KR20050040694A - Method and system for controlling data rate of reverse link in a mobile communication system - Google Patents

Abstract

The present invention relates to a system and method for determining a reverse data rate of a mobile terminal that is being handed off in a mobile communication system. The present invention relates to a mobile communication system having a plurality of base stations communicating with a mobile terminal. A method for determining a data rate by allowing the mobile station to receive rate control information from the plurality of base stations during handoff, the method comprising: receiving rate control information through signaling messages from the plurality of base stations; And determining a data rate allowed to the user according to the highest priority instruction set in the rate control information.

Description

METHOD AND SYSTEM FOR CONTROLLING DATA RATE OF REVERSE LINK IN A MOBILE COMMUNICATION SYSTEM}

The present invention relates to a method and system for controlling a data rate in a mobile communication system, and more particularly, to a method and system for controlling a data rate of a reverse link.

In general, a mobile communication system has been developed to provide a low speed data transmission system developed to provide a voice service. However, such a mobile communication system has evolved to transmit data at a high speed due to the rapid development of users' needs and technology, and thus, a need for efficient transmission of data transmission rates has arisen.

In such a mobile communication system, a direction from a base station to a mobile terminal is generally called a forward direction, and a direction from a mobile terminal to a base station is called a reverse direction. Next, the reverse data rate will be described below. In a typical mobile communication system, reverse data transmission is performed on a physical layer packet basis through a packet data channel. The data rate of each physical layer packet is variable every packet and is generally controlled by the base station. That is, one base station controls transmission rates of various mobile terminals communicating with themselves in their own area.

In general, a process of determining and controlling a data rate of a mobile station by a base station is called scheduling. The scheduling is performed by the base station determining the transmission rate of the mobile terminal by using information fed back from the mobile terminal. The information fed back from the mobile terminal is information such as available power of the mobile terminal and the amount of data to be transmitted by the mobile terminal. The scheduler of the base station performing such scheduling may receive heat noise versus total received power (RoT) or a mobile station belonging to a current base transceiver station (BTS) in addition to the feedback information. The scheduling is performed by considering a load and the like that can be obtained from the signal-to-noise ratio.

On the other hand, the method for controlling the reverse data rate of the mobile station by the base station is divided into two methods depending on the degree of transition (transition) of the reverse data rate of the mobile station. The first scheme is a full rate transition scheme, and the second scheme is a limited rate transition scheme.

The overall rate transition method is a method in which the base station does not limit the transition of the data rate in controlling the reverse data rate of the mobile station. Next, the overall rate transition method will be described in more detail.

In the case of using the full rate transition method, the base station may select one of all available rates without considering the current rate of transmitting the packet data in determining the data rate of the next packet to be transmitted by the mobile station. . This will be described as an example. It is assumed that transmission rates such as 9.6 kbps, 19.2 kbps, 38.4 kbps, 76.8 kbps, 153.6 kbps and 307.2 kbps exist in the set of transmission rates granted to the mobile station. In addition, it is assumed that a specific mobile terminal is currently transmitting packet data at a transmission rate of 9.6 kbps. In this case, the base station may allow the next packet data rate of the mobile station to be changed to 307.2 kbps at a time even if the current data rate of the mobile station is 9.6 kbps when using the full rate transition scheme. That is, in the total rate transition scheme, the reverse rate of the mobile station that the base station can tolerate is not limited by the previous rate of the mobile station, and the change width thereof is also not limited.

Next, the limited transfer rate transition method will be described. When determining the data rate of the next packet of the mobile station, the base station of the limited rate transition method changes the packet data rate by one step increase or one step decrease from the previous packet rate, or by one step increase or maintenance or one step decrease. It's a way to limit the scope. An example of the limited rate transition method will now be described. Here, it is also assumed that there are transmission rates of 9.6 kbps, 19.2 kbps, 38.4 kbps, 76.8 kbps, 153.6 kbps, 307.2 kbps, etc. in the set of transmission rates granted to the mobile station. And it is assumed that a specific mobile terminal is currently transmitting packet data at a transmission rate of 76.8kbps.

In this case, when the base station uses the limited rate transition method, the rate of the next packet for the mobile station is limited to one of 38.4 kbps, 76.8 kbps, and 153.6 kbps. That is, the current rate of 76.8kbps to choose one step up or one step down or maintain the current rate. In other words, the limiting rate transition method is a method of limiting the change of the data rate of the mobile terminal to one step from the current packet data rate. In the limited rate-transfer method as described above, an increase of one step, a decrease of one step, or a maintenance command of the current rate may be transmitted in the form of 'UP', 'DOWN', and 'HOLD', respectively. It can be transmitted through signal mapping to '-1' and '0'.

The base station controls the reverse packet data rate of the mobile station by performing scheduling of the reverse rate by the overall rate shifting method or the limited rate shifting method, and transmitting the result to the mobile station. As described above, in order to transmit the scheduled information to the mobile station, the method of transmitting a scheduling result in the overall rate transition method and the limited rate transition method may be implemented differently. First, the overall rate shifting method is mainly used for a method for allowing a specific mobile station to perform reverse transmission at a specific rate. Therefore, when using the full rate transition method, it is necessary to transmit information for indicating a specific data rate and information for indicating a mobile terminal to perform reverse packet data transmission at the data rate. Therefore, the more types of rates available in the rate set, the greater the amount of information to be transmitted.

On the other hand, the limited rate transition method can be used in two ways. In the first method, all mobile terminals in the base station can be commanded to increase or decrease or maintain a data rate. Alternatively, a specific mobile station can be instructed to increase, decrease or maintain the data rate. In the first case of the limited rate transition method, the control of the rate may consist of only one or two pieces of information in controlling the reverse rate of all mobile stations in the base station. On the other hand, in the second case of the limited rate transition method, there is an advantage that the information transmitted in the forward channel can be slightly reduced compared to the overall rate transition.

Then, the advantages and disadvantages of the overall rate transition method and the limited rate transition method described above will be described.

The overall rate shifting method has an advantage in that there is no limitation in the rate shifting when determining the reverse packet data rate of the mobile station. However, the total rate transition method requires a lot of bits for the base station to transmit the scheduling result to the mobile station. For example, if six data rates exist as described above, three bits are required to represent all data rates. In addition, in order to transmit a transmission rate granted in the overall rate transition method to a specific mobile terminal, an identifier such as a MAC ID of each mobile terminal must be transmitted together, thereby increasing the amount of information to be transmitted. In addition, since the data rate of a specific mobile station varies greatly in the overall rate transition method, the amount of interference affecting another mobile station or an adjacent cell is severe. Therefore, the channel change of mobile terminals belonging to other cells becomes severe and may adversely affect the system.

Next, the limited rate transition method may control the rate of reverse packet data by transmitting only one bit in transmitting the scheduling result. Therefore, there is an advantage that the overhead is small. In addition, the change in the amount of interference to the other set is relatively small by limiting the change of the data rate of the mobile terminal to one step. However, in the limited rate transition method, when the base station determines the data rate of the mobile station, it may change only by one step, thus making it difficult to rapidly increase or decrease the rate.

On the other hand, in a specific system, instead of the base station controlling the data rate of the mobile station, the base station may apply a traffic to pilot power ratio (hereinafter referred to as "TPR") of the mobile station. In a typical mobile communication system, when a base station controls the transmission of reverse packet data, power is controlled together. The power control process is as follows. When the mobile station receives a power control command from the base station, the power of the pilot channel of the mobile station is directly controlled, and the channel other than the pilot channel is controlled using the fixed value of TPR. For example, if the TPR is 3dB, this means that the ratio of the power of the traffic channel transmitted by the mobile station and the power of the pilot channel is 2: 1. Therefore, when determining the power gain of the traffic channel, the mobile station adjusts to double the power of the pilot channel. For other types of channels, the gain of the corresponding channel is controlled by a fixed value in the same principle as the gain of the pilot channel.

Therefore, in the system for controlling the TPR instead of controlling the transmission rate of the mobile station, the base station performs scheduling to determine the reverse rate, and then transmits the TPR allowed to the mobile station instead of notifying the mobile station of the scheduled transmission rate information. The TPR value has a characteristic of increasing as the data rate increases. For example, doubling the data rate means that the power allocated by the mobile station to the traffic channel is about doubled. Therefore, the TPR value is doubled.

However, when the mobile station is performing handoff, a situation may occur in which one mobile station simultaneously receives the rate control information from several base stations. In this case, if each base station uses a different rate transfer method as described above, the base station receives different rate control information received from each base station. The mobile station is then faced with the question of which rate transition scheme should determine the rate of reverse packet data.

In this case, the mobile station determines one of the above schemes without any reference, or determines one of the plurality of uplink rate control information based on different criteria for each of the mobile stations. If you decide to do so, it can cause a big disruption in data transmission.

This will be described as an example. It is assumed that a specific mobile station is in a handoff situation and that each base station included in the active set of the mobile station transmits reverse rate control information in a different rate transition scheme. Then, the mobile station performing the handoff may receive rate control information according to different methods from various base stations. For example, assume that a reverse packet data rate of 153.6 kbps is granted from one base station and a reverse packet data rate of 76.8 kbps is granted from another base station. In this situation, if the mobile station transmits packet data at a transmission rate of 153.6 kbps, the base station that allows 76.8 kbps has an excessive load than the scheduler anticipates, which makes it difficult to control the load of the base station. On the other hand, if the mobile station transmits packet data at a transmission rate of 76.8 kbps in such a situation, this may be more secure, but from a mobile terminal's point of view, a lower throughput is obtained. In addition, the base station allowing the 153.6 kbps does not use the reverse load efficiently. This is because the base station that allows the 153.6 kbps is more efficient to allow only 76.8 kbps for the mobile terminal and to allow a higher data rate for other mobile terminals.

In addition, if a mobile station in a handoff situation needs to determine a data rate according to a different data rate transition method from each base station, should it be based on the current reverse packet data rate or ignore the current reverse data rate and select an allowed data rate? Is also raised. Therefore, when the mobile station is located in a handoff situation and receives rate control information according to different rate information or a different rate transfer method from each base station, a method of clearly indicating a rate to be selected by the mobile station is received. This is required.

Accordingly, an object of the present invention is to provide a method and system for controlling a reverse rate of a mobile station in handoff.

Another object of the present invention is to provide a method and system for determining a reverse rate using a plurality of rate control information received by a mobile terminal in handoff.

It is still another object of the present invention to provide a method and a system capable of determining a reverse rate by receiving rate control information according to different rate rate transition methods received by a mobile terminal in handoff.

It is still another object of the present invention to provide a method and system for a base station to transmit rate control information through signaling in advance so that a mobile terminal in handoff can determine its allowed data rate.

A method of the present invention for achieving the above objects, in a mobile communication system having a plurality of base stations communicating with a mobile terminal, the mobile terminal is controlled from the plurality of base stations during the handoff of the mobile terminal to another base station A method of determining the allowed data rate by receiving information, the method comprising: receiving rate control information from a plurality of base stations through signaling message and a data rate allowed to the user according to a priority instruction set in the rate control information; Determining the process.

A system of the present invention for achieving the above object is a mobile communication system for determining a reverse data rate, a plurality of base stations for transmitting a rate control information indicating the highest priority indication through a signaling message according to a scheduled scheme, and And a mobile terminal that receives the rate control information transmitted from a plurality of base stations and determines the data rate allowed to the user according to the highest priority instruction set in the rate control information.

In the following description of the present invention, detailed descriptions of well-known functions or configurations will be omitted if it is determined that the detailed description of the present invention may unnecessarily obscure the subject matter of the present invention. Terms to be described later are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the specification.

In the base station according to the embodiment of the present invention, as described above in the prior art, scheduling is performed by the overall rate shifting method or the limited rate shifting method. Therefore, the base station controls the transmission rate of the reverse transmission of the mobile station by transmitting the scheduling result to the mobile station. In the following embodiments of the present invention, for convenience of description, the rate control information transmitted from the base station to the mobile station in the overall rate transition scheme is called grant information, and the base station transmits to the mobile station in the limited rate transition scheme. Rate control information is referred to as rate control information. The mobile station receives the rate control information, that is, a grant message or rate control information from the base station and continuously controls its packet data rate.

In the general mobile communication system, the relationship between the data rate of the reverse traffic channel and the TPR is previously known between the mobile station and the base station through a table. Therefore, in practice, controlling the data rate of the mobile terminal and controlling the TPR of the terminal can be interpreted in the same sense. Therefore, controlling the reverse rate and controlling the TPR all have the same meaning. In the following description, it is assumed that the reverse rate is controlled for convenience of description. Therefore, even if the mobile communication system described below takes a method of controlling the TPR instead of controlling the transmission rate of the mobile terminal, the control method proposed by the present invention may be applied in the same manner.

The reverse rate control method proposed by the present invention may give priority to a grant message received from a specific base station according to a signaling message or may be determined according to rate control information. One of the two methods may be a method of applying a high rate of change, and this method may be called an aggressive reverse rate determining method. On the other hand, the other one of the two methods may be a method of selecting a lower transmission rate, and this method may be referred to as a safe reverse rate determination method.

In the present invention, the signaling message according to the present invention is used to control the reverse rate. In the following description, the signaling message according to the present invention is referred to as "permission message priority indicator (PRIMARY_GRANT_PRECEDENCE_IND)". The grant message priority indicator message according to the present invention is a signaling message and may also be used as a name such as "PRIMARY_GRANT_PRECEDENCE_IND" or "GRANT_PRECEDENCE_IND" or "PRIMARY_RC_PRECEDENCE_IND" or "PRIMARY_NB_PRECEDENCE_ID" according to the characteristics of the system. The grant message priority indicator is information indicating whether to determine the reverse rate by giving priority to the grant message or by giving priority to the rate control information. Accordingly, the case of determining the reverse rate by giving priority to the rate control information may be performed by the same method as each embodiment of the present invention described below. It may also be used in the form of a primary base station priority indicator. However, in the following description, for the convenience of explanation, the description will be made as a case of giving priority to the grant message. The case where the primary base station priority indicator is used will be described in the third embodiment described below.

The grant message priority indicator applied in the embodiment of the present invention is a message transmitted from the base station to the mobile terminal, and is transmitted from the base station to the mobile terminal at the time of call setup or through a handoff message. Accordingly, when the mobile station receives the grant message priority indicator from the base station, the mobile station stores the grant message priority indicator, and if the rate control information or the grant message is received from a plurality of base stations due to a handoff or the like, the grant message priority stored by the mobile station. The rate of reverse packet data is determined according to the indicator value.

By applying this method, a method of determining a transmission rate of a mobile terminal according to a first embodiment of the present invention will be described. First, the application rule of the grant message priority indicator applied in the first embodiment of the present invention will be described.

If the grant message priority indicator value is '1', the mobile station first applies the information of the grant message among the rate information received from the various base stations. In addition, if the grant message priority indicator is set and more than one grant message is received, the grant message priority indicator is PRIMARY_GRANT_PRECEDENCE_IND type, so that information can be applied first and foremost from the PROMARY BS that has been communicating continuously. have. However, if only one grant message is received, only the received grant message may be used. In addition, when the grant message priority indication is in the form of PRIMARY_GRANT_PRECEDENCE_IND, it is possible to select a transmission rate of the grant message indicating the highest transmission rate among the plurality of grant messages. When the grant message priority indicator is set, the grant message is first applied in determining the reverse packet data rate.

On the other hand, if the grant message priority indicator value is '0', the mobile station recognizes the rate control information indicating the lowest rate among the rate control information received from the plurality of base stations. That is, when the grant message priority indicator value is '0', the grant message is not used. However, if only grant messages are received from all base stations, it is possible to select the lowest transmission rate among the received grant messages. On the contrary, if the rate control information and the grant message are received together, the rate control information is used. In addition, when only the rate control information is received, the lowest rate control information among the rate control information may be used.

Next, a method of determining a data rate of the mobile station according to an application rule of the grant message priority indicator will be described in detail with reference to the accompanying drawings.

1 is a view showing the structure and each component of a mobile communication system to which the present invention is applied.

Referring to FIG. 1, a mobile communication system includes base station transceivers 21a, 21b, 21c, 21d and base station controllers 22a, 22b for controlling the plurality of base stations 21a, 21b, 21c, 21d. do. For convenience of explanation, hereinafter, the base station transceivers 21a, 21b, 21c, and 21d and the base station controllers 22a and 22 are referred to as base stations 20a and 20b. The base stations 20a and 20b communicate with the mobile station 10 through a wireless channel, and generate a grant message priority indicator and reverse rate control information or grant message to a mobile station through a signaling message according to the present invention. send. In addition, each of the base stations 20a and 20b is connected to an exchange or / and a packet data service node 30 to transmit and receive data.

It is then assumed that the mobile terminal 10 is performing handoff between the first base station 20a and the second base station 20b. The dotted line from the mobile terminal 10 in FIG. 1 is a diagram illustrating a handoff from the first base station 20a to the second base station 20b. Accordingly, the mobile terminal 10 receives the rate control information or the permission message from the two base stations 20a and 20b, respectively. The primary base station for the mobile terminal 10 is the first base station 20a. Here, the primary base station means a base station with which the mobile station continues to communicate with the base station or a base station having the best channel environment with the mobile station 10a among the two base stations.

The first base station 20a, which is a primary base station, controls the rate of the mobile station 10 in a total rate shifting scheme, and the second base station 20b transmits to the mobile station 10 in a limited rate shifting scheme. Control the transmission rate. Accordingly, the mobile terminal 10 receives a grant message at the reverse rate from the first base station 20a and receives rate control information at the reverse rate from the second base station 20b.

In this case, it is assumed that transmission rates included in the set of data rates available to the mobile terminal 10 include 9.6kbps, 19.2kbps, 38.4kbps, 76.8kpbs, 153.6kbps, 307.2kbps, and the like. In addition, it is assumed that the current data rate of the mobile station 10 is 76.8kbps, and the mobile station 10 receives the reverse rate of 'grant = 307.2kbps' from the first base station 20a. Assume that the rate control information of "UP" is received from the second base station 20b at the reverse rate. Then, the grant message of 'grant = 307.2kbps' received from the first base station 20a means that the first base station 20a allows a transmission rate of 307.2 kbps to the mobile station 10. In addition, the reception of the rate control information of "UP" from the second base station 20b means that the second base station 20b allows a transmission rate of 153.6kbps to the mobile terminal 10.

Accordingly, in the present invention, when different reverse rates are allocated according to different methods, the reverse rate is determined according to an application rule of the grant message priority indicator according to the present invention. Next, a method of determining the reverse rate based on the grant message priority indicator will be described. In the above situation, if the value of the grant message priority indicator is '1', it means that the grant message from the first base station 20a should always be prioritized. Therefore, when determining the data rate, the mobile terminal 10 finally determines that a rate of 3072 kbps is allowed.

On the contrary, if the value of the grant message priority indicator is '0', it means to use the rate control information. In this case, when there is a plurality of rate control information, the rate control information indicating the lowest rate among the plurality of rate control information may be recognized first. Of course, on the contrary, the highest rate control information may be selected, and the reverse rate may be determined using the most rate control information. Therefore, in this case, the mobile station 10 finally determines that a transmission rate of 153.6 kbps is allowed when determining the reverse packet data rate.

2 is a flowchart illustrating a procedure of determining a data rate by a mobile terminal in handoff according to a first embodiment of the present invention. Hereinafter, a method of determining a reverse data rate by the method according to the first embodiment of the present invention will be described in detail with reference to FIG. 2.

Referring to FIG. 2, in step 101, the mobile station receives rate control information from base stations in its active set. Here, the rate control information may be a grant message or rate control information depending on whether the base station uses the full rate transition scheme or the limited rate transition scheme.

In step 102, the mobile station checks whether the value of the grant message priority indicator received during the call setup or handoff message reception from the base station is '1' or '0'. If the value of the grant message priority indicator is '1' in step 102, the mobile station indicates that the grant message is indicated by giving a priority to determine the data transfer rate allowed to the mobile station in step 103. Determine the data rate as the data rate allowed for it. In this case, when there is more than one grant message, the grant message having the highest transmission rate may be selected or the grant message received from the base station which has been continuously performing communication may be selected.

On the other hand, if the check result of the grant message priority indicator is '0' in step 102, the mobile station applies the MIN (Rgrant, Rrc) rule to the mobile station in order to determine the data transfer rate allowed in step 104. Determined data rates. Here, the MIN (Rgrant, Rrc) represents a small value among Rgrant and Rrc. Rgrant represents the data rate indicated by the grant message, and Rrc represents the data rate allowed by the power control information. For example, if the data rate currently being transmitted by the mobile station is 76.8 kbps and the received power control information is 'UP', the Rrc is 153.6 kbps.

3 is a flowchart illustrating a method of determining a data rate of a mobile terminal according to a second embodiment of the present invention. Hereinafter, a method of determining a data transmission rate of a mobile terminal according to a second embodiment of the present invention will be described in detail with reference to FIG. 3.

First, the application rule of the grant message priority indicator applied according to the second embodiment of the present invention will be described.

If the value of the grant message priority indicator is set to '1', the mobile station prioritizes a grant message among various rate information received from various base stations. On the other hand, if the grant message priority indicator value is set to '0', the mobile station follows 'DOWN' if there is 'DOWN' among the rate control information received from various base stations, and 'DOWN' does not exist. If 'HOLD' is present, the terminal follows the 'HOLD', and if there is no 'DOWN' or 'HOLD' command from any base station, the mobile terminal follows the grant message.

Next, a more specific example of how the mobile terminal determines its own data rate according to the above-described application rule of the GRANT_PRECEDENCE_IND message according to the second embodiment of the present invention will be described with reference to the accompanying drawings.

Referring back to FIG. 1, the mobile terminal 10 is performing a handoff between the first base station 20a and the second base station 20b and receives rate information from the two base stations 20a and 20b, respectively. . The primary base station for the mobile terminal 10 is the first base station 20a.

The primary first base station 20a controls the rate for the mobile station 10a in a total rate transition manner, and the second base station 20b transmits a rate for the mobile station 10 in a limited rate transition manner. To control. Accordingly, the mobile station 10 receives the grant message at the reverse rate from the first base station 20a, and receives the rate control information at the reverse rate from the second base station 20b.

In this case, it is assumed that there are 9.6 kbps, 19.2 kbps, 38.4 kbps, 76.8 kbps, 153.6 kbps, 307.2 kbps and the like in the data rate set available to the mobile station. For example, the current data rate of the mobile station 10 is 76.8kbps, the mobile station 10 receives the rate information of 'grant = 307.2kbps' from the first base station 20a, the second base station 20b ) Transmits the rate control information of 'rate control information = UP'. In this case, the transmission rate information of 'grant = 307.2kbps' received from the first base station 20a means that the first base station 20a allows a transmission rate of 307.2 kbps to the mobile station 10. In addition, 'transmission rate control information = UP' received from the second base station 20b means that the second base station 20b allows a transmission rate of 153.6 kbps to the mobile terminal 10.

If the value of the grant message priority indicator is '1' in the above situation according to the application rule of the grant message priority indicator, it means that the grant message from the first base station 20a should always be given priority. When determining the data rate, the mobile terminal 10 finally determines that a rate of 307.2 kbps is allowed. On the other hand, when the value of the grant message priority indicator is '0', the MS 10 transmits a grant message if there is no 'DOWN' or 'HOLD' command among the rate control information from the plurality of base stations. Determine the reverse rate according to. Therefore, in this case, the mobile station 10 finally determines that the transmission rate of 307.2 kbps is allowed when determining the reverse data rate.

Next, the second embodiment will be described with reference to FIG. 3.

Referring to FIG. 3, in step 201, the mobile station receives reverse rate information from base stations in its active set. In this case, the reverse rate information may be a grant message or rate control information according to whether the base station uses the full rate shifting scheme or the limited rate shifting scheme.

In step 202, when receiving a call setup process or a handoff message from the base station, the mobile station checks whether the value of the grant message priority indicator is '1' or '0'. If the value of the grant message priority indicator is '1', the process proceeds to step 207; otherwise, to step 203. If the mobile station proceeds to step 203, it checks whether there is a 'DOWN' command among the rate control information received from the plurality of base stations. If the check result indicates that there is a 'DOWN' command among the rate control information received from the plurality of base stations, the mobile station proceeds to step 204 and determines to apply the 'DOWN' command in determining the data rate allowed to the mobile station. That is, the mobile station lowers the data rate allowed by the mobile station by one step from the current rate.

On the other hand, if there is no 'DOWN' command among the rate control information received from the plurality of base stations as a result of the check in step 203, the mobile station transmits a 'HOLD' command among the rate control information received from the plurality of base stations in step 205. Check for existence. If there is a 'HOLD' command among the rate control information received as a result of the test, the mobile terminal proceeds to step 206 to apply the 'HOLD' command to determine the data transfer rate allowed to the mobile station. Keep the same rate. On the other hand, if there is no 'HOLD' command among the transmission rate control information received as a result of the check in step 205, the flow proceeds to step 207. In step 207, the mobile station determines the data rate indicated by the grant message as the data rate allowed to the mobile station in order to determine the data rate allowed for the terminal.

Next, a third embodiment of the present invention will be described.

First, the application rule of the grant message priority indicator PRIMARY_NB_PRECEDENCE_IND will be described when applying the third embodiment of the present invention.

If the value of the grant message priority indicator received from the base station is '1', the mobile station prioritizes scheduling information of the primary base station among reverse rate information received from various base stations. If the value of the grant message priority indicator is '0', the mobile station determines, if 'DOWN' is present among the rate control information received from several base stations, that is, the rate is one step lower than the current reverse rate as the reverse rate. . However, if there is no 'DOWN' command from any base station that transmits the rate control information, the mobile station determines the reverse rate according to the scheduling information of the primary base station.

A more specific example of how the mobile terminal determines its data rate according to the application rule of the grant message priority indicator according to the third preferred embodiment of the present invention will be described with reference to FIG.

It is assumed that the mobile terminal 10 is performing a soft handoff between the first base station 20a and the second base station 20b. Then, the rate information is received from the two base stations 20a and 20b, respectively. At this time, the primary base station for the mobile terminal 10 is the first base station 20a. In this case, the primary base station means a base station having the best channel environment with the mobile station 10 or a base station which has been continuously communicating with the mobile station 10 among the two base stations 20a and 20b.

The reverse rate information received from the base station may be transmitted to each mobile station located in the base station according to a scheduling algorithm, or may be transmitted in common to the mobile stations in the base station. Therefore, when the first base station 20a, which is a primary base station, wants to rapidly increase the transmission rate of the mobile terminal 10, the first base station 20a can control the transmission rate with respect to the mobile terminal 10 in a total transfer rate transition method. The rate may be controlled with respect to the mobile station 10 in a limited transfer rate transition scheme. In addition, the second base station 20b corresponding to the non-primary base station may be configured to control the transmission rate with respect to the mobile station 10 only by the limited transmission rate transition method. In this case, since it is difficult for the second base station 20b, which is a non-primary base station, to accurately schedule the mobile station 10, "DOWN / Don't Care" may be set during the rate control.

If the rate control information transmitted from the non-primary base station 20b is "DOWN", it is instructing the mobile station to lower the one-step rate. On the other hand, "Don't Care" means that the reverse rate is determined based on the rate information provided by another base station. Accordingly, the mobile terminal 10 receives the grant message or the rate control information from the first base station 20a as the rate information, and the " DOWN / Don't Care " as the rate control information from the second base station 20b. Receive information only. In this case, it is assumed that the transmission rates of the set of data rates available to the mobile station are 9.6kbps, 19.2kbps, 38.4kbps, 76.8kpbs, 153.6kbps, 307.2kbps, and the like. Assume that the current data rate of the mobile terminal 10 is 76.8 kbps.

Under the above assumption, the mobile station 10 receives the rate information of 'grant = 307.2 kbps' from the first base station 20a, and transmits the rate control information of 'rate rate control bit = DOWN' from the second base station 20b. Suppose you have received. The transmission rate information of 'grant = 307.2kbps' received from the first base station 20a means that the first base station 20a allows a transmission rate of 307.2 kbps to the mobile terminal 10. In addition, the meaning of 'transmission rate control bit = DOWN' received from the second base station 20b means that the second base station 20b allows the mobile station 10 to transmit a rate of 38.4 kbps.

As described above, when receiving a transmission rate value having a different value and transmission rate information of different formats from different base stations according to the application rule of the grant message priority indicator according to the third embodiment of the present invention, The reverse rate may be determined according to the value of the grant message priority indicator. That is, when the value of the grant message priority indicator is '1', this means that the scheduling information from the first base station 20a should always be prioritized, so that the mobile terminal 10 determines the data rate. The final decision is that the rate of 3072kbps is allowed. On the contrary, when the value of the grant message priority indicator is '0', the mobile station 10 applies 'DOWN' among rate control information from various base stations. In other words, the rate lower one step from the current rate is determined as the reverse packet data rate at the next time. Therefore, when determining the data rate, the mobile terminal 10 finally determines that a rate of 38.4 kbps is allowed.

4 is a control flowchart of determining a reverse rate of a mobile terminal in soft handoff according to a third embodiment of the present invention. Hereinafter, a reverse rate determining method according to a third embodiment of the present invention will be described in detail with reference to FIG. 4.

Referring to FIG. 4, the mobile station in handoff receives rate information from various base stations in step 301. The rate information is a grant message or rate control information. As such, the mobile station receives rate information from the base stations in the active set of the mobile station in step 301. The transmission rate information to be used in the mobile station among the received transmission rate information is determined according to whether the base station preset method uses the full rate shifting method or the limited rate shifting method.

Therefore, the mobile station proceeds to step 302 and checks whether the primary base station priority indicator has a value of '1' or '0'. If the check result of step 302 indicates that the value of the primary base station priority indicator is '1', the mobile station proceeds to step 303 and prioritizes the grant message or the rate control information, which is the transmission rate information transmitted from the primary base station. That is, when the rate information received from the primary base station is a grant message, the data rate indicated by the grant message is regarded as a reverse packet data rate allowed to the sender. On the other hand, if the rate information received from the primary base station is the rate control information, the mobile station determines the reverse packet data rate according to the rate control information received from the primary base station. That is, if the rate control information received from the primary base station is 'UP', the rate is increased, if it is 'DOWN', the rate is decreased, and if it is 'HOLD', the current rate is maintained. In conclusion, the transmission rate of the mobile station is determined using the grant message or the rate control information received from the primary base station.

In contrast, if the check result of step 302 indicates that the value of the primary base station priority indicator is '0', the mobile station proceeds to step 304. In step 304, the mobile station checks whether there is a 'DOWN' command among the rate control information received from various base stations. If there is a 'DOWN' command among the rate control information received from the various base stations as a result of step 304, the mobile station proceeds to step 305, otherwise proceeds to step 306. If the mobile station proceeds from step 304 to step 305, the mobile station applies a 'DOWN' command when determining the data rate allowed for the mobile station. Accordingly, the mobile station lowers the data rate allowed by the mobile station by one step from the current rate. On the contrary, if the flow proceeds from step 304 to 306, that is, when there is no 'DOWN' command among the rate control bits received from the various base stations, the mobile station transmits the data rate transmitted from the primary base station when determining the data rate allowed to the mobile station. It indicates that the data rate allowed by the reverse packet data rate or rate control information indicated by the grant message, which is information, is regarded as a data rate allowed to the user. In conclusion, the reverse rate of the mobile station is determined based on the grant message or the rate control information received from the primary base station.

Next, a method of informing an allocation status of a primary base station priority indicator of a mobile station in which a specific base station is currently performing handoff from another adjacent base station will be described. In the following description, information indicating the allocation status of the primary base station priority indicator is referred to as "Grant Precedence Information".

According to the present invention, a specific base station informs an adjacent base station whether each of the above-described primary base station priority indicators is set, and thus, the base station is regarded as a non-primary base station among mobile stations having the primary base station priority indicator set to 1. The mobile terminal can be considered when performing scheduling or transmitting control information. In the case of the UMTS system, the information may be transmitted through NBAP signaling on the Iub interface.

Next, an example of the use of the grant priority information will be described.

The environment described below is an environment in which the mobile station operates by applying the present invention in a system for transmitting each dedicated rate control bit to a mobile station in which a specific base station is a non-primary base station. In this case, it is meaningless to transmit the rate control information to the mobile station in which the primary base station priority indicator is set to one. Accordingly, the non-primary base station determines whether to transmit the rate control information by using the information of the primary base station priority indicator allocated to each mobile station by the primary base station.

First, when the base station controls the reverse rate of the mobile station in handoff, it checks whether it is set as a primary base station or a non-primary base station. As a result of the check, the base station set as the non-primary base station for the mobile terminal being handed off has a primary base station priority indicator set to 1 in the mobile terminal being handed off using grant priority information received from another base station. Check if it is a mobile terminal. If the test result is that it is a non-primary base station and the mobile terminal in handoff is set to the primary base station priority indicator of 1, it does not transmit rate control information to the mobile terminal. However, the above test results indicate that the mobile station, which is a non-primary base station and whose primary base station priority indicator of the mobile station being handed off is set to 0, transmits transmission rate control information.

Meanwhile, the GRANT_PRECEDENCE_IND information may be delivered through a signaling layer, and a method of delivering GRANT_PRECEDENCE_IND information through the signaling layer will be described as an example. Alternatively, in the case of the UMTS system, the RNC may be delivered to each mobile terminal through RRC (Radio Resource Control) signaling. These methods include conventional extended system parameter messages (hereinafter referred to as ESPM), extended channel assignment messages (hereinafter referred to as ECAM), multi-carrier radio resource (MC-RR) parameter messages (MC). Modifying the RR Parameters Message (hereinafter referred to as MCRRPM) and the Universal Handoff Direction Message (hereinafter referred to as UHDM) to transfer GRANT_PRECEDENCE_IND information and the new grant order (hereinafter called GRANT Precedence Order). Define GRANT_PRECEDENCE_IND information.

If the format of the modified ESPM to deliver the GRANT_PRECEDENCE_IND information is shown in Table 1 below.

In the ESPM shown in Table 1, the preceding indication (hereinafter referred to as REV_PDCH_GRANT_PRECEDENCE_IND) field is added to the conventional ESPM. The reverse packet data channel grant precedence indication field is included in the message only when the reverse packet data channel parameter addition (hereinafter, referred to as REV_PDCH_PARAMS_INCL) field is included in the message and is set to '1'. It always indicates that the grant takes precedence over the power control information.

A modified ECAM for transmitting the GRANT_PRECEDENCE_IND information is shown in Table 2 below.

In Table 2, the modified ECAM is transmitted to deliver GRANT_PRECEDENCE_IND information. When a packet data traffic channel is allocated using a conventional ECAM (ASSIGN_MODE = '101'), one bit of the REV_PDCH_GRANT_PRECEDENCE_IND field is used. Add GRANT_PRECEDENCE_IND information. The REV_PDCH_GRANT_PRECEDENCE_IND field is included in the message only when the REV_PDCH_PARAMS_INCL field is included and has a value of 1. When the REV_PDCH_GRANT_PRECEDENCE_IND field is set to '1', the grant always gives priority to the power control information for the mobile terminal to which the channel is allocated.

The modified MCRRPM to deliver the GRANT_PRECEDENCE_IND information is shown in Table 3 below.

In Table 3, the MCRRPM modified to deliver GRANT_PRECEDENCE_IND information is added with a bit of the REV_PDCH_GRANT_PRECEDENCE_IND field to the conventional MCRRPM similarly to the change of the ESPM.

Table 4 shows the UHDM modified to deliver the GRANT_PRECEDENCE_IND information.

In Table 4, the UHDM modified to deliver the GRANT_PRECEDENCE_IND information is configured to configure a packet data traffic channel using a conventional UHDM (CH_IND = '000', EXT_CH_IND is not '00000', ' 00111 ',' 10111 'to' 11111 '), and adds one bit of the REV_PDCH_GRANT_PRECEDENCE_IND field to transfer GRANT_PRECEDENCE_IND information.

The mobile terminal receiving the message including the GRANT_PRECEDENCE_IND field stores the value of the received GRANT_PRECEDENCE_IND field in GRANT_PRECEDENCE_INDs, which is a shared variable between the signaling layer and the medium access control (MAC) layer, for the operation of the media access control layer. Apply.

Unlike the above, GRANT_PRECEDENCE_IND information can be delivered using a message other than ESPM, ECAM, MCRRPM, UHDM, and in addition to modifying the conventional message structure and delivering GRANT_PRECEDENCE_IND information, GRANT_PRECEDENCE_IND information can also be delivered. have.

Table 5 below shows the structure of Grant Precedence Order, which is a newly defined Order Message for delivering RANT_PRECEDENCE_IND information.

In Table 5, in order to indicate that a grant has priority over power control information, the base station has an order message with an order code of '100100' and an order qualification code (ORDQ) of '00000000'. ) Can be delivered. In addition, to inform that the grant has no priority over RCB, a command message with a command code of '100100' and an ORDQ of '00000001' can be delivered.

A mobile station that receives a command message with a command code of '100100' and an ORDQ of '00000000' sets the value of GRANT_PRECEDENCE_INDs to 1, and receives a command message with a command code of '100100' and an ORDQ of '00000001'. Applies the behavior of the media access control layer by setting the value of GRANT_PRECEDENCE_INDs to 0.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by the equivalents of the claims.

As described above, the present invention can obtain lower throughput in the mobile terminal by determining the data rate of the mobile terminal by combining the rate control information that the mobile station performing the handoff is signaled from a plurality of base stations in advance. Therefore, the load of the scheduling can be reduced in the base station, and the reverse rate can be efficiently controlled.

1 is a view showing the structure and each component of a mobile communication system to which the present invention is applied;

2 is a flowchart illustrating a procedure of determining a data rate by a mobile terminal in handoff according to a first embodiment of the present invention;

3 is a flowchart illustrating a method of determining a data rate of a mobile terminal according to a second embodiment of the present invention;

4 is a control flowchart of determining a reverse rate of a mobile terminal in soft handoff according to a third embodiment of the present invention.

Claims (6)

In a mobile communication system having a plurality of base stations communicating with a mobile terminal, the mobile terminal receives the rate control information from the plurality of base stations during the handoff to the other base station to determine the allowed data rate In Receiving rate control information through signaling messages from the plurality of base stations; And determining a data rate allowed to the user according to the highest priority instruction set in the rate control information. The method of claim 1, wherein the determining of the data rate comprises: If the rate control information indicating the highest priority indication is received from the base station scheduled through the maximum rate transition method, the data rate is determined by giving priority to the rate control information set as the grant information among the rate control information received from the plurality of base stations. Characterized in that the method. The method of claim 1, wherein the determining of the data rate comprises: Receiving rate control information not indicating the highest priority indication from the base station scheduled through the limited rate transition method, the data rate is determined by giving the highest rate control information indicating the lowest rate among the rate control information received from the plurality of base stations. The method characterized in that it determines. In the mobile communication system for determining the reverse data rate, A plurality of base stations transmitting rate control information indicating a highest priority indication through a signaling message according to a scheduled method; And a mobile terminal for receiving the rate control information transmitted from the plurality of base stations and determining a data rate allowed to the user according to the highest priority instruction set in the rate control information. The method of claim 4, wherein the mobile terminal, Receiving the rate control information set to the grant indicating the highest priority from the base station scheduled by the maximum rate transition method, it determines that the data rate allowed to itself as the data rate indicated by the rate control information indicating the highest priority indication Said system. The method of claim 4, wherein the mobile terminal, Receiving rate control information set to a rate control bit not indicating a highest priority indication from a base station scheduled through a limited rate transition scheme, the rate control information indicating the lowest rate among the rate control information received from the plurality of base stations is the highest priority. The data transmission rate is determined by the system.