KR20060027745A - Mobile communication system and method for flow control of high speed downlink packet access traffic - Google Patents

Abstract

The mobile communication system for controlling the flow of fast downlink packet access traffic according to the present invention transmits a first capacity allocation signal corresponding to a receivable capacity in response to a received capacity request signal, and transmits according to the first capacity allocation signal. The base station receives the packet data transmitted according to the second capacity allocation signal by transmitting a second capacity allocation signal corresponding to the available capacity after receiving the packet data, and transmits the capacity request signal to the base station for data transmission. And a base station controller for transmitting subsequent packet data according to the first capacity allocation signal and the second capacity allocation signal in consideration of the capacity of the packet data transmitted while the first capacity allocation signal and the second capacity allocation signal are transmitted from the base station. It is configured to include.

High speed downlink packet access traffic, HDPA, flow control, packet, capacity, allocation, request, inflight packet, base station, base station controller, RNC, Node B

Description

Mobile communication system and method for controlling flow of high speed downlink packet access traffic             

1 is a view for explaining traffic flow control defined in the 3GPP standard,

FIG. 2 is a diagram illustrating an example in which a base station controller schedules transmission of data according to a capacity allocation signal transmitted from a base station in FIG. 1;

3 is a view showing an example of flow control using capacity information (credit),

4 is a diagram illustrating an example of flow control using a rate;

5 is a block diagram showing a preferred embodiment of a mobile communication system for flow control of high speed downlink packet access (HSDPA) traffic according to the present invention;

6 is a view for explaining the flow control of the fast downlink packet access traffic between the base station controller and the base station according to FIG.

7 is a diagram illustrating a process of transmitting packet data from a base station controller to a base station; and

8 is a diagram illustrating a process of generating and assigning a user code to be capacityed by a base station upon receiving a capacity request signal from a base station controller.

The present invention relates to a method for controlling transmission traffic of downlink data of a mobile communication system, and more particularly, to a base station controller of a wideband code division multiple access (Wideband CDMA) mobile communication system. The present invention relates to a mobile communication system and method for controlling a high speed downlink packet access (HSDPA) flow from a base station to a base station.

Currently, wideband code division multiple access (WCDMA) mobile communication systems have a high speed downlink packet access (HSDPA) that can increase traffic transmission of downlink data from a base station (NodeB). The specification is defined in the Third-Generation Partnership Projet (3GPP) standard.

The types of traffic serviced in the High Speed Downlink Packet Access (HSDPA) specification are primarily streaming services (e.g., real-time video), interactive services (e.g., the World Wide Web), Background service {for example, File Transfer Protocol (FTP), email service}. The occurrence of such traffic is bursty. In order to efficiently transmit traffic having bursty characteristics from a radio network controller (RNC) of a WCDMA mobile communication system to a node B (hereinafter referred to as a "base station"), The use of flow control is standardized.

1 is a diagram for describing traffic flow control defined in the 3GPP standard.

When the data to be transmitted is generated and the base station controller (RNC) 20 is desired to transmit the data, the base station controller (RNC) 20 has a capacity request (CR) signal or packet data unit (Packet) having a transmission capacity required for the data transmission as a parameter. Request for transmission permission to the base station (Node B) 10 through a Data Unit (PDU).

When the base station (Node B) 10 receives the capacity request signal from the base station controller 20, the base station (Node B) 10, the packet data unit length (MAC-d PDU length), capacity information (Credit), interval information (Interval) that defines the transmission type Responds to the base station controller 20 using a Capacity Allocation (CA) signal having a parameter including, and a Repetition Period.

Packets are periodically transmitted from the base station controller 20 to the base station 10, where interval information represents an interval of one period and is set in units of 10 [ms]. Credit includes information on the number of packets transmitted in one cycle. The packet data unit length information (MAC-d PDU length) includes information on packet lengths (bytes). Repetition Period includes information on the number of transmission periods.

2 is a diagram illustrating an example in which the base station controller 20 schedules transmission of data according to a capacity allocation signal CA transmitted from the base station 10 in FIG. 1.

Looking at the information contained in the capacity allocation signal transmitted from the base station 10 as follows.

According to the capacity allocation signal, the capacity information Credit is '2', the interval information Interval is '20ms', and the repetition period is '10'.

In the mobile communication system, flow control for controlling transmission between a receiving side and a transmitting side is generally classified into flow control using capacity information and flow control using rate.

First, the flow control using the capacity information is a method of transmitting a message from the transmitting side to the receiving side only by the amount allowed by the receiving side. This is effective to prevent loss of received data due to overflow when receiving data transmitted from the receiving side. However, in such a flow control method, when the transmission interval is long, the data should be transmitted only in the capacity allowed by the receiving side even though the transmission capacity is large. Therefore, the throughput of data may be severely degraded.

Second, the flow control using the transmission rate is a method of continuously transmitting traffic to the receiving side by defining the same transmission amount (transmission rate) at a predetermined time unit at the transmitting side. This is a data transmission (throughput) can be sent quickly, but there is a problem that the loss of the received data due to the overflow (overflow) when receiving the data at the receiving side is high.

The high speed downlink packet access (HSDPA) flow control defined in the WCDMA mobile communication system includes a method including both flow control using the above capacity information and flow control using the rate.

For example, the high speed downlink packet access flow control is used in which a flow control using a transmission rate is used when the repetition period is '0', and a flow control using capacity information is used when the speed information is not '0'.

Therefore, high-speed downlink packet access flow control can select one of two types to achieve desired performance (data loss, delay, etc.) according to the situation. It is possible to selectively apply any one of the flow control using the transmission rate and the flow control using the capacity information by the capacity request signal and the capacity allocation signal.

3 is a diagram illustrating an example of flow control using capacity information (credit).

The base station controller (RNC) 20 transmits a capacity request (CR) signal having a transmission capacity required for data transmission as a parameter to the base station Node B 10.

When the base station (Node B) 10 receives the capacity request signal CR from the base station controller 20, the base station (Node B) 10, the packet data unit length (MAC-d PDU length), capacity information (Credit), interval information that defines the transmission type A capacity allocation (CA) signal having a parameter including an interval and a repetition period is transmitted to the base station controller 20. In the figure, it can be seen that the base station 10 allocates the entire packet transmission amount x to '100' for the capacity request of the base station controller 20. Herein, the transmission amount x may be expressed as 'Credit * Rate Information'.

Accordingly, the base station controller 20 transmits the packet to the base station 10 100 times in accordance with the capacity allocation information allocated from the base station 10.

The base station controller 20 transmits the capacity request signal CR for data transmission to the base station 10 after the transmission of the packet of the allocated capacity (x = 100). The base station 10 receiving the capacity request signal CR from the base station controller 20 allocates a corresponding capacity and transmits a capacity allocation signal CA to the base station controller 10. According to the figure, the base station 10 can know that the capacity (x) allocated to the base station controller 20 is '90'. Accordingly, the base station controller 20 transmits the packet to the base station 10 90 times according to the allocated capacity information.

However, the base station controller 20 transmits the capacity request signal CR to the base station 10 after transmitting the packet 100 times according to the allocated capacity and receives the corresponding capacity allocation signal CA corresponding thereto. The packet data is transmitted to the base station 10 according to the information. Therefore, the base station controller 20 has a problem of generating a transmission delay as much as T _D according to a signaling transmission delay including a capacity request signal CR and a capacity allocation signal CA.

4 is a diagram illustrating an example of flow control using a rate.                         

The base station controller (RNC) 20 transmits a capacity request (CR) signal having a transmission capacity required for data transmission as a parameter to the base station Node B 10.

When the base station (Node B) 10 receives the capacity request signal CR from the base station controller 20, the base station (Node B) 10, the packet data unit length (MAC-d PDU length), capacity information (Credit), interval information that defines the transmission type A capacity allocation (CA) signal having a parameter including Interval and Repetition Period is transmitted to the base station controller 20. In the figure, it can be seen that the base station 10 allocates capacity information Credit: C to '10' for the capacity request of the base station controller 20.

Accordingly, the base station controller 20 transmits the packet data to the base station 10 at a transmission rate of capacity information '10'.

The base station 10 determines that the reception buffer is the maximum when receiving the 50th packet while receiving the packet data transmitted from the base station controller 20, and the capacity allocation of the capacity information C is '0' to stop the transmission. The signal CA is transmitted to the base station controller 20. When the capacity information C transmitted from the base station 10 receives the capacity allocation signal CA having '0', the base station controller 20 stops transmitting the packet data.

However, the base station controller 20 receives the 51st to 76th packet data {In-flight Packet (IP)} received after the reception buffer of the base station 10 is maximized. There is a problem that the loss of data occurs.

An object of the present invention for solving the above problems, the high-speed downlink packet access for minimizing the overflow phenomenon for the received packet data generated in the base station in the HSDPA flow control, and packet data transmission delay between the base station controller and the base station (High Speed Downlink Packet Access: HSDPA) It is to provide a flow control method of traffic and a mobile communication system to which it is applied.

Another object of the present invention is to calculate an accurate packet capacity for an inflight packet which is packet data transmitted from a base station controller while the base station transmits a capacity allocation signal to the base station controller, and to reduce transmission delay and loss of packet data by flow control. The present invention provides a method of controlling a flow of high speed downlink packet access (HSDPA) traffic for minimization and a mobile communication system to which the same is applied.

According to an embodiment of the present invention, in the mobile communication system for the flow control of high-speed downlink packet access traffic, the first capacity allocation signal corresponding to the available capacity is transmitted in response to the received capacity request signal. And a base station for receiving packet data transmitted according to the second capacity allocation signal by transmitting a second capacity allocation signal corresponding to a receivable capacity thereafter while receiving packet data transmitted according to the first capacity allocation signal. The capacity request signal is transmitted to the base station for transmission, and the first capacity allocation signal and the second capacity allocation signal are considered in consideration of the capacity of packet data transmitted while the first capacity allocation signal and the second capacity allocation signal are transmitted from the base station. Is then achieved by a mobile communication system comprising a base station controller for transmitting packet data.

The base station controller performs transmission counting on the packet data transmitted to the base station, and the base station performs reception counting on the packet data received from the base station controller to include the reception counting value in the first and second capacity allocation signals. Transmit to base station controller. At this time, the base station controller calculates the capacity of the packet data to be transmitted after referring to the transmission counting value and the reception counting value.

Preferably, the base station controller subtracts the reception counting value from the transmission counting value to calculate the capacity of the packet data transmitted while the first capacity allocation signal and the second capacity allocation signal are respectively transmitted from the base station.

Preferably, the base station controller transmits a packet transmitted while the first capacity allocation signal and the second capacity allocation signal are respectively transmitted from the base station in the total transmittable packet capacity included in each of the first capacity allocation signal and the second capacity allocation signal. The capacity of the data to be transmitted is then calculated by subtracting the capacity of the data.

The base station controls the base station controller when the capacity of the packet data to be received from the base station controller corresponding to the first capacity allocation signal corresponds to one or two times the capacity information included in the first capacity allocation signal. To send.

The base station controller resets the transmission counting value when the transmission counting value reaches the set threshold, and transmits a reception count reset signal for resetting the reception counting value to the base station. The base station resets the reception counting value according to the reception count reset signal.

On the other hand, the above object is, according to an embodiment of the present invention, in the mobile communication system for the flow control of the high-speed downlink packet access traffic, transmitting a capacity request signal for data transmission, assigned in response to the capacity request signal Packet data is transmitted by the first capacity allocation signal, and when the second capacity request signal is received while transmitting the packet data, the capacity of the packet data transmitted according to the first capacity allocation signal during transmission of the second capacity request signal is considered. When receiving the capacity request signal from the base station controller for transmitting the subsequent packet data according to the second capacity request signal, and the base station controller generates a first capacity allocation signal corresponding to the available capacity of the packet data and transmits it to the base station controller, While receiving the packet data, the second capacity allocation signal is generated according to the capacity that can be received later and transferred to the base station controller. It is achieved by a mobile communication system including a base station.

On the other hand, the above object is, according to an embodiment of the present invention, in the method for the flow control of the high-speed downlink packet access traffic using a mobile communication system comprising a base station controller and a base station, the capacity for the base station controller to transmit data Transmitting the request signal to the base station; transmitting, by the base station, a first capacity allocation signal corresponding to the capacity that can be received in response to the capacity request signal to the base station controller; a packet transmitted by the base station controller during transmission of the first capacity allocation signal. Transmitting packet data in consideration of the capacity of the data, and if the base station controller receives the second capacity allocation signal from the base station during the transmission of the packet data according to the first capacity allocation signal, the transmission of the second capacity allocation signal during transmission. And transmitting the packet data after considering the capacity of the packet data. To be achieved.

According to the present invention, if the base station controller receives the capacity allocation signal from the base station while transmitting the packet data, the base station controller transmits packet data for the capacity allocation signal after considering the amount of packets transmitted by the base station controller while the capacity allocation signal is being transmitted. Therefore, the transmission delay and loss of packet data can be prevented. In addition, the base station transmits a new capacity allocation signal to the base station controller before the base station controller runs out of the transmission amount of packet data designated by the previous capacity allocation signal. By continuously transmitting the data, it is possible to reduce the delay of the transmission of the packet data due to the signaling delay that occurs when the flow control of the fast downlink packet access traffic is controlled using the credit information.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that the same elements in the figures are represented by the same numerals wherever possible. In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

5 is a block diagram illustrating a preferred embodiment of a mobile communication system for flow control of high speed downlink packet access (HSDPA) traffic according to the present invention.

When the data to be transmitted is generated, the base station controller 100 requests the base station 200 to allocate a transmission capacity for data transmission using the capacity request signal CR.                     

The base station 200 allocates a transmission capacity using the capacity allocation signal CA to the base station controller 100 with reference to the capacity request signal at the request of the base station controller 100. The base station 200 transmits data received from the base station controller 100 to the mobile communication terminal 300 in response to the allocated capacity.

The base station 200 according to the present invention has a reception counter 220 provided in the corresponding module provided for the trapper processing. The reception counter 220 counts a High Speed Downlink Packet Access (HSDPA) downlink packet data unit packet received from the base station controller 1000 to the base station 200, and periodically counts' 0. 'Reset.

For example, the reception counter 220 may reset the count to '0' every 1,000,000 times. That is, the reception counter 220 increments the count by '1' each time the packet is received and resets the count to '0' when the predetermined value (for example, 1,000,000) is reached.

On the other hand, the device station controller 100 has a transmission counter 120 provided inside the corresponding module provided for traffic processing.

The transmission counter 120 counts the high speed downlink packet access (HSDPA) downlink packet data unit packets transmitted from the base station controller 100 to the base station 200, and periodically resets the count to '0'. For example, the transmission counter 120 may reset the count to '0' every 1,000,000 times. That is, the transmission counter 120 increments the count by '1' each time the packet is transmitted and resets the count to '0' when the predetermined value (for example, 1,000,000) is reached.                     

When the base station Jay 100 resets the count in the transmission counter 120, information requesting to reset the reception count for the reception counter 220 of the base station 200 in the FP frame used when transmitting the capacity allocation signal. It includes and transmits to the base station 200. Accordingly, the base station 200 resets the reception count of the reception counter 220 to '0' according to the reception count reset request information included in the FP frame transmitted from the base station controller 100.

The base station 200 includes the value counted by the reception counter 220 in the capacity allocation signal CA and transmits it to the base station controller 200.

6 is a view for explaining the flow control of the fast downlink packet access traffic between the base station controller 100 and the base station 200 according to FIG. 5 in the present embodiment. 7 is a diagram illustrating a process of transmitting packet data from the base station controller 100 to the base station 200.

Hereinafter, flow control of high speed downlink packet access traffic will be described in more detail with reference to FIGS. 6 and 7.

First, when the data transmitted to the base station, the base station controller 100 transmits a capacity request signal (CR) for data transmission to the base station 200 (S110). When the base station 200 receives the capacity request signal CR, the base station 200 generates a capacity allocation signal CA1 with reference to the capacity request signal CR (S120). At this time, the base station 200 transmits the generated capacity allocation signal CA1 to the base station controller 100 (S130). The capacity information x included in the capacity allocation signal CA1 is '100'.

The base station controller 100 receives the capacity allocation signal CA1 from the base station 200 and, while the base station 200 transmits the capacity allocation signal CA1, information about the amount of packets transmitted from the base station controller 100. An in-flight packet (I _P ) amount is calculated through Equation 1 below (S140).

Inflight packet (I _P ) = transmission count value (T _V ) of the station controller-reception count value (R _V ) of the base station

Here, since the transmission count value T _V of the device station controller 100 is '0' and the reception count value R _V of the base station 200 is '0', the amount of inflight packets I _P is '0'. Becomes

At this time, the base station controller 100 calculates the packet amount x1 to be transmitted afterwards based on the received capacity allocation information CA through Equation 2 below (S150).

Packet amount to be transmitted after (x1) = Total transmittable packet amount specified in capacity allocation information (CA)-Inflight packet quantity (I _P )

Since the total amount of transmittable packets x specified in the capacity allocation information CA1 is '100' and the amount of inflight packets I _P is '0', the amount of packets x1 to be transmitted is '100'.

Accordingly, the base station controller 100 transmits the packet data to the base station 200 according to the capacity calculated according to the capacity allocation signal CA1 (S160). At this time, the transmission counter 120 of the base station controller 100 increases the transmission count by '1' corresponding to the number of times of transmitting packet data.

If the capacity allocation signal CA2 including the reception count value of the packet data transmitted from the base station 200 is received while transmitting the packet data to the base station 200 (S180), the base station controller 100 at the present time [ Equation 1] to calculate the inflight packet amount (S190). Referring to FIG. 6, it can be seen that the reception count value included in the capacity allocation signal CA2 received from the base station 200 is '50'.

According to FIG. 6, when the capacity allocation signal CA2 is received, the transmission count value T _V of the device station controller 100 is '76' and the reception count value R _V of the base station 200 is '50'. Therefore, the inflight packet I _P amount is '26' (= 76-50).

At this time, the base station controller 100 calculates the packet amount x2 to be transmitted later through Equation 2 according to the received capacity allocation information CA2 (S210).

According to FIG. 6, since the total amount of transmittable packets x specified in the capacity allocation information CA2 is '80' and the amount of inflight packets I _P is '26', then the amount of packets x2 to be transmitted is '54'. Becomes'

Therefore, the base station controller 100 transmits the packet data to the base station 200 according to the amount of packets to be transmitted x2 calculated according to the capacity allocation signal CA2 (S220). That is, the base station controller 100 transmits the packet data to the 54 base stations 200 after receiving the capacity allocation signal CA2. At this time, the transmission counter 220 of the base station controller 100 increases the transmission count each time packet data is transmitted to the base station 200 (S230).                     

On the other hand, the base station controller 100 determines whether the transmission count counted by the transmission counter 220 reaches '1,000,000' times (S240). If it is determined that the transmission count has not reached '1,000,000', the base station controller 100 continues to transmit the allocated packet data to the base station 200.

If it is determined that the transmission count reaches '1,000,000' times, the base station controller 100 resets the transmission count of the transmission counter 120 to '0' (S250). At this time, the base station controller 100 transmits a signal to reset the reception count for the reception counter 220 of the base station 200 to the base station 200 (S260). Preferably, the reception count reset signal is included in the PF frame and transmitted.

Accordingly, when the base station controller 100 receives the capacity allocation signal CA2 from the base station 200 while transmitting packet data, the base station controller 100 considers the amount of packets transmitted from the base station controller 100 while the capacity allocation signal CA2 is being transmitted. Thereafter, by transmitting the packet data for the capacity allocation signal CA2, transmission delay and loss of transmission of the packet data can be prevented.

8 is a diagram illustrating a process of generating and allocating a capacity allocation signal by the base station 200 in response to receiving the capacity request signal from the base station controller 100.

First, the base station 200 receives a capacity request signal (CR) from the base station controller 100 (S310). The base station 200 generates a capacity allocation signal CA1 according to the capacity request signal CR (S320), and transmits it to the base station controller 100 (S330). The capacity allocation signal CA1 includes capacity information Credit, repetition period, interval information, and reception count value.                     

The base station controller 100 calculates a packet amount x1 to be transmitted according to steps S140 and S150 of FIG. 7, and transmits a data packet to the base station 200 according to the capacity allocation signal CA1 (S340).

The reception counter 220 of the base station 200 increases the reception count each time a data packet is received from the base station controller 100 (S350). At this time, the base station 200 in order to prevent the transmission waiting delay that may occur in the base station controller 100, if the packet data to be received after the 'Credit * N' {where Interval information (Interval) = 10ms N = 2, otherwise, it is determined whether the amount remaining equal to the value of N = 1} (S360).

If the packet data to be received is the same as the value of 'Credit * N', the base station 200 transmits a receivable capacity allocation signal CA2 including a reception count value for the packet data received so far. Transmit to 100 (S370).

Upon receiving the capacity allocation signal CA2, the base station controller 100 calculates the packet amount x2 to be transmitted after step S190 and step S210 of FIG. 7, and calculates the packet amount x2 according to the capacity assignment signal CA2. ) Transmits the packet data to the base station 200 as much as (S380). At this time, the reception counter 220 of the base station 200 increases the reception count each time the packet data is received (S390).

When the reception count reset signal is received from the base station controller 100 according to steps S230 to S250 of FIG. 7 (S410), the base station 200 resets the reception count for the reception counter 220 to '0' (S420). ).

In the above, specific preferred embodiments of the present invention have been illustrated and described. However, the present invention is not limited to the above-described embodiment, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention attached to the claims. will be.

According to the present invention, if the base station controller receives the capacity allocation signal from the base station while transmitting the packet data, the base station controller transmits packet data for the capacity allocation signal after considering the amount of packets transmitted by the base station controller while the capacity allocation signal is being transmitted. Therefore, the transmission delay and loss of packet data can be prevented.

In addition, the base station transmits a new capacity allocation signal to the base station controller before the base station controller runs out of the transmission amount of packet data designated by the previous capacity allocation signal. By continuously transmitting the data, it is possible to reduce the delay of the transmission of the packet data due to the signaling delay that occurs when the flow control of the fast downlink packet access traffic is controlled using the credit information.

Claims (18)

A mobile communication system for controlling the flow of high speed downlink packet access traffic, In response to the received capacity request signal, a first capacity allocation signal corresponding to a receivable capacity is transmitted and a second capacity allocation corresponding to a receivable capacity is received while receiving packet data transmitted according to the first capacity allocation signal. A base station transmitting a signal to receive packet data transmitted according to the second capacity allocation signal; And Transmitting the capacity request signal to the base station for data transmission, and considering the capacity of packet data transmitted while the first capacity allocation signal and the second capacity allocation signal are transmitted from the base station, the first capacity allocation signal And a base station controller for transmitting packet data subsequent to the second capacity allocation signal. The method of claim 1, The base station controller performs transmission counting on the packet data transmitted to the base station, The base station performs reception counting on the packet data received from the base station controller and includes the received counting value in the first and second capacity allocation signals and transmits the received counting value to the base station controller. And the base station controller calculates a capacity of packet data to be transmitted later by referring to the transmission counting value and the reception counting value. The method of claim 2, The base station controller subtracts the reception counting value from the transmission counting value to calculate the capacity of packet data transmitted while the first capacity allocation signal and the second capacity allocation signal are respectively transmitted from the base station. Mobile communication system. The method of claim 3, wherein The base station controller transmits the first capacity allocation signal and the second capacity allocation signal while the first capacity allocation signal and the second capacity allocation signal are transmitted from the base station, respectively, in the total transmittable packet capacity included in each of the first capacity allocation signal and the second capacity allocation signal. And a capacity of the packet data to be transmitted afterwards by subtracting the capacity of the packet data. The method of claim 1, The base station allocates the second capacity when the capacity of the packet data to be received from the base station controller corresponding to the first capacity allocation signal corresponds to one or two times the capacity information included in the first capacity allocation signal. And a signal is transmitted to the base station controller. The method of claim 2, The base station controller resets the transmission counting value and transmits a reception count reset signal to the base station to reset the reception counting value when the transmission counting value reaches a set threshold, And the base station resets the reception counting value according to the reception count reset signal. A mobile communication system for controlling the flow of high speed downlink packet access traffic, Transmitting a capacity request signal for data transmission, transmitting packet data according to a first capacity allocation signal allocated in response to the capacity request signal, and receiving the second capacity request signal while transmitting the packet data. A base station controller for transmitting subsequent packet data according to the second capacity request signal in consideration of the capacity of the packet data transmitted according to the first capacity allocation signal during transmission of a capacity request signal; And When the capacity request signal is received from the base station controller, the first capacity allocation signal is generated and transmitted to the base station controller in response to the receivable capacity of the packet data. And a base station generating the second capacity allocation signal and transmitting the second capacity allocation signal to the base station controller. The method of claim 7, wherein The base station controller performs transmission counting on the packet data transmitted to the base station, The base station performs reception counting on the packet data received from the base station controller and includes the received counting value in the first and second capacity allocation signals and transmits the received counting value to the base station controller. And the base station controller calculates a capacity of packet data to be transmitted later by referring to the transmission counting value and the reception counting value. The method of claim 8, The base station controller subtracts the reception counting value from the transmission counting value to calculate the capacity of packet data transmitted while the first capacity allocation signal and the second capacity allocation signal are respectively transmitted from the base station. Mobile communication system. The method of claim 9, The base station controller transmits the first capacity allocation signal and the second capacity allocation signal while the first capacity allocation signal and the second capacity allocation signal are transmitted from the base station, respectively, in the total transmittable packet capacity included in each of the first capacity allocation signal and the second capacity allocation signal. And subtracting the capacity of the packet data to calculate the capacity of the subsequent packet data to be transmitted. The method of claim 7, wherein The base station allocates the second capacity when the capacity of the packet data to be received from the base station controller corresponding to the first capacity allocation signal corresponds to one or two times the capacity information included in the first capacity allocation signal. And a signal is transmitted to the base station controller. The method of claim 8, The base station controller resets the transmission counting value and transmits a reception count reset signal to the base station to reset the reception counting value when the transmission counting value reaches a set threshold, And the base station resets the reception counting value according to the reception count reset signal. A method for controlling the flow of fast downlink packet access traffic using a mobile communication system including a base station controller and a base station, Transmitting, by the base station controller, a capacity request signal for transmitting data to the base station; Transmitting, by the base station, a first capacity allocation signal corresponding to a receivable capacity to the base station controller in response to the capacity request signal; Transmitting, by the base station controller, packet data after considering the capacity of the packet data transmitted during the transmission of the first capacity allocation signal; When the base station controller receives the second capacity allocation signal from the base station during the transmission of the packet data according to the first capacity allocation signal, the packet data is subsequently considered in consideration of the capacity of the packet data transmitted during the transmission of the second capacity allocation signal. Transmitting a step. The method of claim 13, Performing transmission counting on the packet data transmitted by the base station controller to the base station; Performing, by the base station, receiving counting of the packet data received from the base station controller and including the received counting value in the second capacity allocation signal and transmitting the received counting value to the base station controller; And And calculating, by the base station controller, a capacity of packet data to be transmitted later by referring to the transmission counting value and the reception counting value. The method of claim 14, And calculating, by the base station controller, the capacity of packet data transmitted while the second capacity allocation signal is transmitted from the base station by subtracting the reception counting value from the transmission counting value. The method of claim 15, The base station controller calculates the capacity of the packet data to be transmitted by subtracting the capacity of the packet data transmitted while the second capacity allocation signal is transmitted from the base station from the total transmittable packet capacity included in the second capacity allocation signal. The method further comprises the step of. The method of claim 16, Determining, by the base station, whether the capacity of packet data to be received from the base station controller corresponding to the first capacity allocation signal corresponds to one or two times the capacity information included in the first capacity allocation signal; And If it is determined that the capacity of the packet data to be received corresponds to one or two times the capacity information included in the first capacity allocation signal, transmitting the second capacity allocation signal to the base station controller. Method comprising a. The method of claim 17, Resetting the transmission counting value when the base station controller reaches the set threshold value; Transmitting, by the base station controller, a reception count reset signal to the base station to reset the reception counting value; And And receiving, by the base station, the reception count reset signal to reset the reception counting value.

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