CN1851410A - Star-feed-back system physical fault detecting apparatus, and detecting and warning method - Google Patents

Abstract

The invention discloses an antenna feeder system physical fault detecting device and the detecting and alarming method. It uses an axial direction angle detecting unit to construct the corresponding relationship of the triaxiality anger of the antenna itself. The invention supplies the detecting the error testing and alarming method that includes the following steps: setting the testing threshold value, transmitting the anger detecting signal to communicating base station, checking the received signal, if the signal exceeding the threshold value, alarming. The invention is used to the far end detection for wireless honeycomb net antenna feeder system physical fault.

Description

A kind of star-feed-back system physical fault detecting apparatus and the method that detects and alarm

Technical field

The present invention relates to field of wireless, the method that reaches of particularly a kind of cellular communication antenna-feedback system physical location failure detector and alarm.

Background technology

The antenna-feedback system of wireless cellular network comprises parts such as antenna, antenna holder, feeder line and iron tower.In radio honeycomb communication system, antenna or the antenna module that contains other functions are placed on the iron tower at a distance of base station usually, are used for the transmitting/receiving wireless signal.The location parameter of antenna such as the angle of pitch, level point to and left and right sides deviation angle all has very big influence to the performance of wireless network.Most of antennas are under the outdoor harsh environmental baseline, and particularly atrocious weather makes these parameters of antenna change probably.For example, the accumulated snow on antenna and the iron tower makes the variation of antenna holder or iron tower generation angle, and typhoon or hurricane make antenna and iron tower that expendable deformation take place.When antenna or iron tower generation physical damnification or after changing, the antenna direction of previous system setting and angle of declination just might change, these finally will change the physical parameter that antenna was determined originally, bring adverse influence for the performance of the former wireless network that designs.Covering variation, the capacity that for example can cause wireless network descend or the like.

Because it is wide that wireless cellular network covers the region, a common wireless network has thousands of base station.These base station distribution that are in the network latter end are in each place.These latter end device systems expectations are safeguarded with the means that far-end detects, avoided each huge website of quantity to carry out on-the-spot test.And antenna is positioned at the iron tower top, and the detection of carrying out antenna is more difficult.Find that in time it is the key of pinpointing the problems that antenna is installed the variation of back physical location parameter.

One of solution of the prior art is: the location parameter of measuring antenna by artificial on-the-spot range estimation and use angle proving installation to the scene.Its shortcoming is to need to test to the scene.Because base station distribution is extensive, testing efficiency is low.Particularly some antennas are positioned at remote area, and place on the high tower, and the cost of reaching the spot is just not little, and the periodic maintenance of antenna is difficulty very.

Another kind of solution of the prior art is: the variation by the wireless network performance quality is judged.After network quality descends, may be that the antenna installation parameter changes and causes, inferring unusually by the network wireless performance quality like this needs the antenna checked, to reduce antenna detection quantity.Its shortcoming is because the network wireless performance quality is relevant with multiple factor, is difficult to effectively navigate on the problem of antenna installation parameter variation.

Summary of the invention

The objective of the invention is to overcome the technical matters of the variation that can't find antenna installation back physical location parameter in the prior art in time, effectively, the method that a kind of star-feed-back system physical fault detecting apparatus is provided and detects and alarm.

The invention provides a kind of star-feed-back system physical fault detecting apparatus, comprise the axial angle detecting unit, described axial angle detecting unit is positioned on the antenna of antenna-feedback system, and the axial angle detection signal of described detecting unit output is input to the base station.

Described axial angle detecting unit comprises the axial angle sensor and is used for amplifying and analog-to-digital signal processing circuit, described axial angle sensor and antenna axially have a fixed correspondence, described signal of sensor is input to the input end of signal processing circuit.

Described axial angle sensor is a shaft angle degree sensor or diaxon angular transducer or three shaft angle degree sensors.

Described axial angle detecting unit is positioned at antenna inside.

The output signal of described axial angle detecting unit is connected with the base station by feeder line.

Described axial angle detecting unit is fixed in the antenna outside.

The output signal of described detecting unit is passed through independent telecommunication cable that is provided with or optical fiber or Radio Link and is connected with the base station.

The present invention also provides a kind of detection and alarm method that utilizes above-mentioned star-feed-back system physical fault detecting apparatus, said method comprising the steps of:

Steps A: after antenna installs, the axial angle detecting unit to the primitive axis on base station transmitting antenna same day to angle detection signal;

Step B: on the base station, set alarming threshold value;

Step C: the axial angle detecting unit is monitored the axial angle of antenna, and the axial angle detection signal is sent to the base station;

Step D: after the axial angle detection signal was received in the base station, the signal that monitoring is received when this signal surpasses threshold values, proposed to report to the police.

Described alarming threshold value comprises axial angle change in detection signal degree alarming threshold value and axial angle change in detection signal rate alarming threshold value.

Described alarm threshold value can be provided with each base station in the network by network management system, also can be provided with by base station local maintenance platform.

Described step D specifically comprises:

Step D1: after the axial angle detection signal was received in the base station, reference axis calculated axial angle change in detection signal degree and axial angle change in detection signal rate to the angle detection signal initial value;

Step D2: the base station is with axial angle change in detection signal degree and axial angle change in detection signal rate and corresponding alarming threshold value comparison, if axial angle change in detection signal degree and axial angle change in detection signal rate surpass axial angle change in detection signal degree alarming threshold value or axial angle change in detection signal rate alarming threshold value, trigger alarm.

The invention has the beneficial effects as follows:

1, by the far-end detection technique of system, can concentrate the physical parameter of monitoring and management antenna-feedback system to change, improved the verification and measurement ratio and the maintenance cost that has lowered equipment of fault, the wireless performance of network finally is provided.

2, because its detection and warning are in real time, automatically, so on-the-spot base station distribution scope of testing is unrestricted, the testing efficiency height.

Description of drawings

Fig. 1 is the structural drawing of cellular communication system involved in the present invention.

Fig. 2 is one of structural representation of pick-up unit of the present invention.

Fig. 3 be pick-up unit of the present invention structural representation two.

Fig. 4 be pick-up unit of the present invention structural representation three.

Fig. 5 is the process flow diagram of detection of the present invention and alarm method.

Embodiment

Below in conjunction with accompanying drawing technical scheme of the present invention is further detailed.

Fig. 1 has described the structure between the base station of cellular communication system.Wireless communication system is made of wireless access network and the core net that base station and base station controller are formed usually.On core net, come wireless network is carried out the management and the maintenance of system, comprise the detection and the alarming processing of fault by network management system.

Sensor in the axial angle detecting unit in following examples adopts three shaft angle degree sensors, thereby the axial angle detecting unit is called three shaft angle degree detecting units in an embodiment.

Fig. 2 is the embodiments of the invention structural representations.Three shaft angle degree detecting units 2 are installed in antenna element 1 inside, and described three shaft angle degree detecting units, 2 output signals are connected with the base station with feeder line by the feeder line mouth 1-1 of antenna element 1.Described three shaft angle degree detecting units 2 comprise three shaft angle degree sensors and are used for amplifying and analog-to-digital signal processing circuit, three of described three shaft angle degree sensors and antenna element 1 have fixed correspondence, described three shaft angle degree signal of sensor are input to the input end of signal processing circuit, the output signal of described signal processing circuit is the output signal of three shaft angle degree detecting units 2, sets up information interaction by the feeder line mouth 1-1 and the base station equipment of antenna element 1.

Fig. 3 is the structural representation of second embodiment of star-feed-back system physical fault detecting apparatus of the present invention.Three shaft angle degree detecting units 2 are installed in antenna element 1 inside, and external communication interface 1-2 and the telecommunication cable of separately setting or optical fiber or the Radio Link of described three shaft angle degree detecting units, 2 output signals by antenna element 1 is connected with the base station.Described three shaft angle degree detecting units 2 comprise three shaft angle degree sensors and are used for amplifying and analog-to-digital signal processing circuit, three of described three shaft angle degree sensors and antenna have fixed correspondence, described three shaft angle degree signal of sensor are input to the input end of signal processing circuit, the output signal of described signal processing circuit is the output signal of three shaft angle degree detecting units 2, sets up information interaction by the external communication interface 1-2 and the base station equipment of antenna element 1.

Fig. 4 is the structural representation of the 3rd embodiment of star-feed-back system physical fault detecting apparatus of the present invention.Three shaft angle degree detecting units 2 are installed in antenna element 1 outside, and external communication interface 2-1 and the telecommunication cable of separately setting or optical fiber or the Radio Link of the output signal of described three shaft angle degree detecting units 2 by antenna element 1 is connected with the base station.Described three shaft angle degree detecting units, 2 output signals are connected with the base station by telecommunication cable.Described three shaft angle degree detecting units 2 comprise three shaft angle degree sensors and are used for amplifying and analog-to-digital signal processing circuit, three of described three shaft angle degree sensors and antenna have fixed correspondence, described three shaft angle degree signal of sensor are input to the input end of signal processing circuit, the output signal of described signal processing circuit is the output signal of three shaft angle degree detecting units 2, sets up information interaction by the external communication interface 2-1 and the base station equipment of antenna element 1.

In the above-described embodiment, the sensor in the axial detecting unit also can adopt two shaft angle degree sensors or a shaft angle degree sensor.

Referring to Fig. 5, the present invention also provides a kind of detection and alarm method of star-feed-back system physical fault detecting apparatus, may further comprise the steps:

Step 101: after antenna installed, three shaft angle degree detecting units were to the base station transmitting antenna three shaft angle degree detection signals on the same day, and promptly initial three shaft angle degree detection signals are respectively as three initialize signals: 91 degree, 0 degree, 87 degree;

Step 102: the alarming threshold value of on the base station, setting three shaft angle degree change in detection signal degree and three shaft angle degree change in detection signal rates, threshold values as three shaft angle degree change in detection signal degree of three axles is+/-5 degree, the threshold values of its rate of change was 0.2 degree/second, and the above threshold values can be provided with or change; Described alarm threshold value can be provided with each base station in the network by network management system, also can be provided with by base station local maintenance platform;

Step 103: three shaft angle degree detecting units are monitored three shaft angle degree of antenna, and the value of obtaining is 88 degree, 2 degree, and 90 degree are sent to the base station with this three shaft angles degree detection signal;

Step 104: after three shaft angle degree detection signals are received in the base station, the three shaft angle degree detection signals of receiving are deducted three shaft angle degree detection signal initial values to calculate three shaft angle degree change in detection signal degree and is respectively :-3 degree, 2 degree, 3 degree, and a period of time as 10 seconds in detect and calculate three shaft angle degree change in detection signal rates, be respectively for-0.3 degree/second, 0.2 degree/second, 0.1 degree/second;

Step 105: with three shaft angle degree change in detection signal degree-3 degree, 2 degree, 3 degree are spent relatively with corresponding alarming threshold value+/-5, and at this moment, three shaft angle degree change in detection signal degree all do not have the three shaft angle degree change in detection signal degree alarm valves of surpassing, so do not trigger alarm;

Step 106: with three shaft angle degree change in detection signal rate-0.3 degree/seconds, 0.2 degree/second, 0.1 degree/second and corresponding alarming threshold value comparison 0.2 degree/second, at this moment X axis angle detection signal rate of change surpasses three shaft angle degree change in detection signal rate alarming threshold values, if this phenomenon certain time, illustrate that antenna module is subjected to unusual change, the system triggers alarm.

More than just preferred implementation of the present invention is described, those skilled in the art is in the scheme scope of the technology of the present invention, and common variation and the replacement carried out all should be included in protection scope of the present invention.

Claims (11)

1, a kind of star-feed-back system physical fault detecting apparatus is characterized in that, comprises the axial angle detecting unit, and described axial angle detecting unit is positioned on the antenna of antenna-feedback system, and the axial angle detection signal of described detecting unit output is input to the base station.

2, star-feed-back system physical fault detecting apparatus according to claim 1, it is characterized in that, described axial angle detecting unit comprises the axial angle sensor and is used for amplifying and analog-to-digital signal processing circuit, described axial angle sensor and antenna axially have a fixed correspondence, described signal of sensor is input to the input end of signal processing circuit.

3, star-feed-back system physical fault detecting apparatus according to claim 2 is characterized in that, described axial angle sensor is a shaft angle degree sensor or diaxon angular transducer or three shaft angle degree sensors.

4, star-feed-back system physical fault detecting apparatus according to claim 1 is characterized in that, described axial angle detecting unit is positioned at antenna inside.

5, star-feed-back system physical fault detecting apparatus according to claim 4 is characterized in that, the output signal of described axial angle detecting unit is connected with the base station by feeder line.

6, star-feed-back system physical fault detecting apparatus according to claim 1 is characterized in that, described axial angle detecting unit is fixed in the antenna outside.

According to claim 4 or 6 described star-feed-back system physical fault detecting apparatus, it is characterized in that 7, the output signal of described detecting unit is passed through independent telecommunication cable that is provided with or optical fiber or Radio Link and is connected with the base station.

8, a kind of detection and alarm method that utilizes the described star-feed-back system physical fault detecting apparatus of claim 1 is characterized in that, said method comprising the steps of:

Steps A: after antenna installs, the axial angle detecting unit to the primitive axis on base station transmitting antenna same day to angle detection signal;

Step B: on the base station, set alarming threshold value;

Step C: the axial angle detecting unit is monitored the axial angle of antenna, and the axial angle detection signal is sent to the base station;

Step D: after the axial angle detection signal was received in the base station, the signal that monitoring is received when this signal surpasses threshold values, proposed to report to the police.

9, star-feed-back system physical fault according to claim 8 detects and alarm method, it is characterized in that described alarming threshold value comprises axial angle change in detection signal degree alarming threshold value and axial angle change in detection signal rate alarming threshold value.

10, star-feed-back system physical fault according to claim 8 detects and alarm method, it is characterized in that described step D specifically comprises:

Step D1: after the axial angle detection signal was received in the base station, reference axis calculated axial angle change in detection signal degree to the angle detection signal initial value, and interior at certain time intervals reference axis is to the angle detection signal rate of change;

Step D2: the base station is with axial angle change in detection signal degree and axial angle change in detection signal rate and corresponding alarming threshold value comparison, if axial angle change in detection signal degree and axial angle change in detection signal rate surpass axial angle change in detection signal degree alarming threshold value or axial angle change in detection signal rate alarming threshold value, trigger alarm.

11, star-feed-back system physical fault according to claim 8 detects and alarm method, it is characterized in that described alarm threshold value can be provided with each base station in the network by network management system, also can be provided with by base station local maintenance platform.

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