KR20050070375A - Method of controlling reverse link data rate in mobile station of mobile communication system - Google Patents

Abstract

The present invention enables the terminal to more efficiently determine the new transmission rate, optimize the reverse rate, and more appropriate control of the ROT based on the RAB transmitted to adjust the reverse data rate in a mobile communication environment. A reverse data rate control method in a terminal of a mobile communication system for increasing the total capacity that can be accommodated in the mobile communication system. The reverse data rate control method according to the present invention is a method for controlling a reverse data rate in a terminal based on a reverse data rate control command received from a base station, the method comprising: receiving the RAB received in the last slot of a frame consisting of a plurality of slots; Firstly determining a data rate of the next frame as a reference; And finally determining the data rate of the next frame based on the RAB values received in the slots before the last slot and controlling the reverse data rate accordingly.

Description

Method of controlling reverse link data rate in mobile station of mobile communication system

The present invention relates to a reverse data rate control method. More specifically, a new method of reverse transmission speed is more efficient at a terminal based on a reverse activity rate control command (hereinafter referred to as a 'RAB') transmitted to adjust a reverse data rate in a mobile communication environment. The present invention relates to a method of controlling a reverse data rate in a terminal of a mobile communication system for increasing the total capacity that can be accommodated in the mobile communication system by optimizing a reverse rate and optimizing a reverse transmission speed.

In a mobile communication environment, the reverse link is only able to communicate until the total sum of signals received from the terminal to the base station does not exceed a certain standard. That is, the more users a base station accommodates, the higher the data rate being transmitted, the greater the total number of signals received by the base station, which continues and is no longer acceptable at any moment. Will lead to

In this case, ROT (Rise over Thermal noise) is used as one indicator representing the total sum of the signals received by the base station. ROT is an indicator of how much of the total signal currently received is received against thermal noise. If the ROT value exceeds the baseline set by the base station, the call of the terminals accommodated by the base station is rapidly degraded or even no longer possible.

The base station keeps checking the ROT value. If the ROT value is close to the reference value, the base station attempts to lower the sum of the received signals. For example, if there is a user who wants to enter a new entry, the entry is not allowed, and a user who transmits data at a high data rate may transmit at a low data rate to reduce the size of a received signal. Through this process it is possible to lower the overall ROT received by the base station.

Conversely, if the ROT is at a lower level than the baseline, the base station either accepts more users or commands the transmitting user to transmit at a higher rate. This operation can raise the ROT value.

This series of operations allows the base station to use the maximum capacity that the base station can accommodate as long as it does not degrade the communication quality.

The information that the base station measures and transmits the ROT is usually called a reverse activity bit (RAB). RAB can be divided into two types ('round', 'down') or three ('round', 'maintain', 'down'). In two cases, when the ROT is near the baseline, it sends '-1', which means 'down', and when it has more margin than the baseline, it sends '1' which means 'rounded up'. In three cases, '0' which means 'maintenance' is added to '-1' and '1'.

When the base station measures the ROT and informs the measurement results of the terminals, the terminals generally operate as follows.

The terminals receive the RAB to determine the data rate to send next. If the RAB is received at '-1' (down), the terminals go through a series of steps of transmitting the data rate to be transmitted in the next frame at a data rate one step lower than the data rate being transmitted in the current frame. On the other hand, when received at '1' (rounded up), the terminal goes through a step of transmitting data at a higher data rate.

In general, two methods are commonly used to transmit RAB by measuring ROT. First, there is a frame-by-frame method of measuring the ROT for one frame and transmitting the RAB over the next one frame length. Secondly, there is a slot unit method of measuring every slot and transmitting the next one slot. Both methods have advantages and disadvantages, but use slot-by-slot for faster and more accurate rate changes. That is, when the base station transmits a RAB through the ROT measured in slot units, the terminal determines the data rate to be transmitted in the next frame through the RABs received during the frame.

An example in which an RAB is updated and transmitted on a slot basis will be described with reference to FIG. 1. 1 is a diagram in which one frame consists of four slots. ROT is measured in every slot and the result is transmitted through RAB. The terminal processes the RABs received in the n th frame to determine the data rate to transmit in the n + 1 th frame. Methods of processing RAB include a method of simply averaging the RAB and processing using a first-order filter. The above processing determines the increase, maintenance, and decrease of the data rate of the n + 1th frame.

Referring to Figure 2, the n-th frame is being transmitted at this time, the RAB received in each slot was received as -1, -1, -1, +1, respectively. In the state of receiving up to RAB of the last slot of the n th frame, the terminal determines the data rate of the n + 1 th frame. The terminal processes the received RABs and decides whether to raise or lower the data.

As above, when the -th, -1, -1, +1 is received in the nth frame, the simple average or the first-order filter calculation is performed as in the conventional method. -1-1 + 1) / 4 = -0.5, and the data rate of the next frame is reduced. This results in a similar result even if the calculation is done through a first order filter.

However, in the above case, a problem occurs that the last received RAB value +1 is not affected. In other words, although the most recently received RAB is a variable reflecting the most accurate current state, it is not properly reflected because of previous values. If the values such as +1, +1, +1, +1 are consecutively received in the n + 1 th frame as shown in FIG. 2, this results in a further misunderstanding of the current ROT situation. In the situation where the base station wants to increase the data rate, the terminal actually has a problem of lowering the transmission rate.

The present invention has been made to solve the problems of the prior art as described above, the object of the present invention is to weight the most recently received RAB to reflect the most recent situation as possible to determine the reverse transmission rate more efficiently The present invention provides a reverse data rate control method in a terminal of a mobile communication system that can increase the total capacity that a mobile communication system can accommodate by optimizing a reverse transmission speed and enabling more appropriate control of the ROT.

Summary of the Invention

In the present invention, instead of the conventional method in which the most recently received RAB value does not affect, the reverse data rate control method reflecting the most recent situation by weighting the most recently received RAB is proposed.

The present invention is based on the fact that the most recently received RAB value among the RAB values received in one frame most accurately reflects the current state of the reverse direction. Based on the data rate control to apply the most recently received RAB command to the next frame, the previously received RABs are used to determine the degree of retention, increase or decrease.

In the reverse data rate control method according to the present invention, a method for controlling the reverse data rate in the terminal based on a reverse data rate control command (hereinafter referred to as "RAB") received from a base station, Firstly determining a data rate of the next frame based on the RAB received in the last slot of the frame consisting of slots of the first slots; And finally determining the data rate of the next frame based on the RAB values received in the slots before the last slot and controlling the reverse data rate accordingly.

Specifically, if the RAB received in the last slot means to increase the data rate, the first decision is made to increase or maintain the data rate of the next frame, and the tendency of the RAB values received in the slots before the last slot. The final data rate of the next frame is determined accordingly. In addition, if the RAB received in the last slot means to lower the data rate, the first decision is made to lower or maintain the data rate of the next frame, and according to the tendency of the RAB values received in the slots before the last slot. The data rate of the next frame is finally determined.

When the trend of the RAB values received in the slots before the last slot coincides with the RAB received in the last slot, the data rate of the next frame may be increased or decreased by two or more steps.

The trend of the RAB values received in the slots before the last slot may be determined based on the sum of the values of the RABs, an average value, or a ratio thereof.

Example 1

Embodiment 1 is an example of a case in which a terminal receives two types of RABs, RAB (+1) indicating to raise a data rate and RAB (-1) indicating to lower.

Basically, the data rate of the next frame is tentatively determined using the command of the RAB received in the last slot of one frame. However, the RAB commands received in the previous slot of the frame are compared with the RAB received in the last slot to finally determine the maintenance, increase or decrease.

In other words, if the last received RAB is 'raised', the data rate in the next frame will increase or at least maintain the data rate of the previous frame; conversely, if the last received RAB is 'down', the data rate in the next frame will be Reduced or at least maintained.

Previously received RABs actually serve to assist the last received RAB. In other words, if the tendency of the last received RAB and the previously received RAB values coincide with each other, the last received RAB is followed. It would also be possible to adjust the data rate more than two steps that the RAB received in the last slot 'perfectly matches' the tendency of the RABs received in the previous slots.

This will be described in more detail with reference to FIG. 2. As shown in FIG. 2, '-1', which means 'down', is received in the first, second, and third slots of the n-th frame. On the other hand, the fourth last slot received '+1' which means 'round'. In this case, since the data rate of the n + 1 th frame basically follows the RAB command of the fourth slot of the n th frame, the n + 1 th frame is tentatively determined to be raised or maintained at least compared to the data rate of the n th frame. . Whether to raise or maintain the data rate of the n + 1 th frame is finally determined by identifying the tendency of the RABs received in the previous slot. In FIG. 2, '-1', which means 'down', is received in the first, second, and third slots of the nth frame. That is, the trend does not match the RAB received in the last slot. Therefore, the data rate of the n + 1th frame is finally determined to be maintained at the data rate of the nth frame.

Referring to FIG. 2, a data rate control process of an n + 2 th frame is as follows. In this case, the RABs received in the 1st, 2nd, 3rd, and 4th slots of the n + 1th frame are all '+1', which means 'up'. In other words, the RAB received in the last 4th slot is 'perfect match' with the tendency of the values of the RAB received in the previous slot. In this case, since the base station can determine that the ROT is formed significantly lower than the reference value, the terminal can increase the data rate in several stages instead of one stage if there is a lot of power and data to transmit.

Whether the RAB received in the last slot and the RAB received in the previous slot is 'exactly matched', 'matched' or 'mismatched' is determined based on the sum, average, or ratio of the RABs received in the previous slot. Can be.

As an example, a method of determining a tendency of 'exact match', 'match', and 'inconsistency' based on an average value of received RABs of previous slots except the last slot will be described. As shown in Table 2, the trend can be shown in the case where one frame consists of four slots as shown in FIG.

Average of previous slots RAB of the last slot +1 -One +1 Exact match Inconsistency +1/3 Same Inconsistency -1/3 Inconsistency Same -One Inconsistency Exact match

In this case, if the last slot was' +1 ', the previous slot average is' +1', 'match' is' +1/3 ',' mismatch 'is' -1/3' or '-1 ', The last slot is' -1', 'exact match' is' -1 ',' match 'is' -1/3', 'mismatch' is' +1/3 'or Can be determined to be '+1'.

The method of determining the tendency of RABs received in the slot before the last slot is just one example, and the range of 'exact match', 'match', and 'inconsistency' varies depending on the number of slots in the frame and the characteristics of the system. It will be apparent to those skilled in the art that can be adjusted.

In addition, instead of the above average value, the received RAB sum or ratio may be used to grasp the tendency of the RABs received in the slot before the last slot. That is, the RABs received in the slots before the last slot may be summed to determine whether to 'exactly match', 'match' and 'inconsistency' according to the value, and also to determine '+1' and '-1'. It will be possible to determine whether exact matches, 'matches' and 'unmatches' are made according to the ratio.

On the other hand, the present invention is not limited to the case that one frame is 4 slots as in the first embodiment. The RAB reception interval received to change the data rate may be changed according to the system, channel condition, and channel structure. In addition, the range of recently received and previously received RABs can also be optimized according to the system, channel situation, and channel structure.

Example 2

Embodiment 2 relates to a case in which the terminal receives three types of RABs, RAB (+1) indicating to raise the data rate, RAB (0) indicating to keep and RAB (-1) indicating to lower, from the base station. Example.

When the RAB received by the terminal in the last slot of the nth frame is '+1' meaning 'up' or '-1' means 'down', the method of determining the data rate of the n + 1th frame The same as in the first embodiment described above.

If the terminal indicates that the RAB received in the last slot of the nth frame maintains the data rate, the terminal receives the data rate of the n + 1th frame according to the tendency of the RABs received in the slots before the last slot of the nth frame. It is determined whether to increase, maintain or decrease. The trend of the RABs received in the slots before the last slot may be identified as 'increase', 'decrease', 'maintain', etc. based on the sum, average value, or ratio of the RABs received in the previous slot, and n + It is finally determined whether to increase, decrease or maintain the data rate of the first frame.

It is apparent to those skilled in the art that the present invention can be embodied in other specific forms without departing from the spirit and essential features of the present invention. Accordingly, the above detailed description should not be construed as limiting in all aspects and should be considered as illustrative. The scope of the invention should be determined by reasonable interpretation of the appended claims, and all changes within the equivalent scope of the invention are included in the scope of the invention.

The reverse data rate control method according to the present invention is a new method for determining the reverse data rate in a terminal using a RAB transmitted to adjust the reverse data rate in a mobile communication environment. It is possible to increase the total capacity that the mobile communication system can accommodate by optimizing the transmission speed in the reverse direction and enabling more appropriate control of the ROT.

FIG. 1 is a diagram for explaining an example in which an RAB is updated and transmitted on a slot basis.

2 is a view for explaining an embodiment according to the prior art and the present invention.

Claims (15)

In the method for controlling the reverse data rate in the terminal based on a reverse activity rate control command (hereinafter referred to as "RAB") received from the base station, Firstly determining a data rate of a next frame based on the RAB received in the last slot of the frame consisting of a plurality of slots; And And finally determining the data rate of the next frame based on the RAB values received in the slots before the last slot and controlling the reverse data rate accordingly. The method of claim 1, wherein when the terminal receives two types of RABs, a RAB for increasing data rate and a RAB for lowering data rate from the base station, If the RAB received in the last slot means to increase the data rate, the first decision is made to increase or maintain the data rate of the next frame, And finally determining a data rate of the next frame according to a tendency of RABs received in the slots before the last slot. The method of claim 1, wherein when the terminal receives two types of RABs, a RAB for increasing data rate and a RAB for lowering data rate from the base station, If the RAB received in the last slot means to lower the data rate, the first decision is made to lower or maintain the data rate of the next frame. And finally determining a data rate of the next frame according to a tendency of RAB values received in the slots before the last slot. The method of claim 2, If the trend of the RAB values received in the previous slots of the last slot is "perfect match" with the RAB received in the last slot, the data rate of the next frame is increased more than two steps . The method of claim 3, If the trend of the RAB values received in the slots before the last slot is "perfect match" with the RAB received in the last slot, the data rate of the next frame is lowered by two or more steps . The method according to any one of claims 2 to 5, And the tendency of the values of the RABs received in the slots before the last slot is determined based on the sum or average of the values of the RABs. The method according to any one of claims 2 to 5, And the tendency of the RABs value received in the slots before the last slot is determined based on the ratio of the RABs value. The method of claim 1, wherein when the terminal receives three types of RABs from the base station: RAB for increasing data rate, RAB for maintaining data rate, and RAB for lowering rate, If the RAB received in the last slot means to increase the data rate, the first decision is made to increase or maintain the data rate of the next frame, And finally determining a data rate of the next frame according to a tendency of RABs received in the slots before the last slot. The method of claim 1, wherein when the terminal receives three types of RABs from the base station: RAB for increasing data rate, RAB for maintaining data rate, and RAB for lowering rate, If the RAB received in the last slot means to lower the data rate, the first decision is made to lower or maintain the data rate of the next frame. And finally determining a data rate of the next frame according to a tendency of RAB values received in the slots before the last slot. The method of claim 1, wherein when the terminal receives three types of RABs from the base station: RAB for increasing data rate, RAB for maintaining data rate, and RAB for lowering rate, If the RAB received in the last slot is meant to maintain a data rate, determining the data rate of the next frame according to a tendency of the RABs received in the slots before the last slot. . The method of claim 8, If the trend of the RAB values received in the previous slots of the last slot is "perfect match" with the RAB received in the last slot, the data rate of the next frame is increased more than two steps . The method of claim 9, If the trend of the RAB values received in the slots before the last slot is "perfect match" with the RAB received in the last slot, the data rate of the next frame is lowered by two or more steps . The method according to claim 8, 9, 11 or 12, And the tendency of the values of the RABs received in the slots before the last slot is determined by the sum or average of the values of the RABs. Receiving, by the terminal, a data frame including a reverse data rate control command for each slot from the base station at a transmission time corresponding to the N-th data frame; And determining a data rate of the N + 1th data frame according to a reverse data rate control command included in the last slot of the data frame. The method of claim 14, And determining the data rate of the N + 1 th data frame by further considering reverse data rate commands included in last previous slots.