KR20160075253A - Multi-band return signal measurement device - Google Patents

Abstract

The present invention relates to a reflected signal measurement device and, more specifically, to a multiband reflected signal measurement device. The reflected signal measurement device according to an embodiment of the present invention comprises: a signal generation unit for generating and outputting a plurality of reference signals by converting a frequency according to a preset method; a coupling unit for separately outputting the inputted reference signals as a first output signal and a second output signal and outputting a reflected signal which is reflected back according to the output of the first output signal; a signal detection unit for generating and outputting output signal information corresponding to the size of the second output signal and generating and outputting reflected signal information corresponding to the size of the reflected signal; and a control unit for determining whether the reflected signal measurement device normally operates by using the output signal information and the reflected signal information. Therefore, the reflected signal measurement device of the present invention can monitor whether impedance matching is performed for all frequency bands in use.

Description

{Multi-band return signal measurement device}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a reflected signal measuring apparatus, and more particularly, to a multi-band reflected signal measuring apparatus.

Impedance matching refers to all the ways to reduce the reflection due to the impedance difference of two different connections when connecting one input and one output. This impedance matching is used to reduce the reflection loss of the antenna when a wireless signal is output from the antenna when transmitting a wireless signal in the mobile communication terminal.

In general, all communication circuits are given a characteristic impedance. Here, the characteristic impedance means an impedance based on one circuit or system. Therefore, by setting any one of these specific impedance standards, it is possible to have compatibility at the input and output ends of the communication circuit. This is because, when setting the reference impedance of all the communication circuits, it is possible to optimize the reflection loss without special impedance matching. This is also true for mobile communication repeaters. The impedance matching circuit used in the mobile communication repeater is also configured to optimize the return loss based on the characteristic impedance of the antenna of the mobile communication repeater.

However, the antenna used in the wireless communication device is generally manufactured to correspond to a specific impedance standard, but the impedance of the antenna is changed according to the process of installing the antenna and / or the environment in which the wireless communication device is installed. In this case, the wireless communication device must perform impedance matching again according to the impedance change of the antenna.

In order to solve such a problem, Korean Patent Registration No. 20-0432984 (hereinafter referred to as "Prior Art") discloses a transmission line measuring and diagnosing device for a mobile communication repeater. That is, according to the prior art, it is possible to continuously monitor the matching state between the transmission line and the antenna of the repeater equipment in operation by monitoring whether the antenna and the transmission line of the repeater of the mobile communication system operate normally.

However, according to the prior art, it is impossible to monitor whether all the frequency bands used in the wireless communication apparatus are normally operated. That is, in a multi-band mobile communication system, signals of various frequency bands are used in one device. According to the prior art, it is not known what frequency band the impedance matching with the antenna should be performed.

Korean Patent No. 20-0432984

In order to solve the above-described problems, the present invention provides a multi-band reflected signal measuring apparatus capable of monitoring impedance matching for all frequency bands in use.

According to an aspect of the present invention, there is provided a signal processing apparatus including: a signal generator for converting a frequency according to a predetermined method to generate and output a plurality of reference signals; A combining unit for separating each of the plurality of input reference signals into a first output signal and a second output signal and outputting a reflected signal reflected by the output of the first output signal; A signal detector for generating and outputting output signal information corresponding to the magnitude of the second output signal and generating and outputting reflection signal information corresponding to the magnitude of the reflected signal; And a control unit for determining whether the normal operation is performed using the output signal information and the reflection signal information.

Here, the reflection signal measuring apparatus may further include a first switch unit for switching the main signal and the reference signal according to the first switching signal, wherein the control unit outputs the first switching signal when the predetermined event occurs can do.

The reflection signal measuring apparatus may further include a second switch unit for switching the second output signal to be output to the signal detecting unit according to a second switching signal, 2 switching signals.

The apparatus further includes a third switch unit for switching the reflection signal to be output to the signal detection unit according to a third switching signal, wherein when the output signal information is input, It is possible to output a switching signal.

The apparatus further includes a fourth switch unit for switching the reflection signal to be output to the signal detector according to a fourth switching signal, wherein when the output signal information is input, It is possible to output a switching signal.

The control unit may output a fifth switching signal when the reflection signal information is input, and the fourth switch unit may output the output of the reflection signal to the signal detection unit when the fifth switching signal is input, So that an output signal is outputted to the signal detecting unit.

The signal generator may generate the reference signal corresponding to a plurality of predetermined frequencies.

Also, the reference signal may be a signal in which a plurality of signals having different frequencies are generated at predetermined time intervals.

In addition, the controller may set a threshold value to correspond to the output signal information.

In addition, the controller may determine the abnormal operation when the reflection signal information exceeds the threshold value.

In addition, the control unit may determine whether the abnormal operation is performed for each frequency using the order of the sequentially inputted reflection signal information.

The multi-band reflection signal measuring apparatus according to the present invention can monitor whether or not impedance matching is performed on all frequency bands in use.

1 is a block diagram of a reflection signal measuring apparatus according to an embodiment of the present invention;
FIG. 2 illustrates a reference signal that is sequentially generated according to an embodiment of the present invention. FIG.
FIG. 3 illustrates reflection signal information sequentially input according to an embodiment of the present invention; FIG.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. In the following description of the present invention, a detailed description of related art may be omitted if it is determined that the gist of the present invention may be blurred.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof. Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a reflection signal measuring apparatus according to an embodiment of the present invention.

Referring to FIG. 1, a reflection signal measuring apparatus 100 according to an embodiment of the present invention includes a controller 110, a signal generator 120, a first switch 130, a coupler 140, A switch 170, a third switch 160, a load 170, a fourth switch 180, a signal detector 190, and an antenna 195. The reflection signal measuring apparatus 100 includes all the radio communication apparatuses for measuring a reflection signal to determine whether or not impedance matching with an antenna unit 195 including a mobile communication repeater, a base station, and the like is performed. Hereinafter, operation of each component of the reflected signal measurement apparatus 100 according to an embodiment of the present invention will be described in detail with reference to FIG.

The reflected signal measuring apparatus 100 may be set as follows before measuring the reflected signal. First, the first switch unit 130 may be preset to output a main signal to the coupling unit 140. Here, the main signal is a signal input through a down link, and may be a signal to be finally transmitted to the mobile communication terminal. Therefore, the signal generator 120 and the coupling unit may be disconnected. Second, the second switch unit 150 and the third switch unit 160 may be set in advance so that a signal input from the coupling unit 140 is connected to the load 170. That is, the coupling unit 140 can output a part of the main signal to the second switch unit 150, and the second switch unit 150 can output a part of the main signal input to the load 170. [ The coupling unit 140 may output the reflected signal reflected by the main signal to the third switch unit 160 and the third switch unit 160 may output the input reflected signal to the load 170 can do. Thus, the load 170 can consume a part of the incoming main signal and / or a reflected signal according to the output of the main signal. Third, the fourth switch 180 may be connected to the second switch 150 and the signal detector 190, and may be disconnected from the third switch 160 and the signal detector 190.

At this time, the controller 110 generates a reference signal generating signal when a predetermined event occurs, and outputs the generated reference signal to the signal generating unit 120, and may generate the first switching signal and output the generated first switching signal to the first switch unit 130. Here, when a preset event is generated, it may mean a case where a predetermined time has come, a case where an administrator has operated to measure a reflection signal, and the like, in which a reflection signal needs to be measured. For example, it is assumed that the reflection signal is preset to be measured at 4:00 am. At this time, the control unit 110 generates a reference signal generation signal at 4:00 am, outputs the signal to the signal generation unit 120, and generates the first switching signal and outputs the first switching signal to the first switch unit 130. As another example, it is assumed that the manager manipulates an input unit (not shown) of the reflected signal measuring apparatus 100 to measure the reflected signal. The control unit 110 generates a reference signal generation signal and outputs the reference signal generation signal to the signal generation unit 120. The reference signal generation unit 120 generates a reference signal generation signal when the reflection signal measurement signal is input, And generates a switching signal and outputs the switching signal to the first switch unit 130.

The first switch unit 130 may switch the main signal and the reference signal when the first switching signal is input. The first switch unit 130 may output only one of the main signal and the reference signal to the combining unit 140. When the first switching signal is input, can do. Here, the reference signal may refer to a signal generated by the signal generator 120 to measure a reflected signal. Therefore, when the switching signal is inputted, the first switch unit 130 releases the connection of the downlink transmission path and the coupling unit 140, connects the signal generation unit 120 and the coupling unit 140, 140, respectively.

The control unit 110 may generate a second switching signal and output the second switching signal to the second switch unit 150 when a predetermined event occurs. The second switch unit 150 may switch the signal input from the combining unit 140 to be output to the fourth switch unit 180 (not the load 170) when the second switching signal is input.

When the reference signal generation signal is input, the signal generation unit 120 generates a reference signal by converting the frequency according to a predetermined method. That is, the signal generator 120 may generate a reference signal corresponding to a plurality of preset frequencies. For example, the signal generator 120 may generate a reference signal corresponding to a plurality of predetermined frequencies. That is, it is assumed that the signal generator 120 is preset to generate a reference signal corresponding to each of A [KHz], B [KHz], and C [KHz] when the reference signal generating signal is input C are different from each other). At this time, the signal generating unit 120 may generate a signal corresponding to A [KHz], a signal corresponding to B [KHz], and a signal corresponding to C [KHz], respectively, as reference signals. Thus, the reference signal may be a plurality of signals rather than a single signal. Also, a plurality of signals included in the reference signal may be simultaneously generated and output simultaneously, or may be generated at predetermined time intervals and sequentially output. A plurality of phase-locked loops (PLLs) may be included in the signal generator 120 when a plurality of signals included in the reference signal are simultaneously generated and output simultaneously.

For example, the signal generating unit 120 may generate a reference signal including a plurality of signals having different frequencies. That is, the signal generator 120 generates a signal corresponding to a preset frequency (hereinafter, referred to as a reference frequency), and then sweeps a signal corresponding to the reference frequency at a preset frequency to generate a reference signal You may. It is assumed that the reference frequency is D [KHz] and the preset frequency for sweeping is E [KHz]. At this time, when the reference signal generation signal is input, the signal generator 120 generates a signal corresponding to D [KHz] and generates a signal corresponding to 'D + E' [KHz] When a predetermined time elapses again, a signal corresponding to 'D + E + E' [KHz] can be generated. Since the reference signals generated in this manner are generated with a time difference, they can be sequentially output in the order of generation. Hereinafter, the operation of the signal generator 120 to generate the reference signal will be described in more detail with reference to FIG.

2 is a diagram illustrating a reference signal that is sequentially generated according to an exemplary embodiment of the present invention.

Referring to FIG. 2, a case where a plurality of signals having different frequencies at predetermined time intervals are generated as reference signals is exemplified. When the reference signal generating signal is input, the signal generating unit 120 generates reference signals corresponding to A [KHz], B [KHz], and C [KHz] at predetermined time intervals. The signal generating unit 120 may generate and output a signal corresponding to A [KHz] when a predetermined time t elapses after the signal is generated. Also, the signal generator 120 can generate and output a signal corresponding to C [KHz] when a predetermined time (t) elapses. At this time, voltages V1 of signals corresponding to A [KHz], B [KHz], and C [KHz] may all be the same. However, a reference signal having a voltage higher than that of a certain frequency may be required. In this case, the signal generating unit 120 may generate a signal having a voltage higher than that of the other frequencies.

Referring back to FIG. 1, the signal generator 120 may output the generated reference signal to the combiner 140. The combining unit 140 may separate the input reference signal into a first output signal and a second output signal. Here, the first output signal is a signal radiated to the outside through the antenna unit 195, and the second output signal is a signal to be compared with the reflected signal. Here, the coupling unit 140 may include a coupler, thereby separating and outputting the first output signal and the second output signal. Therefore, the coupling unit 140 can output the first output signal to the antenna unit 195 and radiated to the outside, and output the second output signal to the second switch unit 150. Since the operation of the coupling unit 140 to separate the first output signal and the second output signal and output the second output signal to the second switch unit 150 is obvious to those skilled in the art, .

The second switch unit 150 may output the second output signal to the fourth switch unit 180 according to the input of the second switching signal and the fourth switch unit 180 may output the second output signal, And output it to the detection unit 190.

When the second output signal is input, the signal detector 190 generates output signal information corresponding to the magnitude of the second output signal, and outputs the generated signal information to the controller 110. That is, the signal detection unit 190 can detect the voltage level of the second output signal and generate output signal information, and output the generated output signal information to the control unit 110.

The control unit 110 can set the threshold value Vth using the input output signal information. When the signal generator 120 sequentially outputs a plurality of signals having different frequencies, the controller 110 sequentially receives the output signal information. At this time, the controller 110 may set the threshold value Vth corresponding to each output signal information sequentially input. Since each of the plurality of signals included in the reference signal may have different magnitudes of voltages, and accordingly, the threshold value needs to be set differently.

Also, when the output signal information is input, the controller 110 may generate a third switching signal and output the third switching signal to the third switch unit 160. The third switching unit 130 may switch the signal input from the combining unit 140 to be output to the fourth switching unit 180 (not the load 170) when the third switching signal is inputted. Also, when the output signal information is input, the controller 110 generates a fourth switching signal and outputs the fourth switching signal to the fourth switch 180. The fourth switch 180 is turned on so that the signal inputted from the third switch 160 is outputted to the signal detector 190 when the fourth switch 180 is inputted (not the signal inputted from the second switch 150) Can be switched. Since the output signal information for the second output signal has already been generated, the voltage level of the reflected signal corresponding to the second output signal must be detected.

That is, the coupling unit 140 may output the first output signal to the antenna unit 195 to be radiated to the outside as described above. At this time, the first output signal may not be completely radiated through the antenna unit 195, and a signal (i.e., a reflected signal) returned to the coupling unit 140 without being radiated may be output to the third switch unit 160 have. Since the operation of the coupling unit 140 to output the reflection signal to the third switch unit 160 is obvious to those skilled in the art, a detailed description thereof may be omitted. Accordingly, the third switch unit 160 can output the inputted reflection signal to the fourth switch unit 180, and the fourth switch unit 180 can output the inputted reflection signal to the signal detection unit 190 have.

The signal detector 190 generates reflection signal information corresponding to the magnitude of the reflection signal and outputs the reflection signal information to the controller 110 when the reflection signal is input. That is, the signal detector 190 can generate the reflection signal information by detecting the voltage level of the reflection signal, and can output the generated reflection signal information to the controller 110.

Accordingly, the control unit 110 determines whether the reflection signal measuring apparatus 100 operates normally (that is, whether the impedance matching is correct in all of the plurality of frequency bands) using the input signal information and the reflection signal information . For example, the control unit 110 compares the set threshold value with the reflection signal information corresponding to the threshold value, and if the reflection signal information exceeds the threshold value, the reflection signal measuring apparatus 100 is operating abnormally (that is, Impedance matching did not occur).

Meanwhile, the control unit 110 can determine whether or not an abnormal operation is performed for each frequency using the order of sequentially inputted reflection signal information. For example, it is assumed that the reference signal includes three signals corresponding to A [KHz], B [KHz], and C [KHz], respectively, and three signals are output at predetermined intervals of time t . That is, it is assumed that B [KHz] is output after the A [KHz] signal is output, and finally, a C [KHz] signal is output. At this time, the controller 110 determines that the first output signal information (hereinafter, referred to as first output signal information) corresponds to the A [KHz] signal and the second received output signal information (Hereinafter referred to as signal information) is information corresponding to the B [KHz] signal, and finally received output signal information (hereinafter referred to as third output signal information) is information corresponding to the C [KHz] signal. Here, information on the frequency of the reference signals output sequentially may be stored in the controller 110 in advance.

Also, the control unit 110 determines that the first received reflection signal information (hereinafter referred to as first reflection signal information) is information on a reflection signal corresponding to the A [KHz] signal, the second received reflection signal information (Hereinafter referred to as second reflection signal information) is information on a reflection signal corresponding to the B [KHz] signal, and finally received reflection signal information (hereinafter referred to as third reflection signal information) is information on the C [KHz] It can be seen that it is information on the corresponding reflection signal.

Accordingly, the control unit 110 can compare the first threshold value and the first reflected signal information corresponding to the first output signal information, and compare the second threshold value and the second reflected signal information corresponding to the second output signal information And the third threshold value corresponding to the third output signal information and the third reflected signal information can be compared. When the first reflection signal information and the second reflection signal information do not exceed the corresponding threshold value but the third reflection signal information exceeds the third threshold value, the controller 110 controls the antenna 110 in the C [KHz] It can be determined that the impedance matching with the portion 195 is not performed.

3 is a diagram illustrating reflection signal information sequentially input according to an embodiment of the present invention.

Referring to FIG. 3, a case where a plurality of signals included in a reference signal have the same size and three pieces of reflection signal information are input to the controller 110 are exemplified. Since the plurality of signals included in the reference signal have the same magnitude, the magnitudes of the threshold values Vth corresponding to the three pieces of the reflection signal information are all the same. At this time, the controller 110 can know that only the third reflected signal information, which is the last of the inputted three pieces of reflected signal information, exceeds the threshold value, and the antenna unit 195, at the frequency corresponding to the third reflected signal information, It can be judged that the impedance matching is not performed.

Accordingly, the control unit 180 performs an operation such as outputting an alarm or transmitting a text message (SMS) to the terminal of the manager so that the impedance with the antenna unit 195 at a frequency corresponding to the third reflection signal information You will be able to notify the administrator that no matching has been done.

As described above, the reflection signal measuring apparatus 100 according to an embodiment of the present invention can determine whether or not impedance matching is performed on a plurality of frequencies, and thus it is possible to monitor whether impedance matching is performed on all frequency bands in use.

100: reflection signal measuring device
110:
120: Signal generator
130: first switch section
140:
150: second switch section
160: third switch section
170: Load
180: fourth switch section
190:
195:

Claims (11)

A signal generator for converting a frequency according to a preset method to generate and output a plurality of reference signals;
A combining unit for separating each of the plurality of input reference signals into a first output signal and a second output signal and outputting a reflected signal reflected by the output of the first output signal;
A signal detector for generating and outputting output signal information corresponding to the magnitude of the second output signal and generating and outputting reflection signal information corresponding to the magnitude of the reflected signal; And
A controller for determining whether a normal operation is performed using the output signal information and the reflection signal information;
And a reflected signal measuring device.
The method according to claim 1,
A first switch unit for switching between a main signal and the reference signal according to a first switching signal;
Further comprising:
Wherein the controller outputs the first switching signal when a preset event occurs.
The method according to claim 1,
A second switch for switching the second output signal to be output to the signal detector according to a second switching signal;
Further comprising:
Wherein the controller outputs the second switching signal when a preset event occurs.
The method according to claim 1,
A third switch unit for switching the reflection signal to be output to the signal detection unit according to a third switching signal;
Further comprising:
Wherein the controller outputs the third switching signal when the output signal information is input.
The method according to claim 1,
A fourth switch for switching the reflection signal to be output to the signal detector according to a fourth switching signal;
Further comprising:
Wherein the controller outputs the fourth switching signal when the output signal information is input.
6. The method of claim 5,
The control unit outputs a fifth switching signal when the reflection signal information is input,
Wherein the fourth switch unit switches the output of the reflection signal to the signal detection unit when the fifth switching signal is input and switches the second output signal to be output to the signal detection unit.
The method according to claim 1,
Wherein the signal generator generates the reference signal corresponding to a plurality of predetermined frequencies.
The method according to claim 1,
Wherein the reference signal is a signal in which a plurality of signals having different frequencies are generated at predetermined time intervals.
The method according to claim 1,
Wherein the controller sets a threshold value to correspond to the output signal information.
10. The method of claim 9,
Wherein the controller determines that the reflected signal information is abnormal if the reflected signal information exceeds the threshold value.
9. The method of claim 8,
Wherein the control unit determines whether an abnormal operation is performed for each frequency using the order of the sequentially inputted reflection signal information.

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