the method may include separately configuring a frame for a normal burst and a frame for a HARQ burst, and transmitting the configured frame to the terminals.

In addition, in the wireless portable Internet system according to an embodiment of the present invention, the base station for efficient data transmission determines whether the normal burst and the HARQ burst are mixed in the data burst to be transmitted when the transmission frame is configured, and the normal burst and the HARQ burst are mixed. In this case, a transmission scheduling controller for scheduling the normal burst and the HARQ burst separately from each other, a frame configuration unit configured to separately configure a frame for the normal burst and a frame for the HARQ burst according to the scheduling information, and the configured frame to the terminals. It includes a transmitter for transmitting to.

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.

According to an embodiment of the present invention, when a base station simultaneously allocates data bursts to terminals capable of receiving only normal bursts and terminals capable of receiving H-ARQ bursts, the base station sends frames and H-ARQ bursts when sending normal bursts. Configure the frame of time differently. In other words, the base station does not send an H-ARQ burst and does not use an H-ARQ map when sending a normal burst. In addition, when the base station transmits the H-ARQ burst, the base station sends only the H-ARQ burst to the normal burst for the terminal that does not support H-ARQ.

Accordingly, the terminal that can receive only normal bursts sees the DL-map, checks only that there is a data burst that matches its CID, and if it does not find a data burst, recognizes that there is no data burst sent to it.

Also, a terminal capable of receiving an H-ARQ burst checks the DL-map for its own data burst for frames with normal bursts, finds the location of the data bursts sent to it, and finds the frames with the H-ARQ bursts. Since the data burst does not indicate a data burst in the DL-map, the burst position is found through the information of the data bursts in the H-ARQ map.

Accordingly, when the base station sends the normal burst and the H-ARQ burst to the terminals, the base station can easily schedule the data bursts, and the terminals can reduce the complexity for finding their data burst in the map.

4 is a block diagram of a base station according to an embodiment of the present invention. Referring to FIG. 4, the base station 200 includes a transmission scheduling controller 210, a frame constructer 220, and a transmitter 230. The transmission scheduling control unit 210 provides data scheduling information for configuring a frame to be transmitted to the terminals to the frame configuration unit 220. Since the base station must transmit data to one or more terminals communicating with it, the data burst to be transmitted to each terminal must be scheduled according to various conditions, for example, quality of service (QoS), transmission capacity, and capability of the terminal.

First, the transmission scheduling controller 210 schedules the size and transmission order of data bursts when data bursts are transmitted to the terminals to form a transmission frame. At this time, the transmission scheduling controller 210 determines whether both normal burst and HARQ burst to be transmitted to the terminals exist. That is, the transmission scheduling controller 210 determines whether the normal burst and the HARQ burst are mixed in the data burst to be transmitted. If the normal burst and the HARQ burst are mixed, the transmission scheduling controller 210 schedules the normal burst and the HARQ burst separately from each other. Conventionally, data bursts have been scheduled without distinguishing between normal bursts and HARQ bursts. However, according to the embodiment of the present invention, normal bursts and HARQ bursts are not allocated together on one frame.

Subsequently, the transmission scheduling control unit 210 provides the frame configuration unit 220 with scheduling information of the normal burst and the HARQ burst. The frame configuration unit 220 configures the normal burst and the HARQ burst into separate frames according to the scheduling information provided from the transmission scheduling controller 210. 5 shows a frame to which a normal burst has been assigned and FIG. 6 shows a frame to which a HARQ burst has been assigned. Referring to FIG. 5, a HARQ burst is not allocated to a frame to which a normal burst is assigned and thus does not include a HARQ-map. Referring to FIG. 6, a normal burst for a terminal that does not support HARQ is not allocated to a frame to which an HARQ burst is allocated. As shown, the frame configuration unit 220 two-dimensionally displays the position information of the normal burst in the DL-map of the frame to which the normal burst is assigned. Specifically, referring to FIG. 5, the frame configuration unit 220 shows a starting subchannel number, a starting OFDMA symbol number, and the number of normal bursts in a frame on the DL-map. Accordingly, the UE can know the starting point of the normal burst from the point where the starting subchannel number and the starting OFDMA symbol number intersect. In addition, the UE may know from which starting point of the normal burst on the frame to which point the normal burst is to be taken according to the number of subchannels and the number of symbols.

The frame configuration unit 220 is shown one-dimensionally in the HARQ-map of the frame to which the HARQ burst is assigned. In more detail, the frame configuration unit 220 indicates the size of the HARQ burst in the HARQ map. At this time, since the normal burst is not allocated on the frame but HARQ bursts are allocated, the UE can know the location of the HARQ burst to be taken if only the size of other HARQ bursts is known. The frame configured as described above is provided to the transmitter 230 from the frame constructor 220. The transmitter 230 transmits the frame to the terminal.

Accordingly, the terminal that can receive only normal bursts sees the DL-map, checks only that there is a data burst that matches its CID, and if it does not find a data burst, recognizes that there is no data burst sent to it.

Also, a terminal capable of receiving an H-ARQ burst finds the location of a data burst sent to itself by checking whether its own data burst exists in the DL-map for a frame containing only a normal burst, and finds a frame containing only an H-ARQ burst. Since the data burst does not indicate a data burst in the DL-map, the burst position is found through the information of the data bursts in the H-ARQ map.

On the other hand, the configuration of the base station according to the embodiment of the present invention described above can be changed by those skilled in the art. For example, although the transmission scheduling control unit 210, the frame configuration unit 220 and the transmission unit 230 is shown and described as being configured separately as in the present invention, it may be integrated into one implementation. Therefore, the present invention is not limited by the terminal configuration according to the above-described embodiment.

7 shows a control flowchart when a transmission frame is configured in a base station according to an embodiment of the present invention.

Referring to FIG. 7, the base station determines whether to configure a transport frame in step 310. If there is data to be transmitted to the terminal, the base station configures and transmits a transmission frame. Therefore, if there is data to be transmitted to the at least one terminal, the base station proceeds to step 320. The base station determines whether the normal burst and the HARQ burst are mixed in the data burst after transmitting to the terminals in step 320.

If the normal burst and the HARQ burst are mixed, the base station proceeds to step 330 and separately configures the frame for the normal burst and the frame for the HARQ burst and then proceeds to step 350. Thus, normal bursts and HARQ bursts are not assigned together on one frame. If the normal burst and the HARQ burst are not mixed and there are only bursts of one type among the normal bursts and the HARQ bursts, the base station proceeds to step 430 to configure a transmission frame suitable for the burst, and then proceeds to step 350. The base station transmits the frame configured in step 350 to at least one terminal.

Accordingly, the terminal that can receive only normal bursts sees the DL-map, checks only that there is a data burst that matches its CID, and if it does not find a data burst, recognizes that there is no data burst sent to it.

Also, a terminal capable of receiving an H-ARQ burst finds the location of a data burst sent to itself by checking whether its own data burst exists in the DL-map for a frame containing only a normal burst, and finds a frame containing only an H-ARQ burst. Since the data burst does not indicate a data burst in the DL-map, the burst position is found through the information of the data bursts in the H-ARQ map.

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.

By sending the normal burst and the H-ARQ burst to the terminals in separate frames in the base station according to the present invention as described above, the base station can facilitate scheduling for the data bursts, and the terminals can transmit their data in the Map. This greatly reduces the complexity of finding bursts. Accordingly, the terminal can reduce the waiting time for decoding the data burst in the physical layer (PHY) and reduce the size of the buffer storing the frame data.

Claims (16)

In the method for efficient data transmission in the base station of the wireless portable Internet system, When configuring a transmission frame, each of the normal burst and HARQ burst scheduled separately from each other according to the scheduling information Separately configuring a frame for a normal burst and a frame for a HARQ burst; The data transmission method comprising the step of transmitting the separately configured frame to the terminal. The method of claim 1, wherein when the transmission frame is configured, it is determined whether a normal burst and a HARQ burst are mixed in a data burst to be transmitted. If mixed, configure the normal burst frame and HARQ burst frame separately, And if not mixed, constructing a transmission frame suitable for the data burst. The method of claim 1, wherein the position information of the normal burst is two-dimensionally displayed in a DL-map of a frame to which the normal burst is assigned. The method of claim 1, wherein the position information of the normal burst is a starting subchannel number, a starting OFDMA symbol number, and the number thereof, which are located on the frame, and are indicated on a DL-map. The data transmission method. The data transmission method as claimed in claim 1, wherein the position information of the HARQ burst is displayed one-dimensionally in a HARQ-map of a frame to which the HARQ burst is assigned. The method of claim 1, wherein the location information of the HARQ burst is the size of the HARQ burst and is displayed on a HARQ map. A base station for efficient data transmission in a wireless portable internet system, A control unit for scheduling the normal burst and the HARQ burst separately from each other when configuring a transmission frame, A frame configuration unit for separately configuring a frame for a normal burst and a frame for a HARQ burst according to the scheduling information; And a transmitter for transmitting the configured frame to the terminals. The method of claim 7, wherein the controller determines whether the normal burst and the HARQ burst are mixed in the data burst to be transmitted when the transmission frame is constructed. If mixed, configure the normal burst frame and HARQ burst frame separately, If not mixed, the base station comprising a transmission frame suitable for the data burst. The base station according to claim 7, wherein the frame configuration unit displays position information of the normal burst two-dimensionally in a DL-map of a frame to which the normal burst is assigned. 8. The method of claim 7, wherein the position information of the normal burst is a starting subchannel number, a starting OFDMA symbol number, and the number thereof, which are located on the frame, and are indicated on a DL-map. Base station. The base station according to claim 7, wherein the frame configuration unit displays one-dimensionally on a HARQ-map of a frame to which the HARQ burst is assigned. 8. The base station of claim 7, wherein the location information of the HARQ burst is the size of the HARQ burst and is displayed on a HARQ map. In a terminal supporting both a normal burst and a HARQ burst, A receiving unit for receiving a normal burst or a HARQ burst, For frames with only normal bursts, the DL-map checks its own data burst and detects the location of the data bursts sent to it. For frames with only HARQ bursts, its burst position is determined from the data bursts in the HARQ map. And a control unit for detecting the terminal. In the data burst processing method in the terminal that supports both normal burst and HARQ burst, Receiving a normal burst or a HARQ burst, For frames containing only normal bursts, detecting whether a data burst has been sent to the DL-map by detecting whether its own data burst exists; And detecting a magnetic burst position through information of data bursts in a HARQ map for a frame containing only HARQ bursts. In a terminal receiving only a normal burst, A receiver for receiving a normal burst, The terminal characterized in that it finds a data burst by checking that there is a data burst that matches the CID by looking at the DL-map, and if not, the terminal comprising a controller for recognizing that there is no data burst sent to the frame. In the data burst processing method in a terminal receiving only a normal burst, Receiving a normal burst, Find the data burst by looking at the DL-map to see if there is a data burst that matches your CID, And if there is no matching data burst, recognizing that there is no data burst sent to the corresponding frame in the corresponding frame.

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