RU2518012C9 - Method and system for transmitting data frames and base station subsystem - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: invention relates to communication systems. A GPRS service support node splits a TCP retransmission packet into the data frames and adds retransmission identifiers to the data frames. In this way, after the base station subsystem receives a data frame, it can determine whether the data frame is the data frame obtained by splitting the TCP retransmission packet according to whether the data frame carries the retransmission identifier. If the data frame is the data frame obtained by splitting the TCP retransmission packet, the data frame is transmitted to a terminal as a priority, thus the transmission efficiency of the TCP retransmission packet is increased, which is the technical result.

EFFECT: method and system for transmitting data frames and a base station subsystem are provided.

12 cl, 7 dwg, 4 tbl

Description

FIELD OF TECHNOLOGY

The present invention relates to the field of mobile communications, and in particular to a method and system for transmitting data frames, as well as to a base station subsystem.

BACKGROUND

A radio access system based on the global mobile communication system / technology for increasing the data transfer rate for the evolution of the global mobile communication system (Global system for mobile communications (GSM) / enhanced data rate for GSM evolution (EDGE) radio access network, GERAN) is a system in which combines wired and wireless transmission. In the GERAN system, the bandwidth and external radio conditions have a significant effect on the wireless transmission, with the wireless transmission speed being lower than the wire transmission speed, and therefore, some of the data frames accumulate on the side of the base station subsystem. When transmitting transmission control protocol (TCP) data packets, TCP data loss may occur, in which case they must be retransmitted.

In the EDGE system, each TCP data packet is divided into a plurality of logic link control (LLC) control frames, and for each LLC frame, the corresponding LLC header is added and transmitted to the base station controller (BSC) using the serving general service packet radio support (service general packet radio service (GPRS) support node, SGSN); The BSC then partitions the LLC frame into blocks of a radio link control protocol transmitted over a wireless channel. In the GERAN system, each TCP data packet is divided into many frames of the GPRS tunneling protocol (user plane, GTP-U), with the corresponding GTP header added to each GTP-U frame and transmitted to the radio network controller (radio network controller, RNC) using SGSN; The RNC then splits the GTP-U frame into blocks of a packet data channel transmitted in a wireless data channel. The SGSN transmits a TCP data packet to the terminal via the BSC / RNC. After the loss of the TCP data packet, the terminal sends a retransmission request to the SGSN to request the retransmission of the lost TCP data packet. The number of the lost TCP data packet is less than the number of the current TCP data packet, therefore, the SGSN will priority transfer the lost TCP data packet.

Considering the EDGE system shown in FIG. 1 as an example, the SGSN places the retransmitted TCP packet at the top of the TCP queue and splits this retransmitted TCP packet into LLC frames for transmission to the BSC. The transmission from the BSC to the terminal is a wireless transmission, with the wireless transmission rate being lower than the wire transmission speed, as a result of which data frames transmitted from the SGSN will be accumulated on the BSC side. After receiving LLC frames of the retransmitted TCP packet, the BSC does not know that these frames are data frames into which the retransmitted TCP packet has been split, so the BSC does not transmit these frames of data priority. The BSC places these data frames after the LLC frames that have accumulated to the current time, that is, places them at the end of the LLC frame queue (LLC9, LLC8 and LLC7). These LLC frames are transmitted to the terminal only after the transmission of all LLC frames accumulated by the current moment of time, as a result of which the terminal receives the retransmitted TCP packet only after a certain period of time after the terminal sends the request for retransmission, while the transmission efficiency of the TCP packet is reduced.

SUMMARY OF THE INVENTION

The technical task of the present invention is the implementation of a method, a system for transmitting data frames and a base station subsystem, by which the efficiency of retransmission of TCP packets will be increased.

To solve the aforementioned technical problem, the following is a technical diagram in accordance with embodiments of the present invention.

A method for transmitting data frames, including:

receiving a data frame transmitted by a serving general purpose packet radio service (GPRS) support node;

determining whether the received data frame contains retransmission identification; and

priority transmission of the received data frame to the terminal if the data frame contains said retransmission identification.

Mentioned priority transmission of the received data frame to the terminal includes:

adding the received data frame to the retransmission queue;

wherein the retransmission queue is a queue of data frames transmitted priority to the terminal.

Said received data frame includes a logical link control frame or a GPRS tunneling protocol frame.

Said determination of whether the received data frame contains retransmission identification includes:

checking the value of the RIND field in the received data frame and determining whether the data frame contains a retransmission identification based on the value of the RIND field.

Said retransmission identification is: the identification added to each data frame by the serving GPRS support node after splitting the retransmitted Transmission Control Protocol (TCP) packet into at least one data frame.

Said verification of the value of the RIND field in the received data frame and determining whether the data frame contains retransmission identification based on the value of the RIND field includes:

determining that the data frame contains retransmission identification if the value of the RIND field is 1.

The base station subsystem includes:

a receiving module, configured to receive a data frame from a serving general purpose packet radio service (GPRS) support node;

a determining module, configured to determine if the received data frame contains retransmission identification; and

a processing unit configured to priority transmit the received data frame to the terminal if the data frame contains the retransmission identification.

Said processing module may be configured to add a data frame that contains the retransmission identification in the retransmission queue; wherein the retransmission queue is a queue of data frames transmitted priority to the terminal.

Said determination module includes a verification submodule and a determination submodule, wherein

said verification submodule is configured to check the value of the RIND field in the received data frame; and

said determination submodule is configured to determine whether the data frame contains retransmission identification based on the value of the RIND field.

A system for transmitting data frames includes:

a general purpose packet radio service (GPRS) support node configured to split retransmitted Transmission Control Protocol (TCP) packets into at least one data frame, add retransmission identification to each data frame, and transmit a data frame supplemented with retransmission identification , to the device of the base station subsystem; and

a base station subsystem configured to receive a data frame from a serving GPRS support node, determine if a data frame contains a retransmission identification, and priority transfers the data frame to the terminal if the data frame contains a retransmission identification.

The serving GPRS support node may be configured to add a RIND field to the free field of each data frame and set the value of the RIND field to indicate whether this data frame corresponds to a retransmitted TCP packet; and

said base station subsystem may be configured to check the value of the RIND field in the received data frame and determine whether this data frame contains retransmission identification based on the value of the RIND field.

Said serving GPRS support node may be configured to set the RIND field value to 1 to indicate that this data frame corresponds to a retransmitted TCP packet; and

said base station subsystem may be configured to determine that the data frame contains a retransmission identification if the checked value of the RIND field is 1.

Embodiments of the present invention have the following advantages: the serving GPRS support node splits the retransmitted TCP packet into data frames and adds retransmission identifiers to these data frames. Thus, the device of the base station subsystem, after receiving said data frames, can determine whether the data frame is one of the data frames into which the retransmitted TCP packet has been split, based on whether the said data frame contains the retransmission identifier. If the data frame is one of the data frames into which the retransmitted TCP packet has been split, then it is priority transmitted to the terminal, thereby increasing the transmission efficiency of the retransmitted TCP packet.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is a block diagram of a multilevel transmission of TCP data in a mobile communication system in the prior art;

Figure 2 is a flowchart of a method for transmitting data frames in accordance with one embodiment of the present invention;

Figure 3 is a block diagram of the structure of a base station subsystem in accordance with one embodiment of the present invention;

Figure 4 is a structural diagram of a system for transmitting data frames in accordance with one embodiment of the present invention;

5 is a flowchart of a method for transmitting data frames in accordance with another embodiment of the present invention;

6 is a block diagram of an LLC frame transmission queue by a base station controller in accordance with one embodiment of the present invention; and

7 is a block diagram of a GTP frame transmission queue by a wireless network controller in accordance with one embodiment of the present invention.

PREFERRED EMBODIMENTS OF THE PRESENT INVENTION

In order to provide a deeper understanding of the technical problem being solved, the technical scheme, and the advantages of various embodiments of the present invention, the present invention will be described in detail below in conjunction with the attached drawings and embodiments thereof.

Figure 2 is a flowchart of a method for transmitting data frames in accordance with one embodiment of the present invention. It presents a method of transmitting data frames, and in accordance with the image of figure 2, this embodiment of the present invention includes the following steps:

step 201: the base station subsystem receives a data frame transmitted by the serving GPRS support node;

step 202: the base station subsystem determines whether said data frame contains a retransmission identifier;

step 203: if said data frame contains a retransmission identifier, then the base station subsystem performs priority transmission of said data frame to a terminal.

If the data frame received by the base station subsystem contains a retransmission identifier, then this data frame is one of the data frames into which the retransmitted TCP packet has been split. Thus, the base station subsystem carries out priority transmission of said data frame to the terminal.

In the method of transmitting data frames according to this embodiment, the base station subsystem, upon receiving the data frame, can determine whether this data frame is allocated from the retransmitted TCP packet based on whether the data frame includes a retransmission identifier. If said data frame contains a retransmission identifier, it is determined that this data frame is extracted from the retransmitted TCP packet, and then the base station subsystem transmits this data frame priority to the terminal, thereby increasing the transmission efficiency of the retransmitted TCP packet.

Figure 3 is a block diagram of the structure of a base station subsystem in accordance with one embodiment of the present invention. In accordance with the image of FIG. 3, the base station subsystem includes, in the general case, a reception module 31, a determination module 32 and a processing module 33, wherein

a receiving unit 31 is configured to receive a data frame from a serving GPRS support node;

determination module 32 is configured to determine if a received data frame contains a retransmission identifier;

the processing unit 33 is configured to priority transmit the received data frame to the terminal if the data frame contains the said retransmission identifier.

The processing module 33 is configured to add said data frame containing a retransmission identifier to the retransmission queue. Said retransmission queue is a queue of data frames priority transmitted to the terminal.

The determination module 32 in the present invention includes a verification submodule 34 and a determination submodule 35, wherein

said verification submodule 34 is configured to check the value of the RIND field in the received data frame;

said determination submodule 35 is configured to determine if the data frame contains a retransmission identifier based on the value of the RIND field.

Namely, if the verification submodule 34 receives a RIND field value of 1, then the determining module 35 may determine that the retransmission identifier is contained in this data frame.

The base station subsystem in this embodiment of the present invention, after receiving said data frame, can determine whether this data frame is one of the data frames into which the retransmitted TCP packet has been split based on the fact of the content of the retransmission identifier in said data frame. If the data frame contains a retransmission identifier, then it can be determined that this data frame is one of the data frames into which the retransmitted TCP packet has been split, and therefore, the base station subsystem device transfers this data frame to the terminal, due to which increases the transmission efficiency of the retransmitted TCP packet.

4 is a structural block diagram of a system for transmitting data frames in accordance with one embodiment of the present invention. In accordance with the image of figure 4, this embodiment of the present invention includes:

a GPRS support serving node 41 configured to split the retransmitted TCP packet into at least one data frame, add a retransmission identifier to each data frame, and transmit a data frame supplemented with a retransmit identifier to the base station subsystem 42; and

a base station subsystem 42 configured to receive a data frame from a serving GPRS support node 41, determine if a data frame contains a retransmission identifier, and priority transfers the data frame to the terminal if the data frame contains a retransmit identifier.

The serving GPRS support node 41 may be configured to add a RIND field to the free field of each data frame and set the value of the RIND field to indicate whether this data frame corresponds to a retransmitted TCP packet;

base station subsystem 42 may be configured to check the value of the RIND field in said data frame and determine whether this data frame contains a retransmission identifier based on the value of the RIND field.

In particular, the serving GPRS support node 41 may set the RIND field to 1 to indicate that this data frame corresponds to a retransmitted TCP packet; wherein the base station subsystem 42 subsequently determines that the data frame contains a retransmission identifier if the check performed by the base station subsystem 24 indicates that the value of the RIND field is 1.

In the EDGE system, the base station subsystem 42 may be located in the base station controller. In the GERAN system, the base station subsystem 42 may reside in a wireless network controller.

In a system for transmitting data frames in accordance with one embodiment of the invention, the SGSN splits the retransmitted TCP packet into data frames and adds a retransmission identifier to each of these data frames. Thus, the device of the base station subsystem after receiving said data frame can determine whether the data frame is one of the data frames into which the retransmitted TCP packet has been split, based on whether the said data frame contains a retransmission identifier. If the data frame is one of the data frames into which the retransmitted TCP packet has been split, then it is priority transmitted to the terminal, whereby the retransmitted TCP packet is transmitted priority, transmission efficiency of the retransmitted TCP packet is increased.

With the example of an EDGE system, a method for transmitting data frames in accordance with one embodiment of the invention will be described in more detail below. In accordance with FIG. 5, this embodiment of the present invention includes the following steps:

step 501, the SGSN splits the retransmitted TCP packet into at least one LLC frame.

For example, the SGSN receives a retransmission request sent by a terminal that requests retransmission of TCP data packet number 0, after which the SGSN splits TCP 0 data packet into at least one LLC frame. For example, SGSN can split TCP 0 data packet into 3 LLC frames.

Step 502, the SGSN adds the RIND identification field to the free field of the LLC frame.

In the EDGE system, the LLC frame is encapsulated in the Base Station System GPRS Protocol (BSSGP) in the GPRS protocol. The serving GPRS support node adds the RIND identification field to the free field of the BSSGP frame structure. For example, the RIND identification field is added to the SPARE field of the QoS Profile field. The structure of the QoS Profile field before the addition of the RIND field is shown in Table 1.

Table 1 8 7 6 5 four 3 2 one octet 1 IEI octet 2, 2a Length indicator octet 3-4 The maximum peak bitrate that can be processed by the network (Bucket Leak Rate), "R value", see subsection 11.3.4 (note) octet 5 SPARE C / r T BUT A priority NOTE: bitrate 0 (zero) should mean "maximum possible" in this information element (IE).

The structure of the QoS Profile field after the mentioned addition of the RIND field is shown in Table 2.

table 2 8 7 6 5 four 3 2 one octet 1 IEI octet 2, 2a Length indicator octet 3-4 The maximum peak bitrate that can be processed by the network (Bucket Leak Rate), "R value", see subsection 11.3.4 (note) octet 5 SPARE Rind T BUT A priority NOTE: bitrate 0 (zero) should mean "maximum possible" in this information element (IE).

Step 503, the SGSN fills in the RIND field and transmits the LLC frame to the base station subsystem device.

The QoS Profile field is optional. When retransmitting the TCP 0 data packet, the SGSN must add a QoS Profile field to each LLC frame into which the TCP 0 data packet was split, and fill in the RIND field. In particular, SGSN can fill the RIND field with a value of 1, meaning that this LLC frame is one of the frames into which the transmitted TCP packet was split.

Step 504, the base station controller checks the value of the RIND field in the LLC frame.

In the EDGE system, the base station subsystem is located in the base station controller. When the base station controller receives the LLC frame, there is no need to process all the fields in the QoS Profile field, just check the value of the RIND field.

Step 505, if the value of the RIND field is 1, the base station controller places the LLC frame in the retransmission queue.

If the value of the RIND field is 1, this means that this LLC frame is one of the LLC frames into which the retransmitted TCP packet has been split. The base station controller creates the LLC normal transmission queue and the LLC retransmission queue. When transmitting an LLC frame to a terminal, the base station controller transmits LLC frames from the LLC retransmission queue.

For example, SGSN can split TCP 0 data packet into 3 LLC frames, add the RIND identification field to the free field of each of the 3 mentioned LLC frames, set the RIND fields to 1 and then transfer these 3 LLC frames to the base station controller. After receiving the mentioned 3 frames LLC, the base station controller places these 3 frames LLC in the queue after the currently accumulated LLC frames. 6 is a block diagram of an LLC frame transmission queue by a base station controller in accordance with one embodiment of the present invention. In accordance with FIG. 6, LLC 9, LLC 8 and LLC 7 are the 3 mentioned LLC frames. After determining that these 3 LLC frames are LLC frames into which the retransmitted TCP packet has been split, the base station controller places LLC 9, LLC 8 and LLC 7 in the retransmission queue. When LLC frames are transmitted, priority frames are transferred from the LLC retransmission queue if the LLC retransmission queue is not empty.

The technical scheme of the present invention can also be applied to the GERAN system. In the GERAN system, which is different from the EDGE system, the base station subsystem is located in the wireless controller, while the SGSN splits the TCP data packet into GTP-U frames; wherein the RIND identification field is added to the free field of the header structure of each GTP-U frame. The GTP-U frame header structure before the mentioned addition of the RIND field is shown in Table 3.

Table 3 Bits Octets 8 7 6 5 four 3 2 one one Version RT ABOUT E S PN 2 Message type 3 Length (1st octet) four Length (2nd octet) 5 Tunnel Endpoint Identifier (1st octet) 6 Tunnel Endpoint Identifier (2nd octet) 7 Tunnel Endpoint Identifier (3rd octet) 8 Tunnel Endpoint Identifier (4th octet) 9 Sequence number (1st octet) 1) 4) 10 Sequence number (2nd octet) 1) 4) eleven N-PDU Number 2) 4) 12 The header type of the next extension 3) 4)

The header structure of the GTP-U frame after the aforementioned addition of the RIND field is shown in Table 4.

Table 4 Bits Octets 8 7 6 5 four 3 2 one one Version RT Rind E S PN 2 Message type 3 Length (1st octet) four Length (2nd octet) 5 Tunnel Endpoint Identifier (1st octet) 6 Tunnel Endpoint Identifier (2nd octet) 7 Tunnel Endpoint Identifier (3rd octet) 8 Tunnel Endpoint Identifier (4th octet) 9 Sequence number (1st octet) 1) 4) 10 Sequence number (2nd octet) 1) 4) eleven N-PDU Number 2) 4) 12 The header type of the next extension 3) 4)

For example, an SGSN can split a TCP 0 data packet into 3 GTP-U frames, add the RIND identification field to the free field of each of the 3 mentioned GTP-U frames, set the RIND fields to 1 and then transfer these 3 GTP-U frames to the base controller stations. After receiving the mentioned 3 GTP-U frames, the base station controller places these 3 GTP-U frames in the queue after the GTP-U frames accumulated by the current moment. 7 is a block diagram of a GTP-U frame transmission queue by a base station controller in accordance with one embodiment of the present invention. In accordance with FIG. 7, GTP 9, GTP 8, and GTP 7 are the 3 mentioned GTP-U frames. After determining that these 3 GTP-U frames are GTP-U frames into which the retransmitted TCP packet has been split, the base station controller places GTP 9, GTP 8 and GTP 7 in the retransmission queue. When transmitting GTP-U frames, priority transmission of frames from the GTP-U retransmission queue is performed if the GTP-U retransmission queue is not empty.

In the method of transmitting data frames of this embodiment of the present invention, the SGSN splits the retransmitted TCP packet into data frames and adds retransmission identifiers to these data frames. Thus, after receiving said data frames, the base station controller or the wireless network controller can determine whether the data frame contains a retransmission identifier. If the data frame is one of the data frames into which the retransmitted TCP packet has been split, then this data frame is priority transmitted to the terminal, which ensures the priority transmission of the retransmitted TCP packet and the transmission efficiency of the retransmitted TCP packets is realized.

An embodiment of the method in the present invention corresponds to an embodiment of the device. For a description of parts not described in detail in an embodiment of the method, one can refer to a description of the corresponding parts in an embodiment of the device, while parts not described in detail in an embodiment of the device can be referred to a description of corresponding parts in an embodiment of the method.

For a person skilled in the art it is obvious that all steps (or part thereof) implementing the method embodiment described above can be performed by programs that execute the corresponding hardware, while said programs can be stored on a computer-readable storage medium; when executing programs, the steps of the method embodiment described above are performed; wherein said storage medium may be, for example, a magnetic disk, an optical disk, read only memory (ROM) or random access memory (RAM), or the like.

In any of the embodiments of the method of the present invention, step numbers cannot be used to limit the sequence of steps. For a person skilled in the art it is obvious that changes in the sequence of steps without changing the concept of the present invention should be included in the scope of the present invention.

The above description represents preferred embodiments of the present invention. For a person skilled in the art it should be obvious that many modifications and changes can be made without departing from the described concept of the present invention, while all such modifications and improvements are included in the scope of the present invention.

Claims (12)

1. A method of transmitting data frames, including:
receiving a data frame transmitted by a serving general purpose packet radio service (GPRS) support node, wherein if said data frame is a data frame corresponding to a retransmission transmission control protocol (TCP) packet, the serving GPRS support node adds a RIND field to the free field of said a data frame and sets the value of said RIND field to the corresponding retransmission identification;
determining whether the received data frame contains said retransmission identification; and
priority transmission of the received data frame to the terminal if the data frame contains said retransmission identification. 2. The method according to claim 1, wherein said priority transmission of the received data frame to the terminal includes:
adding the received data frame to the retransmission queue; wherein the retransmission queue is a queue of data frames transmitted priority to the terminal. 3. The method of claim 1, wherein said received data frame includes a logical link control frame or a GPRS tunneling protocol frame. 4. The method according to claim 1, wherein said determining whether the received data frame contains retransmission identification includes:
checking said RIND field value in the received data frame and determining if the data frame contains retransmission identification based on the value of the RIND field. 5. The method according to any one of claims 1 to 4, wherein said retransmission identification is: an identification in said RIND field added to each data frame by a serving GPRS support node after splitting the retransmitted transmission control protocol packet into at least one frame data. 6. The method according to claim 4, wherein said checking the value of the RIND field in the received data frame and determining whether the data frame contains a retransmission identification based on the value of the RIND field includes:
determining that the data frame contains retransmission identification if the value of the RIND field is 1. 7. The base station subsystem, including:
a receiving module configured to receive a data frame from a serving general purpose packet radio service (GPRS) support node, while if the data frame is a data frame corresponding to a retransmitted transmission control protocol (TCP) packet, the serving GPRS support node adds a field RIND in a free field of said data frame and sets the value of said RIND field to match the retransmission identification;
a determining module, configured to determine if the received data frame contains retransmission identification; and
a processing unit configured to priority transmit the received data frame to the terminal if the data frame contains a retransmission identification. 8. The base station subsystem according to claim 7, in which
said processing module is configured to add a data frame that contains a retransmission identification in a retransmission queue; wherein the retransmission queue is a queue of data frames transmitted priority to the terminal. 9. The base station subsystem according to claim 7, in which said determination module includes a verification submodule and a determination submodule, wherein
said verification submodule is configured to verify said value of a RIND field in a received data frame; and
said determination submodule is configured to determine whether the data frame contains retransmission identification based on the value of the RIND field. 10. A system for transmitting data frames, including:
a serving General Packet Radio Service (GPRS) support node configured to split retransmitted packets of the transmission control protocol into at least one data frame, add a RIND field to the free field of each data frame, set the value of said RIND field to correspond to the retransmission identification, and transmitting a data frame containing a retransmission identification to a base station subsystem; and
a base station subsystem configured to receive a data frame from a serving GPRS support node, determine if a data frame contains a retransmission identification, and priority transfers the data frame to the terminal if the data frame contains a retransmission identification. 11. The system of claim 10, in which
the serving GPRS support node is configured to set said RIND field value to an appropriate identification indicating whether this data frame corresponds to a retransmission packet of a transmission control protocol; and
said base station subsystem is configured to check the value of the RIND field in the received data frame and determine whether this data frame contains retransmission identification based on the value of the RIND field. 12. The system of claim 10, in which
said serving GPRS support node is configured to set the RIND field value to 1 to indicate that this data frame corresponds to a retransmission packet of a transmission control protocol; and
said base station subsystem is configured to determine that the data frame contains a retransmission identification if the checked value of the RIND field is 1.

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