KR100991774B1 - Method of adjusting data transmission rate for a reverse link - Google Patents

Abstract

The present invention relates to a communication system, and more particularly to a method of controlling a reverse link data transmission rate. The method for controlling the reverse link data transmission rate includes generating data transmission rate control information dedicated for a corresponding terminal based on a state of each terminal, and transmitting the data transmission rate control information to the corresponding terminal. Is done.

Reverse Transmission Rate Control Bits (RCB)

Description

Method of adjusting data transmission rate for a reverse link}

1 is a flowchart illustrating a method of controlling a reverse data transmission rate in the prior art.

2 is a block diagram illustrating a channel configuration for transmitting reverse transmission rate control bits and ACK / NACK bits according to the present invention.

3 is a flowchart illustrating a method of controlling a reverse data transmission rate according to an embodiment of the present invention.

4 is a flowchart illustrating a process of acquiring one RCB based on RCBs from sectors in an active set according to another embodiment of the present invention.

* Description of the major symbols in the drawings *

10, 17: repeater

11, 18: signal point mapper

12, 19: channel gain section

13, 20: multiplexer

14: relative offset calculation unit

15: decimator                 

16: long code generator

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

In general, the data transmission rate on the reverse link is closely related to the total amount of interference received by the base station (hereinafter referred to as ROT). The total amount of interference received by the base station refers to the sum of signal powers of signals of all terminals received by the base station. This will be described with reference to the example of FIG. 1.

1 is a flowchart illustrating a method of controlling a data transmission rate in the prior art.

The terminal may transmit data by increasing the data transmission rate on the reverse link when the total amount of interference received by the base station is small, but otherwise, that is, when the total amount of interference is greater than or equal to a certain level. In some cases, it may be necessary to reduce the transmission of data or stop transmitting data.

In the case of a 1x EV-DO (1x Evolution Data Only) system, as shown in FIG. 1, the base station estimates the total amount of interference of data on the reverse link (S10), so that an instruction of increasing or decreasing the data transmission rate, that is, RA Generate a (Reverse Activity) bit and transmit it to all active terminals (S12). This Reverse Activity (RA) bit is transmitted to all terminals in the active set that are transmitting data on the reverse link through a common channel called a random access channel.

The base station compares the total interference amount with the threshold value (S11), and when the total interference amount is large, that is, when the sum of signal powers of all terminals is equal to or greater than a predetermined threshold, the RA bit corresponding to the data transmission rate reduction command. Create and send to the active terminals. However, when the total interference amount is smaller than the threshold, that is, when the sum of the signal powers of the terminals is less than or equal to the predetermined threshold, the base station generates and transmits an RA bit corresponding to the data transmission rate increasing command to the active terminals.

That is, all the terminals simultaneously receive the increase command RA bit or at the same time receive the decrease command RA bit.

This RA bit is transmitted from the base station to the terminals for one frame, and the corresponding terminal adjusts the data transmission rate of the next frame using the RA bit (S14).

Prior to adjusting the data rate, when the corresponding terminal receives the RA bit, each terminal performs a test for increasing or decreasing the data transmission rate (S13). That is, the fact that terminals are commanded to increase or decrease does not necessarily increase or decrease the data transmission rate.

After each terminal receives the RA bit, it tests itself using this RA bit to determine whether to increase or decrease the data transmission rate. Each terminal does not increase or decrease the data transmission rate after performing this test, otherwise it maintains the current data transmission rate without increasing or decreasing the data transmission rate.

If the data transmission rate of the current reverse transmission frame is low, the probability of increasing the data transmission rate of the next frame is high, but the probability of decreasing the data transmission rate is low, and conversely, if the data transmission rate of the current reverse transmission frame is high, the next frame The terminal performs a test on whether the data transmission rate changes so that the probability of increasing the data transmission rate is low while the probability of decreasing it is high.

As such, the prior art has been made based only on the total amount of interference of data received by the base station without the RA bit taking into account the reception of data from the terminal. Thus, this RA bit has been delivered to all terminals in the same increment or decrement instruction.

Therefore, since the terminal needs to execute an increase or decrease in the data transmission rate without considering its channel situation, the terminal cannot transmit data efficiently.

As a result, this problem is better than the data processing degradation problem of the terminal.

For the base station, even if the terminal receives the RA bit corresponding to the increase or decrease command of the data transmission rate, since the terminal increases or decreases the data transmission rate only after executing its own test, the total amount of interference as the base station predicts is changed. There is a problem that can not obtain the effect that can be obtained.

The present invention has been made in view of the above-mentioned problems of the prior art, and an object of the present invention is to provide a method for controlling a reverse link data transmission rate.

Another object of the present invention is to provide a method of controlling a reverse link data transmission rate in which a corresponding terminal can efficiently transmit data in consideration of a resource state and a channel state of each terminal.

According to an aspect of the present invention for achieving the above object, the method for controlling the reverse link data transmission rate generating the data transmission rate control information dedicated for the terminal based on the state of each terminal, And transmitting the data transmission rate control information to a terminal.

According to another aspect of the present invention, a method for controlling a reverse link data transmission rate includes detecting dedicated data transmission rate control information for itself in a forward common rate control channel, the data transmission rate control information, its state, Determining a reverse link data transmission rate to be transmitted based on at least one of the previous data transmission rates.

According to still another aspect of the present invention, a method for controlling a reverse link data transmission rate may include, when in a soft handoff region, a base station controller for a terminal, based on the state of the terminal, to provide dedicated data transmission rate control information for the terminal. Generating and transmitting to the base stations in the active set, transmitting the data transmission rate control information from the base stations to the terminal, respectively, to the rate control information obtained by combining the data transmission rate control information in the terminal. And adjusting the reverse link data transmission rate based on that.

According to still another aspect of the present invention, a method for controlling a reverse link data transmission rate may include, when in a soft handoff region, base stations with respect to a terminal based on a state of the terminal based on the state of the terminal. Generating and transmitting each to the terminal, the terminal adjusting the reverse link data transmission rate based on data transmission rate control information received from the base stations.

Hereinafter, a configuration and an operation according to an exemplary embodiment of the present invention will be described with reference to the accompanying drawings.

If the terminal has data to transmit, the terminal starts transmitting data independently without the control of the base station.

As described above, when the terminal starts to transmit data independently, there are two methods for determining the transmission rate of the first data to be transmitted.

The first method is to transmit data at the lowest data transmission rate currently supported by each terminal.                     

For example, if 9.6 kbps is the lowest data transmission rate that can be supported, the terminal can start transmitting data without the control of the base station only at a data transmission rate of 9.6 kbps.

The second method is a method in which a base station and a terminal determine a transmission rate of data initially transmitted from the terminal through a negotiation process. For example, if the initial transmission data transmission rate is determined to be 38.4 kbps by the negotiation process, the terminal may start data transmission without the control of the base station only at the data transmission rate of 38.4 kbps.

After starting to transmit data at the data transmission rate determined above, the terminal receives at least one bit of information (e.g., mobile station status information bit (MSIB)) indicating the status of the terminal (terminal). Transmit to base station. As a basis for determining the state of the terminal, the available power of the terminal, the amount of data to be sent, etc. are considered.

For example, if the MSIB consists of one bit, if the terminal has enough power and has enough data, the MSIB can be set to 0 and transmitted, otherwise it can be set to 1.

When the terminal transmits data on the reverse link, the base station is controlled for the transmission rate of data to be sent later, except for the first data. That is, when the base station transmits at least one bit of a dedicated reverse rate control bit (RCB bit) to each terminal, the terminal controls the transmission rate of data to be sent to the base station using the RCB. do.                     

As an example of the RCB, there may be an increase, decrease, or maintain command information of a data transmission rate.

Each dedicated RCB for multiple terminals can transmit to the corresponding terminals via one shared channel, and FIG. 2 is one example of this shared channel. For convenience of explanation, hereinafter, such a common channel is referred to as a forward-common rate control channel (F-CRCCH). In the example of FIG. 2, the F-CRCCH is transmitted along with a Forward-Common ACKnowledgement Channel (F-CACKCH) for transmitting dedicated ACK / NACK for the reverse link packet transmitted from a plurality of terminals to the corresponding terminals.

Considerations when the base station generates dedicated RCBs for multiple terminals are the channel state of the reverse link, MSIB, and Rise Over Thermal (ROT). That is, the base station determines whether to increase, maintain or decrease the data transmission rate of the terminal based on the MSIB received from the terminal, the channel state of the reverse link, and the current ROT. The RCB transmitted by the base station to the terminal may indicate two states or may indicate three states.

When the RCB indicates two states, the RCB is composed of one bit. For example, the RCB value may be set to 0 to increase the data transmission rate of the terminal, and may be set to 1 to decrease the RCB value.

In the case where the RCB represents three states, the RCB consists of one or two bits. For example, in the case of one bit, the RCB value may be set to 0 to increase the data transmission rate of the terminal, set to 1 to decrease, and the RCB may not be transmitted to maintain. For example, in the case of two bits, the RCB value may be set to 00 to increase the data transmission rate of the terminal, 01 to maintain, and 10 to decrease.

The varying magnitude of the data transfer rate increased / decreased by the RCB is not limited to one step increase / decrease. That is, it may be an increase / decrease of two steps, an increase / decrease of three steps, or more. At this time, the increase step number, the decrease step number is predetermined through negotiation between the base station and each terminal (negotiation).

The base station transmits a dedicated RCB to the terminal periodically or aperiodically. At this time, the base station designates a minimum transmission time unit to transmit a dedicated RCB to the corresponding terminal, and transmits the RCB within a time interval corresponding to an integer multiple of the minimum transmission time unit. If the minimum transmission time unit is 20ms, the base station transmits the RCB to the terminal at most once every 20ms.

3 is a flowchart illustrating a method of controlling a reverse data transmission rate according to the present invention.

3 illustrates a process in which a corresponding terminal determines a data transmission rate when the RCB indicates three states of increasing, maintaining, and decreasing.

When the terminal checks the received RCB (S100) and the value indicates an increase, it is checked whether the state of the terminal (terminal) supports an increase in the data transmission rate (S110). Uses the amount of power currently available, buffer status, and more. It is checked whether the terminal state can support an increase in the data transmission rate, and if the increase in the data transmission rate can be supported, the data transmission rate is increased by an increment α compared to the previous data transmission rate (S130). The increment 'α' is previously determined through an agreement between the base station and each terminal as described above, and may be increased by at least one step. If the terminal state cannot support the increase of the data transmission rate or if the value of the received RCB indicates maintenance, it is checked whether it can support the maintenance of the data transmission rate (S120). The data transmission rate is maintained at the previous data transmission rate (S140). If the value of the received RCB indicates an increase, if the state of the terminal cannot support the increase and maintenance of the data transmission rate, or if the value of the received RCB indicates the maintenance, the state of the terminal indicates the data transfer rate. If maintenance cannot be supported or if the value of the received RCB indicates a decrease, the terminal reduces the data transfer rate by a decrease β compared to the previous data transfer rate. This reduction width β is predetermined through agreement between the base station and each terminal as described above.

In summary, the method of determining the data transmission rate may increase, maintain, or decrease the data transmission rate according to the state of the terminal when the terminal receives the RCB indicating the increase. When the terminal receives the RCB indicating maintenance, the data transmission rate must be maintained or reduced according to the terminal state. If the terminal receives an RCB indicating a decrease, it should reduce the data transmission rate.

Meanwhile, in order to transmit a dedicated RCB to a terminal in a soft handoff region, the base station may transmit the RCB in four ways.

The first method is to generate an RCB in a base station controller (BSC) and transmit the same RCBs to the base station (s) of all sectors in the active set managed by the base station controller. In this case the terminal receives the same value of RCBs from the base station (s) of the sectors in the soft handoff area. However, the received energy values of the RCBs may vary depending on how far they are located from the base station (s) of the sectors within the soft handoff area. Accordingly, the terminal combines the received RCBs to obtain one RCB at a level below a target error rate, and sets the RCB value to one of increasing, decreasing, and maintaining based on the combined value. Using the set value of RCB, the terminal finally determines whether to increase, maintain or decrease the data transmission rate according to the procedure shown in FIG. 3. That is, the data transmission rate is determined by considering whether the data transmission rate control command indicated by the RCB set as described above can be supported by its own state such as the amount of power currently available and the buffer state. For example, when the RCB is set to increase, the terminal increases, maintains, or decreases the data transmission rate according to its state. If the RCB is set to maintain, the data transmission rate is maintained or reduced according to its state. When the RCB is set to decrease, the data transmission rate is reduced according to its state.

In the second method, the base station (s) of sectors in the active set generate each RCB and transmit it to the corresponding terminal. In this case, the terminal may acquire one RCB indicating increase, decrease, or maintenance based on the values of the RCBs received from the base station (s) of the sectors in the active set. As an example, when the RCBs received from the base stations are increased, the terminal sets the value of the RCB to be used for data transmission rate control to increase. If any one of the RCBs received from the base stations is reduced, the terminal sets the value of the RCB to be used for data transmission rate control to be reduced. If the RCBs indicating an increase in the RCBs received from the base stations and the RCBs indicating maintaining are simultaneously received, the terminal sets the value of the RCB to be used for data transmission rate control to maintain. Using the set value of RCB, the terminal finally determines whether to increase, maintain or decrease the data transmission rate according to the procedure shown in FIG. 3. As in the first method, the data transfer rate is determined by considering its state such as the amount of power currently available and the buffer state whether it can support the data transfer rate control command indicated by the RCB set as described above. For example, when the RCB is set to increase, the terminal increases, maintains, or decreases the data transmission rate according to its state. If the RCB is set to maintain, the data transmission rate is maintained or reduced according to its state. When the RCB is set to decrease, the data transmission rate is reduced according to its state.

The third method is a method of transmitting an RCB indicating a reduction command to a terminal only when a base station of a sector other than a serving sector among active sectors wants to request the terminal to decrease a data transmission rate. That is, a base station of a sector other than the serving sector does not transmit an RCB indicating an increase or maintenance of a data transmission rate. However, the base station of the serving sector among the sectors in the active set transmits to the terminal the RCB indicating the increase, decrease or maintain command of the data transmission rate.

4 is a flowchart illustrating a process of acquiring one RCB from the RCBs thus received.

The terminal determines whether it receives an RCB indicating a decrease command from the base station (s) of sectors other than the serving sector. (S200) If the terminal indicates a decrease command from the base station (s) of the sectors other than the serving sector, If the RCB is received, the terminal sets the value of the RCB to be used for data transmission rate control to a decrease (S201). However, if no RCB indicating a decrease command is received from the base station (s) of sectors other than the serving sector, the terminal sets the RCB to be used for data transmission rate control according to the RCB received from the base station of the serving sector. (S202 to S205) That is, if the RCB received from the base station of the serving sector indicates an increase, the value of the RCB to be used for data transmission rate control is set to increase (S203), and the RCB received from the base station of the serving sector. If is instructed to maintain, the value of the RCB to be used for data transmission rate control is set to hold (S204), if the RCB received from the base station of the serving sector indicates a decrease, the value of the RCB to be used for data transmission rate control is Set to decrease (S205).

Using the RCB set as described above, the terminal finally determines whether to increase, maintain or decrease the data transmission rate according to the procedure of FIG. 3. The data transmission rate is determined in consideration of its own state such as the amount of power currently available and the buffer state whether it can support the data transmission rate control command indicated by the RCB set as described above. For example, when the RCB is set to increase, the terminal increases, maintains, or decreases the data transmission rate according to its state. If the RCB is set to maintain, the data transmission rate is maintained or reduced according to its state. When the RCB is set to decrease, the data transmission rate is reduced according to its state.

In the fourth method, the base station (s) of the non-serving sectors among the sectors in the active set do not transmit the RCB to the corresponding terminal, and only the base station of the serving sector commands to increase, maintain, or decrease for data transmission rate control. A method of transmitting an RCB indicating a to a corresponding terminal. Accordingly, the terminal sets the RCB to be used for data transmission rate control using the RCB received from the base station of the serving sector. That is, if the RCB received from the base station of the serving sector indicates an increase, the value of the RCB to be used for data transmission rate control is set to increase, and if the RCB received from the base station of the serving sector indicates maintenance. When the RCB received from the base station of the serving sector indicates a decrease, the value of the RCB to be used for data transmission rate control is set to decrease. As shown in FIG. 3, the terminal transmits data in consideration of its own state such as the amount of power currently available and the buffer state whether it can support the data transmission rate control command indicated by the RCB set as described above. Determine the rate. For example, when the RCB is set to increase, the terminal increases, maintains, or decreases the data transmission rate according to its state. If the RCB is set to maintain, the data transmission rate is maintained or reduced according to its state. When the RCB is set to decrease, the data transmission rate is reduced according to its state.

As described above, the present invention reduces the total interference amount by exclusively transmitting data transmission rate control information for each terminal in consideration of the buffer state of each terminal, the channel condition of the reverse link, and the total interference amount at the base station. Reverse link transmission efficiency is improved.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention.

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

Claims (39)

delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete A method for a terminal to control a data transmission rate in a wireless communication system in a soft handoff region, the method comprising: Receiving first data transfer rate control information used for determining a reverse link data transfer rate from the serving sector; Determining whether second data transfer rate control information indicating a reduction in data transfer rate has been received from one or more non-serving sectors; And Adjusting a reverse link data transmission rate based on the first data transmission rate control information or the second data transmission rate control information according to whether the second data transmission rate control information is received; And wherein the first data transfer rate control information indicates an increase, a maintenance, or a decrease of the data transfer rate. The method of claim 33, When receiving at least one second data transfer rate control information from sectors other than the one or more serving sectors, And determining the reverse link data transfer rate in accordance with the second data transfer rate control information. The method of claim 34, Determining to reduce the reverse link data transmission rate. The method of claim 33, If the second data transfer rate control information is not received from a sector other than the one or more serving sectors, And determining the reverse link data transfer rate based on the first data transfer rate control information. The method of claim 36, If the first data transmission rate control information indicates an increase, determine one of increasing, maintaining, and decreasing the reverse link data transmission rate according to the state of the terminal itself; If the first data transmission rate control information indicates maintenance, determine whether to maintain or decrease the reverse link data transmission rate according to the state of the terminal itself; And if the first data transfer rate control information indicates a decrease, determining the reverse link data transfer rate control information as a decrease. The method of claim 37, The state of the terminal itself includes information about the amount of power available, buffer state. The method of claim 33, And wherein the first data transfer rate control information and the second data transfer rate control information are received with dedicated repair confirmation / non-confirmation information for forward packet data.

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