KR100676879B1 - Isolation test method and apparatus - Google Patents

Abstract

The present invention relates to a method and apparatus for checking isolation. In the repeater for checking the isolation according to the present invention, a donor antenna coupled to the base station and the wireless mobile communication network, a service antenna coupled to the mobile terminal included in the coverage of the repeater, a base station side duplexer coupled to the donor antenna, the service antenna A low noise amplifier for amplifying a first frequency signal from a mobile terminal and a low noise amplifier for coupling to a service side duplexer and a service side duplexer, and combining a predetermined frequency with a low noise amplified first frequency signal to an intermediate frequency. It is coupled to a low frequency mixer and a low frequency mixer to be converted, and is coupled to a surface acoustic wave filter and a surface acoustic wave filter to filter to a predetermined area based on an intermediate frequency. High frequency to convert to the second frequency A high power amplifier coupled to a wave mixer, a high frequency mixer, and amplifying a second frequency, where the amplified second frequency is transmitted to the base station via a base station side duplexer and a donor antenna, coupled to a high power amplifier, and from a high power amplifier A guard band frequency signal coupled to a detector for detecting the output signal, and a detector and a high frequency mixer, controlling the high frequency mixer to output a guard band frequency signal during the isolation test, wherein the guard band frequency signal from at least the surface acoustic wave filter is passed from the detector, The guard band frequency signal is received from the donor antenna and received by the service antenna to receive a detection value of the surface acoustic wave filter, and includes a controller for comparing the detection value with a preset standard value to determine the degree of isolation.

Isolation, Isolation, Repeater

Description

Method and apparatus for testing isolation             

1 is a block diagram of a repeater including an isolation test method using a conventional pilot signal.

2 is a block diagram of a repeater including a method of using a conventional in-band noise.

Figure 3 is a block diagram of a repeater including an isolation test method using a guard band according to an embodiment of the present invention.

4 is a schematic flowchart illustrating an isolation test method in a repeater including an isolation test method using a guard band according to an exemplary embodiment of the present invention.

5 is a block diagram showing a schematic system of a repeater including an isolation test method using a guard band according to an embodiment of the present invention.

Figure 6 is an exemplary installation of a repeater including an isolation test using a guard band according to an embodiment of the present invention.

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

301: Donor Antenna

303: base station side duplexer

305 high power amplifier (HPA)

307: high frequency mixer

309: Attenuator

311: isolation attenuator

313: Surface Acoustic Wave Filter

315: low frequency mixer

317: Low Noise Amplifier (LNA)

319: duplexer on the service side

321: service antenna

323: calling party detector

325: Controller

The present invention relates to a method and apparatus for checking isolation using a guard band.

Isolation is a concept commonly used to isolate two signals. When multiple signals use a system or circuit simultaneously, the degree to which they are separated from each other is usually called isolation. In other words, it can be understood as a measure of how much less interference with each other.

Since this isolation affects the quality of service especially in the repeater, the isolation test is essential when determining the repeater's antenna location.

Conventional isolation measurement methods include a method using a pilot signal (FIG. 1) and a method using in-band noise (FIG. 2).

In the method using a pilot signal, the pilot frequency oscillator generates a pilot signal having the same frequency as the in-band serviced by the repeater and loads it with the service frequency in the signal path, and then the pilot signal is radiated through the source antenna. This is a method of measuring the isolation between two antennas by comparing the signal fed back to the receiving antenna.

In-band noise is a method that uses the system gain to increase the system gain to meet the specified isolation criteria while the controller checks for isolation, and then outputs the output value at the final output detector. This value is detected and the controller uses this value to determine if the separation between antennas is within specification. However, since both methods use isolation frequency to check for isolation, the quality of the call is affected while the isolation is checked.

1 is a block diagram of a repeater including an isolation test method using a conventional pilot signal.

Referring to FIG. 1, a repeater including an isolation test method using a conventional pilot signal includes a donor antenna 101, a base station side duplexer 103, a high power amplifier (HPA) 105, and a high frequency mixer 107. , Attenuator 109, surface acoustic wave filter (SAW filter) 111, low frequency mixer 113, low noise amplifier (LNA) 115, service side duplexer 117, service antenna 119, transmitter A detector 121, a pilot signal oscillator 123, a controller 125, a pilot signal filter 127, and a receiver detector 129 are included.

The isolation test method using the conventional pilot signal first generates a pilot signal included in a frequency band serviced by the pilot signal oscillator 123. The signal is transmitted outside the repeater. At this time, the transmitter detector 121 detects the pilot signal. The transmitted pilot signal is then fed back and detected by the receiver detector 129. Then, the controller 125 compares the source detector 121 and the receiver detector 129 to measure the degree of isolation. This method judges only the pure pilot signal strength without changing the gain of the repeater while measuring the isolation. However, there are many additional components required to check the isolation and the poor quality of the call due to the pilot signal during the isolation check.

2 is a block diagram of a repeater including a method using a conventional in-band noise.

Referring to FIG. 2, a repeater including a method using in-band noise includes a donor antenna 201, a base station side duplexer 203, a high power amplifier (HPA) 205, a high frequency mixer 207, and an attenuator 209. , Isolation attenuator 211, SAW filter 213, low frequency mixer 215, low noise amplifier (LNA) 217, service side duplexer 219, service antenna 221, The calling party detector 223 and the controller 225 are included.

In the conventional isolation test using in-band noise, the high frequency mixer 207 generates noise and the noise generated by the high frequency mixer 207 is transmitted to the outside. The transmitted noise is fed back through the service antenna 221 and received. This received signal then flows along the signal path of the system and is detected by the source detector 223. At this time, with the value detected by the source detector 223, the controller 225 determines whether the isolation of the antenna meets the standard. If the antenna isolation is less than the standard, the repeater will oscillate, so the detected value is instantaneously large enough. Therefore, it is possible to determine whether the antenna is isolated enough. However, this method using in-band noise has a drawback that the SAW filter is a full-service filter, which affects the quality of the call at the time of checking for isolation.

In order to solve the above problems, an object of the present invention is to provide a method and apparatus for checking isolation using a guard band.

Another object of the present invention is to provide an isolation test method and apparatus using a guard band having no abnormality in call quality during the isolation test.

Another object of the present invention is to provide a method and apparatus for checking the isolation using a guard band that can automatically check the isolation when power is input to the repeater.

It is still another object of the present invention to provide an isolation test method and apparatus using a guard band that does not operate normally with a warning when the isolation rate is not met to meet a predetermined standard.

In order to achieve the above object, according to an aspect of the present invention, a repeater for checking the isolation, the donor antenna coupled to the base station and the wireless mobile communication network; A service antenna for communicating with a mobile terminal included in the coverage of the repeater; A base station side duplexer coupled to the donor antenna; A service side duplexer coupled to the service antenna; A low noise amplifier coupled to the service side duplexer and amplifying a first frequency signal from the mobile terminal; A low frequency mixer coupled to the low noise amplifier, for mixing a predetermined frequency into a first frequency signal amplified by the low noise amplifier and converting the predetermined frequency into an intermediate frequency signal; A surface acoustic wave filter coupled to the low frequency mixer, the surface acoustic wave filter filtering a predetermined area based on the intermediate frequency signal converted by the low frequency mixer; A high frequency mixer coupled to the surface acoustic wave filter and converting a predetermined frequency into a second frequency signal filtered by the surface acoustic wave filter and converting the predetermined frequency into a second frequency signal that can be received by the base station; A high output amplifier coupled to the high frequency mixer and amplifying a second frequency signal converted by the high frequency mixer, wherein the amplified second frequency signal is transmitted to the base station via the base station side duplexer and the donor antenna -; A detector coupled to the high output amplifier and detecting a signal amplified and output from the high output amplifier; A guard band frequency signal coupled to the detector and a high frequency mixer and controlling the high frequency mixer to output a guard band frequency signal upon isolation checking, the guard band frequency signal from the detector via at least the surface acoustic wave filter, wherein the guard band frequency A signal emitted from the donor antenna and received by the service antenna to be input to the surface acoustic wave filter to receive a detection value, and to determine the degree of isolation by comparing the detection value with a preset standard value; And an isolation attenuator for increasing the system gain of the repeater by an isolation test standard according to a control signal of the controller.
Here, the detector is characterized in that for detecting the guard band frequency signal generated by the high frequency mixer from the signal converted into the second frequency signal.
According to another aspect of the invention, the repeater for checking the isolation, the donor antenna coupled to the base station and the wireless mobile communication network; A service antenna for communicating with a mobile terminal included in the coverage of the repeater; High frequency mixer; A surface acoustic wave filter coupled to the high frequency mixer and filtering a signal transmitted from the service antenna to a predetermined area; A detector for detecting a signal filtered from the surface acoustic wave filter; A guard band frequency signal coupled to the detector and a high frequency mixer and controlling the high frequency mixer to output a guard band frequency signal upon isolation checking, the guard band frequency signal from the detector via at least the surface acoustic wave filter, wherein the guard band frequency A signal emitted from the donor antenna and received by the service antenna to be input to the surface acoustic wave filter to receive a detection value, and to determine the degree of isolation by comparing the detection value with a preset standard value; And an isolation attenuator for increasing the system gain of the repeater by an isolation test standard according to a control signal of the controller.
According to still another aspect of the present invention, a method of checking isolation in a repeater including a donor antenna, a service antenna, a high frequency mixer, a surface acoustic wave filter, a detector, a controller, and an isolation attenuator, wherein the control is performed by the controller. The isolation attenuator increases the system gain of the repeater by the isolation inspection specification; Controlling, by the controller, the high frequency mixer to output a guard band frequency signal; Radiating, by the donor antenna, a guard band frequency signal output by the high frequency mixer; The service antenna receiving a guard band frequency signal radiated from the donor antenna; The surface acoustic wave filter filtering a guard band frequency signal received by the service antenna; Detecting the guard band frequency signal filtered by the surface acoustic wave filter; Receiving, by the controller, a detection value detected by the detector; And determining, by the controller, the degree of isolation by comparing the detected detection value with a preset standard value.
Here, the detecting of the guard band frequency signal filtered by the surface acoustic wave filter may be performed by detecting the guard band frequency signal generated by the high frequency mixer.

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

3 is a block diagram of a repeater including an isolation test method using a guard band according to an embodiment of the present invention.

Referring to FIG. 3, a repeater including an isolation test method using a guard band according to an exemplary embodiment of the present invention may include a donor antenna 301, a base station side duplexer 303, and a high power amplifier. (HPA) 305, high frequency mixer 307, attenuator 309, isolation attenuator 311, surface acoustic wave filter (SAW filter) 313, low frequency mixer 315, low noise amplifier (LNA) 317 And a service side duplexer 319, a service antenna 321, a calling party detector 323, and a controller 325.

In the isolation test method using the guard band, the controller 325 first adjusts the mixing frequency of the high frequency mixer 307 and the low frequency mixer 315 to the guard band. The controller 325 then adjusts the isolation attenuator 311 to increase the gain of the system by the isolation specification. Thereafter, the high frequency mixer 307 generates noise corresponding to the guard band, and the generated noise passes through the high power amplifier (HPA) 305 and the base station side duplexer 303 to the outside from the donor antenna 301. Is sent. The noise of the guard band transmitted is service antenna 321, service side duplexer 319, low noise amplifier (LNA) 317, low frequency mixer 315, surface acoustic wave filter 313, isolation attenuator 311 And the attenuator 309 is detected by the calling party detector 323. At this time, with the value detected by the transmitter detector 323, the controller 325 determines whether the isolation of the antenna meets the standard. If the antenna isolation is less than the standard, the repeater will oscillate, so the detected value is instantaneously large enough. Therefore, it is possible to determine whether the antenna is isolated enough.

4 is a schematic flowchart illustrating an isolation test method in a repeater including an isolation test method using a guard band according to an exemplary embodiment of the present invention.

Referring to FIG. 4, first, a repeater is installed and the positions of the service antenna 321 and the donor antenna 301 are adjusted (step 401). The power of the repeater is then connected (step 402). The controller of the repeater then automatically turns off the circuit portion associated with the signal from the base station of the repeater to the mobile terminal (hereinafter, forward pass) (step 403). The controller then locks the oscillation frequency of the circuit portion associated with the signal from the mobile terminal of the repeater to the base station to the guard band frequency channel (step 405). Controller 325 then amplifies the system gain of the guard band to meet the isolation criteria (step 407). The amplified guard band frequency signal is then sent via donor antenna 301 (step 409). The sent signal is then received by the service antenna 321 (step 411), and the received signal is amplified by a low noise amplifier (LNA) 317 (step 413). The frequency of the guard band fed back by the SAW filter 313 is then filtered (step 415). After that, it is again the same as the origin of the original guard band. At this time, if the calling party detector 323 detects the dispatch signal, it is possible to check the degree of isolation (step 417). At this time, the controller 325 checks the isolation degree and completes the implementation if it satisfies the specification, and the repeater operates normally (step 421). Otherwise the repeater will not operate normally, then go back to step 401 to adjust the position of the antenna (step 419).

5 is a block diagram showing a schematic system of a repeater including an isolation test method using a guard band according to an embodiment of the present invention.

Referring to FIG. 5, a repeater including an isolation test method using the guard band may first be divided into a forward pass and a reverse pass. The forward pass is a portion of the circuit related to the signal path from the base station to the terminal, and the reverse pass is a portion of the circuit related to the signal path from the terminal to the base station.

The circuit of the reverse pass section includes a donor antenna 501, a base station side duplexer 503, a reverse pass source detector 505, a high power amplifier (HPA) 507, an attenuator 509, and an automatic gain control device (AGC). 511, high frequency mixer module 513, digital attenuator 515, surface acoustic wave filter (SAW filter) 517, low frequency mixer module 519, low noise amplifier (LNA) 521, service side duplex The document 523 and the service antenna 529 may be included as main components.

The components of the circuit of the forward pass portion also have components that are symmetrical with the components of the circuit of the reverse pass portion, such that the service antenna 529, the service side duplexer 523, the forward pass source detector 527, High power amplifier (HPA) 531, attenuator 533, automatic gain control unit (AGC) 535, high frequency mixer module 537, surface acoustic wave filter (SAW filter) 539, low frequency mixer module 541, The low noise amplifier (LNA) 543, the base station side duplexer 503, the donor antenna 501, and the like may be included as main components.

In addition, the controller 545 for controlling the entire repeater and the oscillator 625 for inputting the frequency to the mixer may be included as a major component.

The donor antenna 501 receives a signal transmitted from the base station, transmits the signal to the repeater, and simultaneously transmits the signal of the terminal amplified by the repeater to the base station.

The base station-side duplexer 503 is an antenna common device that allows the use of one antenna at a different frequency at the same time, characterized in that for the donor antenna.

The reverse pass transmitter detector 505 detects noise of a guard band generated by the high frequency mixer of the reverse pass.

The high power amplifier (HPA) 507 is characterized by amplifying the signal produced by the high frequency mixer to a linear high power.

The attenuator 509 is characterized by stabilizing the output level of the oscillation frequency.

The automatic gain control unit (AGC) 511 is characterized in that the gain is automatically adjusted so that the output is always constant even when there is a change in the input of the receiver or amplifier.

The high frequency mixer module 513 mixes a signal of a frequency oscillator and a reverse pass to make a signal that can be received by a base station.

Digital Attenuator 515 A type of attenuator, characterized in that it is used to adjust the gain of the system to measure the isolation.

Surface acoustic wave filter (SAW filter) 517 is a communication filter using the mechanical vibration of the piezoelectric plate characterized in that it accurately screens the frequency of the signal transmitted from the terminal of the various signals entering the reverse pass.

The low frequency mixer module 519 mixes a signal of a frequency oscillator and a reverse pass to produce a signal that can be properly filtered by the surface acoustic wave filter.

The low noise amplifier (LNA) 521 amplifies the signal while minimizing the noise and amplifies the signal of the terminal received in the reverse pass.

The service side duplexer 523 serves to enable the service antenna to simultaneously receive signals from the terminal and transmit signals from the base station.

The service antenna 529 receives a signal transmitted from the terminal, transmits the signal to the repeater, and simultaneously transmits the signal of the base station amplified by the repeater to the terminal.

The controller 545 is responsible for the overall control of the repeater, such as checking the repeater's isolation and adjusting the automatic gain control device.

Oscillator 525 is characterized in that by supplying a signal of a constant frequency to the high frequency mixer and low frequency mixer, to help the mixer generate a signal of the required frequency.

Figure 6 is an exemplary installation of a repeater including an isolation test using a guard band according to an embodiment of the present invention.

Referring to FIG. 6, a repeater including an isolation test using a guard band includes a donor antenna 601, a repeater main body 603, a service antenna 605, and a power supply 607.

The separation distance between the donor antenna 601 and the service antenna 605 may be appropriately selected through an isolation test performed by the repeater body 603.

The present invention is not limited to the above embodiments, and many variations are possible by those skilled in the art within the spirit of the present invention.

According to the present invention, it is possible to provide an isolation test method and apparatus using a guard band. Therefore, it is not necessary to generate a specific signal during the isolation test.

According to the present invention, it is possible to provide an isolation test method and apparatus using a guard band having no abnormality in call quality during the isolation test. Therefore, the isolation quality can be prevented when the quality of the call is reduced or the call is impossible.

In addition, according to the present invention can provide an isolation test method and apparatus using a guard band that can automatically check the isolation when the power is input to the repeater. Therefore, if you connect the power to the repeater, you can see if the antenna separation distance is appropriate.

In addition, according to the present invention can provide an isolation test method and apparatus using a guard band that does not perform a normal operation with a warning when the degree of isolation is not checked to meet a predetermined criterion. This prevents the repeater from working if the isolation is not adequate.

Claims (9)

In the repeater to check the isolation, A donor antenna coupled to the base station and the wireless mobile communication network; A service antenna for communicating with a mobile terminal included in the coverage of the repeater; A base station side duplexer coupled to the donor antenna; A service side duplexer coupled to the service antenna; A low noise amplifier coupled to the service side duplexer and amplifying a first frequency signal from the mobile terminal; A low frequency mixer coupled to the low noise amplifier, for mixing a predetermined frequency into a first frequency signal amplified by the low noise amplifier and converting the predetermined frequency into an intermediate frequency signal; A surface acoustic wave filter coupled to the low frequency mixer, the surface acoustic wave filter filtering a predetermined area based on the intermediate frequency signal converted by the low frequency mixer; A high frequency mixer coupled to the surface acoustic wave filter and converting a predetermined frequency into a second frequency signal filtered by the surface acoustic wave filter and converting the predetermined frequency into a second frequency signal that can be received by the base station; A high output amplifier coupled to the high frequency mixer and amplifying a second frequency signal converted by the high frequency mixer, wherein the amplified second frequency signal is transmitted to the base station via the base station side duplexer and the donor antenna -; A detector coupled to the high output amplifier and detecting a signal amplified and output from the high output amplifier; A guard band frequency signal coupled to the detector and a high frequency mixer and controlling the high frequency mixer to output a guard band frequency signal upon isolation checking, the guard band frequency signal from the detector via at least the surface acoustic wave filter, wherein the guard band frequency A signal emitted from the donor antenna and received by the service antenna to be input to the surface acoustic wave filter to receive a detection value, and to determine the degree of isolation by comparing the detection value with a preset standard value; And An isolation attenuator that increases the system gain of the repeater by an isolation test specification in accordance with a control signal of the controller. Repeater comprising a. The method of claim 1, The detector detects a guard band frequency signal generated by the high frequency mixer from the signal converted into the second frequency signal. Repeater characterized in that. delete delete In the repeater to check the isolation, A donor antenna coupled to the base station and the wireless mobile communication network; A service antenna for communicating with a mobile terminal included in the coverage of the repeater; High frequency mixer; A surface acoustic wave filter coupled to the high frequency mixer and filtering a signal transmitted from the service antenna to a predetermined area; A detector for detecting a signal filtered from the surface acoustic wave filter; A guard band frequency signal coupled to the detector and a high frequency mixer and controlling the high frequency mixer to output a guard band frequency signal upon isolation checking, the guard band frequency signal from the detector via at least the surface acoustic wave filter, wherein the guard band frequency A signal emitted from the donor antenna and received by the service antenna to be input to the surface acoustic wave filter to receive a detection value, and to determine the degree of isolation by comparing the detection value with a preset standard value; And An isolation attenuator that increases the system gain of the repeater by an isolation test specification in accordance with a control signal of the controller. Repeater comprising a. A method of checking isolation in a repeater comprising a donor antenna, a service antenna, a high frequency mixer, a surface acoustic wave filter, a detector, a controller, and an isolation attenuator, Increasing, by the control of the controller, the isolation attenuator to increase the system gain of the repeater by the isolation inspection specification; Controlling, by the controller, the high frequency mixer to output a guard band frequency signal; Radiating, by the donor antenna, a guard band frequency signal output by the high frequency mixer; The service antenna receiving a guard band frequency signal radiated from the donor antenna; The surface acoustic wave filter filtering a guard band frequency signal received by the service antenna; Detecting the guard band frequency signal filtered by the surface acoustic wave filter; Receiving, by the controller, a detection value detected by the detector; And Determining, by the controller, the degree of isolation by comparing the received detection value with a preset standard value. Isolation degree inspection method comprising a. The method of claim 6, The detecting of the guard band frequency signal filtered by the surface acoustic wave filter may include detecting a guard band frequency signal generated by the high frequency mixer. Isolatedness test method characterized in that. delete delete

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