KR101652281B1 - System and method for measuring passive inter modulation - Google Patents

Abstract

The present invention relates to a system and a method for measuring a passive inter modulation (PIM). The system comprises: N PIM measurement devices (where N is a positive integer) each having one end connected to an antenna for measuring the PIM, interface units which are respectively included in the N PIM measurement devices; and a control device which is connected to the other end of each of the N PIM measurement devices and each of the interface units to control operations thereof. According to the present invention, it is possible to individually or simultaneously control a plurality of PIM measurement devices connected to an RF component including a plurality of ports, thereby simply measuring the PIM of the RF component such as an antenna. Since it is possible to automatically output a PIM measurement result measured by the PIM measurement devices, the measurement result need not be recorded in full.

Description

TECHNICAL FIELD [0001] The present invention relates to a PIM measuring system,

The present invention relates to a PIM measurement system and method, and more particularly, to a PIM measurement system and method including one control device capable of controlling N PIM measurement devices individually or simultaneously.

 PIM (Passive Intermodulation) is a phenomenon in which, when two or more frequency signals are input to a passive element, unintended other frequency signals are generated in addition to two or more signals inputted, an antenna using multiple frequency bands Which is a common phenomenon in RF components such as RF. However, since the quality of the wireless communication deteriorates and the wireless communication itself is seriously disconnected, it is necessary to measure the PIM in advance and to solve the problems.

For PIM measurement, a PIM measurement device must be connected to a port of an RF component. If only one port is connected to one PIM measurement device, plural PIM measurement devices are also required if plural ports exist in an RF component. In addition, since the RF parts such as the recent antennas transmit and receive signals in multiple frequency bands, the number of ports increases. In this case, a plurality of PIM measuring devices for measuring PIM are indispensably required, There is a problem in that it is inconvenient to record the result individually after measuring the PIM. For example, if there are two PIM measurement devices, two control devices must also be connected to control the PIM measurement device individually, which inevitably increases the size of the entire PIM measurement system.

Therefore, in the present invention, a new PIM measurement system and method in which a plurality of PIM measurement devices can be controlled individually or simultaneously by one control device, and the PIM can be measured, the measurement result can be automatically output, We will propose.

Korean Registered Patent No. 10-1148192 (May 15, 2012)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a reduced-size PIM measurement system and method that includes a single control device capable of individually or simultaneously controlling a plurality of PIM measurement devices connected to RF components including a plurality of ports .

It is another object of the present invention to provide a PIM measurement system and method that can be automatically output without recording the measurement results measured by a plurality of PIM measurement devices.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.

A PIM measurement system according to an embodiment of the present invention includes N (N is a positive integer) PIM measuring device, one end of which is connected to an antenna for PIM measurement, an interface part separately included in the N PIM measuring devices, And a control unit connected to the other end of the N PIM measurement apparatuses and the interface unit to control the operation. According to the present invention, a plurality of PIM measuring devices connected to RF parts including a plurality of ports can be controlled individually or simultaneously, so that it is possible to easily measure a PIM of an RF part such as an antenna, The PIM measurement result is automatically output, so that it is not necessary to record the measurement result one by one.

The interface unit may be an MCU (Micro Control Unit), and may transmit and receive data including a set value for PIM measurement with the control unit. The interface unit and the control unit may be an Ethernet line, bluetooth, USB, RS232 It may be connected through either one.

In addition, the N (N is a positive integer) is the number of frequency bands of a signal transmitted / received by the antenna for the PIM measurement, and the control device controls the N PIM measurement devices individually or simultaneously And the control device may be able to set the interval of the frequency band with respect to the signal transmitted / received by the antenna for the PIM measurement.

The controller may transmit and receive the PIM measurement result measured by the PIM measurement apparatus through the interface unit. The antenna may be connected between the antenna for PIM measurement and the PIM measurement apparatus, And a duplexer connected to the PIM measuring device at the other end.

 Meanwhile, the PIM measurement system according to an embodiment of the present invention includes (a) a controller connected to N (N is a positive integer) PIM measurement apparatus connected to an antenna for PIM measurement, (b) transmitting, to the control device, a setting value for PIM measurement separately included in the N PIM measuring devices, (c) applying a setting value for the PIM measurement to the control device (d) applying RF power to the N PIM measuring devices by the control device, and (e) measuring the PIM of the antenna for the PIM measurement by the N PIM measuring devices. The same effect can be obtained.

The method may further include, after the step (e), (f) interrupting the RF power applied to the N PIM measurement apparatus by the control apparatus, (g) transmitting the PIM measurement result to the control unit and h) outputting the received PIM measurement result by the controller.

The PIM measurement method according to an embodiment of the present invention may be implemented by a computer-readable recording medium having recorded thereon a program for executing the method of the present invention on a computer, and a computer program capable of being stored in a recording medium for execution by the computer.

According to the present invention, since a plurality of PIM measuring apparatuses connected to RF parts including a plurality of ports can be controlled individually or simultaneously, PIM of an RF part such as an antenna can be easily measured.

In addition, since a plurality of PIM measurement devices are controlled by one control device, the size of the entire PIM measurement system can be reduced.

In addition, since the PIM measurement results measured by the plurality of PIM measurement devices are automatically output, it is not necessary to record the measurement results one by one.

The effects of the present invention are not limited to the above-mentioned effects, and various effects can be included within the scope of what is well known to a person skilled in the art from the following description.

1 is a diagram illustrating a configuration of a PIM measurement system according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a duplexer added to the configuration of the PIM measurement system of FIG. 1. FIG.
FIG. 3 is a diagram showing a PIM automatic measuring apparatus of Application No. 10-2015-0024234.
FIG. 4 is an enlarged view of a portion where the control device is connected to the PIM measuring device and the interface unit in FIGS. 1 and 2. FIG.
5 is a view showing a screen displayed on the display unit of the controller in a state where the controller is connected to the other end of the PIM measuring apparatus and the interface unit.
6 is a flowchart illustrating a method of measuring a PIM according to another embodiment of the present invention.
FIG. 7 is a flow chart in which a predetermined step is added to the flowchart of the PIM measurement method of FIG.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. The embodiments described above are provided so that those skilled in the art can easily understand the technical idea of the present invention and thus the present invention is not limited thereto and the detailed description of the related known structure or function may be considered to blur the gist of the present invention Detailed description thereof will be omitted.

In the drawings, the same or similar elements are denoted by the same reference numerals, and the same reference numerals are used throughout the drawings to refer to the same or like elements. It should be noted that the elements have the same reference numerals as much as possible even if they are displayed on different drawings.

In addition, the expression " comprising " is intended to merely denote that such elements exist as an 'open expression', and should not be understood as excluding additional elements.

1 is a diagram illustrating a configuration of a PIM measurement system 100 according to an embodiment of the present invention.

The PIM measurement system 100 includes a PIM measurement apparatus 10, an interface unit 20,

On the other hand, an RF component may include all components that emit an RF signal, but for convenience, the RF component is set as an antenna in this specification.

The PIM measuring apparatus 10 is connected to an antenna for PIM measurement. Specifically, one end is connected to a port of the antenna for PIM measurement, and the other end is connected to a control device 30 to be described later through a PIM cable or the like, and the ON signal transmitted from the control device 30 is checked to measure the PIM . On the other hand, when the antenna for PIM measurement includes a plurality of ports, a plurality of PIM measurement apparatuses 10 are also required. For example, if the antenna for PIM measurement includes three ports of + 45 ° polarization for 800MHz, 2100MHz and 2600MHz, and three ports of -45 ° polarization for 800MHz, 2100MHz and 2600MHz, To measure the PIM simultaneously, six PIM measuring devices (10) are required, and the PIM of the port for the + 45 ° polarization is measured first and then the PIM of the port for the -45 ° polarization is measured Three PIM measuring devices 10 are required. That is, if the number of ports included in the antenna for the PIM measurement is plural, in order to simultaneously measure or sequentially measure the PIMs of all the ports, the PIM measuring apparatus 10 generally includes N (N is a positive integer) It can be considered necessary. However, since it is not easy to provide a relatively expensive PIM measuring apparatus 10 at the number of ports including the antenna for PIM measurement, it is desirable to perform the PIM measurement with a minimum number of PIM measuring apparatuses 10 quickly. N of the present invention related thereto will be described later.

Further, a diplexer 15 may be further provided between the PIM measuring apparatus 10 and the antenna for PIM measurement, one end connected to the antenna for PIM measurement and the other end connected to the PIM measuring apparatus. Referring to FIG. 2, it can be seen that a duplexer 15 is further included between the PIM measuring apparatus 10 and the antenna for PIM measurement. Here, when the antenna for PIM measurement transmits / receives a signal for a wide band or a single band, since the antenna for PIM measurement can include only one port, the duplexer 15 can connect it to the plurality of PIM measurement apparatuses 10 It plays a role. Therefore, when the antenna for PIM measurement includes a plurality of ports, it is not necessary to include the duplexer 15.

Meanwhile, the PIM measurement apparatus 10 may use a commercially available PIM measurement apparatus, or may use the PIM automatic measurement apparatus of the application No. 10-2015-0024234 shown in FIG. In case of using the PIM automatic measuring device of the application No. 10-2015-0024234, it is possible to connect the antenna for the PIM measurement and the connector of the PIM automatic measuring device automatically without requiring human effort, In changing the phase of the signal radiated by the antenna, the efficiency can be increased in implementing the entire PIM measurement system 100, and the time required for the PIM measurement can be increased by changing the phase without changing the phase by turning the motor individually It is preferable to use such a PIM automatic measuring device.

The PIM measurement apparatus 10 includes an interface unit 20, which is the same as the above-described commercially available PIM measurement apparatus or PIM automatic measurement apparatus. Here, the interface unit 20 may be formed of an MCU (Micro Control Unit), or more specifically, an MCU board. That is, the interface unit 20 is included as one configuration of the PIM measuring apparatus 10, but may be formed as a separate external configuration when it is difficult to form the single configuration by the internal configuration of the PIM measuring apparatus 10 have.

The interface unit 20 transmits and receives data to and from a control device 30 to be described later. Here, the data includes a frequency for transmitting and receiving an antenna for PIM measurement, a setting value for PIM measurement such as a value of an IP address and an RF power of the PIM measuring apparatus 100, a PIM measurement result, . ≪ / RTI > Since the interface unit 20 and the control unit 30 can be connected to each other through any one of the Ethernet line, Bluetooth, USB, and RS232, data transmission and reception can be performed through the interface unit 20 and the control unit 30. [ In addition, data transmission can be performed through other wired / wireless communication means.

If there are a plurality of PIM measuring apparatuses 10, it is preferable that the interface unit 20 is formed to correspond to the number of the PIM measuring apparatuses 10. For example, when there are three PIM measuring apparatuses 10, three interface units 20 are formed one by one in the individual PIM measuring apparatuses 10. For example, even if there are three PIM measuring apparatuses 10, only one interface unit 20 may be formed. In this case, the number of the interface units 20 may be different from the number of the PIM measuring apparatuses 10, . In this case, since one interface unit 20 has to transmit and receive data to all three PIM measurement apparatuses 10, the data transmission / reception speed may be slowed, and it should be connected to all three PIM measurement apparatuses 10 Therefore, the interface unit 20 can not be formed as a constitution of the PIM measurement apparatus 10, but should be formed in a separate external configuration.

The controller 30 is connected to the other end of the PIM measuring apparatus 10 and the interface unit 20 to control the operation, and can be confirmed with reference to FIG. 4 is an enlarged view of a portion where the PIM measuring apparatus 10 and the interface unit 20 are connected to the controller 30 in FIGS. 1 and 2. More specifically, the PIM measuring apparatus 10 includes a PIM cable And can be connected to the interface unit 20 through any one of the Ethernet line, Bluetooth, USB, and RS232 (dotted line). Here, the control device 30 may be a computer, a PDA, a PMP, a mobile communication terminal, or the like, and may be an electronic device including a display unit and a display unit. In this specification, it is assumed that the control device 30 is a computer for convenience of explanation.

5 is a view showing a screen displayed on the display unit of the controller 30 when the controller 30 is connected to the other end of the PIM measuring apparatus 10 and the interface unit 20. [

When the controller 30 is connected to the other end of the PIM measuring apparatus 10, the frequency at which the antenna for PIM measurement connected to one end of the PIM measuring apparatus is transmitted and received, the IP address of the PIM measuring apparatus 100, A setting value for the same PIM measurement is automatically transmitted to the control device 30 through the interface section 20. [ Referring to the list of reference numerals 31 and 32 shown in FIG. 5, it can be seen that the two PIM measurement apparatuses 100 are connected to the port of the antenna for PIM measurement to measure the PIM. Specifically, the PIM measuring apparatus 100 having the IP address 192.168.5.150 is connected to a port for transmitting and receiving signals of 800 MHz, and at the same time, RF power of 43 dBm is applied to measure the PIM, and the PIM measuring apparatus 100 having the IP address 192.168.5.153 (10) is connected to a port for transmitting and receiving a signal of 2600 MHz, and at the same time, 43 dBm of RF power is applied to measure PIM. As a result, it can be seen that the antenna for PIM measurement transmits and receives signals of 800 MHz and 2600 MHz, and the RF power for driving is 43 dBm. In the following description, for convenience of explanation, the PIM measuring apparatus 10 connected to a port for transmitting / receiving a signal of 800 MHz is connected to a port for transmitting / receiving a signal of 2600 MHz to the PIM measuring apparatus 1 to measure the PIM And the PIM measuring apparatus 10 will be referred to as the PIM measuring apparatus 2.

On the other hand, the list including the reference numeral 31 also indicates 700 MHz and 900 MHz, but the PIM measuring apparatus 100 is not connected to the list. In addition, the frequency band is automatically transmitted to the control device 30, but it can be configured so that it can be selected by the user, as can be seen at 31. Here, the frequency band to which the antenna for the PIM measurement is transmitted and received and the N associated with the number of the PIM measuring apparatuses 10 will be described.

As described above, if the number of ports included in the antenna for the PIM measurement is plural, the PIM measuring apparatus 10 generally requires N (N is a positive integer), where N is specifically a PIM measurement Which corresponds to the number of frequency bands of the signal transmitted / received by the antenna. According to the above-described embodiment, when the antenna for PIM measurement includes three ports of +45 ° polarization for 800MHz, 2100MHz and 2600MHz, and three ports of -45 ° polarization for 800MHz, 2100MHz and 2600MHz, At least three measuring devices 10 are required, and N is 3 in this case. In addition, in this case, the frequency band of signals transmitted and received by the antennas for PIM measurement can also be three at 800 MHz, 2100 MHz, and 2600 MHz. 5, two PIM measurement apparatuses 10 are connected to a port of an antenna for PIM measurement, and transmission and reception of signals in the 800 MHz and 2600 MHz bands are described above. In this case, the PIM measurement N indicating the number of apparatuses 10 is 2, and 2 is equal to the number of frequency bands of signals transmitted and received by the antennas for PIM measurement.

Meanwhile, the controller 30 can control the RF power applied to the N PIM measuring apparatuses 10. Specifically, the RF power applied to the N PIM measuring apparatuses 10 can be individually or simultaneously controlled. Referring to the reference numeral 32 shown in FIG. 5, the "Power 1" of the PIM measuring apparatus 1 and the PIM measuring apparatus 2 "And" Power 2 " Here, Power 1 corresponds to the (+) connector of the PIM measuring device 1 and the (+) connector of the PIM measuring device 2, and Power 2 denotes the RF power applied to the (-) connector of the PIM measuring device 1 and the PIM measuring device 2. (-) connector of Power1 and the RF power applied to the (+) connector of Power2 by changing the order. In addition, although the value of the RF power is automatically transmitted to the control device 30 by the interface unit 20 as described above, the user can individually input the value of the RF power, .

For example, as shown in FIG. 5, when the control device 30 controls the RF power applied to the N PIM measurement devices 10 individually or simultaneously, After confirming the value of the RF power and confirming the value of the RF power inputted to the Power 1 and Power 2 of the PIM measuring apparatus 2 and transmitting the ON signal to the PIM measuring apparatus, RF power is supplied to the PIM measuring apparatus 1 and the PIM measuring apparatus 2 Can be simultaneously applied. In addition, even if both the PIM measuring apparatus 1 and the PIM measuring apparatus 2 are connected, RF power can be separately applied if the value of the RF power applied to one PIM measuring apparatus is set to zero. For example, if Power 1 and Power 2 of the PIM measuring apparatus 2 are set to 0 in FIG. 3, RF power will be applied only to the PIM measuring apparatus 1. Also, it is possible to implement a separate ON signal transmission start button without setting a value of RF power such as Power 1 and Power 2 to zero. In such a case, the control device 30 may not require a plurality of control devices to correspond to the number of the PIM measuring devices as in the case of the conventional PIM measuring device, and a plurality of PIM measuring devices 10 ) Can be integrally controlled and managed.

The control device 30 can set the interval of the frequency band of the signal transmitted / received by the antenna for PIM measurement. Referring to FIG. 5, it can be seen that the PIM measuring apparatus 1 can measure a signal of 800 MHz and the PIM measuring apparatus 2 can measure a PIM of a signal of 2600 MHz. Here, it should not be interpreted that the PIM measurement devices 1 and 2 measure the PIM of the signals of 800 MHz and 2600 MHz, respectively, but only 800 MHz and 2600 MHz themselves. This is because the signal transmitted and received by the antenna is not a single fixed frequency but a frequency band. That is, since the signals of 800 MHz and 2600 MHz are transmitted and received, the PIM measurement must also be measured for such a frequency band. 5, the PIM measuring apparatus 1 measures the PIM for the 869 to 894 MHz band for 800 MHz and the PIM measuring apparatus 2 measures the PIM for the 2620 to 2690 MHz band for 2600 MHz Can be confirmed. The interval setting of the frequency band may also be individually input by the user, and may be configured to be selectable by the user as in the above-described frequency band.

In addition, the controller 30 can receive and output the PIM measurement result measured by the PIM measuring apparatus 10 through the interface unit 20. Referring to reference numeral 33 shown in FIG. 5, it can be seen that the PIM measurement result is output to the PIM measurement device 1 and the PIM measurement device 2. Specifically, the minimum PIM value, the maximum PIM value, and the average PIM value measured for the value of the RF power applied to the (+) and (-) connectors of the PIM measuring apparatus can be output. On the other hand, in the case of the PIM measuring apparatus 1, the minimum PIM value is -170.4 dBc, the maximum PIM value is -95.9 dBc, the minimum PIM value is -169.7 dBc and the maximum PIM value is -97.7 dBc The reason why the PIM value is larger than the maximum PIM value is that the corrected PIM value is outputted because the measured PIM value is negative. In this way, since the PIM measurement results measured by the plurality of PIM measurement apparatuses 10 are automatically output to the control device 30, it is not necessary to individually record the PIM measurement results.

As described above, the PIM measuring system 100 according to the embodiment of the present invention includes the PIM measuring apparatus 10, the interface unit 20, and the controller 30, The PIM measurement apparatus 10 can be controlled individually or simultaneously and the PIM measurement results measured by the plurality of PIM measurement apparatuses 10 can be automatically output.

Meanwhile, the PIM measurement system 100 according to an exemplary embodiment of the present invention can be implemented by a PIM measurement method including categories that are different but substantially the same technical features. The following description will be made with reference to Fig.

FIG. 6 is a flow chart illustrating a method of measuring a PIM according to another embodiment of the present invention, which is merely a sequential step illustrated in order to achieve the most desirable result in the practice of the present invention, Or some of the steps may be deleted.

First, the controller 30 is connected to N (N is a positive integer) PIM measurement apparatus connected to an antenna for PIM measurement (S210). The control unit 30 and the PIM measuring unit 20 are connected to the control unit 30 and the interface unit included in the PIM measuring unit 20 via the PIM cable, 20 may be connected through any one of an Ethernet line, Bluetooth, USB, and RS232, and may be connected through other types of wire / wireless communication means.

Thereafter, the interface unit 20 transmits a set value for the PIM measurement to the controller 30 (S220). This corresponds to a preparatory step for the PIM measurement, wherein the interface unit 20 can be formed of an MCU (Micro Control Unit), more specifically, an MCU board. That is, the interface unit 20 is included as one configuration of the PIM measuring apparatus 10, but may be formed as a separate external configuration when it is difficult to form the single configuration by the internal configuration of the PIM measuring apparatus 10 have. Specifically, the set values that the interface unit 20 transmits to the controller 30 include the frequency at which the antenna for PIM measurement is transmitted and received, the IP address of the PIM measuring apparatus 100, and the RF power for driving, and the like .

The control unit 30, which has received the setting value for the PIM measurement from the interface unit 20, sets the PIM measurement to a state in which the PIM measurement can be immediately started (S230). For example, if the antenna transmits and receives the frequency, the IP address of the PIM measuring apparatus 100, and the RF power for driving, the received set value is automatically applied as shown in FIG. In addition, the applied setting values can be individually input or selected by the user.

If the control device 30 has applied the set values for the PIM measurement, the RF power is applied to the N PIM measurement devices 10 (S240). Specifically, the RF power applied to the N PIM measuring apparatuses 10 can be applied individually or simultaneously. In this case, N corresponds to the number of frequency bands of the signal transmitted / received by the antenna for PIM measurement. For example, if the antenna for the PIM measurement includes six ports, three PIM measuring apparatuses 10 are required, and N is three in this case. In this case, the antenna for PIM measurement may have three frequency bands for transmitting and receiving signals. 5, two PIM measurement apparatuses 10 are connected to a port of an antenna for PIM measurement, and transmission and reception of signals in the 800 MHz band and the 2600 MHz band are described above. In this case, the PIM N indicating the number of measurement apparatuses 10 is 2, and 2 is equal to the number of frequency bands of signals transmitted and received by the antennas for PIM measurement.

5, the control unit 30 controls the RF power applied to the N PIM measuring apparatuses 10 individually or simultaneously. For example, as shown in FIG. 5, The RF power of the PIM measuring device 1 and the PIM measuring device 2 can be measured by confirming the value of the RF power inputted to the PIM measuring device 2 and confirming the value of the RF power inputted to the Power 1 and the power 2 of the PIM measuring device 2, Can be simultaneously applied. In addition, even if both the PIM measuring apparatus 1 and the PIM measuring apparatus 2 are connected, RF power can be separately applied if the value of the RF power applied to one PIM measuring apparatus is set to zero. For example, if Power 1 and Power 2 of the PIM measuring apparatus 2 are set to 0 in FIG. 5, RF power will be applied only to the PIM measuring apparatus 1. Also, it is possible to implement a separate ON signal transmission start button without setting a value of RF power such as Power 1 and Power 2 to zero. In such a case, the control device 30 may not require a plurality of control devices to correspond to the number of the PIM measuring devices as in the case of the conventional PIM measuring device, and a plurality of PIM measuring devices 10 ) Can be integrally controlled and managed.

At the same time as the application of the RF power, the controller 30 can set the interval of the frequency band of the signal transmitted / received by the antenna for the PIM measurement. Referring to FIG. 5, it can be seen that the PIM measuring apparatus 1 can measure a signal of 800 MHz and the PIM measuring apparatus 2 can measure a PIM of a signal of 2600 MHz. Here, it should not be interpreted that the PIM measurement devices 1 and 2 measure the PIM of the signals of 800 MHz and 2600 MHz, respectively, but only 800 MHz and 2600 MHz themselves. This is because the signal transmitted and received by the antenna is not a single fixed frequency but a frequency band. That is, since the signals of 800 MHz and 2600 MHz are transmitted and received, the PIM measurement must also be measured for such a frequency band. 5, the PIM measuring apparatus 1 measures the PIM for the 869 to 894 MHz band for 800 MHz and the PIM measuring apparatus 2 measures the PIM for the 2620 to 2690 MHz band for 2600 MHz Can be confirmed. The interval setting of the frequency band may also be individually input by the user, and may be configured to be selectable by the user as in the above-described frequency band.

When RF power is applied to the N PIM measurement apparatuses 10, the PIM measurement apparatus 10 measures the PIM of the antenna for the PIM measurement (S250).

The PIM of the antenna for PIM measurement can be measured according to the steps S210 to S250 described above. When the PIM measuring apparatus 10 and the controller 30 are connected, the set value for the PIM measurement is transmitted to the interface unit 20 To the control device 30, which can be individually input and selected by the user. Meanwhile, the PIM measuring method according to an embodiment of the present invention further includes an additional step of measuring the PIM of the antenna and then outputting the measurement result, which will be described with reference to FIG. Steps S210 to S250 shown in Fig. 7 are the same as those described above.

When the PIM measurement is completed, the controller 30 cuts off the RF power applied to the N PIM measuring apparatuses 10 (S260). The cutoff of the RF power can also be performed individually or simultaneously with the N PIM measuring apparatuses 10 as well as the application of the RF power. Specifically, the OFF signal .

If the N PIM measurement apparatus 10 receives the OFF signal, the interface unit 20 transmits the PIM measurement result to the controller 30 (S270). The transmission of the PIM measurement result may also be performed through any one of the Ethernet line, Bluetooth, USB, and RS232.

Finally, the control device 30 outputs the received PIM measurement result (S280). The output of the PIM measurement result can output the minimum PIM value, the maximum PIM value, and the average PIM value as indicated by reference numeral 33 shown in FIG. 5. However, this is only one example and the addition It is also possible to output the same thing together. In addition, the controller 30 may store the output of the PIM measurement itself in a predetermined file format in a memory unit (not shown) or a database (not shown).

The above-described PIM measurement method may be implemented in the form of a computer program that can be stored in a recording medium for execution by a computer. In this state, the PIM measurement method may be stored in a computer-readable recording medium, It can be distributed through a server. In addition, although not described in detail to avoid redundancy, the technical characteristics and effects of the PIM measurement system 100 can be inherently applied to the PIM measurement method. For example, the PIM measurement method is also connected between the PIM measurement apparatus 10 and the antenna for PIM measurement, like the PIM measurement system 100, with one end connected to the antenna for PIM measurement and the other end connected to the PIM measurement apparatus And a duplexer 15 connected to the base station.

The embodiments of the present invention described above are disclosed for the purpose of illustration, and the present invention is not limited thereto. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention.

100: PIM measurement system
10: PIM measuring device
15: Duplexer
20:
30: Control device

Claims (18)

N (N is a positive integer) PIM measuring device connected to an antenna for PIM measurement to measure PIM;
An interface unit separately included in the N PIM measuring apparatuses and storing setting values for PIM measurement; And
A control unit connected to the other end of the N PIM measuring apparatuses and the interface unit to apply RF power to the N PIM measuring apparatuses and to receive a set value for PIM measurement from the interface unit and apply the measured value to the PIM measurement;
A system for measuring a PIM comprising:
When the PIM measurement apparatus completes the PIM measurement,
The control device includes:
Wherein the PIM measurement device is configured to block the RF power applied to the N PIM measuring devices and to receive and output the PIM measurement result from the interface part
The method according to claim 1,
The interface unit includes:
It is an MCU (Micro Control Unit)
And transmits and receives data including a set value for PIM measurement to the control device
The method according to claim 1,
The interface unit and the control device may be configured,
PIM measurement system characterized in that it is connected via an Ethernet line, bluetooth, USB, RS232
The method according to claim 1,
The N (N is a positive integer)
Wherein the PIM measurement system is a PIM measurement system.
5. The method of claim 4,
The control device includes:
Characterized in that it is possible to apply RF power separately or simultaneously to the N PIM measuring devices
5. The method of claim 4,
The control device includes:
Wherein the PIM measurement system is capable of setting a period of a frequency band with respect to a signal transmitted and received by the antenna for the PIM measurement.
The method according to claim 1,
The control device includes:
Wherein the PIM measuring device measures the PIM measurement result of the PIM measuring device,
The method according to claim 1,
Between the antenna for the PIM measurement and the PIM measuring device,
A duplexer having one end connected to the antenna for the PIM measurement and the other end connected to the PIM measurement device;
Further comprising a PIM measurement system
(a) connecting a control device with N (N is a positive integer) PIM measuring device connected to an antenna for PIM measurement;
(b) transmitting, to the control device, a setting value for an interface unit PIM measurement separately included in the N PIM measurement devices;
(c) applying a set value for the received PIM measurement by the control device;
(d) applying a RF power to the N PIM measurement devices by the control device; And
(e) N PIM measurement devices measure the PIM of the antenna for the PIM measurement;
A method for measuring a PIM,
After the step (e)
(f) blocking the RF power applied to the N PIM measurement devices by the control device;
(g) transmitting, by the interface unit, the PIM measurement result to the control device; And
(h) the controller outputs the received PIM measurement result;
Further comprising the step of:
10. The method of claim 9,
The interface unit includes:
It is an MCU (Micro Control Unit)
And transmitting and receiving data including a set value for the PIM measurement to the control device
10. The method of claim 9,
The interface unit and the control device may be configured,
PIM measurement method characterized by being connected through an Ethernet line, bluetooth, USB, RS232
10. The method of claim 9,
The N (N is a positive integer)
Wherein the number of frequency bands transmitted and received by the antenna for the PIM measurement
10. The method of claim 9,
The control device includes:
Wherein the N PIM measurement apparatuses can individually or simultaneously apply RF power to the N PIM measurement apparatuses
10. The method of claim 9,
The control device includes:
The PIM measurement method is characterized in that a period of a frequency band can be set for a signal transmitted / received by the antenna for the PIM measurement
10. The method of claim 9,
Between the antenna for the PIM measurement and the PIM measuring device,
A duplexer having one end connected to the antenna for the PIM measurement and the other end connected to the PIM measurement device;
Further comprising the step of:
delete A computer-readable recording medium on which a program for causing a computer to execute the PIM measurement method according to any one of claims 9 to 15 is recorded delete

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