KR100413424B1 - self-diagnosis method of base station test equipment - Google Patents

Abstract

The present invention relates to a base station diagnostic unit (BTU: Base-station Test Unit) and a base station analysis diagnostic unit (BADA) which are used for measuring the standing wave ratio of a base station antenna in a base station system. The present invention relates to a self-diagnostic method of the same base station test equipment. In the present invention, the linear response characteristics of the base station test equipment are tested to determine whether the measurement reliability of the standing wave ratio of the transmitting / receiving antenna is abnormal. To provide.

Description

Self-diagnosis method of base station test equipment

The present invention relates to a communication device, and more particularly, to a self-diagnostic method of base station test equipment such as a base station diagnostic apparatus (BTU) and a base station analysis diagnostic apparatus (BADA) used for measuring standing wave ratios of base station antennas in a base station system.

The base station test equipment currently in use is used to measure the voltage standing wave ratio of several transmit / receive antennas of the base station system.

The standing wave ratio of the base station transmitting antenna is calculated by the ratio of the strength of the transmission power of the base station to the signal strength reflected from the transmitting antenna, and the standing wave ratio of the base station receiving antenna is directly measured to the receiving antenna measured by the test terminal. It is calculated by the ratio of the transmission power adjustment value of the input path to the transmission power adjustment value of the reception antenna reflection path.

Currently, the base station test equipment includes a transmission coupler for outputting a signal coupled from a base station system and a reflection signal reflected from a transmission antenna, and a reception signal and a reflection path coupled through a direct input path. A reception coupler for outputting the signal reflected from the antenna to the base station system, an on / off switch for selecting one of a reflection path and a direct input path of the transmission coupler and the reception coupler, and a transmission output at the base station transmission path A test terminal for measuring the strength of the signal and an adjustment of the transmission power in the base station reception path, a digital step attenuator for attenuating the strength of the signal introduced into the test terminal in advance to create a virtual signal strength, The standing wave ratio is measured by using the transmission power and the transmission power adjustment value by the test terminal. It consists of software.

In this configuration, the standing wave ratio of the base station transmitting antenna is measured through the following operation.

First, the test terminal receives a signal from the base station system through a direct input path. Thereafter, a markov call is set to a frequency to be measured, and an aiming point of the reception attenuator is adjusted to satisfy the reception strength linear response of the test terminal.

Next, measure the received power (P _dFWD ) at the direct input path, and measure the adjusted transmit power from the test terminal. In addition, the switch is operated so that the test terminal receives a signal through the reflection path of the transmitting antenna, and measures the received power (P _dREV ).

After that, the difference between the two received powers P _dFWD and P _dREV is calculated, and the reflection coefficient τ is calculated from the difference between the received powers. As a result, the standing wave ratio of the transmitting antenna is calculated from the calculated reflection coefficient?.

In the above configuration, the standing wave ratio of the base station receiving antenna is measured through the following operation.

First, a markov call is set up so that a test terminal can make a call through a receiving antenna to be measured.

The aiming point of the transmission attenuator is then adjusted to satisfy the linear response of the transmit power adjustment of the test terminal.

Next, measure the transmission power adjustment value (Adj _FWD ) in the direct input path from the test terminal to the receiving antenna, and change the transmission path of the test terminal from the direct input path to the reflection path while maintaining the receiving path of the test terminal. do. After that, the transmit power adjustment value (Adj _REV ) is measured on the reflection path.

Then, the difference between the two measured transmission power adjustment values (Adj _FWD , Adj _REV ) is calculated, and the reflection coefficient τ is calculated from the difference value of the transmission power adjustment values. As a result, the standing wave ratio of the receiving antenna is calculated from the calculated reflection coefficient?.

In this prior art, after setting up the Markov call, the aiming point of the digital step attenuator is adjusted by adjusting the received power and the transmitted power satisfying the linear response. To this end, in the related art, a digital step attenuator for attenuating the strength of a high frequency signal in a base station test equipment is adjusted, and the test terminal repeatedly performs a procedure of reading received and transmit power values.

However, in such a prior art, when the digital step attenuator constituting the base station test equipment is bad or the measurement data of the test terminal is abnormal, the aiming point adjustment of the attenuator may fail, and thus the data measured by the test terminal. Is not reliable. As a result, there is a problem in that the reliability of the standing wave ratio measurement of the transmitting / receiving antenna is deteriorated. This problem is problematic even when the digital step attenuator itself is not detected.

An object of the present invention has been made in view of the problems of the prior art as described above, in particular, whether the measurement reliability of the digital step attenuator itself to the standing wave ratio measurement of the antenna for transmission and reception by testing the linear response characteristics of the base station test equipment The present invention provides a self-diagnostic method for determining the self-diagnosis method. The self-diagnostic method of the base station test equipment according to the present invention for achieving the above object is characterized in that the test terminal receives a pilot from a base station system through a direct input path. Thereafter, setting a Markov call to a frequency to be measured, and changing attenuation values of each attenuator of a transmission / reception path for the test terminal in a designated range after setting the Markov call step by step, thereby receiving and transmitting power of the test terminal. Measuring the adjustment value and subjecting to the step change Checking whether the measured values of the received power and the transmitted power adjustment values of the test terminal fluctuate within an allowable error range; and checking whether the measured values fluctuate, so as to satisfy an optimal linear response. Adjusting the attenuator.

In this case, after setting the Markov call, the attenuation value of the reception attenuator of the reception path for the test terminal for the test terminal is gradually increased in a designated range, and the reception power of the test terminal is measured. The reception attenuator checks whether a measurement value of the reception power of the terminal decreases within an allowable error range, and satisfies an optimal reception linear response when the measurement value of the reception power decreases as the attenuation value increases. Adjust the aiming point of.

In addition, after the Markov call is set, the attenuation value of the transmission attenuator of the transmission path for the test terminal is gradually increased in a designated range, and the transmission power adjustment value of the test terminal is measured, and as the stepped attenuation value is increased, Check whether the measured value of the transmission power adjustment value of the test terminal increases within the tolerance range, and satisfies the optimal transmission linear response when the measurement value of the transmission power adjustment value increases with the increase of the attenuation value. Adjust the aiming point of the transmission attenuator to make it.

1 is a block diagram showing a configuration of a general base station test equipment.

2 is a flow chart showing a self-diagnostic procedure of the base station test equipment according to the present invention.

* Description of the symbols for the main parts of the drawings *

1: test terminal 2: the first mux

3: reception attenuator 4: transmission attenuator

5: second mux 6,7,8: on / off switch

9: transmitting coupler 10,11 receiving coupler

Hereinafter, a preferred embodiment of a self-diagnostic method of a base station test equipment according to the present invention will be described with reference to the accompanying drawings.

The device configuration of the base station test equipment for the self-diagnosis procedure of the present invention is the same as before, and the core of the present invention is to test the linear response characteristics of the base station test equipment to obtain the standing wave ratio of the transmission / reception antenna which is the original purpose of the test equipment. In this case, the digital step attenuator is adjusted to satisfy the optimum linear response by checking whether the measured values of the received and transmitted power adjustment values of the test terminal fluctuate within the tolerance range.

1 is a block diagram illustrating an internal configuration of a general base station test equipment. The base station test equipment includes a transmission coupler 9 for outputting a signal coupled from a base station system and a reflected signal reflected from a transmission antenna; Receiving couplers 10 and 11 for outputting signals coupled through a direct input path and signals reflected from a receiving antenna via a reflection path to a base station system, a transmitting coupler 9 and a receiving coupler 10 (6), (7) and (8) switches for selecting one of the reflection path and the direct input path, and the strength of the transmission power in the base station transmission path and the adjustment of the transmission power in the base station reception path. And attenuators 3 and 4 for attenuating the strength of the signal introduced into the test terminal 1 in advance to create a virtual signal strength.

In this configuration, the diagnostic procedure for more reliably measuring the standing wave ratio of the base station antenna operates as follows.

First, a markov call is set in the test terminal 1.

Thereafter, the attenuation values of the attenuators 3 and 4, which are the test subjects of the present invention, are initialized to minimum values of a specified range, and the received power and transmission power adjustment values of the current test terminal 1 are measured.

At this time, in the case of the response linearity test in the test form (receive response linearity test or transmission response linearity test) for the test terminal, the attenuation value of the reception attenuator 3 is increased, whereas in the case of the transmission response linearity test, the transmission attenuator 4 Increase the attenuation value. This is repeated to the upper limit of each specified test.

Then, as the attenuation value increases, it is determined whether the received power and the transmit power adjustment value of the test terminal 1 react (decrease or increase) within a predetermined tolerance range.

Hereinafter, the basic diagnostic procedure described above will be described in more detail with reference to FIG. 2.

2 is a flowchart illustrating a self-diagnosis procedure of the base station test equipment according to the present invention.

When the test type for the test terminal is the reception response linearity test, the reception power of the test terminal 1 according to the attenuation value of the reception attenuator 3 is first measured according to the following procedure, and then the attenuation value is gradually increased. Accordingly, it is observed whether the measured received power value continues to decrease within a predetermined tolerance range.

In response to this, the test terminal 1 first receives a pilot from a base station system through a direct input path and then sets a markov call at a frequency to be measured (S1).

The attenuation value of the reception attenuator 3 is initialized to the minimum value of the specified range (S4), and the reception power (in dBm unit) of the current test terminal 1 is measured (S5).

Next, the attenuation value of the reception attenuator 3 is increased by the designated step, and the reception power of the test terminal 1 is measured as each step is increased (S8, S9). The procedure up to this point is repeated up to the upper limit of the specified response response linearity test (S7 to S10).

Thereafter, as the attenuation value increases, it is checked whether the measured reception power values continue to decrease within a predetermined tolerance range, and report this to the base station manager (BSM) (S11).

When the test type for the next test terminal is a transmission response linearity test, first, closed loop power control between the base station system and the test terminal 1 is performed according to the stepped increase in the attenuation value of the transmission attenuator 4. The base station system issues a command for increasing transmission power to the test terminal. Accordingly, it is checked whether the transmission power adjustment value is increased. Then, the transmission power adjustment value of the test terminal is measured according to the following procedure to observe whether the measured transmission power adjustment value continues to increase within a predetermined tolerance range as the attenuation value of the transmission attenuator 4 increases.

In response to this, the test terminal 1 receives a pilot from a base station system through a direct input path. Thereafter, a markov call is set to the frequency to be measured (S1).

Next, the attenuation value of the reception attenuator 3 is adjusted so that this transmission response linearity test is tested in a region satisfying the optimum transmission power linear response of the test terminal 1 (S3).

Thereafter, the attenuation value of the transmission attenuator 4 is initialized to the minimum value of the specified range (S4), and the transmission power adjustment value (in dBm units) in the direct input path of the current test terminal 1 is measured (S5).

Next, the attenuation value of the transmission attenuator 4 is increased by a specified step, and each time the step is increased, the transmission power adjustment value of the test terminal 1 is measured (S8, S9). The procedure up to this point is repeated up to the upper limit of the specified transmission response linearity test (S7 to S10).

Thereafter, as the attenuation value increases, the transmission power adjustments measured respectively continue to increase within a predetermined tolerance range, and report this to the base station manager BSM (S11).

The procedure up to now checks the measurement reliability of the base station test equipment from time to time, and for this purpose, a specific processor in the base station system controls the switching to change the transmission / reception path to the test terminal.

In addition, the self-diagnosis result of the base station test equipment is reported to the upper processor of the base station manager (BSM) to allow the operator to check the abnormality of the equipment.

According to the self-diagnostic method of the base station test equipment according to the present invention, because it improves the measurement reliability of the base station test equipment, especially the digital step attenuator, such as the base station diagnostic apparatus (BTU) and the base station analysis diagnostic apparatus (BADA), poor equipment operation The post-processing cost of the test equipment is reduced.

In addition, it is possible to reduce maintenance costs of unnecessary base station systems caused by determining an incorrect standing wave ratio in a normal antenna.

Claims (3)

Setting up a Markov call at a frequency to be measured after receiving a pilot from a base station system through a direct input path; Measuring the received power and transmit power adjustment values of the test terminal by changing the attenuation values of the attenuators of the transmission and reception paths to the test terminal in a designated range after setting the mark call; Checking whether the measured values of the received power and the transmit power adjustment value of the test terminal fluctuate within an allowable error range according to the stepped attenuation value change; Self-diagnostic method of the base station test equipment, characterized in that for determining whether the measured value changes, adjusting each attenuator to satisfy the optimum linear response. The method of claim 1, wherein after the Markov call setup: Step by increasing the attenuation value of the reception attenuator of the reception path for the test terminal in a specified range, to measure the received power of the test terminal, As the stepped attenuation value increases, it is checked whether the measured value of the received power of the test terminal decreases within an allowable error range. Self-diagnostic method of the base station test equipment, characterized in that the aiming point of the reception attenuator is adjusted to satisfy an optimal reception linear response when the measured value of the received power decreases as the attenuation value increases. The method of claim 1, wherein after the Markov call setup: Step by step increase the attenuation value of the transmission attenuator of the transmission path to the test terminal in the specified range, to measure the transmission power adjustment value of the test terminal, As the stepped attenuation value increases, it is checked whether the measured value of the transmission power adjustment value of the test terminal increases within an allowable error range. Self-diagnostic method of the base station test equipment, characterized in that the aiming point of the transmission attenuator is adjusted to satisfy an optimal transmission linear response when the measured value of the transmission power adjustment value increases with the increase of the attenuation value.