KR20040042483A - Method for controlling data rate in communication system - Google Patents

Abstract

PURPOSE: A method for controlling a data transmission rate in a communication system is provided to assign and control the transmission rate of an R-SCH(Reverse link-Supplemental CHannel) on the basis of an ROT(Rise Over Thermal noise). CONSTITUTION: A base station sets an offset value of data transmitted to a reverse link according to a data transmission rate. The base station sets the total offset value of the entire channel capable of being accommodated to the reverse link as the total capacity. The base station decides the assignment and control of the data transmission rate of an R-FCH(Reverse link-Fundamental CHannel) and an R-SCH according to the limit of the total offset value.

Description

Method for controlling data rate in communication system

The present invention relates to a data rate control method in a communication system, and more particularly, to a data rate control method in a communication system for controlling the data rate in accordance with the load of the base station.

The communication system, inter alia, the synchronous CDMA2000 1x Reverse Link Supplemental Channel (hereinafter referred to as R-SCH), is a Reverse Fundamental channel (hereinafter referred to as R-SCH) that mainly handles voice services. Unlike FCH), it is mainly used for data services.

In other words, R-SCH is a channel mainly used for services requiring high-speed data transmission, and handles a very high data rate (maximum data rate 614,400bps) compared to R-FCH, which has a maximum data rate of 9600bps. can do.

The data rate of the R-SCH is transmitted by selecting an appropriate rate from the terminal in consideration of the current transmission power, reception state, and buffer state of the terminal, and the base station negotiates the transmission rate of the terminal based on this. Try to negotiate.

If the negotiation is successful at the base station, the base station sends a grant message to the terminal, which informs the terminal of the number of bits to be transmitted and transmission duration information. That is, it informs the transmission rate (rate) and the transmission period.

Even after the above transmission is completed, if there is data to be transmitted by the terminal, the terminal and the base station perform the above negotiation process again to perform the transmission.

One of the most important channel resources on the reverse link is a value called Rise over Thermal Noise (ROT), where ROT is the amount of interference received by the base station. This value represents the total amount. This value is similar to the total load in the base station.

Therefore, when the value of ROT is high, it means that the amount of interference at the base station currently received is high. When the value of ROT is low, it means that the amount of interference is small.

If the ROT is high, especially above the reference value, the reception quality of the reverse link may be greatly degraded and a situation in which communication can no longer be performed may occur. In this case, it is necessary to reduce the ROT by lowering the rate of users transmitting on the reverse link.

When the ROT is low, since the amount of interference is small, the rate of users transmitting on the reverse link may be additionally increased.

The most accurate and efficient way is for the base station to measure the above ROT value and assign and control the rate based on this value.

In the conventional R-SCH, a base station allocates a rate without considering the ROT situation in a rate assign process. Therefore, great difficulty has arisen in maintaining an appropriate level of communication quality. In other words, even when the ROT value is so large that fast data rate allocation is no longer possible, the operation of lowering the rate of users has not been performed. In addition, the rate control method using the ROT has a problem that the actual measurement of the ROT is not only very difficult, but additional work is required, so that the actual application is somewhat difficult.

The present invention has been made in view of the above, and by setting an offset value in the channels according to the data rate transmitted on the reverse link, by using the numerical value of the interference received from the base station by using the reverse direction according to the load state of the base station A data rate control method in a communication system capable of allocating and controlling a data rate of an auxiliary channel is provided.

In the data rate control method of the present invention, the offset value is set according to the data rate for data transmitted on the reverse link, and the base station sets the total offset value of all channels that can be accommodated on the reverse link as the total capacity. The base station determines the data rate allocation and control of the primary channel of the reverse link and the auxiliary channel of the reverse link according to the total offset value limit.

Preferably, the total offset value of the entire channel is the same value as the total load amount or the total interference amount of the data rate that can be allocated by the base station.

Preferably, when the total offset value limit is set, a method for allocating a data rate of the maximum allowable limit for a data rate request that is greater than or equal to the offset value being allocated and controlled by the base station, the channel status of the base station, and the regional characteristics of the terminal. According to the data rate allocation method, the channel status of the base station, the regional characteristics of the terminal, and the allocation method in consideration of the performance of the terminal. It is determined by the power strength measurement message (PSMM) transmitted by the terminal.

According to another aspect of the present invention as described above, by configuring an indicator based on the thermal noise rise (ROT) according to the data rate in the data channel transmitted on the reverse link, the primary channel and the reverse link of the reverse link by using the indicator values Allocates or controls the data rate of the secondary channel.

Preferably, the indicator assigns a low offset value for a channel having a low data rate and a high offset value for a channel having a high data rate.

Other objects, features and advantages of the present invention will become apparent from the detailed description of the embodiments with reference to the accompanying drawings.

1 is a diagram for explaining an offset value according to a data rate.

2 is a view for explaining a data rate control method in a communication system according to the present invention.

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

1 is a diagram for explaining a data rate in a general communication system.

The present invention proposes a method for allocating and controlling a transmission rate of an R-SCH based on an ROT received by a base station, but not directly using the ROT, but using an indicator close to the ROT.

Here, a method of using an index that is close to ROT without directly measuring ROT is to use a low amount of interference when the data rate is low and a high amount of interference when the rate is high. Quantify the impact of interference on a base station by assigning a low offset value for channels with low data rates and a high offset value for channels with high data rates. It is.

These offsets are used as specific values that indirectly indicate the amount of interference to impose on the base station when the channel is connected to the base station. At this time, the total offset of all channels of users connected to the base station is an indirect value indicating the total interference amount, which is equal to the total load amount.

Therefore, using the offset value has the same effect as measuring and using the ROT value without measuring the ROT directly.

To this end, as shown in FIG. 1, first, an offset value for each data rate is specified.

At this time, the offset of the 9600bps channel is set to 1 for the reference of the offset value, and an offset value for each rate is specified. At this time, the offset value for each rate is calculated based on the ROT actually acting on the base station, through simulation, or using the nominal attribute gain table provided in the specification. Specify.

For example, as shown in FIG. 1, if the transmission rate of 9600bps is offset = 1, 38400bps (9600x4) can be specified as offset = 4 and the transmission rate of 153600bps (9600x16) as offset = 16.

Next, the total capacity that can be accommodated by one cell or one sector is calculated using an offset concept. In this case, the concept of ignoring the amount of interference received from users served by another base station and using only the amount of interference received from users served by the base station is introduced. That is, only the offset values of the users serving the own base station is added up.

In this case, the total capacity is implemented by simulation or field test. In the embodiment of the present invention, as an example, it is assumed that the total capacity that one cell or one sector can accommodate is 50.

Once the total capacity is found, rate assign and rate control should be carried out with the total capacity not exceeding 50.

For example, if one 1 x FCH (9600 bps) and one 16 x SCH (153600 bps) are allocated to one cell or sector, the current capacity is 1 x 25 + 16 x 1 = 41. In this case, it can be seen that the capacity limit of offset = 9 (50-41) remains. 2 illustrates this.

That is, in the above situation, a channel requiring an offset less than 9 can be allocated, but criteria for a rate assign are required for a channel requiring more than that.

For example, when a request of 16 x SCH (153600bps), that is, offset = 16 is received in a situation where offset = 9 remains as in the above situation, rate allocation and rate control may be determined in several aspects.

The first is to accept the maximum allowable limit of the required maximum rates. That is, in the situation where offset = 9 remains, the maximum allowable 8 × SCH (76800bps), that is, offset = 8 even when 16 × SCH (153600bps), that is, offset = 16 is required.

Secondly, consider the channel situation or regional characteristics. That is, it is a method of lowering the transmission rates of users in poor channel conditions, or users in SHO regions and cell edges, and instead allowing the requested data rates.

As an example, if the total capacity is 50 as described above, and there are currently 15 1 x FCH (9600 bps), 4 4 x SCHs (38400 bps), and one 16 x SCH (153600 bps), the current capacity. Is 15 x 1 + 4 x 4 + 16 x 1 = 47, so the additional usable capacity is 3.

However, if there is a user requesting 8 x SCH (76800bps), that is, offset = 8, the base station determines the channel status of the currently connected users. At this time, if the channel condition of the user using the 16 x SCH (153600bps) is determined to be poor, the user's transmission rate is reduced to 8 x SCH (76800bps), and the resulting 8 x SCH (76800bps) is reduced. Assign to users who require offset = 8.

At this time, if the channel condition or region of the user who requested 8 x SCH (76800bps) is not better than the channel condition or regional characteristic of the user who uses the 16 x SCH (153600bps), the 8 x SCH (76800bps) is used. It is also possible to assign a request rate of the requesting user to a lower rate.

Here, the channel state or regional characteristics may be known through a PSMM (Power Strength Measurement Message) transmitted by the terminal.

Third, assign and control in consideration of fairness.

That is, the channel situation, regional characteristics, and user's performance are all considered. Considering these values collectively, fairness can be defined as a method of guaranteeing minimum throughput to users with poor channel conditions and allocating higher rates to users with good channel conditions. Various methods are possible.

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.

As described above, the present invention may execute rate assign and rate control of a reverse auxiliary channel (R-SCH) on a communication system (for example, CDMA2000 1x) based on ROT. This is possible without additional channel or signaling assistance.

In addition, using this method has the same effect as measuring and using the ROT value without measuring the ROT directly.

Accordingly, efficient R-SCH data rate assign and control based on ROT can be performed without changing the current system, thereby improving stability while maintaining high performance.

Claims (6)

The offset value is set according to the data rate for the data transmitted on the reverse link, and the base station sets the total offset value of all channels acceptable to the reverse link to the total capacity, so that the base station determines the And determining a data rate allocation and control of an auxiliary channel according to the total offset value limit. The method of claim 1, wherein the total offset value of the entire channel is equal to the total load amount or the total interference amount of the data rate allocable by the base station. The method of claim 1, wherein when the total offset value limit is set, a request for a data rate greater than or equal to the offset value being allocated and controlled by the base station is performed. A method of allocating a maximum allowable data rate, a method of allocating a data rate according to the channel condition of the base station, a regional characteristic of the terminal, a channel characteristic of the base station and a regional characteristic of the terminal, and a performance of the terminal Data rate control method in a communication system, characterized in that the allocation and control using one of the methods. 4. The method of claim 3, wherein the channel state or region characteristics are determined by a power strength measurement message (PSMM) transmitted by the terminal. By configuring an indicator based on the thermal noise rise (ROT) according to the data rate to the data channel transmitted on the reverse link, assigning or controlling the data rate of the primary channel of the reverse link and the secondary channel of the reverse link using the indicator values. A data rate control method in a communication system characterized by the above-mentioned. 6. The data rate of claim 5, wherein the indicator allocates a low offset value for a channel having a low data rate and a high offset value for a channel having a high data rate. Control method.