KR20030054344A - Dynamic allocation method of truncated power control decision parameter in wireless communication system - Google Patents

Abstract

PURPOSE: A method of variably assigning a selective power control decision parameter in a wireless communication system is provided to periodically collect load state information of a neighboring base station in a base station, and to change a transmission limit threshold value of a terminal, thereby variably assigning the threshold value according to channel environment and load. CONSTITUTION: While a base station is in idle state(501), if a reset cycle timer for a transmission limit threshold value is completed(506), the base station obtains load state information of a neighboring cell and distance information between a terminal and a neighboring base station(502). The base station calculates interferences for the neighboring cell(503). If an optimal transmission limit threshold value is determined(504), the determined threshold value is transmitted to the terminal(505). If the terminal is in speech state(507), the terminal receives the transmission limit threshold value(508), and obtains a wireless channel estimate value(509). The terminal compares the estimate value with the limit threshold value(510). If the estimate value is bigger, the terminal determines transmission power, and transmits data(511).

Description

Dynamic allocation method of truncated power control decision parameter in wireless communication system

The present invention relates to a variable allocation method of selective power control decision parameters in a wireless communication system. In particular, the terminal does not limit transmission to only a predetermined threshold value, and the load state of the neighboring cell and the cell being serviced and the terminal and each cell. The present invention relates to a variable allocation method of a selective power control decision parameter for variably allocating a threshold value for determining transmission interruption in consideration of distance information.

In the code division multiple access (CDMA) mobile communication system, power control is an essential technique to guarantee the performance of the system. CDMA mobile communication has the characteristic of using the same frequency band by multiple users at the same time. For this reason, it is important to minimize the amount of power used by one subscriber while ensuring the call of required quality.

As such, minimizing the transmission amount of one subscriber can increase capacity because the amount of interference affecting the other subscriber is relatively small. In order to minimize this, power control is performed in a CDMA system.

In particular, since the connected terminal has the characteristic of moving randomly, the reverse power control for controlling it becomes more important for the system. Reverse power control is to keep the power transmitted from the terminal to the minimum amount that can be received by the base station, because it can increase the capacity of the system by minimizing the amount of interference to other users when transmitting at the minimum amount.

When the terminal moves in the mobile communication system, the propagation path is changed according to the distance between the base station and the terminal, obstacles, etc., and the wireless channel is changed by various factors including this path. The environment changes dynamically. In particular, when passing through a shaded area that is hidden in a building, the channel falls into deep fading. In this case, according to the conventional power control method, since the power received from the terminal becomes smaller and the reception characteristics thereof become worse, the terminal transmits a signal with high power to solve the "near-far" problem. This will act as a large interference signal, which adversely affects the call quality and capacity. In particular, when the terminal is located in the boundary area of the cell, it affects the neighboring base station more seriously. To solve this drawback, if the characteristics of the radio channel, i.e., the signal strength received from the terminal, is below a certain threshold, the transmission is temporarily limited to reduce interference to neighboring cells, and when data is recovered above the threshold, the data is transmitted by increasing the transmission speed. This method has a problem in that the data transmission efficiency is lowered overall since the transmission is stopped during deep fading and the power is transmitted later.

Therefore, in the present technical field, in order to reduce such a decrease in transmission efficiency, the terminal does not merely limit transmission to a predetermined threshold value, but transmits in consideration of the load status of the neighboring cell and the cell being serviced and the location information of the terminal. There is a need for a method for variably allocating a threshold for determining interruption. That is, in order to consider the load of the neighboring cell, if the terminal falls into deep fading due to a shadow area or the like, it acquires load information of the neighboring cell. This is because the terminal is able to increase data transmission efficiency by transmitting data at high power because the capacity is not affected.

The present invention has been proposed to solve the above problems, and the base station periodically collects the load status of the adjacent base station and the location information of the terminal to change the transmission limit threshold of the terminal, thereby limiting the transmission limitation of the terminal It is an object of the present invention to provide a variable allocation method of a selective power control decision parameter so that a value is variably assigned according to a load of a channel environment and an adjacent cell.

1 is an exemplary configuration diagram of a CDMA mobile communication system to which the present invention is applied.

2 is an exemplary diagram of a paging channel applied to FIG. 1.

3 is a diagram illustrating an arrangement relationship between a base station and a terminal applied to FIG. 1.

4 is another exemplary diagram illustrating an arrangement relationship between a base station and a terminal applied to FIG. 1.

5 is a flowchart illustrating a variable allocation method of a selective power control determination parameter in a wireless communication system according to the present invention.

* Explanation of symbols for the main parts of the drawings

101, 104: modulator / demodulator 102, 103: RF transmitter / receiver

The present invention for achieving the above object, in the variable allocation method of the selective power control decision parameters in a wireless communication system, the base station load status information (L (i)) of the neighbor cells and the location information (d (i) of the terminal) Collecting the first step; A second step of estimating an interference amount by using the collected load state information of neighboring cells and location information of a terminal; Determining a transmission limit threshold TX_Limit_Threshold based on the predicted interference amount; And a fourth step of transmitting the determined transmission limit threshold to the terminal through forward signaling. In addition, the present invention obtains a radio channel estimate value so that a terminal receiving the transmission limit threshold value from the base station determines the strength of reverse transmission power, compares the transmission limit threshold value with the radio channel estimate value, and according to the result. And a fifth step of variably allocating the transmission limit threshold value.

In addition, the present invention, in the variable allocation method of the selective power control determination parameter in a wireless communication system, the base station collects the load state information (L (i)) and the location information (d (i)) of the terminal of the neighbor cells; First step; A second step of estimating an interference amount by using the collected load state information of neighboring cells and location information of a terminal; Determining a transmission limit threshold TX_Limit_Threshold based on the predicted interference amount; A fourth step of transmitting the determined transmission limit threshold to a terminal through forward signaling; And obtaining a radio channel estimate value to compare the transmission limit threshold value with the radio channel estimate value so that the terminal, which has received the transmission limit threshold value from the base station, can determine the strength of reverse transmission power. And a fifth step of variably allocating.

In the present invention, when the terminal is in deep fading due to shading or the like at the boundary region of the cell, the influence of the interference in the adjacent cell due to the interference generated by the terminal transmitting a signal with high power is considered.

That is, if there is not a heavy load by the user in the neighboring cell, even if some interference comes in, the signal-to-noise ratio of the serviced system may not reach the threshold. In this case, when the terminal is in deep fading, the output of a large transmission power to compensate for this will not cause a problem in the performance of the entire system. In this case, the threshold value for limiting the output of the terminal is lowered so that the terminal can transmit at high power.

On the contrary, when the signal-to-noise ratio is expected to drop below the threshold due to the heavy load of the neighboring base station, the terminal transmits with the lowest power possible by increasing the threshold limiting the output of the terminal.

Accordingly, the present invention proposes a method of increasing data transmission efficiency by calculating loads of adjacent cells and talking cells when the terminal is in deep fading due to the effect of the terminal covering a building, an obstacle, etc., and transmitting them at high power when the load is small. do.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is an exemplary configuration diagram of a CDMA mobile communication system to which the present invention is applied, and a configuration diagram from the viewpoint of power control in a CDMA mobile communication system may be represented as shown in FIG. 1. Particularly, in the case of reverse closed loop power control, a signal coming in the reverse direction through the RF transmitter / receiver 103 of the base station is transmitted to the modulator / demodulator 104, and the modulator / demodulator 104 enters the terminal in the reverse direction. The quality of the signal is measured to determine the parameters for closed-loop power control. The determined parameters are transmitted to the terminal through the base station RF transmitter / receiver 103.

Meanwhile, the terminal receives the signal transmitted from the base station through the terminal RF transmitter / receiver 102 and transmits the signal to the terminal modulator / demodulator 101. The terminal modulator / demodulator 101 extracts the closed loop power control parameter and transmits the closed loop power control parameter to the terminal RF transmitter / receiver 102 to adjust the output power of the terminal.

The technique proposed in the present invention is performed in the base station modulator / demodulator 104 and the base station RF transmitter / receiver 103.

The power control algorithm proposed and performed in the conventional system is a base station in the terminal when the terminal M falls into deep fading as shown in FIG. 2 due to a shadowed area when the terminal M is in the cell boundary region as shown in FIGS. 3 and 4. The signal received from the device is measured small and the path loss is high, so that the terminal transmits the signal with high power. At this time, the terminal is located at the boundary of the cell, so that the neighboring cells (B1 to B6) have a large interference. Works.

In order to solve this drawback, when the radio channel estimate falls into a deep fading below a certain threshold, a method of limiting transmission of the terminal is used. In this case, however, if the channel environment falls into deep fading regardless of the load of the adjacent cells, data transmission is unconditionally restricted, and the channel is recovered at a normal state, and the data rate is increased. Falling problem will occur.

In order to solve the above problems, the present invention collects load (L1 to L6) information of adjacent cells and distances (d1 to d6) between neighboring cells and a terminal, and thus the amount of interference of the corresponding terminal affects the neighboring cell. Considering the impact, if the impact is small, the data can be transmitted at high power to increase the data transmission efficiency. Of course, if the load of the neighbor cell is high, and the corresponding terminal has a relatively large impact when transmitting at a high power, the existing transmission method is used. When considering the load of neighboring cells, distance information between each base station and the terminal is used. If the distance between the base station and the base station is far, the attenuation of the radio signal is large, so that the weight of the base station is small and the close base station is large. Gives. That is, the weight is proportional to the inverse of the distance (see FIG. 4).

Now, the operation of the variable allocation method of the selective power control determination parameter in the wireless communication system according to the embodiment of the present invention having the above structure will be described in detail as follows.

5 is a flowchart illustrating a variable allocation method of a selective power control determination parameter in a wireless communication system according to the present invention.

As shown in FIG. 5, when the base station completes the transmission limit threshold reset period timer in the idle state 501 (506), the base station establishes a connection between the load state information L (i) of the adjacent cell and the terminal and the adjacent base station. The distance information d (i) is obtained (502).

Subsequently, the amount of interference for each neighboring cell is calculated and obtained using the load information L (i) of the neighboring base station and the distance information d (i) between the terminal and the neighboring base station (503).

Then, if the optimal transmission limit threshold TX_Limit_Threshold is determined according to the determined interference amount (504), the determined transmission limit threshold value is transmitted to the terminal through forward signaling (505).

Subsequently, the base station checks whether the transmission limit threshold reset period timer is completed (506), repeats the process (506) if it is not completed, and proceeds to the process (502) of acquiring load state information of the neighboring cell. .

Meanwhile, when the terminal enters the call state 507, power control is performed.

That is, the terminal receives a transmission limit threshold received from the base station (508) and obtains a radio channel estimate (509) for the purpose of determining the strength of the reverse transmission power.

Subsequently, the wireless channel estimate is compared with the transmission limit threshold to determine whether the terminal is in deep fading (510).

As a result of the comparison (510), if the radio channel estimate is larger than the transmission limit threshold, the terminal determines the transmission power according to the radio channel estimate and transmits data (511), and then receives the transmission limit threshold from the base station (508). If the radio channel estimate is less than the transmission threshold, the terminal stops transmitting data (512) and continuously receives the transmission transmission threshold received from the base station (508). Reset it.

That is, in the present invention, since a network is formed between each base station, it is possible to exchange information about each base station, so that the load information of neighboring base stations can be known. If the load is calculated and the load is small, communication can be performed without a large effect even if the signal is transmitted with a high signal, thereby improving data transmission quality by transmitting data at high power.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the art without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

As described above, according to the present invention, when the terminal falls into deep fading due to a shadow or the like at the boundary area of the cell, the load state of adjacent cells may be reduced. In consideration of the instantaneous adjustment of the threshold limiting the transmission of the terminal, it is possible to increase the overall system transmission efficiency.

Claims (4)

In the variable allocation method of the selective power control decision parameters in a wireless communication system, A first step of the base station collecting load state information L (i) of neighbor cells and location information d (i) of the terminal; A second step of estimating an interference amount by using the collected load state information of neighboring cells and location information of a terminal; Determining a transmission limit threshold TX_Limit_Threshold based on the predicted interference amount; And A fourth step of transmitting the determined transmission limit threshold to a terminal through forward signaling; Variable allocation method of the selective power control decision parameters in a wireless communication system comprising a. The method of claim 1, Obtain a radio channel estimate value and compare the transmission limit threshold value with the radio channel estimate value so that the terminal, which has received the transmission limit threshold value from the base station, can determine the strength of reverse transmission power, and vary the transmission limit threshold value accordingly. 5th step to assign Variable allocation method of the selective power control determination parameters in a wireless communication system further comprising. The method of claim 2, The fifth step, Receiving a transmission limit threshold value through the base station to obtain a radio channel estimate value; A seventh step of comparing a radio channel estimate and a transmission limit threshold to determine whether the terminal is in deep fading; And As a result of the comparison in the seventh step, if the radio channel estimate is greater than the transmission threshold, the terminal determines the transmission power according to the radio channel estimate and transmits the data. If the radio channel estimate is less than the transmission threshold, the terminal is determined. An eighth step of interrupting data transmission and continuously resetting a transmission limit threshold received from the base station through Variable allocation method of the selective power control decision parameters in a wireless communication system comprising a. In the variable allocation method of the selective power control decision parameters in a wireless communication system, A first step of the base station collecting load state information L (i) of neighbor cells and location information d (i) of the terminal; A second step of estimating an interference amount by using the collected load state information of neighboring cells and location information of a terminal; Determining a transmission limit threshold TX_Limit_Threshold based on the predicted interference amount; A fourth step of transmitting the determined transmission limit threshold to a terminal through forward signaling; And Obtain a radio channel estimate value and compare the transmission limit threshold value with the radio channel estimate value so that the terminal, which has received the transmission limit threshold value from the base station, can determine the strength of reverse transmission power, and vary the transmission limit threshold value accordingly. 5th step to assign Variable allocation method of the selective power control decision parameters in a wireless communication system comprising a.