KR100979511B1 - Method for transmitting data packet using the MIMO and HARQ system, and system for supporting that method - Google Patents

Abstract

The present invention relates to a data packet transmission method of wireless communication, and more particularly, to a data packet transmission method using a MIMO and HARQ system, and a system supporting the method.

A data packet transmission method according to an embodiment of the present invention includes the steps of: (a) receiving a request for changing a MIMO mode from a first MIMO mode to a second MIMO mode; (b) determining whether there is a data packet to be retransmitted after receiving the MIMO mode change request; (c) changing the MIMO mode to the second MIMO mode when there is no data packet to be retransmitted as a result of the determination; Or (d) if there is a data packet to be retransmitted as a result of the determination, the MIMO mode of the retransmitted data packet maintains the first MIMO mode, and the MIMO of data packets other than the retransmitted data packet changes the second MIMO mode. Characterized in that it comprises a step.

Wireless communication, WiBro, HARQ, MIMO, MCS level, ACID

Description

Method for transmitting data packet using the MIMO and HARQ system, and system for supporting that method}

The present invention relates to a data packet transmission method of wireless communication, and more particularly, to a data packet transmission method using a MIMO and HARQ system, and a system supporting the method.

In a wireless channel environment, many factors such as multi-path interference, shadowing, propagation attenuation, time-varying noise, interference, and fading can cause unavoidable errors. Loss occurs. This loss of information causes severe distortion in the actual transmission signal, which causes a decrease in the overall performance of the wireless communication system.

In order to prevent performance degradation of a wireless communication system caused by the above reasons, a multiple input multiple output (MIMO) system has been proposed.

The MIMO system transmits data through multiple paths by increasing the number of antennas of a base station and a terminal, reduces interference by detecting signals received on each path at the receiving end, and increases transmission efficiency through space-time diversity and spatial multiplexing at the transmitting end. have.

The MIMO system can be classified into Space Time Transmit Diversity (STTD) and Spatial Multiplexing (SM) modes according to a method of allocating a plurality of antennas and symbols to be transmitted, and in particular, IEEE 802.16d / In the e-based wireless communication system, STTD (Matrix A) and SM (Matrix B) can be selectively transmitted. In addition to the MIMO system, a hybrid ARQ (HARQ) is used to solve the problem of data packet error occurring on a wireless channel.

In the wireless communication system in which the MIMO system and the HARQ scheme described above are applied together, if an error occurs in the data transmitted to the terminal, the base station retransmits the corresponding data packet, and the terminal chases the error-produced data and the retransmitted data. The data is decoded by inning (chase combining).

On the other hand, the UE may request to change the MIMO mode (Matrix A, Matrix B) to the base station according to the change in the wireless channel environment, if the MIMO mode is changed during the retransmission process of the data packet, the previous data packet with an error And the MIMO mode of the data packet to be retransmitted are different.

For example, when a previous data packet having an error is transmitted to Matrix A, if the MIMO mode is changed at the request of the UE, the retransmitted data packet is transmitted to Matrix B. In this case, the terminal that has received the MIMO mode of the previous data of the Matrix A scheme and the retransmission data of the Matrix B scheme is different.

In such a case, data can be decoded even if the MIMO mode is different in the case of chase combining the data packet in bit units, but data can not be decoded in the case of chase combining the received data packet in symbol units. .

The present invention is to solve the above problems, in the data packet transmission method using a MIMO and HARQ system, a data packet transmission method that can prevent a problem caused by the request for changing the MIMO mode during the retransmission process of the data packet and It is a technical problem to provide a system supporting the method.

In the data packet transmission method according to an embodiment of the present invention, a data packet transmission method using MIMO and HARQ, the method comprising: setting an initial value of retransmission information indicating the number of HARQ channels in use and an initial value of a MIMO mode; Generating a map information element for allocation indication of the MIMO mode and the HARQ subburst; Transmitting the data packet to a receiving unit and increasing the retransmission information value; Determining whether to retransmit the data packet according to whether to receive an ACK for the data packet transmitted from the receiver; And reducing the retransmission information value when the reception result is an ACK, and retransmitting the data packet when the reception result is not an ACK.

A data packet transmission method according to an embodiment of the present invention includes the steps of: (a) receiving a request for changing a MIMO mode from a first MIMO mode to a second MIMO mode; (b) determining whether there is a data packet to be retransmitted after receiving the MIMO mode change request; (c) changing the MIMO mode to the second MIMO mode when there is no data packet to be retransmitted as a result of the determination; Or (d) if there is a data packet to be retransmitted as a result of the determination, the MIMO mode of the retransmitted data packet maintains the first MIMO mode, and the MIMO of data packets other than the retransmitted data packet changes the second MIMO mode. Characterized in that it comprises a step.

According to an embodiment of the present invention, a method of transmitting a data packet may include determining whether to retransmit a data packet to be transmitted when a MIMO mode change request is received from a first MIMO mode to a second MIMO mode; And in the case of retransmission, transmitting the data packet in the first MIMO mode, and in the case of non-retransmission, transmitting the data packet in the second MIMO mode.

According to an embodiment of the present invention, a wireless communication system supporting HARQ and MIMO includes: a receiving unit receiving a MIMO mode change request transmitted from a terminal (receiving unit); A MIMO mode determination unit which determines whether to change the MIMO mode according to whether to retransmit the data packet to be transmitted; And a burst transmitter for transmitting data packets according to all of the MIMO determined by the MIMO mode determiner.

When a data packet transmission method and a base station according to an embodiment of the present invention are requested to change the MIMO mode during the retransmission of the data packet, the base station controls the change in the MIMO mode according to the presence or absence of data for which the retransmission is performed, thereby receiving at the terminal. The data can be transmitted so that the data can be decoded smoothly.

In the following description, a case of a downlink (DL) in which a base station (BS) is a transmitting unit and a mobile station (MS) is a receiving unit will be described as an example. However, this is merely exemplary and the roles of the base station and the terminal for the transmitter or the receiver may be switched with each other.

Hereinafter, a data packet transmission method and a base station according to an embodiment of the present invention will be described with reference to the accompanying drawings 1 to 9b.

1 is a block diagram illustrating a base station supporting a data packet transmission method according to an embodiment of the present invention.

Referring to FIG. 1, the base station 100 according to an embodiment of the present invention includes an ACID counting unit 110 that counts a retransmission information value (Preempted ACID) indicating the number of data that may be requested to be retransmitted; A burst allocator 120 for allocating a two-dimensional burst area defined by time and frequency in the data area; A MIMO mode feedback receiver 130 for receiving a MIMO mode change request transmitted from a terminal (receiver); A MIMO mode determination unit 140 for determining whether to change the MIMO mode when the MIMO mode change request is received; A burst transmitter 150 for transmitting a data burst according to the determined MIMO mode; Map message creation unit 160 for creating and assigning down (down) link map (DL-MAP) message and up (up) link map (UL-MAP) message in the map area among down (down) link subframes. do.

The ACID counting unit 110 counts ACID. Here, ACID represents the number of HARQ channels (Preempted ACID) in use, and an initial value is set to '0'.

If the preempted ACID is the initial value ('0'), it means that no data packet is being transmitted. As the number of data packets being transmitted increases, the preempted ACID also increases. For example, if two data packets are being transmitted, the Preempted ACID is also two. That is, if the Preempted ACID is not the initial value ('0'), it means that there is a data packet being transmitted. Through this preempted ACID, it is possible to check the existence, presence, and quantity of data packets that can be retransmitted.

The burst allocator 120 allocates a burst to a two-dimensional area (or resource) defined by time and frequency in the data area. Specifically, when a data burst is allocated to a data area of a downlink, a symbol offset, a sub channel offset, a number of symbols used (No. OFDMA Symbols) and a sub used are used. Allocates a data burst in a rectangular region defined by the number of channels (No. Sub Channels).

The MIMO mode feedback receiver 130 receives the MIMO mode change request transmitted from the terminal (receiver) and transmits the received MIMO mode change request to the MIMO mode determiner 140.

When the MIMO mode change request from the terminal (receiver) is received, the MIMO mode determination unit 140 checks whether there is a data packet to be retransmitted in the current communication system, and determines whether to change the MIMO mode according to the confirmation result. . Here, the changed MIMO mode may be set differently from the MIMO mode applied to the retransmitted data packet and the MIMO mode applied to the newly transmitted data packet. Details thereof will be described in detail later in the description of the method for determining the MIMO mode.

The map message generator 160 creates and assigns a downlink (DL-MAP) message and an uplink (UL) map message in a map area of the downlink (downlink) subframe.

Here, the downlink map message includes information indicating which user's data are transmitted downlink data bursts transmitted from the base station and in which area within the downlink frame, the uplink map message is an uplink map message transmitted by the terminals Contains information about link bursts.

Among these map messages, the downlink map message includes a downlink map information element (IE) in which information on each data burst is defined for each data burst. Here, the downlink map information element includes the modulation level of the data burst, the starting point of the data burst (symbol offset and subchannel offset), the length of the data burst (number of symbols and number of subchannels), and terminal information to receive the data burst. Included.

The burst transmitter 150 transmits the data burst in the previous MIMO mode or the changed MIMO mode according to the data burst allocated by the burst assigner 120 and the MIMO mode determined by the MIMO mode determiner 140. At this time, the information of the transmitted data burst is defined by the downlink map information element from the map message generator 160.

The burst transmitter 150 includes a retransmission determining unit 152 that determines whether to retransmit the previously transmitted data packet and a transmission counting unit 154 that counts initial transmission and retransmission data packets. .

The transmission counting unit 154 is configured to determine whether the number of retransmissions of the retransmitted data packet satisfies a preset maximum retransmission number of the data packet first transmitted from the burst transmitter 150 and the retransmitted data packet. The number is counted, and the counting information of the data packet is transmitted to the retransmission determining unit 152.

The retransmission determining unit 152 determines whether to retransmit the data packet when there is no feedback from the terminal (receiver) or the content of the feedback is NACK for the data packet transmitted to the terminal (receiver). At this time, the transmission counting unit 154 determines whether the number of retransmissions of the corresponding data packet is less than the maximum number of retransmissions or whether the number of retransmissions of the data packet is greater than or equal to the maximum number of retransmissions using the counting information of the counted data packets.

As a result of confirming the number of retransmissions, retransmission is performed when the number of retransmissions of the data packet is less than the maximum retransmission number (satisfying the maximum number of retransmissions). To give up.

A method of transmitting and retransmitting a data packet using the base station 100 will be described with reference to FIG. 2.

Data transmission method according to an embodiment of the present invention is assumed that the terminal supports both the MIMO mode and HARQ scheme. Therefore, a case in which the terminal supports only one of the MIMO mode and the HARQ scheme or does not support both of them will be briefly described, and then the present invention will be described in detail.

As shown in FIG. 2, it is checked whether the terminal supports downlink (DL) MIMO (S100). Then, it is checked whether the terminal supports the HARQ scheme (S110) to determine whether the terminal supports the MIMO mode and the HARQ scheme.

First, in step S100, the result of checking whether the terminal supports the downlink (DL) MIMO (S100), if the terminal does not support the downlink (DL) MIMO, it is determined whether the HARQ scheme is supported again (S200). . If the terminal does not support the HARQ scheme, the downlink (DL) map IE is set to not support the downlink (DL) MIMO and HARQ scheme (S240), and downlink frame is allocated to transmit a data packet (S245). ).

However, if the terminal does not support downlink (DL) MIMO in step S200, but supports the HARQ scheme, it is determined whether the current transmission is the initial transmission (S210). Thereafter, when the current transmission is the initial transmission, the MCS level is set (S220), the downlink burst IE is set to support HARQ (S230), and the data packet is transmitted (S235).

In step S110, when the terminal supports downlink (DL) MIMO but does not support the HARQ scheme, the downlink (DL) map IE is set to support only downlink (DL) MIMO (S250). . According to the configuration, a downlink frame is allocated and a data packet is transmitted (S255).

As a result of checking the steps S100 and S110, if the terminal supports the MIMO mode and the HARQ scheme, a preempted ACID (retransmission information value indicating the number of data packets that can be requested to be retransmitted) is a first value (initial value). In addition, the MIMO mode is set to the first mode Matrix A (S120). Here, Matrix A, which is the first mode of the MIMO mode, refers to a Space Time Transmit Diversity (STTD) scheme.

Then, it is checked whether the current transmission is the initial transmission (S130). As a result of the check, when the current transmission is the initial transmission, the MCS level is set (S140). Here, the MCS level setting is to set the adaptive modulation / coding scheme (AMCS), modulation scheme (QPSK, 8PSK, 16QAM and 64QAM) and code rate (1/2, 3/4) of the channel encoder between the base station and the terminal. Include.

In the MCS level, the modulation scheme and the code rate of the channel encoder can be changed according to the change of the channel environment of the downlink. That is, if the channel environment is good, the modulation method and the code rate are adjusted upward. If the channel environment is poor, the modulation method and the code rate are adjusted downward.

Thereafter, DL Chase HARQ Sub_burst IE is allocated (S150) to transmit the data packet (S155). Since the number of data packets being transmitted and currently being transmitted is increased in step S155, the number of data packets that may be required to be retransmitted is increased. Accordingly, the retransmission information value (Preempted ACID) is increased (S160). Here, the increase or decrease of the retransmission information value is caused by the increase or decrease of the data packet to which the transmission is made.

Thereafter, it is checked whether or not feedback is received from the receiving unit with respect to the transmitted data packet (S170). When the feedback is received from the receiver, it is checked whether the received feedback is ACK (S180).

Here, if the feedback from the receiver is ACK, it means that the transmitted data packet was transmitted without error. In this case, the data packet does not need to be retransmitted, that is, it is assumed that there is no retransmission data packet, and the preempted ACID, which was previously increased when the data packet is transmitted, is reduced (S190). After the transmission of one data packet is completed through the above process, the next data may be transmitted.

If the feedback is not received from the receiver as a result of checking whether the feedback is received from the receiver (S170), the process returns to step S170 to compare the number of retransmissions of the corresponding data packet with the maximum number of retransmissions to determine whether to retransmit the corresponding data packet. (S260).

As a result of the comparison of the number of transmissions in step S260, when the number of retransmissions of the corresponding data packet is equal to or greater than the set maximum number of retransmissions, retransmission is abandoned (S270). If the retransmission of the data packet is abandoned, the preempted ACID increased in step S160 is decreased because there is no retransmission data packet (S190). Thereafter, another data packet can be transmitted.

If the number of retransmissions is less than the maximum number of retransmissions, the maximum number of retransmissions of the corresponding data packet is increased (S280). Thereafter, while maintaining the MIMO mode applied in the previous transmission step (S290), and maintains the MCS level of the previous transmission (S300) and retransmits the corresponding data packet (S310).

Here, maintaining the MCS level and the MIMO mode of the previous transmission, when changing the MCS level and the MIMO mode of the retransmitted data, chases the previously received data and the retransmitted data in the terminal performing the chase combining at the symbol level. This is because it cannot be combined. That is, the data packet is retransmitted by maintaining the MCS level and the MIMO mode of the previous transmission so that the terminal can decode the data smoothly.

Again, returning to step S180 of checking whether the received feedback is an ACK. If the feedback content is confirmed as a result of the feedback from the receiver, an error occurred in the transmitted data packet, and then it is determined whether to retransmit the data packet. In this case, the retransmission determination method and the retransmission determination result applied here are the same as the steps (S260, S270, S280, S290, S300, and S310 steps) that are applied when the feedback is not received in step S170.

In the process of transmitting and retransmitting the data packet described above, FIGS. 3 to 5 will be described with reference to data packet transmission methods and MIMO mode changing methods that may be applied when the MIMO mode change of the data packet transmission is requested from the terminal. This will be described with reference.

Referring to the drawings, the gist of the data packet transmission method according to an embodiment of the present invention will be described. According to an embodiment of the present invention, a data packet transmission method is performed from a first MIMO mode to a second MIMO mode by a terminal (receiving unit). When a MIMO mode change request is received, the Preempted ACID (retransmission information value indicating a data packet for which retransmission may be requested) is checked. As a result of the check, when the preempted ACID (retransmission information value) is the initial value, it means that there is no data packet to be retransmitted, and therefore, the MIMO is changed to the second MIMO mode. On the other hand, if the preempted ACID (retransmission information value) is not the initial value, it means that there is a data packet that is currently being transmitted. Therefore, the retransmission data packet is set to the first MIMO mode as before. The data packet is set to the second MIMO mode as requested by the terminal to transmit the data packet.

First, a first embodiment that can be applied when a MIMO mode change of data packet transmission is requested from a terminal will be described with reference to FIG. 3.

When the MIMO mode change request from the terminal (receiving unit) is received (S400) while the data packet is being transmitted and retransmitted, the MIMO mode change scheduled value (pending mode value) indicating whether to change the MIMO mode is initialized. It is set to a value different from "1" (S410).

Thereafter, it is checked whether the retransmission information value (Preempted ACID) is an initial value (first value = 0) (S420). Here, if the retransmission information value (Preempted ACID value) is set to an initial value ('0'), it means that no data packet is currently being transmitted, and therefore, it can be seen that no data packet is retransmitted.

On the other hand, if the retransmission information value (Preempted ACID) is set to a second value (one or more) different from the initial value '0', it means that there is a data packet currently being transmitted. At this time, it is determined whether the retransmission data packet and other data packets are located in the same symbol of the same frame, and the MIMO mode is maintained or the MIMO mode is changed according to the determination result.

In the following description, a case where the retransmission information value (Preempted ACID) is an initial value will be described. Next, a case where the retransmission information value (Preempted ACID) is not an initial value will be described.

Returning to step S420, when the retransmission information value (Preempted ACID) is the initial value, when the retransmission information value (Preempted ACID) is the initial value, it means that no data packet is currently retransmitted, and thus, set to '1' in step S410. A MIMO mode change scheduled value indicating whether to change one MIMO mode is set to an initial value '0', and the first MIMO mode is changed to the second MIMO mode requested from the terminal (receiver) (S430).

For example, when the previous MIMO mode is Matrix A, that is, Space Time Transmit Diversity (STTD) mode, the MIMO mode is changed to Matrix B, that is, Spatial Multiplexing (SM) mode. On the other hand, if the previous MIMO mode is Matrix B, the MIMO mode is changed to Matrix A. Thereafter, the next data is transmitted in the changed MIMO mode (S440).

Again, returning to step S420, if the retransmission information value (Preempted ACID) is confirmed as a result, if the retransmission information value (Preempted ACID) is set to a second value different from the initial, it means that there is currently a data packet to be retransmitted, It is checked whether data packets to be retransmitted and other data packets are located in the same frame (S450).

If the data packet to be retransmitted is not located in the same frame as a result of step S450, the MIMO mode is changed from the first MIMO mode to the second MIMO mode requested by the terminal (receiver) (S500) and the data packet is transmitted ( S510).

On the other hand, if there is a data packet to be retransmitted as a result of step S450, even if a request for changing the MIMO mode is received from the terminal (receiver), the MIMO mode of the retransmitted data packet is maintained at the first MIMO mode previously set (S460). )do.

Here, maintaining the MIMO mode of the data to be retransmitted as the previous first MIMO mode may cause a problem in that the data received by the terminal cannot be decoded when the MIMO mode in the previous transmission is different from the MIMO mode in the retransmission. to be. In order to prevent such a problem, even if a request for changing the MIMO mode is received from the terminal (receiver), the retransmitted data packet is retransmitted to the previous MIMO mode.

In order to prevent the above problem, in step S460, the MIMO mode of the retransmission data packet is maintained as the first MIMO mode. Here, there is a point to consider, which relates to the MIMO mode of data packets other than retransmission data packets. The data packet other than the retransmission data packet has no problem in restoring the data even if the terminal changes the MIMO mode as requested by the terminal in step S400. Therefore, in order to change the MIMO mode of the data packet other than the retransmitted data packet, it is determined whether other data packets besides the retransmitted data packet and the retransmitted data packet to which the first MIMO mode is applied are located in the same symbol on the data burst (S470).

Here, the step S470 may be performed to change the MIMO mode other than the retransmission data packet as requested by the terminal, except that the retransmission data packet and the other data packet are not arranged in the same symbol on the data burst. to be. Herein, it is assumed that data packets other than the retransmission data packet and the retransmission data packet are data packets transmitted to the same terminal.

As shown in FIG. 6, if there are different data packets (other data packets other than the retransmitted data packet) transmitted to the same terminal, and the MIMO modes of these two data packets are different, for example, retransmitted data packets Is transmitted in the first MIMO mode (Matrix A), and other data packets are transmitted in the second MIMO mode (Matrix B). When the two data packets are located in the same symbol, the terminal (receiving unit) receiving the two data packets is located in the same symbol. There may be difficulty in decoding the data.

In order to prevent this problem, it is determined whether the retransmission data packet and the other data packet are located in the same symbol on the data burst through the step S470 (S470).

As a result of the determination in step S470, if the retransmission data packet and the other data packet are located in different symbols as shown in FIG. 7, the MIMO mode of the other data packet is changed to the second MIMO mode as requested by the terminal (S500). The data packet is transmitted (S510).

On the other hand, as a result of the determination in step S470, if the retransmission data packet and the other data packet is located in the same symbol, as shown in Figure 6, it is checked whether the symbol of the other data packet is the last symbol (S480).

As a result of the checking in step S480, if the last symbol, the other data packet is placed in the next frame (S520), and the MIMO mode of the other data packet is changed to the second MIMO mode as requested by the terminal (S500). Thereafter, the retransmission data packet is transmitted in the first MIMO mode, and other data packets are transmitted in the second MIMO mode in which the terminal requests a change (S510).

On the other hand, as a result of checking in step S480, if it is not the last symbol, another data packet is moved to the next symbol (S490), and it is determined whether a retransmission data packet exists in the moved symbol in the same manner as in step S470 (S470). . Subsequently, if the retransmission data packet and the other data packet are arranged in different symbols by repeating the process after operation S470, the retransmission data packet is in the first MIMO mode and the second data packet other than the second is requested by the terminal. Send data in MIMO mode.

This means that the data packet can be decoded by retransmitting the previous data packet in the previous first MIMO mode, but other data packets other than the retransmitted data packet are not located in the same symbol of the same terminal as the retransmitted data packet. This is because the terminal (receiving unit) is not greatly affected by the decoding of the data packet even when transmitted in the MIMO mode.

Next, referring to FIG. 4, a second embodiment that can be applied when a MIMO mode change of data packet transmission is requested from a terminal will be described.

In the data packet transmission method according to the second embodiment of the present invention, when the MIMO mode change request from the terminal (receiving unit) is received in a situation where the data packet is transmitted and retransmitted as in the first embodiment described above. 4, the steps S400 to S450 are performed by the same process as the above-described first embodiment, and thus description thereof will be omitted.

If there is no data packet to be retransmitted as a result of step S450, the MIMO mode is changed from the first MIMO mode to the second MIMO mode requested by the terminal (receiver) (S600) and the data packet is transmitted (S610).

On the other hand, if there is a data packet to be retransmitted as a result of step S450, even if a request for changing the MIMO mode is received from the terminal (receiving unit), the MIMO mode of the retransmitted data packet is maintained as the first MIMO mode previously set (S620). )do.

Here, maintaining the MIMO mode of the data to be retransmitted as the previous first MIMO mode may cause a problem in that the data received by the terminal cannot be decoded when the MIMO mode in the previous transmission is different from the MIMO mode in the retransmission. to be. In order to prevent such a problem, even if a request for changing the MIMO mode is received from the terminal (receiver), the retransmitted data packet is retransmitted to the previous MIMO mode.

Similarly to the first embodiment, the second embodiment of the present invention also considers the MIMO mode of data packets other than the retransmission data packets.

The data packet other than the retransmission data packet has no problem in restoring the data even if the terminal changes the MIMO mode as requested by the terminal in step S400. Therefore, in order to change the MIMO mode of the data packet other than the retransmitted data packet, it is determined whether the retransmitted data packet to which the first MIMO mode is applied and other data packets exist in the same frame on the data burst (S630).

Here, in the step S630, the data packet other than the retransmission data packet is changed to the MIMO mode as requested by the terminal, except that the retransmission data packet and the other data packet are arranged in the same frame on the data burst to the same terminal (receiver). This is to prevent it. When a retransmission data packet transmitted to the same terminal and another data packet other than the retransmission packet are arranged and transmitted in the same frame in different MIMO modes, it may be difficult for the terminal to receive the data to decode the data. In order to prevent such a problem, retransmission data packets transmitted to the same terminal and other data packets other than the retransmission packets are arranged in different frames.

As a result of the determination in step S630, as shown in FIG. 8A, data packets located in the same frame are data packets of different terminals, or as shown in FIG. 8B, data packets transmitted to the same terminal are different frames. If it is located at, the MIMO mode of the data packet other than the retransmission data packet is changed to the second MIMO mode requested from the terminal (receiver) (S600). That is, if the retransmission data packet and the other data packet transmitted to the same terminal do not exist in the same frame, the MIMO mode of the other data packet is changed to the second MIMO mode requested from the terminal (receiver).

Thereafter, the retransmitted data packet is transmitted in the previous first MIMO mode, and other data packets are changed to the second MIMO mode requested from the terminal to transmit the data packet (S610).

On the other hand, as a result of the determination in step S630, as shown in Figure 9a, if the retransmission data packet and another data packet (B) transmitted to the same terminal is set to a different MIMO mode and located in the same frame, the other data packet As shown in FIG. 9B, the next frame is placed in the next frame (S640).

After the other data packet is placed in the next frame, steps S630 and S640 are repeated until the retransmission data packet and the other data packet transmitted to the same terminal are not arranged in the same frame.

By the above process, if the retransmission data packet transmitted to the same terminal and another data packet are arranged in different frames, the MIMO mode of the other data packet is changed to the second MIMO mode requested by the terminal (S600). Thereafter, the retransmission data packet is transmitted in the first MIMO mode, and the other data packet is transmitted in the second MIMO mode (S610).

Referring to FIG. 4, a third embodiment that can be applied when a MIMO mode change of data packet transmission is requested from a terminal will be described with reference to FIG. 5.

In the data packet transmission method according to the third embodiment of the present invention, when the MIMO mode change request is received from the terminal (receiving unit) under the same conditions as the first and second embodiments, the data packet is transmitted and retransmitted. 5, the steps S400 to S440 are performed by the same process as the above-described first embodiment, which will be briefly described.

In step S420, it is checked whether the retransmission information value (Preempted ACID) is an initial value (S420). If the retransmission information value (Preempted ACID) is the initial value, that is, the first value, it means that no data packet is currently retransmitted. Therefore, the MIMO mode change scheduled value set to '1' in step S410 is set to '0'. ', And changes the first MIMO mode to the second MIMO mode requested from the terminal (receiver) (S430). Thereafter, the data packet is transmitted in the changed second MIMO mode (S440).

In step S420, if the retransmission information value (Preempted ACID) is the initial value, and the retransmission information value (Preempted ACID) is set to a second value different from the initial value, there is a data packet currently being retransmitted. Means. At this time, even if the change of the MIMO mode is received from the terminal maintains the MIMO mode (S700). The MIMO mode maintenance according to the step S700 is provisional, and the change of the MIMO mode is suspended until the transmission of the data packet for which retransmission is being completed. After the transmission of all retransmission data packets, that is, when there is no retransmission data packet on the transmission path, since the retransmission information value (Preempted ACID) becomes an initial value, steps S420 to S440 are performed. As requested by the terminal, the data packet is transmitted by changing the MIMO mode.

After maintaining the MIMO mode by the step S700, it is checked whether the number of retransmissions of the retransmission data packet is less than the set maximum retransmission number (S710).

As a result of checking in step S710, if the number of retransmissions of the retransmission data packet is more than the maximum retransmission number, the retransmission of the corresponding data packet is abandoned (S720). Thereafter, since the number of data packets to be retransmitted is reduced by step S720, the retransmission information value (Preempted ACID) is reduced (S730). Thereafter, the process returns to step S420 to check whether the reduced retransmission information value (Preempted ACID) is an initial value.

As a result of the check, if the retransmission information value (Preempted ACID) is the initial value, the UE sets the MIMO mode change scheduled value set to '1' in step S410 to '0' and the UE requests the MIMO mode maintained in step S700. As described above, the first MIMO mode is changed from the second MIMO mode (S430) to transmit subsequent data packets (S440).

If the retransmission information value (Preempted ACID) is not the initial value as a result of the check, the above-described process is repeated until the retransmission information value (Preempted ACID) is the initial value.

Again, returning to step S710, it is checked whether the number of retransmissions of the retransmission data packet is less than the set maximum retransmission number (S710).

As a result of checking in step S710, when the number of retransmissions of the retransmission data packet is less than the maximum number of retransmissions, the number of retransmissions of the corresponding data packet is increased (S740), and the data packet is retransmitted (S750). If the retransmission of the retransmission data packet is successful, since the number of data packets to be retransmitted is reduced, the retransmission information value (Preempted ACID) is reduced (S730). On the other hand, if the transmission of the retransmission data packet fails retransmission, the process returns to step S710, and repeats the above-described process.

When the data packet transmission method and the base station according to an embodiment of the present invention are requested to change the MIMO mode during the retransmission process of the data packet through the above-described method and configuration, the data packet transmission method and the base station change the MIMO mode according to the presence or absence of the retransmission data. By controlling, the data can be transmitted so that the data received by the terminal can be decoded smoothly.

Those skilled in the art to which the present invention pertains will understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features.

Therefore, it is to be understood that the embodiments described above are exemplary in all respects and not restrictive. The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention. do.

1 is a block diagram illustrating a base station supporting a data packet transmission method according to an embodiment of the present invention.

2 to 5 are flowcharts illustrating a data packet transmission method according to an embodiment of the present invention.

6 to 9 are frame configuration diagrams illustrating the configuration of a downlink frame in a data packet transmission method according to an exemplary embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

100: base station 110: ACID counting unit

120: burst allocator 130: MIMO mode feedback receiver

140: MIMO mode determination unit 150: burst transmission unit

160: map message creation unit

Claims (27)

In the data packet transmission method using MIMO and HARQ, Setting an initial value of retransmission information indicating the number of HARQ channels in use and an initial value of a MIMO mode; Generating a map information element for allocation indication of the MIMO mode and the HARQ subburst; Transmitting the data packet to a receiving unit and increasing the retransmission information value; Determining whether to retransmit the data packet according to whether to receive an ACK for the data packet transmitted from the receiver; And And if the ACK is received, reducing the retransmission information value, and if the ACK is not received, retransmitting the data packet. The method of claim 1, After setting the MIMO mode to the initial value, Confirming whether the transmission of the data packet is an initial transmission; And And as a result of the checking, further comprising the step of setting the MCS level in the case of initial transmission. The method of claim 1, Comparing the number of retransmissions of the transmitted data packet with the maximum number of retransmissions when the feedback is not received from the receiver or the received feedback is NACK; And If the number of retransmissions is greater than or equal to the maximum number of retransmissions, the method further comprises the step of abandoning the retransmissions. The method of claim 3, wherein After the step of giving up retransmission, And reducing the value of the retransmission information. The method of claim 3, wherein Increasing the number of retransmissions when the number of retransmissions of the transmitted data packets is less than the maximum number of retransmissions; Retransmitting the data packet while maintaining the MIMO mode and the MCS level of the previous transmission. The method of claim 1, The retransmission information value is represented by a preempted ACID. The method of claim 1, Data packet transmission method, characterized in that the default value of the MIMO mode is STTD (Matrix A). (a) receiving a MIMO mode change request from a first MIMO mode to a second MIMO mode; (b) determining whether there is a data packet to be retransmitted after receiving the MIMO mode change request; (c) changing the MIMO mode to the second MIMO mode when there is no data packet to be retransmitted as a result of the determination; or (d) If there is a data packet to be retransmitted as a result of the determination, the MIMO mode of the retransmitted data packet maintains the first MIMO mode, and the MIMO of data packets other than the retransmitted data packet changes the second MIMO mode. And transmitting the data packet. The method of claim 8, The step (b) is performed by checking the retransmission information value indicating the number of data packets for which retransmission can be requested. The method of claim 9, Before step (a), And increasing or decreasing the retransmission information value according to the increase or decrease of the number of data packets being transmitted. The method of claim 10, If the retransmission information value is the first value (initial value), maintain the MIMO mode, And if the retransmission information value is a second value different from the first value, change the MIMO mode to the second MIMO mode. The method of claim 11, The first value indicates that the retransmission data packet does not exist, The second value is a data packet transmission method, characterized in that the retransmission data packet exists. The method of claim 8, wherein after step (d), And allocating the retransmission data packet and the other data packet in the same frame, and allocating the retransmission data packet and the other data packet to different symbol intervals. The method of claim 13, Assigning the retransmission data packet to the first MIMO mode and assigning the retransmission data packet to a predetermined symbol region in the frame; And And assigning the second data packet to the second MIMO mode from the symbol region after the allocation of the retransmission data packet is completed. The method of claim 14, Checking whether a predetermined symbol region to which the retransmission data packet is allocated is a last symbol region; And And if it is the last symbol, allocating the other data packet to a symbol region of a frame different from the frame to which the retransmission data packet is allocated. The method of claim 8, wherein after step (d), And allocating the retransmission data packet and the other data packet in different frames. The method of claim 8, wherein after step (b), As a result of the determination, if there is a data packet to be retransmitted, the MIMO mode of the retransmitted data packet is maintained in the first MIMO mode and retransmitted. The other data packet comprises the step of delaying the change and transmission of the MIMO mode until the transmission of the retransmission data packet is completed. The method of claim 17, When the transmission of the retransmission data packet is completed, changing the MIMO mode of the other data packet to the second MIMO and transmitting the data packet. The method of claim 18, Completion of the transmission of the retransmission data packet indicates that the transmission of the retransmission data packet is successful or And abandoning retransmission because the number of retransmissions exceeds the maximum number of retransmissions. The method of claim 8, After the step (a), setting a MIMO mode change scheduled value (pending mode value) indicating whether to change the MIMO mode to a value different from the initial value; And After the step (d), further comprising the step of setting the MIMO mode change scheduled value changed to the other value as an initial value. Determining whether to retransmit a data packet to be transmitted when a MIMO mode change request from the first MIMO mode to the second MIMO mode is received; If it is determined that the data packet corresponds to retransmission, the data packet is transmitted in the first MIMO mode, And transmitting the data packet in the second MIMO mode if the data packet does not correspond to retransmission. The method of claim 21, And the retransmission is performed within a set maximum number of retransmissions. A receiver for receiving a MIMO mode change request; A MIMO mode determination unit which determines whether to change the MIMO mode according to whether to retransmit the data packet to be transmitted; And And a burst transmitter configured to transmit a data packet according to the MIMO mode determined by the MIMO mode determiner. The method of claim 23, The retransmission is a wireless communication system supporting HARQ and MIMO, characterized in that performed within the set maximum number of retransmissions. The method of claim 23, The MIMO mode determination unit includes an ACID counting unit for counting the ACID being used as the basis of the retransmission determination, The burst transmitter includes a map message generator for creating and assigning a downlink map message and an uplink message in a map area of a downlink frame according to the MIMO mode determined by the MIMO mode determiner. A wireless communication system supporting HARQ and MIMO. The method of claim 25, The ACID counting unit counts the ACID value being used, And if there is no data packet to be retransmitted, is set to a first value, and if there is a data packet to be retransmitted, the wireless communication system supports HARQ and MIMO. The method of claim 25, And the MIMO mode determining unit sets a different MIMO mode applied to a retransmitted data packet and a different MIMO mode applied to another newly transmitted data packet.

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