KR100282803B1 - Cell Operation Method of Wireless Subscriber Network System - Google Patents

Abstract

The present invention adjusts the transmission gain of the forward link at the time of cell blasming and wilting, maintains the balance of the forward and reverse link coverage by continuing the bridging algorithm, and introduces the IIR filter concept when performing the bridging algorithm. The present invention relates to a cell operating method of a WLL system that can remove effects such as general fading, reverse power control, and voice activation rate.

The present invention provides a wireless subscriber network system in which a base station RF processor adjusts an output power of a subscriber access device, and introduces the concept of an IIR filter in measuring a magnitude of received power from an RF processor in a bridging algorithm, and a blooming and Wilting algorithm. In the previous step of measuring the power of the receive path, K _level Insert the process of determining the attenuation of the transmission path according to the value and performing the variable attenuation control of the transmission path to minimize the mutual influence on the independent power control while performing cell management quickly. It can be applied by changing only relevant software program in DCS or PCS system.

Description

Cell Operation Method of Wireless Subscriber Network System

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a WLL system. In particular, when performing cell blassoming and Wilting algorithms, attenuation of the transmission path is first determined and variable attenuation control of the transmission path is performed. Cells of the wireless subscriber network system to achieve the desired effect in a short time, and to mitigate the drastic change in the received power intensity of the measurement object by using the Infinite Impulse Response (IIR) filter when performing the britting algorithm. It is about how to operate.

In general, the WLL is a telephone system that wirelessly connects subscriber lines located about 2-6 km away from a base station without using a conventional telephone line.

This is expected to play an important role in the construction of information infrastructure in the future because it has the advantage that not only the network can be configured in a short period of time, but also easy to maintain than the conventional wired network configuration.

These WLLs are largely connected to a subscriber station terminal (RIU) for establishing a radio link with a subscriber, a base station (RP) for forming a radio link with a subscriber by being wired with a telephone station, and performs overall management functions for one base station. It consists of a base station controller (RPC).

Cell management in consideration of maximization and stability of conventional system capacity has been used in conventional commercial CDMA systems.

In general, cell management is an algorithm for changing cell coverage by adjusting a transmission output of a base station according to a load of a base station, and includes a blooming algorithm, a wilting algorithm, and a breathing algorithm.

The blooming algorithm is an algorithm for increasing the area of a cell controlled by one base station as needed, and the Wilting algorithm is an algorithm for reducing the area of a cell under the control of the base station, and the bridging algorithm is a reverse direction under the control of the base station. Algorithms for balancing the size of the link and the forward link are achieved by sending commands from the base station controller to the RF processor.

Since the cell management is performed every 5Hz, the desired effect can be obtained in a short time without affecting the simultaneous power control, and of course, the link coverage in the forward and reverse directions must be balanced.

In the IS-95 CDMA system, the most basic of cell management is the briefing equation

[Equation 1]

A _rx = K _level -K _{slopeP rx}

here, K _level Is a constant that determines the radius of the cell and is a constant that only changes when the blasming and Wilting algorithms are applied. K _slope Is a variable related to cell breeding, and the slope of the breeding equation, P _rx Is the magnitude of the reverse received power estimated by the RSSI (received Siginal Strength Indicator) value of the reverse link (variable used to measure the received power of the base station), the size of the cell seen on the reverse link can be estimated.

Also, A _rx Is the magnitude of the received power of the forward link finally determined by Equation 1, and determines the size of the cell seen in the forward link.

FIG. 1 illustrates a general WLL system, and includes a subscriber access device 100, a base station 200, a base station controller 300, and a switch 400.

The base station 200 is connected to the base station controller 300 by E1 and HDSL and outputs a call and control signal, and an interface unit 10 and a synchronization unit connected to the interface unit 10 and outputting a timing signal. And a digital processing unit 30 which receives a timing signal from the synchronization unit 20 and operates to report a state of a base station to a higher system by a control signal of the interface unit 10. An RF processor 40 which operates by a timing signal of the synchronization unit 20 and exchanges an interface signal with the digital processor 30 and controls RF, exchanges an RF signal with the RF processor 40 and the interface. It consists of a base station test unit 50 for exchanging control signals with the unit 10.

Figure 2 illustrates the flow of the conventional blasming and Wilting algorithm.

When the size of the cell needs to be adjusted in actual operation, such a blasming and Wilting algorithm is used. This method inserts noise into the reverse link to increase the power of the reverse link and then is forced by [Equation 1]. K _level It is a method of determining and adjusting the size of and applying a bridging algorithm as shown in FIG.

That is, referring to the operation of FIG. 2, when the base station controller 300 commands the RF processor 40 of the base station 200 to perform a blasming and Wilting algorithm, the RF processor 40 is configured. K _level The noise insertion amount of the reception path is determined according to the value (steps S10 and S11).

Next, variable attenuation control of the reception path is performed (step S12), and the power of the reception path is measured (step S13).

Then, by calculating the transmission path gain according to the britting equation as shown in [Equation 1] (step S14), the variable attenuation control of the transmission path is performed (step S15).

In the above, when the power measurement of the reception path is made K _level The gain value of the transmission path is determined according to the value (value given by the experimental data).

Next, it is determined whether the calculated transmission path gain is equal to the previous transmission path gain (step S16).

If the calculated transmission path gain is equal to the previous transmission path gain, go to step S13 to measure the power of the reception path again, and if the transmission path gain is different from the previous transmission path gain, the blasming and Wilting algorithm is finished (S17). step).

3 is a flowchart illustrating the operation of a conventional britting algorithm.

When the base station controller 300 instructs the RF processing unit 40 of the base station 200 to perform a breeding algorithm (step S1), the RF processing unit 40 measures the sum of the noise power and the signal power at the base station receiving end. In order to measure the magnitude of the received power (S2).

In addition, the transmission path gain for calculating the cell radius in the current forward link is calculated by the bridging equation (step S3).

In this case, it is determined whether the gain of the transmission path obtained is equal to the previous transmission path gain (step S4). If the gain of the transmission path is the same, the variable attenuation control of the transmission path is performed, and then the bridging algorithm is finished (steps S5 and S6).

However, as described above, in the conventional browsing and Wilting algorithm of FIG. 2 and the Britting algorithm of FIG. K _level It is a method of determining and adjusting the size and applying a bridging algorithm. Therefore, a large number of bridging algorithms need to be attempted to have an effect.

In other words, as shown in FIG. 2, since the variable attenuation control of the transmission path is first performed after the power of the reception path is measured, various complicated steps have been performed, and thus there is a problem that the desired effect cannot be obtained in a short time.

SUMMARY OF THE INVENTION The present invention has been made to solve such a conventional problem, and when performing cell blasming and Wilting algorithm, the attenuation amount of the transmission path is determined first, and then the variable attenuation control of the transmission path is performed to simplify the steps in a short time. It is to provide a cell operating method of a wireless subscriber network system to achieve the desired effect.

In addition, another object of the present invention is to provide a cell operating method of a wireless subscriber network system that can mitigate abrupt changes in the received power intensity of a measurement object by using an IIR filter. have.

1 is a general configuration diagram of a typical wireless subscriber network system

2 is a flowchart illustrating the operation of the conventional blooming and wilting algorithm.

3 is a flowchart illustrating the operation of the conventional britting algorithm.

4 is an operation flowchart of the blooming and Wilting algorithm of the present invention.

5 is a flowchart illustrating the operation of the briefing algorithm of the present invention.

<Explanation of symbols for main parts of drawing>

10: interface unit 20: synchronization unit

30: digital processing unit 40: RF processing unit

50: base station test section 100: subscriber connection device

200: base station 300: base station controller

400: exchanger

In order to achieve the above object, in the wireless subscriber network system in which the blasting and wilting algorithm of the present invention adjusts the output power of a subscriber access device in a base station RF processing unit, the RF processing unit instructs the RF processing unit to perform the blasming and wilting algorithm. Step, set K _level Determining the attenuation amount of the transmission path according to the value, performing variable attenuation control of the transmission path, measuring the power of the reception path, calculating the transmission path gain based on the bridging equation, and the transmission path gain being previously transmitted. Determining whether the gain is equal to the path gain, and measuring the power of the reception path if it is equal to the previous transmission path gain, and terminating the blasming and Wilting algorithm if it is different from the gain of the previous transmission path. .

In addition, in the wireless subscriber network system in which the base station RF processor adjusts the output power to the subscriber access device in the base station RF processing unit, when the RF processing unit instructs the RF processing unit to perform the bridging algorithm, the RF processing unit performs an IIR filter. By measuring the magnitude of the received power according to the concept, calculating the transmission path gain by the bridging equation, and determining whether the transmission path gain is equal to the previous transmission path gain if the same is equal to the variable attenuation of the transmission path. Perform adjustments and, if different, to complete the bridging algorithm.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Since the hardware configuration of the cell operating method of the wireless subscriber network system of the present invention is the same as that of the wireless subscriber network system of FIG. 1, description thereof will be omitted.

The present invention configured as described above will be described with reference to FIGS. 4 and 5, wherein FIGS. 4 and 5 illustrate an algorithm for adjusting the output power with respect to the subscriber access device 100 in the RF processor 40 of the base station of FIG. 1. It is shown.

That is, FIG. 5 is a briefing algorithm according to the present invention, which may be performed alone, or may be performed in parallel with the blooming and wilting algorithm of FIG. 4.

However, the blooming and Wilting algorithm of FIG. 4 must be performed in parallel with the Britting algorithm of FIG.

For example, in the state where the bridging algorithm of FIG. 5 is still being performed, the blasming and wilting algorithm of FIG. 4 is performed once per hour or once per day.

FIG. 4 is a new blooming and welting algorithm according to the present invention which is an improvement on the same blooming and wetting algorithm as in FIG.

First, the base station controller 300 instructs the RF processing unit 40 of the base station 200 to perform a blasming and Wilting algorithm (step S20).

And set K _level The attenuation amount of the transmission path is determined to calculate the cell radius to be adjusted in the forward link according to the value (step S21), and the variable attenuation control of the transmission path is performed (step S22).

Next, the power of the reception path is measured, and the transmission path gain based on the breathing equation is calculated to determine whether this transmission path gain is equal to the previous transmission path gain (S23-S25).

Here, measuring the power of the receive path and calculating the transmit path gain is for calculating the path gain for measuring the sum of the noise power and the signal power at the base station receiving end and thereby determining the cell radius in the forward link. .

If the current transmission path gain is the same as the previous transmission path gain, go to step S23 to determine whether the gain of the transmission path has been indirectly changed by the bridging equation, and to determine whether or not to terminate the blooming and Wilting algorithm. In order to measure the power of the reception path, if the transmission path gain is different from the gain of the previous transmission path, the blasting and Wilting algorithm is terminated (step S26).

That is, if the new forward transmission gain is set according to the cell coverage constant given above and the variable attenuator of the transmitter is adjusted, the noise level of the reverse link power is increased by the size of the forward link power set as described above. Equation 1 repeats this process until the backward and forward links are balanced while establishing a new forward transmission gain.

Figure 5 shows a briefing algorithm according to the present invention.

The briefing algorithm is an algorithm for checking cell size at each time to maintain a constant cell size. An algorithm for determining a gain of a transmission path by measuring a magnitude of a received power input from an RSSI.

That is, when the base station controller 300 instructs the RF processing unit 40 of the base station 200 to perform a breeding algorithm (step S30), the RF processing unit 40 makes noise at the base station receiving end by the concept of an IIR filter. In order to measure the sum of the power and the signal power, the magnitude of the received power is measured (step S31).

At this time, the IIR filter is as shown in Equation 2 below.

[Equation 2]

P _rx1 (n) = (1-k) P _rx (n) + _{kP rx} (n-1)

here, P _rx1 Received power after passing through the filter, n Is a time variable, P _rx Is the received power before passing through the filter, k Is any value that can be selected between 0 and 1 by field test data.

On the other hand, after performing the step S31, the transmission path gain is calculated to calculate the cell radius in the current forward link by the breathing equation (step S32).

In this case, it is determined whether the gain of the transmission path obtained is equal to the previous transmission path gain (step S33). If the gain of the transmission path is the same, the variable attenuation control of the transmission path is performed, and then the bridging algorithm is finished (steps S34 and S35).

Here, in step S33, determining whether the gain of the transmission path is the same as the previous transmission path gain is for determining whether to increase the size of the cell of the forward link according to the gain of the transmission path obtained by the bridging algorithm. will be.

In this case, when the calculated gain of the transmission path is equal to the gain of the previous transmission path, it is preferable that the transmission is in good condition so that the transmission power (powder) can be lowered to have the same performance (capacity) at the minimum power. In this step, the variable attenuation control of the transmission path is performed.

However, if the calculated gain of the transmission path is different from the gain of the previous transmission path, the transmission is unstable and attenuating the transmission power results in no communication, thus completing the bridging algorithm.

The present invention as described above has two effects.

First, when performing the blasming and Wilting algorithm, instead of first determining the power magnitude of the reception path as in the prior art, the attenuation amount of the transmission path is determined first, and then the variable attenuation control of the transmission path is performed to simplify the steps to achieve the desired effect in a short time. You can get it.

That is, the desired effect can be obtained in a short time without affecting the power control that is performed at the same time when cell management is performed every 5 Hz.

Second, when performing the bridging algorithm, it is possible to mitigate the rapid change in the received power strength of the measurement object using the IIR filter.

Claims (3)

In the wireless subscriber network system for adjusting the output power to the subscriber access unit in the RF processing unit of the base station, When the base station controller instructs the RF processor to perform a bridging algorithm, the RF processor measures the magnitude of the received power to measure the sum of the noise power and the signal power at the base station receiving end according to the concept of the IIR filter. Wow, A second step of calculating, by the RF processor, a transmission path gain for calculating a cell radius in a current forward link by a britting equation; The RF processor determines whether or not the transmission path gain is equal to the previous transmission path gain to determine whether to increase the size of the cell of the forward link by the gain of the transmission path by a breeding algorithm. A method of operating a cell of a wireless subscriber network system, characterized in that it performs a variable attenuation control to lower transmission power and, if different, to complete a bridging algorithm. The method of operating a cell of a wireless subscriber network system according to claim 1, wherein the IIR filter has the following equation. P _rx1 (n) = (1-k) P _rx (n) + _{kP rx} (n-1) In the wireless subscriber network system for adjusting the output power to the subscriber access unit in the base station RF processing unit, A first step of instructing the base station controller to perform a blasming and Wilting algorithm from the base station controller; The RF processor K _level A second step of performing a variable attenuation control of the transmission path by determining an attenuation amount of the transmission path to calculate a cell radius to be adjusted in the forward link according to the value; The RF processor measures the sum of the noise power and the signal power at the base station receiving end, and measures the power of the receiving path to calculate the path gain for determining the cell radius in the forward link. A third step of calculating If it is determined that the transmission path gain is equal to the previous transmission path gain, if it is the same, go to the third step to determine whether the gain of the transmission path has been indirectly changed by the bridging equation, and whether the blasming and Wilting algorithm is terminated. And measuring a power of a reception path to determine a fourth step of terminating the blazing and Wilting algorithm.