KR20190009148A - Apparatus for analyzing - Google Patents

Abstract

The present invention relates to an analysis apparatus and, more specifically, to an analysis apparatus for analyzing the characteristics of a device to be tested which transmits a signal. According to an embodiment of the present invention, an analysis apparatus for analyzing the characteristics of a device under test (DUT) for transmitting a signal comprises: a signal generation unit for inputting a first signal to the DUT; a spectrum analysis unit for analyzing a first signal outputted from the DUT; a network analysis unit for inputting a second signal to the DUT and comparing and analyzing a second signal outputted from the DUT with an inputted second signal; a switching module for forming a connection path of a signal among the signal generation unit, the spectrum analysis unit, the network analysis unit, and the DUT; and a control unit for controlling an operation of the switching module.

Description

[0001] APPARATUS FOR ANALYZING [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an analysis apparatus, and more particularly, to an analysis apparatus for analyzing characteristics of a test target apparatus that transmits a signal.

A spectrum analyzer or a network analyzer is mainly used for analyzing the characteristics of a communication device or a communication device (test target device) used in various communication systems and transmitting a signal.

The spectrum analyzer receives the signal input from the signal generator to the test target device, obtains the output level measurement value of the received signal, and analyzes the pulse parameter, P1dB, and the like. The spectrum analyzer is connected to the receiving channel of the device under test when the signal generator is connected to the transmission channel of the device under test and analyzes the spectrum of the transmitted signal. If the signal generator is connected to the receiving channel of the device under test, And is connected to the transmission channel to analyze the spectrum of the received signal.

In addition, the network analyzer obtains various parameters such as transfer function, reflection characteristic, and phase characteristic (scattering parameter: hereinafter referred to as 'S parameter') of the device under test. This S parameter is determined by obtaining the frequency response (voltage and phase) of the device under test resulting from a network analyzer in response to a sweep frequency signal.

Here, unlike the spectrum analyzer, the network analyzer generally consists of two ports, one of which is an input port and the other is an output port. The input port transmits a sweep frequency signal to the test subject device, and the output port receives the output signal of the test subject device. The network analyzer compares and analyzes the input signal with the output signal to measure and analyze the S parameter.

However, in order to analyze the spectrum of the transmission signal by the spectrum analyzer, the signal generator should be connected to the transmission channel of the device under test by a cable, and the spectrum analyzer should be connected to the receiving channel of the device under test by a cable. On the other hand, in order to analyze the spectrum of the received signal by the spectrum analyzer, the signal generator is connected to the receiving channel of the device under test by a cable, and the spectrum analyzer is connected to the transmission channel of the device under test .

This is also the case for network analysis by a network analyzer. That is, in order to analyze the network of the transmission signal, the input port and the output port of the network analyzer should be connected to the transmission channel and the reception channel of the device under test, respectively. To analyze the network of the received signal, It is necessary to reconnect the cable to connect to the receive and transmit channels of the device under test. In addition, in order to perform spectral analysis and network analysis sequentially, it is necessary to re-establish the cable to correspond to the analyzer.

That is, in the case of the conventional analyzing apparatus, it is necessary to separate and reconnect the test target device, the signal generating unit and the spectrum analyzing unit according to contents to be measured, or to separate and reconnect the test target device and the network analyzing unit, And the separation or reconnection process is performed by the manual operation, so that there is a problem that the measurement signal and the measurement result in a uniform state are not outputted when reconnecting. This causes a serious problem when the transmission channel and the reception channel of the test-purpose apparatus are composed of a plurality of channels, respectively.

KR 10-1730162 B1

The present invention provides an analyzer capable of analyzing signal characteristics of a device under test without changing the connection between the device under test and the analyzer having a transmission channel and a receiving channel for signal transmission.

An analyzing apparatus according to an embodiment of the present invention is an analyzing apparatus for analyzing characteristics of a device under test (DUT) that delivers a signal, comprising: a signal generating unit for inputting a first signal to the device under test; A spectrum analyzer for analyzing a first signal output from the device under test; A network analyzer for inputting a second signal to the device under test and comparing and analyzing a second signal outputted from the device under test with an inputted second signal; A switching module for forming a signal path between the signal generator, the spectrum analyzer, and the network analyzer and the test target device; And a controller for controlling operation of the switching module.

The first signal and the second signal may include an RF signal, and the first signal may have a greater intensity than the second signal.

The spectrum analyzer may analyze a specific frequency band characteristic of the first signal, and the network analyzer may analyze frequency characteristics of the second signal.

The switching module may include a first switch unit for selectively connecting a transmission channel and a reception channel of the test target device to the input port and the output port of the signal generation unit and the spectrum analysis unit or the network analysis unit have.

The switching module may switch the connection positions of the transmission channel and the reception channel of the test target device connected to the signal generating unit and the spectrum analyzing unit or may change the connection position of the test target device connected to the input port and the output port of the network analyzing unit, And a second switch unit for switching connection positions of the transmission channel and the reception channel.

The switching module may further include a third switch unit for switching a signal input path through which a signal is input to a receiving channel of the test target device and a signal output path through which a signal is output from a receiving channel of the test target device have.

And a signal attenuator disposed on the signal output path.

Wherein the test target device includes a plurality of transmission channels and a plurality of reception channels, and the switching module is configured to transmit, to an input port and an output port of the signal generation unit and the spectrum analysis unit or the network analysis unit, And a fourth switch unit for connecting a selected one of the channel and the receive channel to the receive channel.

And a chiller part connected to the device under test to maintain the device under test at a predetermined temperature, wherein the controller can control a set temperature of the chiller part.

According to the analyzing apparatus according to the embodiment of the present invention, it is possible to sequentially analyze the spectrum and the network of the transmission signal and the reception signal of the device under test without changing the connection between the device under test and the analyzer.

In addition, the spectrum analyzer and the network analyzer can be integrated to analyze all of the specific frequency band and frequency-specific characteristics of the signal through the test target device by one analyzing device that maintains the connection.

In addition, according to the analyzing apparatus according to the embodiment of the present invention, it is possible to obtain accurate and uniform analysis results by automating the spectrum and network analysis of the transmission signal and the reception signal through the device under test, .

1 is a view showing a connection structure of a general spectrum analyzer;
2 is a diagram showing a connection structure of a general network analysis apparatus;
3 schematically shows an analysis apparatus according to an embodiment of the present invention.
4 is a diagram illustrating a switching module according to an embodiment of the present invention forming a connection path of a signal for spectral analysis of a transmission signal.
5 is a diagram showing a switching module according to an embodiment of the present invention forming a connection path of a signal for spectral analysis of a received signal;
6 is a diagram illustrating a switching module according to an embodiment of the present invention forming a connection path of a signal for network analysis of a transmission signal;
7 is a diagram illustrating a switching module according to an embodiment of the present invention forming a connection path of a signal for network analysis of a received signal;

The analyzing apparatus according to the present invention presents a technical feature capable of analyzing the signal characteristics of the test target apparatus without changing the connection between the test target apparatus having the transmission channel and the receiving channel for transmitting the signal and the analyzing apparatus.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, Is provided to fully inform the user. Wherein like reference numerals refer to like elements throughout.

FIG. 1 is a view showing a connection structure of a general spectrum analyzer, and FIG. 2 is a diagram showing a connection structure of a general network analyzer.

More specifically, FIG. 1 (a) is a view showing a state in which a general spectrum analyzing apparatus analyzes a transmission spectrum, and FIG. 1 (b) is a view showing a state in which a general spectrum analyzing apparatus analyzes a receiving spectrum. 2 (a) is a view showing a general network analyzing apparatus analyzing a transmitting network, and FIG. 2 (b) is a view showing a general network analyzing apparatus analyzing a receiving network.

1 (a), when the spectrum analyzing apparatus measures and analyzes the transmission spectrum, the signal generating unit 10 outputs the signal to the transmission channel 82 of the DUT (Device Under Test) And the spectrum analyzer 20 is connected to the receiving channel 84 of the device 10 to be tested. As shown in the figure, when the test subject device 80 has a plurality of transmission channels 82 and a plurality of reception channels 84, the signal generation unit 10 generates a plurality of transmission channels 82 And the spectrum analyzer 20 is connected to one of the plurality of reception channels 84 of the device under test 80 to measure the transmission spectrum.

Generally, for spectrum analysis of a transmission signal, the signal generator 10 and the spectrum analyzer 20 are connected to the transmission channel 82 and the reception channel 84 of the device under test 80 by RF cables, respectively The spectral measurement of the transmission signal is performed such that the device under test 80 has a plurality of transmission channels 82 and a reception channel 84, , It is sequentially and repeatedly measured for each transmission channel and reception channel.

2 (a), when the reception spectrum is measured and analyzed, the signal generator 10 is connected to the reception channel 84 of the device under test 80, and the spectrum analyzer 20 And is connected to the transmission channel 82 of the device under test 80. [ If the test subject device 80 has a plurality of transmission channels 82 and a plurality of reception channels 84, the signal generation unit 10 generates one of the plurality of reception channels 84 of the device under test 80 And the spectrum analyzer 20 is connected to one of the plurality of transmission channels 82 of the device under test.

The spectrum analyzing unit 10 and the spectrum analyzing unit 20 are connected to the receiving channel 84 and the transmitting channel 82 of the device under test 80 by RF cables, And the spectrum of the received signal is measured when the device under test 80 has a plurality of transmission channels 82 and a reception channel 84, 82 and the reception channel 84 are measured in the same manner as described above.

2 (a), when analyzing and analyzing the transmission network, the network analysis unit 30 is connected to the transmission channel 82 and the reception channel 84 of the device under test 80, respectively . The network analyzer 30 includes an input port 32 for inputting a signal to the test target device 80 and an output port 34 for receiving a signal output from the test target device 80. The input port 32 of the network analysis unit 30 is connected to the transmission channel 82 of the device under test 80 and the output port 34 of the network analysis unit 30 Is connected to the receiving channel 84 of the device under test 80. [

In this case, when the test target device 80 has a plurality of transmission channels 82 and a plurality of receive channels 84, the input port 32 of the network analysis unit 30 receives a plurality of transmission And the output port 34 of the network analyzer 30 is connected to one of the plurality of receiving channels 84 of the test subject device 80 and is connected to one of the channels 82, The transmission channel 82 and the reception channel 84 are sequentially connected to measure a network such as a scattering parameter (S parameter) of a transmission signal.

2B, when the reception network is measured and analyzed, the network analysis unit 30 is connected to the reception channel 84 and the transmission channel 82 of the device under test 80, respectively . That is, when measuring and analyzing the receiving network, the input port 32 of the network analyzer 30 is connected to the receiving channel 84 of the test target device 80 and the output port 34 of the network analyzer 30 Is connected to the transmission channel 82 of the device under test 80. [ In this case, when the test target device 80 has a plurality of transmission channels 82 and a plurality of reception channels 84, the input port 32 of the network analysis unit 30 receives a plurality of The output port 34 of the network analyzer 30 is connected to one of the plurality of transmission channels 82 of the test target device 80 and the output port 34 of the network analyzer 30 is connected to one of the plurality of transmission channels 82 of the test target device 80, The transmission channel 82 and the reception channel 84 are sequentially connected to measure a network such as a scattering parameter (S parameter) and a noise factor (NF) of a received signal.

Generally, in order to perform a spectrum analysis or a network analysis of a transmission signal or a reception signal, the test subject device 80 is separated from the signal generation unit 10 and the spectrum analysis unit 20 according to contents to be measured and each channel It is troublesome to disconnect and reconnect the test target device 80 and to disconnect and reconnect the test target device 80 and the network analysis unit 30. Such a separation or reconnection process is performed manually, There is a problem that the measurement signal and the measurement result in a uniform state are not outputted at the time of connection.

3 is a schematic view of an analysis apparatus according to an embodiment of the present invention.

3, an analysis apparatus according to an embodiment of the present invention is an analyzing apparatus for analyzing characteristics of a test object device 800 that transmits a signal, and is configured to input a first signal to the test object apparatus 800 A signal generating unit 100; A spectrum analyzer 200 for analyzing a first signal output from the test object device 800; A network analyzer 300 for inputting a second signal to the device under test 800 and for comparing and analyzing a second signal output from the device under test 800 with an input second signal; A switching module 400 for forming a signal connection path between the signal generator 100, the spectrum analyzer 200 and the network analyzer 300 and the device under test 800; And a control unit 500 for controlling the operation of the switching module 400.

The test target device 800 means a transmitting / receiving device such as a communication device or a communication device used in various communication systems for transmitting signals. The device under test 800 includes the transmission channel 820 and the reception channel 840 and inputs and outputs the signals through the transmission channel 820 and the reception channel 840. The characteristics of the device under test 800 are analyzed by the spectrum analyzer 200 and the network analyzer 300.

The signal generating unit 100 generates a first signal and inputs the generated first signal to the test object device 800. [ That is, the first signal may include an RF signal. For example, the first signal may receive an RF signal output command including a specific frequency band and an output level setting value from the controller 500, , And outputs an RF signal at a specific frequency and output level setting value.

The spectrum analyzer 200 receives a signal input from the signal generator 100 and output from the test target device 800, and obtains an output level measurement value of the signal. Here, the spectrum analyzer 200 can measure the spectrum or the frequency domain of the RF signal and display it on the screen. That is, the spectrum analyzer 200 receives a signal input to the test object device 800 from the signal generator 100, obtains an output level measurement value of the received signal, and outputs a pulse parameter, P1dB, And analyzes the specific frequency band characteristic of the first signal.

The network analyzer 300 inputs the second signal to the test object device 800 and compares and analyzes the second signal output from the test object device 800 with the input second signal. The network analyzer 300 includes an input port 320 for inputting a second signal to the test target device 800 and an output port 340 for receiving a second signal output from the test target device 800, . ≪ / RTI > The input port 320 transmits a sweep frequency signal to the test subject device 800, and the output port 340 receives the output signal of the test subject device 800. The network analyzer 300 compares and analyzes the input signal with the output signal to obtain a second signal such as a transfer function, a reflection characteristic, and a phase characteristic (hereinafter, referred to as 'S parameter') of the device under test Can be analyzed.

Here, the first signal input from the signal generator 100 and the second signal input from the input port 320 of the network analyzer 300 may include an RF signal, and the first signal may include a second signal It can have a large intensity. Accordingly, the spectrum analyzer 200 can analyze the output characteristics of the first signal in a specific frequency band, and the network analyzer 300 analyzes the second signal input in the entire frequency band and the second signal outputted S parameter, NA and the like can be measured by comparative analysis. The detailed structure of the spectrum analyzing unit 200 for analyzing the spectrum characteristics of the signal and the network analyzing unit 300 for analyzing the network characteristics is well known and a detailed description thereof will be omitted.

The switching module 400 forms a connection path of signals between the signal generator 100, the spectrum analyzer 200 and the network analyzer 300 and the test target device 800. That is, the switching module 400 connects the signal generator 100 and the spectrum analyzer 200 to the transmission channel 820 and the reception channel 840 of the device under test 800, And connects the input port 320 and the output port 340 of the device under test 800 to the transmission channel 820 and the reception channel 840 of the device under test 800. [ The specific contents of the switching module 400 forming the connection path of each signal in performing the spectrum analysis of the transmission signal, the spectrum analysis of the reception signal, the network analysis of the transmission signal, and the network analysis of the reception signal are shown in FIGS. Will be described later.

The control unit 500 controls the operation of the switching module 400. That is, the control unit 500 includes a PC (Personal Computer) or the like and outputs the signal generator 100 and the spectrum analyzer 200 to the transmission channel 820 and the reception channel 840 of the device under test 800, respectively And the input port 320 and the output port 340 of the network analysis unit 300 are connected to the transmission channel 820 and the reception channel 840 of the device under test 800, Respectively, or to be connected to the opposite channels. In addition, it goes without saying that the controller 500 can control the overall configuration of the analyzer according to the embodiment of the present invention.

The analyzing apparatus according to the embodiment of the present invention may further include a chiller connected to the test target device 800 to maintain the test target device 800 at a set temperature . The chiller section is configured to maintain the temperature of the test subject chiller at the set temperature, and the temperature of the test subject chiller can be adjusted by circulating the cooling fluid. To this end, the chiller part may include a supply line for supplying a cooling fluid having a predetermined temperature and a discharge line for discharging the cooling fluid. The chiller part can be connected to the test object device 800 by a chiller cable, and the set temperature of the chiller part can be controlled by the control part 500. [

Hereinafter, the operation of the analyzing apparatus according to the embodiment of the present invention will be described.

First, the connection of the analyzer is checked to analyze the device under test 800. That is, the connection procedure of the signal generator 100, the spectrum analyzer 200, and the network analyzer 300 is checked before automatically measuring the device under test 800. If it is determined that the connection is poor, The spectrum analysis unit 200, and the network analysis unit 300 of the base station 100, In addition, if the analyzer includes a chiller part, the connection status of the chiller part can also be confirmed here, and the connection status of the chiller part can be checked whether or not the temperature setting of the chiller part is normally performed. Here, if the temperature of the chiller unit is not controlled at the set temperature, the connection status of the USB connecting the controller 500 and the chiller unit is checked.

When the signal generator 100, the spectrum analyzer 200, the network analyzer 300 and the chiller unit are normally connected, the signal generator 100, the spectrum analyzer 200, and the network analyzer 300 calibration is performed. The calibration process corrects the errors of the signal generator 100, the spectrum analyzer 200, and the network analyzer 300 by connecting an impedance that is already known instead of the test target device 800 to be analyzed. The known impedance is called standard impedance. The calibration process is performed using several error items. Therefore, various kinds of standard impedance are required, and the specific calibration process depends on the connected standard impedance. In this way, the calibration process is performed to check the validity. If the calibration is not normally performed, check the cable connection and re-tighten the cable to perform the recalibration process.

Thereafter, when the calibration process is normally performed, the testing device 800 is connected to the analyzing device and the chiller part is connected to the testing device 800. Then, the connection path of the switching module 400 is formed according to the measurement or analysis contents to analyze characteristics of the test object device 800. If the test object device 800 is not normally analyzed, the connection state of the test object device 800 is checked. Even if the test object device 800 is normally connected, The test subject device 800 is replaced when the analysis of the test subject device 800 is not normally performed and the test subject device 800 is reconnected and analyzed when the test subject device 800 is not normally connected.

Finally, when the analysis of the device under test 800 is completed, the analysis result is outputted and the analysis process is completed.

Hereinafter, a configuration for forming a connection path of signals according to measurement or analysis contents by the switching module 400 will be described in detail with reference to FIGS. 4 to 7. FIG.

FIG. 4 is a diagram illustrating a switching module according to an embodiment of the present invention forming a signal path for spectrum analysis of a transmission signal. FIG. 5 is a block diagram of a switching module according to an embodiment of the present invention. And forms a connection path of a signal for analysis. 6 is a diagram illustrating a switching module forming a connection path of a signal for network analysis of a transmission signal according to an embodiment of the present invention. FIG. 7 is a block diagram of a switching module according to an embodiment of the present invention, FIG. 2 is a diagram showing a state in which a connection path of a signal is formed for network analysis of FIG.

Here, in order to analyze a spectrum according to a transmission signal and a reception signal, or to analyze a network according to a transmission signal and a reception signal, the switching module 400 includes a first switch 410, a second switch 420, 3 switch unit 430 and a fourth switch unit 440. [

The first switch unit 410 connects the transmission channel 820 and the reception channel 840 of the test target device 800 to the signal input unit 100 and the spectrum analyzer 200, The second switch unit 420 is configured to selectively connect the transmission channel 820 and the reception channel 840 of the device under test 800 to the input port 320 and the output port 340, The control unit 300 may switch the connection positions of the transmission channel 820 and the reception channel 840 of the test target device 800 connected to the signal input unit 100 and the spectrum analyzer 200, And a connection position between the transmission channel 820 and the reception channel 840 of the test object device 800 connected to the port 320 and the output port 340. [

The third switch unit 430 outputs a signal from the signal input path through which the signal is inputted to the receiving channel 840 of the device under test 800 and the receiving channel 840 of the device 800 under test And the fourth switch unit 440 is a configuration for switching the signal output paths between the test subject device 800 and the test subject device 800. When the test subject device 800 includes a plurality of transmission channels 821 and 822 and reception channels 841 and 842, A plurality of transmission channels 821 and 822 of the test target device 800 are connected to the input port 320 and the output port 340 of the input unit 100 and the spectrum analyzer 200 or the network analyzer 300, (821 in the figure) and a reception channel (841 in the figure) among the reception channels 821 and 822, respectively.

A signal generated from the signal generator 100 is input 820 to a transmission channel of the device under test 800 and a signal from a reception channel 840 of the device 800 The output signal should be input to the spectrum analyzer 200.

4, the first switch unit 410 performs a switching operation so that the transmission channel 820 and the reception channel (not shown) of the device under test 800 are transmitted to the signal input unit 100 and the spectrum analyzer 200, 840). The second switch unit 420 receives the signal generated from the signal generator 100 through the transmission channel 820 of the device under test 800 and the signal from the reception channel 840 of the device under test 800 Since the output signal is input to the spectrum analyzer 200, the path of the first signal is maintained.

The first signal is generated from the signal generator 100 by the first switch unit 810 and the second switch unit 820 and transmitted to the transmission channel 820 and the reception channel 840 The path connected to the receiving channel 840 of the test target device 800 to prevent the test target device 800 from being damaged and to assure the degree of isolation of the signal can be transmitted to the spectrum analyzer 200 And may include a signal input path through which a signal is input and a signal output path through which a signal is output. Here, on the signal output path, a signal attenuator 600 for attenuating the output of the signal may be provided. The reason why the signal attenuation unit 600 is provided on the signal output path is that the signal output from the receiving channel 840 of the device under test 800 can have high output characteristics, It is possible to cause a back power of the signal on the signal output path and damage the device under test 800. [ On the other hand, in the case of the signal input path, since the input signal is an output-controlled signal, there is no need to provide a separate signal attenuator 600.

Also, the device under test 800 may include a plurality of transmit channels 821, 822 and receive channels 841, 842. In this case, the fourth switch unit 440 is connected to the input port 320 and the output port 340 of the signal generator 100, the spectrum analyzer 200 or the network analyzer 300, The transmission channel 821 and the reception channel 841 of the selected one of the plurality of transmission channels 821 and 822 and the reception channels 841 and 842 can be connected. 4, a first signal is input to and output from the first channel (ch1) 821 of the transmission channel and the first channel (ch1) 841 of the reception channel. However, the fourth switch unit 440 The test subject device 800 can be switched to the second channel (ch2) 822 of the transmission channel or the second channel (ch2) 842 of the receiving channel by operation, It is natural that the number of switch elements included in the fourth switch part 440 or the number of connection terminals can be increased and applied even when the reception channel is included.

On the other hand, in order to analyze the spectrum of the received signal, a signal generated from the signal generating unit 100 is input to a receiving channel 840 of the device under test 800, The output signal should be input to the spectrum analyzer 200.

5, the first switch unit 410 operates as shown in FIG. 5 so that the reception channel 840 and the transmission channel 820 of the device under test 800 are transmitted to the signal input unit 100 and the spectrum analyzer 200, Lt; / RTI > The second switch unit 420 receives the signal generated from the signal generating unit 100 as the reception channel 840 of the device under test 800 and the signal from the transmission channel 820 of the device under test 800 The output signal is input to the spectrum analyzer 200, so that the movement path of the first signal is switched. Here, since the first signal is input to the receiving channel 840 of the device under test 800, the third switch 430 is switched so that the first signal passes through the signal input path.

The network analysis of the transmission signal may be performed by inputting a signal generated from the input port 320 of the network analysis unit 300 to the transmission channel 820 of the test target device 800, The signal output from the receiving channel 840 should be input to the output port 340 of the network analyzer 300.

The first switch unit 410 operates as shown in FIG. 6 to transmit the transmission channel 820 of the test target device 800 to the input port 320 and the output port 340 of the network analyzer 300, And the reception channel 840. The second switch unit 420 receives the signal generated from the input port 320 of the network analysis unit 300 as the transmission channel 820 of the test target device 800, Since the signal output from the receiving channel 840 is input to the output port 340 of the network analyzer 300, the path of the second signal is maintained. Here, since the second signal is outputted from the receiving channel 840 of the device under test 800, the third switch 430 is switched so that the second signal passes through the signal output path.

In order to analyze the network of the received signal, a signal generated from the input port 320 of the network analyzer 300 is input to the receiving channel 840 of the test target device 800, The signal output from the transmission channel 820 should be input to the output port 340 of the network analysis unit 300.

The first switch unit 410 operates as shown in FIG. 7 to transmit the reception channel 840 of the test target device 800 to the input port 320 and the output port 340 of the network analysis unit 300, And the transmission channel 820 are connected to each other. The second switch unit 420 receives the signal generated from the input port 320 of the network analyzer 300 as the receive channel 840 of the test target device 800 and outputs the signal Since the signal output from the transmission channel 820 is input to the output port 340 of the network analysis unit 300, the path of the second signal is switched. Here, since the second signal is outputted from the receiving channel 840 of the device under test 800, the third switch unit 340 is switched so that the second signal passes through the signal output path.

As described above, according to the analyzing apparatus according to the embodiment of the present invention, the spectrum and the network of the transmission signal and the reception signal of the test target device can be sequentially analyzed without changing the connection between the test target device and the analysis device.

In addition, the spectrum analyzer and the network analyzer can be integrated to analyze all of the specific frequency band and frequency-specific characteristics of the signal through the test target device by one analyzing device that maintains the connection.

In addition, according to the analyzing apparatus according to the embodiment of the present invention, it is possible to obtain accurate and uniform analysis results by automating the spectrum and network analysis of the transmission signal and the reception signal through the device under test, .

While the preferred embodiments of the present invention have been described and illustrated above using specific terms, such terms are used only for the purpose of clarifying the invention, and the embodiments of the present invention and the described terminology are intended to be illustrative, It will be obvious that various changes and modifications can be made without departing from the spirit and scope of the invention. Such modified embodiments should not be individually understood from the spirit and scope of the present invention, but should be regarded as being within the scope of the claims of the present invention.

100: Signal generator 200: Spectrum analyzer
300: network analysis unit 320: input port
340: output port 400: switching module
410: first switch unit 420: second switch unit
430: third switch part 440: fourth switch part
500: control unit 800: test target device
820: Transmission channel 840: Receive channel

Claims (9)

An analysis device for analyzing characteristics of a device under test (DUT) that transmits a signal,
A signal generator for inputting a first signal to the device under test;
A spectrum analyzer for analyzing a first signal output from the device under test;
A network analyzer for inputting a second signal to the device under test and comparing and analyzing a second signal outputted from the device under test with an inputted second signal;
A switching module for forming a signal path between the signal generator, the spectrum analyzer, and the network analyzer and the test target device; And
And a controller for controlling operation of the switching module.
The method according to claim 1,
Wherein the first signal and the second signal comprise an RF signal,
Wherein the first signal has a greater intensity than the second signal.
The method of claim 2,
Wherein the spectrum analyzer analyzes a specific frequency band characteristic of the first signal,
And the network analyzer analyzes frequency-specific characteristics of the second signal.
The method according to claim 1,
The switching module includes:
And a first switch unit for selectively connecting a transmission channel and a reception channel of the test target device to the input port and the output port of the signal generator and the spectrum analyzer or the network analyzer.
The method of claim 2,
The switching module includes:
A transmission channel of the test target device connected to the signal generator and the spectrum analyzer and a connection channel between the transmission channel and the reception channel of the test target device connected to the input / And a second switch unit for switching a connection position of the first switch unit.
The method of claim 2,
The switching module includes:
And a third switch unit for switching between a signal input path through which a signal is input to the receiving channel of the test target device and a signal output path through which the signal is output from the receiving channel of the test target device.
The method of claim 6,
And a signal attenuator disposed on the signal output path.
The method of claim 2,
Wherein the test target device includes a plurality of transmission channels and a plurality of reception channels,
The switching module includes:
A fourth switch for connecting a receiving channel and a selected one of a plurality of transmission channels and a receiving channel of the test target device to an input port and an output port of the signal generator and the spectrum analyzer or the network analyzer; Further comprising:
The method according to claim 1,
And a chiller part connected to the device under test to maintain the device under test at a set temperature,
Wherein the control unit controls the set temperature of the chiller unit.

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