KR100293945B1 - Method for obtaining optimal parameter and verifying reverse power control function - Google Patents

Abstract

A method of verifying a reverse power control algorithm and deriving optimal parameters in a CDMA cellular system is disclosed. In this method, the BTS or BSC system 20 connects the DCP equipment 22 to the HINA port and the DM tool 26 to the mobile station 24 for verification of the reverse power control algorithm and derivation of the parameters. Connect to 232C and collect data. The collected data as described above is analyzed using SCAT97 (28) (30). By using the results obtained by repeatedly performing the above tests, the verification of the reverse power control algorithm and the optimal parameters are derived.

Description

Verification of reverse power control function and derivation of optimal parameter {METHOD FOR OBTAINING OPTIMAL PARAMETER AND VERIFYING REVERSE POWER CONTROL FUNCTION}

The present invention relates to a method for verifying and analyzing a reverse power control algorithm of a code division multiple access cellular system using a data collection and analysis apparatus.

Looking at the prior art as follows. 1 is a diagram illustrating a power control verification and analysis method according to the prior art. As shown in FIG. 1, in order to verify a reverse power control algorithm, a terminal 12 is connected to a corresponding debug port (RS-232C) 16 of various equipment and systems 10 to reverse a frame error. (Reverse Frame Error) and the power control threshold (Power Control Threshold) determined by the system (BSC: Base Station Controller) is output to the terminal 12 to verify the power control function.

In the prior art as described above, a monitor is connected to a debugger of a tester system to derive a reverse frame error rate (FER) and an Eb / No of a measurement device.

However, when the above method is used to verify the reverse power control algorithm, there is a problem in that the reliability of the test is poor.

The present invention was devised to solve the problems of the prior art as described above, and provides a method for solving the following problems, so that a method for debugging analysis in a field and a system is more easily collected and a tool for analysis. The purpose is to verify power control function and verify and derive the optimal parameters more easily and accurately.

The problem solving method is as follows. First, a power control bit (PCB) transmitted to a forward link is collected.

Secondly, it collects the power control threshold (PCT) sent from the upper system (BSC) to the lower system (BTS).

Third, collect Eb / No and FER of the reverse link.

Fourth, the reverse link-related Tx Gain Adjust and Tx power are collected by the mobile station Mobile Mediation Device (DM).

Fifth, the collected data is verified by using SCAT97 (CDMA Analysis Tool) and the power control algorithm of the reverse link is derived.

Other objects and advantages of the present invention will become more apparent from the following detailed description of the invention and the accompanying drawings.

1 is a diagram illustrating a power control verification and analysis method according to the prior art.

2 is a diagram illustrating a power control verification method according to the present invention.

3 is a result analysis embodiment for the verification of the reverse power control algorithm according to the present invention.

4 is a diagram illustrating a method for deriving power control optimal parameters in accordance with the present invention.

<Explanation of symbols for the main parts of the drawings>

10: base station transceiver system 26,36: MDM

12: monitor terminal 28, 38: SCAT97

14,24: Mobile station 30: Power control result display

16: RS-232C debug port 32: Field test according to parameter change

20: base station or control station 40: PCT algorithm analysis compared to FER

22,34: Data Acquisition Platform

42: Reverse Power Control Algorithm and Optimal Parameter Derivation

In order to achieve the above object, according to an embodiment of the present invention, a method for verifying a reverse power control algorithm in a CDMA cellular system,

Collecting data by connecting a data collection platform (DCP) device for data collection to a BTS or BCS system;

The mobile station connecting with the DM tool to collect data;

Analyzing the collected data by SCAT97; And

Performing a reverse power control algorithm verification using the analysis result.

In the present invention, when connecting the DCP to the BTS or BSC, it is preferable to connect to the high speed IPC Node board Assembly (HINA) port of the BTS or BSC,

The data collected by the BTS or BSC is preferably a power control threshold, a power control bit, reverse Eb / No, and reverse FER.

Preferably, the mobile station and the DM tool are connected by RS-232C.

Preferably, the mobile station is connected at a full rate by applying a service option in a BSM.

The service option is preferably 2 or 9,

Preferably, the data collected by the mobile station is Tx gain control and Rx power and Tx power.

The reverse power control algorithm is preferably verified by the rate of change of the PCT relative to the reverse FER,

The change rate of the PCT relative to the reverse FER is preferably a distribution analysis and ratio analysis result of the collected data.

In accordance with another aspect of the present invention, a method of deriving an optimal parameter related to a reverse power control threshold in a CDMA cellular system is provided.

Collecting data by the BTS or BCS system connected to the DCP equipment for data collection;

The mobile station connecting with the DM tool to collect data;

Analyzing the collected data by SCAT97;

Deriving a reverse power control parameter using the analysis result.

In the present invention, the parameter derivation is preferably made by deriving a PCT relative to the FER distribution,

The PCT relative to the FER distribution is preferably derived by comparing and analyzing the results of testing and measurement with the minimum and maximum PCT coverage.

Hereinafter, a detailed operation principle of the present invention will be described with reference to the drawings. 2 is a diagram illustrating a power control verification method according to the present invention. As shown in FIG. 2, a DCP device 22 for collecting is connected to a HINA port of a BTS or BSC 20 system to collect data. The mobile station 24 also connects the DM tool 26 to RS-232C to collect data. The data collected as above is analyzed by the SCAT97 28. The algorithm and the optimal parameters are derived 30 with the repeated test results of the above test.

The reverse link power control algorithm derives a power control related parameter, i.e., an up / down period value of a threshold value, from the BSC and verifies whether the actually measured value is changed up / down value according to the reverse FER. .

In addition, when deriving the parameter, the relevant power control threshold range is applied to the maximum and minimum values that can be applied in the system, and then the mobile station Tx of the Nominal / Max / Min distribution of the FER power control threshold after the test is applied. After comparing the gain control distribution, apply the repeatedly derived parameters and derive the parameters to satisfy the required capacity and FER.

For example, Figure 3 is an embodiment of the results analysis for the verification of the reverse power control algorithm according to the present invention. Closed loop power control is closed loop power control based on the PCTRL threshold in the BTS channel element, so Eb / No (Locking Finger Combined Measurement Eb / No) It is measured as shown in FIG. 3 above. In FIG. 1, a bed frame does not occur during a period defined as a reverse path at point 1, and the PCTRL value is lowered by a defined delta.

In point 2, the bed frame does not occur in the reverse path, but the down delta is no longer applied because the current PCTRL threshold is the PCTRL minimum value.

At point 3, a bed frame is generated in the reverse path to increase the defined PCTRL threshold by up delta.

4 is a diagram illustrating a method for deriving power control optimal parameters according to the present invention. As described above, data is collected by connecting a DCP device 34 for data collection to a HINA port of the BTS or BSC system, and collecting data. Connects to MDM 36 and collects data.

The BTS or BSC collects a power control threshold, a power control bit, a reverse Eb / No and a reverse FER, and applies a service option 2 (8k) or 9 (13k) in a base station manager (BSM) to full rate. The mobile station at a rate.

The mobile station collects Tx gain adjustment and Rx power and Tx power.

The data collected as described above is analyzed using the SCAT97 38. The SCAT97 (38) tool is used to derive the rate of change of PCT relative to the reverse FER by analyzing the power control bit rate, reverse FER, reverse Eb / No power control threshold, mobile station Tx gain adjustment, and distribution characteristics and ratios of mobile station Tx powers. And application test (40).

In addition, the derivation of the parameters related to the reverse power control threshold 42 is performed by deriving the effective coverage of the PCT by deriving the distribution of the PCT to the FER distribution by comparing and analyzing the test and measured results with the minimum and maximum PCT coverage. .

While the invention is susceptible to various modifications and alternative forms, the disclosure thereof has been described with reference to specific embodiments only. It is to be understood, however, that the present invention is not limited to the specific forms referred to in the specification, but rather that the invention is intended to cover all modifications, equivalents, and substitutions within the spirit and scope of the invention as defined by the appended claims. It should be understood to include.

The present invention configured as described above can be verified through time-consuming waste factor and standardized test by systematic test and analysis by escaping the uncertain verification dimension by the test by debug, and has an effect of increasing reliability.

In addition, it is possible to increase system performance and algorithm reliability through the verification of maximum / minimum / nominal and algorithm of PCT value of reverse link, to implement optimal parameters, and to optimize system operation and efficient power distribution during system operation. There is also an effect that can maximize the capacity of.

Claims (12)

In the reverse power control function verification and optimal parameter derivation method, Collecting a forward power control parameter threshold value transmitted from the BSC to the BTS; Receiving, by the mobile station, a transmission signal including a forward power control parameter having the threshold in the BTS, and collecting, by the mobile station, reverse power control parameters generated in response to the transmission signal; A third step of checking whether the collected reverse power control parameters exist within a preset set power parameter value range; If the test result is within the set power parameter value range, the process returns to the first process to change the threshold value of the forward power control parameter to repeat the first to third processes so that the reverse power control parameter is the set power parameter value. And a fourth process of detecting a threshold range of the forward power control parameters by determining the valid range if the range exists. The method of claim 1, The forward power control parameter threshold collection transmitted from the BSC to the BTS connects the DCP to the BSC or the BTS, and connects to the HINA port of the BTS or the BSC when connecting to the DCP. The method of claim 1, The collected forward power control parameter is a power control bit. The method of claim 1, The reverse power control parameters of the mobile station are collected in connection with a DM tool, and the mobile station and the DM tool are connected by RS-232C. The method of claim 1, The mobile station is connected at full rate by applying a service option in a BSM. The method of claim 5, The service option is two or nine. 2. The method of claim 1, wherein the reverse power control parameters are transmit gain adjustment, receive power and transmit power. The method of claim 1, And wherein the set power control parameter value range is verified as a rate of change of the forward power control parameter threshold relative to the reverse FER. The method of claim 8, And the rate of change of the threshold value of the forward power control parameter relative to the reverse FER is a result of analyzing the distribution characteristics and the ratio of the collected data. A method of deriving an optimal parameter associated with a reverse power control threshold in a CDMA cellular system, Collecting, by the BTS or BCS system, data connected to the DCP equipment for data collection; The mobile station is connected to a DM tool to collect data; Analyzing the collected data by SCAT97; And deriving a reverse power control parameter by using the analysis result. The method of claim 10, The parameter derivation is achieved by deriving a PCT relative to the FER distribution. The method of claim 11, And the PCT compared to the FER distribution is derived by comparing and analyzing the test and measured results with the minimum and maximum PCT coverage.