JP2004364277A - Packet communication method and packet communication system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a packet communication system which can change the transmission rate of a downlink packet, while preventing the throughput from being reduced, due to the deletion of the packet stored in the transmission buffer 11, and provide a packet communication method. <P>SOLUTION: The packet communication system for transmitting a packet at a predetermined transmission rate includes a packet size management part 14 configured to change the size of the packet in accordance with the available state of the transmission buffer 11 for storing the packet when changing the predetermined transmission rate (from Tx1 to Tx2). <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a packet communication method and a packet communication system for transmitting a packet at a predetermined transmission rate. In particular, the present invention relates to "HSDPA (High speed)," which is a packet communication technology for the purpose of increasing the peak transmission speed in the downlink direction, reducing the transmission delay, increasing the throughput, and improving the efficiency of radio resources. The present invention relates to a packet communication method and a packet communication system using a “downlink packet access” scheme.

  FIG. 1 shows a packet communication system using the HSDPA method. As shown in FIG. 1, the packet communication system includes a core network CN and a radio access network RAN including a plurality of radio control devices RNC and radio base station devices Node B.

  In addition, the radio access network RAN is connected to the mobile station UE via a radio interface. As shown in FIG. 1, the radio access network RAN transmits a transport channel “HS-DSCH (High speed-Downlink Shared Channel)” for downlink packet transmission to the mobile device UE.

  Here, with reference to the flowchart shown in FIG. 2, a description will be given of how the transmission rate of the downlink packet is changed in the conventional packet communication system (for example, see Non-Patent Documents 1 and 2).

  As shown in FIG. 2, in step 601, between the radio access network RAN and the mobile station UE, on a logical channel “DTCH (Dedicated Traffic Channel)” mapped to the HS-DSCH, an RLC (Radio Link Control) is provided. 3.) A connection is established. Here, the transmission rate of the downlink packet (the transmission rate of the HS-DSCH or the transmission rate of the DTCH) is “Tx1 (384 kbps or less)”, and the packet transmitted via the RLC connection (RLC-PDU: Radio Link). It is assumed that the size of the Control-Packet Data Unit is “336 bits”.

  In step 602, the radio access network RAN changes the transmission rate of packets in the downlink direction, for example, when the data amount of packets to be transmitted increases. For example, the transmission rate of the downlink packet is changed to “Tx2 (over 384 kbps)”.

  In step 603, when the transmission rate of the packet in the downlink direction is changed, a Re-establishment of the RLC connection between the radio access network RAN and the mobile station UE occurs.

In step 604, the size of the RLC-PDU is changed to “656 bits” after the occurrence of the above-described R-establishment of the RLC connection. Such a change in the RLC-PDU size takes into account transmission efficiency.
3rd Generation Partnership Project Project Technical Specification Group Radio Access Network, 25.321 V5.4.0 Medium Access Control (MAC) 25.322 V5.4.0 Radio Link Control (RLC) 3rd Generation Partnership Project Technology Technical Specification Group Radio Access Network, 25.322 V5.4.0 Radio Link Control (RLC)

  However, in the conventional packet communication system, when the transmission rate of the downlink packet is changed, R-establishment of the RLC connection occurs, so that the packet accumulated in the transmission buffer is deleted, and the throughput is reduced. There was a problem.

  SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and has been made in view of the above, and has been made in view of the above. Packet communication that makes it possible to change the transmission rate of downlink packets while preventing a decrease in throughput due to deletion of packets stored in a transmission buffer It is an object to provide a method and a packet communication system.

  A first feature of the present invention is a packet communication method for transmitting a packet at a predetermined transmission rate, wherein when changing the predetermined transmission rate, the packet communication method is performed according to a vacant state of a transmission buffer for storing the packet. Therefore, the gist of the present invention is to change the size of the packet.

  A second feature of the present invention is a packet communication system for transmitting a packet at a predetermined transmission rate, wherein when the predetermined transmission rate is changed, the packet communication system responds to the availability of a transmission buffer for storing the packet. Therefore, the gist of the present invention is to include a packet size management unit for changing the size of the packet.

  According to this invention, when the data amount of the packet stored in the transmission buffer is large, for example, when the data amount of the packet stored in the transmission buffer is large, the size of the packet is not changed, so that the transmission by the R-establishment of the RLC connection is performed. Deletion of packets in the buffer can be prevented.

  In the second aspect of the present invention, the packet size management unit is configured to determine whether a data amount of the packet stored in the transmission buffer is equal to or greater than a first data amount threshold, or that the remaining amount of the transmission buffer is If the packet size is equal to or less than the first buffer remaining amount threshold, the size of the packet may not be changed.

  In the second aspect of the present invention, the data amount of the packet stored in the transmission buffer is equal to or larger than a second data amount threshold, or the remaining amount of the transmission buffer is equal to a second buffer remaining amount. If the transmission rate is equal to or less than the threshold, the transmission rate changing unit may be configured to change the predetermined transmission rate to a higher transmission rate.

  Further, in the second aspect of the present invention, the transmission rate changing unit determines whether a data amount of the packet accumulated in the transmission buffer is equal to or larger than the second data amount threshold continuously for a certain period of time, Alternatively, when the remaining amount of the transmission buffer is continuously equal to or less than the second buffer remaining amount threshold for a predetermined period, the predetermined transmission speed may be changed to a higher transmission speed.

  As described above, according to the present invention, a packet communication method capable of changing the transmission rate of downlink packets while preventing a decrease in throughput due to deletion of packets stored in the transmission buffer 11 is provided. A packet communication system can be provided.

(Configuration of the packet communication system according to the first embodiment of the present invention)
The configuration of the radio access network RAN in the packet communication system according to the first embodiment of the present invention will be described with reference to FIG.

  The radio access network RAN according to the present embodiment includes a transmission buffer 11, a transmission buffer management unit 12, a transmission speed management unit 13, a packet size management unit 14, and a transmission unit 15.

  The transmission buffer 11 stores packets (RLC-PDU) to be transmitted to the mobile station UE via the RLC connection. Further, the transmission buffer 11 may be configured to accumulate packets to be retransmitted to the mobile station UE via the RLC connection. In addition, the transmission buffer 11 may be configured to delete packets that have been stored for a predetermined period of time, packets that have been retransmitted a predetermined number of times, and the like.

  The transmission buffer management unit 12 manages the vacancy status in the transmission buffer 11. Specifically, the transmission buffer management unit 12 manages the data amount (the number of bits or the number of packets) of the packets stored in the transmission buffer 11, the remaining amount (the free space) of the transmission buffer 11, and the like. .

  The transmission rate management unit 13 manages the transmission rate of packets in the downlink direction to the mobile station UE.

  For example, as shown in FIG. 4, when the data amount x of the packet stored in the transmission buffer 11 is continuously equal to or more than the second data amount threshold Thd2 for a certain period, the transmission rate management unit 13 The transmission rate of packets in the direction can be changed from a predetermined transmission rate Tx1 (for example, 384 kbps or less) to a higher transmission rate Tx2 (for example, over 384 kbps).

  When the average value of the data amount x of the packets stored in the transmission buffer 11 during the predetermined period is equal to or greater than the second data amount threshold Thd2, the transmission speed management unit 13 determines the transmission speed of the downlink packet. Can be changed from a predetermined transmission rate Tx1 to a higher transmission rate Tx2.

  Also, as shown in FIG. 4, when the remaining amount Br of the transmission buffer 11 is equal to or less than the second buffer remaining amount threshold Thbr2 for a certain period of time, the transmission rate management unit 13 The speed can be changed from the predetermined transmission speed Tx1 to a higher transmission speed Tx2.

  When the average value of the remaining amount Br of the transmission buffer 11 during a predetermined period is equal to or less than a second buffer remaining amount threshold Thbr2, the transmission speed management unit 13 determines the transmission speed of the downlink packet by a predetermined transmission amount. The transmission rate Tx1 can be changed to a higher transmission rate Tx2.

  As described above, the transmission rate management unit 13 can change the transmission rate of the downstream packet to a higher transmission rate when the data amount of the packet to be transmitted increases.

  Further, the transmission rate management unit 13 reduces the transmission rate of the downlink packet to a higher transmission rate when a predetermined condition such as when the condition of the radio channel with the mobile station UE is improved is satisfied. It may be configured to change.

  The packet size management unit 14 manages the size of a packet to be transmitted to the mobile station UE over the RLC connection (that is, the size of the RLC-PDU).

  Further, the packet size management unit 14 is configured to generate a R-establishment of the RLC connection when changing the transmission speed of the packet in the downlink direction, and change the size of the above-described packet.

  In principle, the packet size management unit 14 is configured to increase the size of the above-mentioned packet when the transmission speed of the downstream packet changes from the predetermined transmission speed Tx1 to the high transmission speed Tx2. For example, in such a case, the packet size management unit 14 changes the size of the above-mentioned packet from “336 bits” to “656 bits”.

  However, as shown in FIG. 4, even when changing the transmission rate of the packet in the downlink direction, the packet size management unit 14 sets the data amount x of the packet stored in the transmission buffer 11 to the first value. When the data amount is equal to or larger than the threshold value Thd1, the configuration is such that the Re-establishment of the RLC connection does not occur and the size of the packet is not changed.

  As shown in FIG. 4, the packet size management unit 14 determines that the remaining amount Br of the transmission buffer 11 is equal to or less than the first buffer remaining amount threshold Thbr1 even when the transmission speed of the downstream packet is changed. In the case of, the configuration is such that Re-establishment of the RLC connection is not generated and the size of the above-mentioned packet is not changed.

  As described above, the packet size management unit 14 does not change the packet size when the data amount of the packet stored in the transmission buffer 11 is large (that is, when the free space of the transmission buffer 11 is small). Deletion of a packet in the transmission buffer due to Re-establishment of the RLC connection can be prevented.

  The transmission unit 15 transmits a packet to the mobile station UE at the transmission rate specified by the transmission rate management unit 13 and at the RLC-PDU size specified by the packet size management unit 14.

  Note that the transmission buffer 11, the transmission buffer management unit 12, the transmission rate management unit 13, the packet size management unit 14, and the transmission unit 15 may be any one of the radio control device RNC and the radio base station device Node B configuring the radio access network RAN. It is sufficient if it is provided in the crab.

(Packet communication method according to the present embodiment)
With reference to FIG. 5 and FIG. 6, an operation of changing the transmission rate of a downstream packet in the packet communication method according to the present embodiment will be described.

  As shown in FIG. 5, in step 301, an RLC connection is established between the radio access network RAN and the mobile station UE. Here, it is assumed that the transmission rate of the downlink packet is “Tx1 (384 kbps or less)” and the size of the RLC-PDU is “336 bits”.

  In step 302, the transmission rate manager 13 of the radio access network RAN determines whether or not the data amount x of the packet stored in the transmission buffer 11 is equal to or greater than a second data amount threshold Thd2. If the data amount x is equal to or greater than the second data amount threshold Thd2, the flow proceeds to step 303. If the data amount x is not equal to or greater than the second data amount threshold Thd2, the flow repeats step 302.

  In step 303, the transmission rate management unit 13 changes the transmission rate of the downstream packet. That is, the transmission rate of the downlink packet is changed to “Tx2 (over 384 kbps)”.

  In step 304, the packet size management unit 14 of the radio access network RAN determines whether the data amount x of the packet stored in the transmission buffer 11 is equal to or greater than the first data amount threshold Thd1. If the data amount x is not equal to or greater than the first data amount threshold Thd1, the flow proceeds to step 305. If the data amount x is equal to or greater than the first data amount threshold Thd1, the flow repeats step 304.

  In step 305, Re-establishment of the RLC connection between the radio access network RAN and the mobile station UE occurs.

  In step 306, the size of the RLC-PDU is changed to “656 bits” after the occurrence of the above-described R-establishment of the RLC connection.

  Also, as shown in FIG. 6, the packet communication method according to the present embodiment changes the transmission rate of the downlink packet by changing steps 302 and 304 shown in FIG. 5 to steps 402 and 404. May be configured.

  As shown in FIG. 6, in step 402, the transmission rate management unit 13 of the radio access network RAN determines whether the remaining amount Br of the transmission buffer 11 is equal to or less than a second buffer remaining amount threshold Thbr2. If the remaining amount Br of the transmission buffer 11 is equal to or less than the second buffer remaining amount threshold Thbr2, the flow proceeds to step 403. If the remaining amount Br of the transmission buffer 11 is not equal to or less than the second buffer remaining amount threshold Thbr2, The flow repeats step 402.

  In step 404, the packet size management unit 14 of the radio access network RAN determines whether the remaining amount Br of the transmission buffer 11 is equal to or less than a first buffer remaining amount threshold Thbr1. If the remaining amount Br of the transmission buffer 11 is not equal to or less than the first buffer remaining amount threshold Thbr1, the flow proceeds to step 405, and if the remaining amount Br of the transmission buffer 11 is equal to or less than the first buffer remaining amount threshold Thbr1, The flow repeats step 404.

  Next, with reference to FIGS. 7 to 9, the operation of the radio access network RAN when changing the transmission rate of the downlink packet will be described from the viewpoint of the protocol architecture.

  First, the example of FIG. 7 will be described. In step 701, the protocol function (RLC entity) of the RLC layer of the radio access network RAN determines the amount of RLC-PDU data to be transmitted (or retransmitted) to the mobile station UE via the RLC connection stored in the transmission buffer 11. Monitor x.

  In step 702, when the predetermined condition is satisfied in the transmission buffer 11, the RLC layer protocol function determines that the data amount x of the RLC-PDU in the transmission buffer 11 continues for a certain period and the second data amount threshold Thd2. In the case where the transmission rate is equal to or greater than the above, or when the remaining amount Br of the transmission buffer 11 is continuously equal to or less than the second buffer remaining amount threshold Thbr2 for a predetermined period, the transmission rate of the DTCH corresponding to the RLC connection is set to a predetermined transmission rate. It instructs the MAC layer protocol function (MAC entity) to change from Tx1 to a higher transmission rate Tx2.

  In step 703, the protocol function of the MAC layer changes the transmission rate of the HS-DSCH mapped to the DTCH from a predetermined transmission rate Tx1 to a higher transmission rate in response to an instruction from the protocol function of the RLC layer. Instruct the physical layer protocol function to change to Tx2.

  The physical layer protocol function changes the transmission rate of the physical channel mapped to the HS-DSCH from a predetermined transmission rate Tx1 to a higher transmission rate Tx2 according to an instruction from the protocol function of the MAC layer. .

  In step 704, when the protocol function of the RLC layer instructs the protocol function of the MAC layer to change the transmission rate of the DTCH, the measurement result of the data amount x of the RLC-PDU in the transmission buffer 11 is Notify the layer protocol function.

  In step 705, the protocol function of the upper layer determines whether the data amount x of the RLC-PDU in the transmission buffer 11 is equal to or larger than the first data amount threshold Thd1, or if the remaining amount Br of the transmission buffer 11 is It is determined whether or not the buffer remaining amount threshold value is equal to or smaller than the threshold value Thbr1.

  If the data amount x of the RLC-PDU in the transmission buffer 11 is not more than the first data amount threshold Thd1, or if the remaining amount Br of the transmission buffer 11 is not less than the first buffer remaining amount threshold Thbr1, the protocol of the upper layer The function notifies the RLC layer protocol function of a Re-establish request instructing to change the size of the RLC-PDU.

  On the other hand, when the data amount x of the RLC-PDU in the transmission buffer 11 is equal to or more than the first data amount threshold Thd1, or when the remaining amount Br of the transmission buffer 11 is equal to or less than the first buffer remaining amount threshold Thbr1, The upper layer protocol function does not notify the RLC layer protocol function of a Re-establish request.

  In step 706, the protocol function of the RLC layer performs a Re-establish process in response to a Re-establish request from the protocol function of the upper layer.

  Specifically, the protocol function of the RLC layer sets up a new RLC connection with the protocol function of the RLC layer in the mobile station UE after discarding all RLC-PDUs in the transmission buffer 11.

  Note that the size of the RLC-PDU transmitted on the newly set RCL connection has been changed to the size indicated by the Re-establish request, and the RLC-PDU transmitted on the previous RCL connection is usually changed. Larger than the size of.

  Second, the example of FIG. 8 will be described. In step 801, the protocol function of the RLC layer of the radio access network RAN monitors the data amount x of the RLC-PDU to be transmitted (or retransmitted) to the mobile station UE via the RLC connection stored in the transmission buffer 11. .

  In step 802, the protocol function of the RLC layer notifies the upper layer of the measurement result of the data amount x of the RLC-PDU in the transmission buffer 11 at a predetermined cycle.

  In step 803, the upper layer protocol function determines whether to change the transmission speed and size of the RLC-PDU transmitted on the RLC connection according to the measurement result from the RLC layer protocol function.

  When a predetermined condition is satisfied in the transmission buffer 11, the upper layer protocol function notifies the RLC layer protocol function of a Re-establish request that instructs the RLC layer protocol function to change the transmission speed and size of the RLC-PDU. .

  For example, the data amount x of the RLC-PDU in the transmission buffer 11 is continuously equal to or greater than the second data amount threshold Thd2 for a certain period, and the data amount x of the RLC-PDU in the transmission buffer 11 is equal to the first data amount Thd2. If the data amount threshold is smaller than Thd1, the protocol function of the upper layer notifies the protocol function of the RLC layer of a Re-establish request.

  Further, when the remaining amount Br of the transmission buffer 11 is equal to or less than the second buffer remaining amount threshold Thbr2 for a certain period of time, and the remaining amount Br of the transmission buffer 11 is not equal to or less than the first buffer remaining amount threshold Thbr1. The upper layer protocol function notifies the RLC layer protocol function of a Re-establish request.

  In other cases, the upper layer protocol function does not notify the RLC layer protocol function of a Re-establish request.

  In step 804, in response to the Re-establish request from the protocol function of the upper layer, the protocol function of the RLC layer changes the transmission rate of the DTCH corresponding to the RLC connection from a predetermined transmission rate Tx1 to a higher transmission rate. (Transmission rate instructed in Re-establish request) Instructs the MAC layer protocol function to change to Tx2.

  In step 805, the protocol function of the MAC layer changes the transmission rate of the HS-DSCH mapped to the DTCH from a predetermined transmission rate Tx1 to a higher transmission rate in response to an instruction from the protocol function of the RLC layer. Instruct the physical layer protocol function to change to Tx2.

  The physical layer protocol function changes the transmission rate of the physical channel mapped to the HS-DSCH from a predetermined transmission rate Tx1 to a higher transmission rate Tx2 according to an instruction from the protocol function of the MAC layer. .

  In step 806, the protocol function of the RLC layer performs a re-establish process in response to a re-establish request from the protocol function of the step upper layer, as in step 706 described above.

  Third, the example of FIG. 9 will be described. In step 901, the protocol function of the RLC layer of the radio access network RAN monitors the data amount x of the RLC-PDU to be transmitted (or retransmitted) to the mobile station UE via the RLC connection stored in the transmission buffer 11. .

  Here, the protocol function of the RLC layer determines whether to change the transmission rate and size of the RLC-PDU transmitted on the RLC connection according to the measurement result of the data amount x of the RLC-PDU in the transmission buffer 11. to decide.

  When the predetermined condition is satisfied in the transmission buffer 11, the RLC layer protocol function instructs the MAC layer protocol function to change the transmission rate of the RLC-PDU in step 902.

  For example, when the data amount x of the RLC-PDU in the transmission buffer 11 is continuously equal to or more than the second data amount threshold Thd2 for a certain period, or when the remaining amount Br of the transmission buffer 11 continues for a certain period. When the buffer capacity is equal to or smaller than the second buffer remaining capacity threshold Thbr2, the protocol function of the RLC layer changes the transmission rate of the DTCH corresponding to the RLC connection from a predetermined transmission rate Tx1 to a higher transmission rate Tx2. Then, it instructs the protocol function of the MAC layer.

  In step 903, the protocol function of the MAC layer changes the transmission rate of the HS-DSCH mapped to the DTCH from a predetermined transmission rate Tx1 to a higher transmission rate in response to an instruction from the protocol function of the RLC layer. Instruct the physical layer protocol function to change to Tx2.

  The physical layer protocol function changes the transmission rate of the physical channel mapped to the HS-DSCH from a predetermined transmission rate Tx1 to a higher transmission rate Tx2 according to an instruction from the protocol function of the MAC layer. .

  In step 904, when the protocol function of the RLC layer instructs the protocol function of the MAC layer to change the transmission rate of the DTCH, the data amount x of the RLC-PDU in the transmission buffer 11 becomes equal to the first data amount. It is determined whether or not the threshold value is equal to or greater than the threshold Thd1, or whether the remaining amount Br of the transmission buffer 11 is equal to or less than the first buffer remaining amount threshold Thbr1.

  If the data amount x of the RLC-PDU in the transmission buffer 11 is not equal to or larger than the first data amount threshold Thd1, or if the remaining amount Br of the transmission buffer 11 is not equal to or smaller than the first buffer remaining amount threshold Thbr1, the RLC layer protocol The function performs the Re-establish process as in step 706 described above.

  On the other hand, when the data amount x of the RLC-PDU in the transmission buffer 11 is equal to or more than the first data amount threshold Thd1, or when the remaining amount Br of the transmission buffer 11 is equal to or less than the first buffer remaining amount threshold Thbr1, The protocol function of the RLC layer does not perform the above-described Re-establish processing.

(Operation / Effect of Packet Communication System and Packet Communication Method According to Present Embodiment)
According to the packet communication system and the packet communication method according to the present embodiment, for example, when the data amount x of the packet stored in the transmission buffer 11 is large (that is, when the transmission buffer 11 (When the free space Br is small), it is possible to prevent the packet in the transmission buffer from being deleted due to the re-establishment of the RLC connection by not changing the packet size.

1 is an overall configuration diagram of a packet communication system including a radio access network. FIG. 11 is a flowchart illustrating an operation of changing a packet transmission speed and a size in a wireless access network according to the related art. FIG. 2 is a functional block diagram of a wireless access network according to an embodiment of the present invention. FIG. 3 is a diagram for explaining a transmission buffer in the wireless access network according to one embodiment of the present invention. FIG. 4 is a flowchart illustrating an operation of changing a transmission speed and a size of a packet in a wireless access network according to an embodiment of the present invention. FIG. 4 is a flowchart illustrating an operation of changing a transmission speed and a size of a packet in a wireless access network according to an embodiment of the present invention. FIG. 7 is a sequence diagram illustrating an example of an operation of changing a packet transmission speed and a size as viewed from a protocol architecture in a wireless access network according to an embodiment of the present invention. FIG. 7 is a sequence diagram illustrating an example of an operation of changing a packet transmission speed and a size as viewed from a protocol architecture in a wireless access network according to an embodiment of the present invention. FIG. 7 is a sequence diagram illustrating an example of an operation of changing a packet transmission speed and a size as viewed from a protocol architecture in a wireless access network according to an embodiment of the present invention.

Explanation of reference numerals

CN: Core network RAN: Radio access network RNC: Radio control device Node B: Radio base station device UE: Mobile station 11: Transmission buffer 12: Transmission buffer manager 13: Transmission speed manager 14: Packet size manager 15: Transmission Department

Claims (5)

A packet communication method for transmitting a packet at a predetermined transmission speed,
A packet communication method, wherein when changing the predetermined transmission rate, the size of the packet is changed according to the availability of a transmission buffer for storing the packet. A packet communication system for transmitting a packet at a predetermined transmission rate,
A packet communication system, comprising: a packet size management unit that changes the size of a packet according to the availability of a transmission buffer for storing the packet when changing the predetermined transmission rate.   The packet size management unit may be configured such that the data amount of the packet stored in the transmission buffer is equal to or greater than a first data amount threshold, or the remaining amount of the transmission buffer is equal to or less than the first buffer remaining amount threshold. 3. The packet communication system according to claim 2, wherein in some cases, the size of the packet is not changed.   If the data amount of the packet stored in the transmission buffer is equal to or greater than a second data amount threshold, or if the remaining amount of the transmission buffer is equal to or less than a second buffer remaining amount threshold, the predetermined transmission is performed. The packet communication system according to claim 2 or 3, further comprising a transmission rate changing unit that changes a transmission rate to a higher transmission rate. The transmission rate changing unit may be configured such that the data amount of the packet stored in the transmission buffer is equal to or greater than the second data amount threshold continuously for a certain period of time, or the remaining amount of the transmission buffer is constant. 5. The packet communication system according to claim 4, wherein the predetermined transmission rate is changed to a higher transmission rate when the remaining buffer level is equal to or less than the second remaining buffer threshold for a continuous period.

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