KR100937415B1 - Method for controlling data rate in mobile communication system - Google Patents

Abstract

The present invention relates to a data rate control method of a mobile communication system, in which a base station changes and transmits a data rate transition probability to a mobile terminal in order to control a data rate of a mobile terminal, particularly in a 1xEV-DO (evolution data only) system. The method of claim 1, further comprising: identifying a system situation (loading amount of reverse link) at a data receiving side, and changing a data rate transition probability according to the identified system situation, and at the receiving side, Transmitting information, performing a test for controlling the transmission data rate by using the information on the received data rate transition probability, and transmitting at the data transmission side according to the test result. In order to improve the data transmission efficiency of the mobile terminal through a procedure comprising the step of determining the data rate A person.

Data rate transition probability, p-persistent test,

Description

Method for controlling data rate in mobile communication system

1 is a table showing a data rate transition probability that a base station informs a mobile station in a service negotiation process in the prior art.

2 is a table showing examples of determining a reverse link data rate in the prior art;

3A is a flowchart illustrating a procedure at a base station for data rate control in a mobile communication system according to the present invention.

3b is a flowchart illustrating a procedure in mobile terminals for data rate control of a mobile communication system according to the present invention;

4A-4B are diagrams illustrating the structure of a parameter message for transmitting a data rate transition probability in accordance with the present invention.

5 is a table showing data rate transition probabilities and an identifier corresponding to the data rate transition probabilities according to the present invention.

The present invention relates to a mobile communication system, and in particular, a data rate of a mobile communication system in which a base station changes and transmits a data rate transition probability to a mobile terminal in order to control a data rate of a mobile terminal in a 1xEV-DO (evolution data only) system. It relates to a control method.

In general, data transmission of the reverse link (link from the mobile terminal to the base station) is closely related to the total amount of interference of the reverse link data received at the base station.

If the total amount of interference on the reverse link is small, the mobile stations can transmit data by increasing the data rate of the reverse link. However, when the total amount of interference exceeds a certain level, the mobile terminal may need to reduce the data rate or stop transmitting data.

In the 1xEV-DO system, the base station estimates the total amount of interference on the reverse link and generates a command for increasing or decreasing the data rate, that is, a reverse activity bit (hereinafter, abbreviated as RAB).

The RAB is delivered to all mobile terminals that transmit data on the reverse link through a common channel called a reverse activity channel.

If the total amount of interference on the reverse link is large, that is, when the estimated total amount of interference exceeds a certain threshold, a data rate reduction command is transmitted to the mobile stations. On the other hand, when the total amount of interference on the reverse link is small, that is, when the estimated total amount of interference is less than a predetermined threshold, a data rate increase command is transmitted to the mobile stations.

The RAB is generated based on the reception state of each mobile station, that is, the total amount of interference of the reverse link signal received by the base station.

Therefore, the RAB is delivered with the same command to all mobile terminals (users) served by the base station.

The RAB is transmitted from the base station to the mobile terminal for one frame, and the mobile terminal uses the RAB to adjust the transmission data rate of the next frame.

When the mobile terminal receives the RAB, the mobile terminals test to increase or decrease the transmission data rate. That is, the mobile station determines that the transmission data rate is changed after performing the p-persistent test without necessarily increasing or decreasing the transmission data rate of the next frame because it is commanded to increase or decrease.

In other words, after receiving a data rate transition command (RAB) for increasing or decreasing the transmission data rate from the base station, the mobile stations themselves test to determine whether to increase or decrease the transmission data rate of the next frame. Conduct.

The p-persistent test determines the transition or retention of the transmission data rate. This p-persistent test uses the data rate transition probability.

In the prior art, the base station informs the mobile station of the data rate transition probability as shown in FIG. 1 in advance in the service negotiation process.

1, for example, "Transition076k8_153k6" represents a probability of increasing from a data rate of 76.8 kbps to a data rate of 153.6 kbps, and the data rate transition probability is "0x08". "Transition076k8_038k4" represents a probability of decreasing from a data rate of 76.8kbps to a data rate of 38.4kbps, and the data rate transition probability is "0x20".

Therefore, when the transmission data rate of the current frame is 76.8kbps, the transition probability (0x20) of decreasing the data rate of the next frame to 38.4kbps at that 76.8kbps is higher than the probability (0x08) of increasing the data rate of the next frame to 153.6kbps. high.

The mobile station always uses the data rate transition probability of FIG. 1 provided in the service negotiation process from the base station regardless of the change of the system situation.

2 is a diagram illustrating examples of determining a data rate of a reverse link by using a data rate transition probability provided in a service negotiation process in the prior art.

In FIG. 2, RAB having a value of '0' represents a data rate increasing command and RAB having a value of '1' represents a data rate decreasing command.

Referring to FIG. 2, one example is described. When the transmission data rate of the current frame of the mobile station is 76.8 kbps, the mobile station receiving the RAB having a value of '1' from the base station is a received data rate transition command. Since the data rate reduction command, the data rate transition probability (0x20) corresponding to "Transition076k8_038k4" among the data rate transition probabilities shown in FIG. 1 is used for the p-persistent test.

The mobile terminal then determines the authenticity of the transition condition.

If the transition condition is met, that is, "true", the mobile station reduces the transmission data rate of the frame to 76.8kbps to 38.4kbps. Otherwise, if "false", the mobile station maintains the current transmission data rate of 76.8kbps.                         

In addition, when the transmission data rate of the current frame of the mobile station is 76.8kbps, the mobile station receiving the RAB having a value of '0' from the base station is a data rate increase command because the received data rate transition command is shown in FIG. Among the data rate transition probabilities, the data rate transition probability (0x08) corresponding to "Transition076k8_153k6" is used for the p-persistent test.

The mobile terminal then determines the authenticity of the transition condition.

If the transition condition is met, that is, "true", the mobile station increases the transmission data rate of the frame to 73.6kbps to 153.6kbps. Otherwise, if "false", the mobile station maintains the current transmission data rate of 76.8kbps.

On the other hand, when the data rate of the current frame is 76.8kbps, the data rate transition probability used for the p-persistent test is always constant regardless of the system situation. More specifically, the probability that the data rate of the next frame will decrease to 38.4kbps at 76.8kbps is always high as "0x20" and the probability to increase to 153.6kbps is always low as 0x08. For that reason, it is always highly likely that the data rate will pass the p-persistent test to decrease from 76.8 kbps to 38.4 kbps, while the p-persistent test to increase the data rate from 76.8 kbps to 153.6 kbps (true) ) Is always low.

As a result, there is a problem that the data transmission efficiency of the mobile station to the reverse link is deteriorated according to the current system situation.

On the other hand, the above-mentioned problem is the same when the data rate of the current frame is 38.4kbps in FIG. 1, even when the data rate of the next frame decreases to 19.2kbps and increases to 76.8kbps. That is, when the data rate of the current frame is 38.4kbps, the probability of decreasing the data rate of the next frame to 19.2kbps is always high as "0x10" and the probability of increasing to 76.8kbps is always low as 0x08.

As described above, the data rate transition probability used in the reverse link data rate control in the conventional 1xEV-DO system is transmitted to the mobile station by the base station in the service negotiation process so that it is always constant regardless of the current system situation. This results in a decrease in data transmission efficiency.

An object of the present invention has been made in view of the above point, the base station changes the data rate transition probability according to the system situation and transmits to the mobile terminals, so as to more efficiently control the transmission data rate of the mobile terminals To provide a data rate control method of a mobile communication system.

A data rate control method of a mobile communication system according to the present invention for achieving the above object is, the first receiving the system state at the data receiving side (base station) to change the data rate transition probability in accordance with the confirmed system situation And a second step of transmitting information on the changed data rate transition probability at the receiving side, and transmitting data rate using information on the received data rate transition probability at the data transmitting side (mobile terminal). And a fourth step of conducting a test for control of the control unit and a fourth step of determining, at the transmitting side, a transmission data rate according to the test result.

More preferably, the first step includes the step of the receiver measuring the current data load, determining the system situation, and setting the data rate transition probability differently according to the system situation.

Here, the data rate increase probability when the system condition is in good condition with respect to the data rate increase probability used in the control for increasing the transmission data rate by a predetermined step among the data rate transition probabilities. It is set larger than the data rate increase probability when the situation is in a bad state.

Further, the data rate reduction probability when the system condition is in good condition with respect to the data rate reduction probability used in the control for reducing the transmission data rate by a predetermined step among the data rate transition probabilities. It is set smaller than the data rate reduction probability when the situation is in a bad state.

More preferably, the receiving side transmits the changed data rate transition probability through one of a common channel and a dedicated channel.

In particular, when there is no valid data transmission from the transmitting side, the receiving side broadcasts the changed data rate transition probability through the common channel, and when there is valid data transmission from the transmitting side, the receiving side transmits the changed data rate transition probability. Is transmitted through a dedicated channel allocated to the transmitter.

More specifically, the changed data rate transition probability is broadcasted through a broadcast rate parameter message of the common channel, and the changed data rate transition probability is a unicast rate parameter message of the dedicated channel. Is sent through.

More preferably, in the second step, the receiving side transmits an identifier indicating the changed data rate transition probability to the transmitting side, for which the receiving side and the transmitting side transmit data rate transition probabilities according to the system situation. And a table including identifiers corresponding to the data rate transition probabilities.

Hereinafter, a preferred embodiment of a data rate control method of a mobile communication system according to the present invention will be described with reference to the accompanying drawings.

In the present invention, the base station changes the data rate transition probability according to the system situation and transmits it to the mobile terminals. Here, the base station is the receiving side of the reverse link data, and the mobile terminal is the transmitting side of the reverse link data.

The base station measures the load on the reverse link to check the current system situation.

The base station determines the system situation according to the measured load amount. In this case, the situation of the system is determined in several stages. The method of determining may be used by a general method of determining based on a predetermined threshold value, or may be determined by other methods used in a mobile communication system. Therefore, the method of determining the system status according to the measured load of the base station is not limited to any one, and the method applied to the mobile communication system in which the present invention is used is used.

Subsequently, the base station changes the data rate transition probability according to the current system situation, and informs the mobile stations located in its service area or mobile terminals serving the base station of the changed data rate transition probability.

The mobile stations then use the received data rate transition probability to control the data rate. The MSs do not use the information on the data rate transition probability provided in advance in the service negotiation process to control the data rate.

See FIG. 3 for a detailed description thereof.

3A is a flowchart illustrating a procedure in a base station for data rate control of a mobile communication system according to the present invention.

Referring to FIG. 3A, the base station sets an initial data rate transition probability in a service negotiation process with a plurality of mobile terminals, and provides the set initial data rate transition probability to a plurality of mobile terminals (S1). Accordingly, the mobile terminals also set the initial data rate transition probability as the data rate transition probability for data rate control.

Subsequently, the base station continuously checks the current system status by measuring the load of the reverse link (S2, S3).

More specifically, the base station measures the data load of the reverse link and determines the system situation according to the measured load. The system is divided into several steps depending on whether the system is good or bad.

When the change of the current data rate transition probability is required, the base station changes the current data rate transition probability from a preset initial data rate transition probability to a data rate transition probability according to the system situation. (S4).

At this time, the base station sets the data rate transition probability when the determined system situation is in a better state and the data rate transition probability in a worse state. To this end, the base station already has information on data rate transition probabilities to be used according to each system situation.

In general, the mobile station transmits the next frame in the reverse direction at the transmission data rate that is increased or decreased in the transmission data rate of the current frame through data rate control, and the data rate is increased / decreased by a predetermined step. Of course, the data rate control may maintain the transmission data rate of the current frame in the next frame.

In addition, the base station, when the mobile station is in a worse state of the data rate increase probability when the system situation is better than the data rate increase probability used for the data rate control for increasing the transmission data rate by a predetermined step. It is set larger than the probability of data rate increase.

Thus, when the system condition is in a better state than in a bad state, the probability that the transmission data rate of the mobile terminal is increased is increased. This mitigates the increase in load when system conditions are in poor condition.

In addition, the base station has a data rate when the mobile station is in a bad state of the data rate increase probability when the mobile station is in a good state with respect to the data rate reduction probability used by the mobile terminal to reduce the transmission data rate by a predetermined step. Set less than the increase probability.                     

Thus, when the system situation is in a worse state than in a good state, the probability that the transmission data rate of the mobile terminal is reduced is increased.

If the data rate transition probability is set differently according to the system situation as described above, when the mobile station receives the data rate increase command (RAB) in a good system state, the probability of passing the p-persistent test increases. Therefore, when the system situation is good, there are many mobile terminals that increase the transmission data rate of the reverse link.

In addition, when the mobile station receives a data rate reduction command (RAB) in a bad system condition, the probability of passing the p-persistent test is increased. Therefore, when the system situation is poor, there are many mobile terminals that reduce the transmission data rate of the reverse link.

The base station transmits the changed data rate transition probability to mobile terminals (S5).

In particular, the present invention transmits the changed data rate transition probability through one of a common channel and a dedicated channel.

When there is no valid data transmission from the mobile station, i.e., when there is no traffic condition, the mobile station broadcasts the changed data rate transition probability through the common channel.

In particular, when a data rate transition probability changed through a common channel is broadcasted, the broadcast rate broadcast message is broadcast through a broadcast rate parameter message of the common channel.

On the other hand, when there is valid data transmission from the mobile terminal, i.e. in a traffic situation, it transmits the changed data rate transition probability through the dedicated channel assigned to the mobile terminal.

In particular, when the changed data rate transition probability is broadcasted through a dedicated channel, the unicast rate parameter message of the dedicated channel is transmitted.

More preferably, the base station broadcasts the data rate transition probability that is changed through a common channel among the mobile stations that are not in the traffic situation among the mobile terminals serving the mobile station, and the mobile stations that are in the traffic situation to the terminals. The changed data rate transition probability is transmitted through each allocated dedicated channel.

The base station transmits the changed data rate transition probability through the parameter messages whenever a change in the current data rate transition probability is required.

4A to 4B illustrate the structure of parameter messages used in the present invention. If the data rate transition probability changed according to a specific system situation is transmitted as shown in FIG. 4A, the mobile stations may have fields corresponding to their current data rates. The value is applied to the data rate control to determine the transmission data rate of the next frame. That is, the mobile station transmitting data at the current data rate of 19.2kbps increases or decreases the transmission data rate of the next frame by applying the "transition019k2_038k4" field value and the "transition019k2_009k6" field value to the data rate control in the data rate transition probability.

A case where the data rate transition probability changed according to a specific system situation is transmitted in the form of an identifier as shown in FIG. 4B will be described below.

Subsequently, after transmitting the changed data rate transition probability, the base station estimates the total interference amount of the reverse link (S6). This total interference estimate is also performed before transmitting the data rate transition probability.

The base station transmits a data rate transition command (RAB), that is, a data rate increase command or a data rate decrease command, according to the estimated total amount of interference of the reverse link (S7).

3B is a flowchart illustrating a procedure in mobile terminals for data rate control of a mobile communication system according to the present invention.

Referring to FIG. 3B, the mobile station sets the data rate transition probability provided from the base station in the service negotiation process as an initial data rate transition probability for data rate control.

The mobile station then receives the changed data rate transition probability from the base station (S10). The changed data rate transition probability is illustrated in FIG. 4.

Accordingly, the mobile station changes the initially set data rate transition probability to the data rate transition probability received from the base station (S11).

After the changed data rate transition probability is set for data rate control, the mobile station checks whether a data rate transition command (RAB) has been received from the base station (S12).

If a data rate transition command is received, the mobile station determines a data rate transition probability value to be used for data rate control based on the data rate of the current frame transmitted on the reverse link and the received data rate transition command (S13). For example, if the mobile station transmitting the current frame at 19.2 kbps receives the data rate increasing command, the value of the "transition019k2_038k4" field is converted into the data rate transition probability value for the data rate control from the received data rate transition probability of FIG. 4. Decide

Then, using the determined data rate transition probability value, a p-persistent test for data rate control described below is performed.

The mobile terminal compares the randomly generated number x randomly with the determined data rate transition probability value D (S14). Herein, the mobile terminal generates a random number x in a range larger than 0 and smaller than 1.

If the generated random number (x) is smaller than the determined data rate transition probability value, the test passes "true", and if the generated random number (x) is greater than or equal to the determined data rate transition probability value, the test is performed. "False" for not passing

In this way, the mobile station determines the transition (increase or decrease) or maintenance of the transmission data rate through a p-persistent test comparing the generated random number (x) with the determined data rate transition probability value (S15, S16). .

Hereinafter, an example in which the mobile station determines the transmission data rate of the next frame will be described.

When the transmission data rate of the current frame of the mobile station is 76.8kbps, the mobile station receiving the data rate reduction command (RAB) having a value of '1' from the base station is "Transition076k8_038k4" at the changed data rate transition probability received from the base station. The data rate transition probability value corresponding to "is used for the p-persistent test.

If the generated random number x is smaller than the determined data rate transition probability value, that is, "true", the mobile station reduces the transmission data rate of the frame to 76.8kbps to 38.4kbps. Otherwise, if "false", the mobile station maintains the current transmission data rate of 76.8kbps.

In addition, when the transmission data rate of the current frame of the mobile station is 76.8kbps, the mobile station receiving a data rate increase command (RAB) having a value of '0' from the base station is determined by the " The data rate transition probability value corresponding to Transition076k8_153k6 "is used for the p-persistent test.

If the generated random number x is smaller than the determined data rate transition probability value, that is, "true", the mobile station increases the transmission data rate of the frame to 73.6kbps to 153.6kbps. Otherwise, if "false", the mobile station maintains the current transmission data rate of 76.8kbps.

When the data rate of the current frame is 76.8kbps, the data rate transition probability values used for the p-persistent test are different values according to changes in the system situation. Therefore, if the system condition is in good condition, the probability that the data rate of the next frame decreases to 38.4kbps at 76.8kbps is lower than when the system condition is bad, and the probability that it increases to 153.6kbps is higher than when the system condition is bad. .

Next, a case of transmitting the changed data rate transition probability according to a specific system situation in the form of an identifier as shown in FIG. 4B will be described.

The base station and the mobile stations preset and store data rate transition probabilities according to each system situation and identifiers corresponding to data rate transition probabilities for each system situation in a table as shown in FIG. 5. Here, the transition table identifier of FIG. 5 shows each state when the system situation is divided into several steps.

As shown in FIG. 5, n transition table IDs for each system situation are set, and data rate transition probabilities for each system condition are set differently. In short, if the transition table identifiers are different, the probability of each transition condition is different. The number of bits of the transition table ID is determined according to n.

At this time, the data rate increase probability according to different system situations sets the data rate increase probability when the system state is in a good state to be greater than the data rate increase probability when the system state is in a bad state. In addition, the data rate reduction probability according to different system situations sets the data rate reduction probability when the system situation is in a good state to be smaller than the data rate reduction probability when the system state is in a bad state.

In the present invention, if the identifier value is larger, the system situation is set to be better. However, it is not limited to one example.

If the value of the larger identifier is greater, the probability of increasing the data rate corresponding to the identifier (probability of increasing the good state) increases and the probability of decreasing the data rate (probability of decreasing the good state) decreases.

In addition, as the smaller identifier value, the probability of increasing the data rate corresponding to the identifier (probability of increasing the bad state) decreases, and the probability of decreasing the data rate (probability of decreasing the bad state) increases.                     

For example, the data rate increase probability with the identifier value "K + 1" is set to be greater than the data rate increase probability with the identifier value "K", and the data rate decrease probability with the identifier value "K + 1" is the identifier value. It is set smaller than the data rate reduction probability of "K". Where K is any identifier value greater than or equal to 1 and less than n.

The base station continuously measures the reverse link load to confirm the current system status. That is, the base station measures the data load of the reverse link, and determines the system situation according to the measured load.

When the change of the current data rate transition probability is required, the base station changes the current data rate transition probability from a preset initial data rate transition probability to a data rate transition probability according to the system situation. do.

The base station transmits an identifier corresponding to the changed data rate transition probability to the mobile stations.

In particular, in the present invention, the identifier is transmitted through one of a common channel and a dedicated channel.

More specifically, when there is no valid data transmission from the mobile terminal, i.e., when there is no traffic condition, the identifier of the changed data rate transition probability is broadcast through the common channel. In particular, when the identifier of the changed data rate transition probability is broadcast through the common channel, the broadcast rate parameter is broadcasted through a broadcast rate parameter message of the common channel.

On the other hand, when there is valid data transmission from the mobile terminal, i.e. in a traffic situation, the identifier of the changed data rate transition probability is transmitted through the dedicated channel allocated to the mobile terminal. In particular, when the changed data rate transition probability is broadcasted through a dedicated channel, the unicast rate parameter message of the dedicated channel is transmitted.

More preferably, the base station broadcasts an identifier of a data rate transition probability changed through a common channel to mobile stations that are not in a traffic situation among the mobile stations that it serves, and the mobile station to the mobile stations that are in a traffic situation. The identifier of the changed data rate transition probability is transmitted through each allocated dedicated channel.

The base station transmits the identifier of the changed data rate transition probability through the parameter messages whenever a change in the current data rate transition probability is required.

4B illustrates a structure of parameter messages for transmitting an identifier of a changed data rate transition probability.

The mobile station checks the identifier value of the data rate transition probability changed according to the system situation in the received parameter message and applies one data rate transition probability indicated by the identified identifier value to the data rate control.

When the mobile station receives a data rate transition command (RAB) from the base station, the mobile station performs the same test as described above to change or maintain the transmission data rate of the next frame.

 According to the present invention as described above, since the base station changes and transmits the data rate transition probability to the mobile terminals according to the system situation, the probability that the mobile terminal increases the data rate of the next frame when the system situation is good Is higher, and at the same time the probability of decreasing the data rate of the next frame is lower. In addition, when the mobile terminal has a bad system situation, the probability of increasing the data rate of the next frame becomes low, and at the same time, the probability of decreasing the data rate of the next frame increases.

In addition, since the data rate transition probability is set differently according to the system situation, the probability of passing the p-persistent test is increased when the mobile station receives the data rate increase command (RAB) in a good system condition. Accordingly, when the system situation is in a better state than in a bad state, the number of mobile terminals for increasing the transmission data rate of the reverse link is increased, thereby improving the overall reverse transmission efficiency of the overall mobile terminals.

In addition, when the mobile station receives a data rate reduction command (RAB) in a bad system condition, the probability of passing the p-persistent test is increased. As a result, when the system condition is worse than that in a good state, the number of mobile terminals that reduce the transmission data rate of the reverse link increases, thereby mitigating the load increase of the overall mobile terminals more efficiently.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

Claims (21)

A first step of checking a system condition at a data receiving side and changing a data rate transition probability according to the identified system condition; Transmitting, at the receiving side, information on the changed data rate transition probability; A third step of, on a data transmission side, performing a test for control of a transmission data rate using information on the received data rate transition probability; And a fourth step of determining, on the transmitting side, a transmission data rate in accordance with the test result. The method of claim 1, wherein the first step, Setting an initial data rate transition probability in a service negotiation conducted between the receiving side and the transmitting side; Checking, by the receiver, the current system status; And changing the set initial data rate transition probability to a data rate transition probability according to the identified system situation. The method of claim 1, wherein the receiving side is a base station, and the transmitting side is one or more mobile terminals serviced by the base station. 4. The method of claim 3, wherein the base station determines the system status by measuring a data load of a reverse link. The method of claim 1, wherein the first step, Determining, by the receiving side, the current data load to determine the system situation; And setting the data rate transition probabilities differently according to the system situation. 6. The data rate increase according to claim 5, wherein the data rate increases when the system condition is in good condition with respect to a data rate increase probability used in a control for increasing the transmission data rate by a predetermined step among the data rate transition probabilities. And a probability is set to be greater than a probability of increasing the data rate when the system situation is in a bad state. 6. The data rate reduction according to claim 5, wherein the system rate is in a good state with respect to a data rate reduction probability used in a control for reducing the transmission data rate by a predetermined step among the data rate transition probabilities. And a probability is set smaller than the probability of reducing the data rate when the system situation is in a bad state. The method of claim 1, wherein the second step, And at the receiving side, transmitting the changed data rate transition probability through one of a common channel and a dedicated channel. The method of claim 8, wherein when there is no valid data transmission from the transmitting side, the receiving side broadcasts the changed data rate transition probability through the common channel. The data rate control of the mobile communication system according to claim 8, wherein, when there is valid data transmission from the transmitting side, the receiving side transmits the changed data rate transition probability through a dedicated channel assigned to the transmitting side. Way. 10. The method of claim 8, wherein the changed data rate transition probability is broadcast through a broadcast rate parameter message of the common channel. The method of claim 8, wherein the changed data rate transition probability is transmitted through a unicast rate parameter message of the dedicated channel. The method of claim 1, Estimating the total amount of interference on a reverse link after the receiving side transmits the changed data rate transition probability; And transmitting a data rate transition command according to the estimated total interference amount to the transmitting side. The method of claim 1, wherein the third step, Receiving, by the transmitting side, a data rate transition command (RAB: Reverse Activity Bit) for controlling the transmission data rate from the receiving side; Determining a data rate transition probability value corresponding to the received data rate transition command and the current transmission data rate among a plurality of data rate transition probabilities based on the received data rate transition probability information; And performing the test to compare the determined data rate transition probability value with a randomly generated random number. 15. The data rate control of a mobile communication system according to claim 14, wherein if the random number is less than the determined data rate transition probability value, it is determined that the test has passed; otherwise, it is determined that the test has not passed. Way. The method of claim 1, wherein the fourth step, If the test passes, increasing or decreasing the current transmission data rate. The data rate control of the mobile communication system according to claim 1, wherein the receiving side checks the system condition and transmits the changed data rate transition probability information whenever a change in the current data rate transition probability is required. Way. A first step of the base station and the mobile terminal presetting and storing data rate transition probabilities according to a system situation and identifiers corresponding to the data rate transition probabilities; Transmitting, by the base station, identifiers of data rate transition probabilities changed according to a current system situation to the mobile terminal; A third step of the mobile terminal performing a test for determining a transmission data rate by using stored data rate transition probabilities corresponding to the received identifiers; And if the test passes, the mobile station comprises a fourth step of increasing or decreasing the current transmission data rate. The method of claim 18, wherein the second step, When there is no traffic of the reverse link from the mobile station, the base station broadcasts each identifier of the changed data rate transition probabilities through a broadcast rate parameter message of a common channel. Data rate control method of mobile communication system. The method of claim 18, wherein the second step, When there is traffic of the reverse link from the mobile station, the base station transmits each identifier of the changed data rate transition probabilities through a unicast rate parameter message of a dedicated channel assigned to the mobile station. A data rate control method of a mobile communication system, characterized in that for transmitting. 19. The mobile communication system according to claim 18, wherein the base station and the mobile station have a table including data rate transition probabilities according to the system situation and identifiers corresponding to the data rate transition probabilities. Data rate control method.

Images