KR20240034576A - Antenna System and Method for Detecting Defect of Antenna - Google Patents

Abstract

Disclosed is a method for detecting defective antennas and an antenna system.
According to one aspect of the present invention, in an antenna system for detecting defects in an antenna element and a filter connected to the antenna element, a plurality of transmission/reception circuits connected to inspection objects including antenna elements and filters, each transmission/reception circuit comprising: It is connected to one test object and includes a transmitting circuit and a receiving circuit that share the connection with the test object; And transmitting a test signal through the transmission circuit, receiving a reflected signal of the test signal reflected by the inspection object through the reception circuit, and detecting defects in the inspection object based on the strength of the reflected signal. An antenna system including a defect detection unit is provided.

Description

Antenna System and Method for Detecting Defect of Antenna}

Embodiments of the present invention relate to a method and antenna system for detecting defective antennas, and particularly to a method and antenna system for detecting defective antennas using a test signal and a reflected signal.

The content described below simply provides background information related to this embodiment and does not constitute prior art.

In operating a wireless communication system, system stability is an important factor. In order to operate the system stably, when system operation is interrupted, broken parts must be quickly found and repaired. In particular, a method of detecting a fault in a base station is very important.

In a wireless communication system, when the base station's antenna element is normal, most of the base station's transmission signal is radiated through the antenna element, but when the antenna element is defective, the transmission signal is reflected by the antenna element.

Based on this concept, voltage standing wave ratio (VSWR) can be used to determine whether there is an abnormality in the antenna port connection of the base station in a wireless communication system. A standing wave refers to a waveform that appears when an incident wave and a reflected wave overlap or disappear at the boundary of two different media. Unlike traveling waves, which move forward, standing waves vibrate while remaining stationary. VSWR represents the ratio of the voltage amplitude of the maximum voltage point and the voltage amplitude of the adjacent minimum voltage point in a standing wave.

The system operator of the base station can determine whether a specific antenna is abnormal by measuring VSWR. For example, VSWR can be calculated by transmitting a transmit signal through a specific antenna on a base station, measuring the power of the transmitted signal, measuring the power of the signal reflected by the specific antenna, and comparing the power of the two signals. . If the calculated VSWR exceeds a predetermined reference value, the system operator may determine that the base station antenna has failed.

However, in order to measure the power of the transmitted signal and the reflected signal, there is a problem that a separate expensive circuit is needed to measure the power of the signal for each antenna port or RF (Radio Frequency) chain. If there are 64 antenna ports, 64 power measurement circuits are required. This increases the cost and circuit complexity of detecting antenna failure.

The main purpose of embodiments of the present invention is to provide an antenna system for detecting defects in an antenna element and a filter connected to the antenna element without a separate power measurement circuit.

The purpose of other embodiments of the present invention is to provide an antenna system for detecting defects in antenna elements and filters while minimizing interference between adjacent antenna ports.

According to one aspect of the present invention, in an antenna system for detecting defects in an antenna element and a filter connected to the antenna element, a plurality of transmission/reception circuits connected to inspection objects including antenna elements and filters, each transmission/reception circuit comprising: It is connected to one test object and includes a transmitting circuit and a receiving circuit that share the connection with the test object; And transmitting a test signal through the transmission circuit, receiving a reflected signal of the test signal reflected by the inspection object through the reception circuit, and detecting defects in the inspection object based on the strength of the reflected signal. An antenna system including a defect detection unit is provided.

As described above, according to an embodiment of the present invention, circuit complexity, cost, and product size required for defect detection can be reduced by removing the circuit required to detect defects in the antenna element and filter but using a software algorithm. .

According to another embodiment of the present invention, defects in antenna elements and filters can be detected while minimizing interference between adjacent antenna ports.

1 is a schematic configuration diagram of an antenna system according to an embodiment of the present invention.
Figure 2 is a configuration diagram showing a radio unit according to an embodiment of the present invention.
Figure 3 is a configuration diagram of a radio unit to explain a defect detection process of a filter-antenna element pair according to an embodiment of the present invention.
Figure 4 is a control timing diagram according to an embodiment of the present invention.
FIGS. 5A, 5B, and 5C are diagrams for explaining a method of transmitting test signals according to an embodiment of the present invention.

Hereinafter, some embodiments of the present disclosure will be described in detail using exemplary drawings. When adding reference signs to components in each drawing, it should be noted that the same components are given the same reference numerals as much as possible even if they are shown in different drawings. Additionally, in describing the present disclosure, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present disclosure, the detailed description will be omitted.

In describing the components of the embodiment according to the present disclosure, symbols such as first, second, i), ii), a), and b) may be used. These codes are only used to distinguish the component from other components, and the nature, sequence, or order of the component is not limited by the code. In the specification, when a part is said to 'include' or 'have' a certain element, this means that it does not exclude other elements, but may further include other elements, unless explicitly stated to the contrary. .

Each component of the device or method according to the present invention may be implemented as hardware or software, or may be implemented as a combination of hardware and software. Additionally, the function of each component may be implemented as software and a microprocessor may be implemented to execute the function of the software corresponding to each component.

1 is a schematic configuration diagram of an antenna system according to an embodiment of the present invention.

Referring to FIG. 1, the antenna system includes a plurality of transmission/reception circuits (20) and a plurality of filter-antenna element pairs (30). The antenna system further includes a digital unit 10 or a failure detection unit 11.

The antenna system is divided into a digital unit 10 that processes baseband and one or more RUs that process analog wireless signals. The digital unit 10 and one or more RUs may be configured as one device or may be configured separately at a certain distance. The RU that is separated from the digital unit 10 and is controlled by the digital unit 10 is called a remote RF device (Remote Radio Frequency Unit, RRU), and can be configured by connecting multiple RRUs to one digital unit 10. .

In FIG. 1, a plurality of transmission/reception circuits 20 and a plurality of filter-antenna element pairs constitute radio units (RUs). A filter-antenna element pair corresponding to one of the plurality of transmission/reception circuits 20 constitutes one RU.

An antenna system may be referred to as a wireless device. Within the antenna system, the digital unit 10 may be referred to as a digital processing circuit that processes digital signals, and the plurality of transmitting and receiving circuits 20 may be referred to as analog processing circuits that process analog signals. Additionally, among the plurality of filter-antenna element pairs 30, a filter may also be part of an analog processing circuit.

The antenna system can perform two-way wireless communication with other wireless communication devices such as wireless terminals in a time division duplex (TDD) method. In the TDD method, an antenna system can transmit and receive a transmission signal using a single transmission line or antenna element. That is, the transmission path and reception path may be partially shared.

The antenna system may be installed in a base station or in a terminal. Hereinafter, the antenna system will be described as being provided in a base station.

The digital unit 10 transmits or receives digital signals with a plurality of transmission/reception circuits 20 and further processes digital signals.

The digital unit 10 may receive a baseband signal and perform an up-converter operation to upconvert the baseband signal into a signal in an intermediate frequency band or RF (Radio Frequency) band. The digital unit 10 transmits the up-converted signal to a plurality of transmission and reception circuits 20. Likewise, the digital unit 10 may receive a signal in the intermediate frequency band or RF band and perform a down-converter operation to downconvert it to a baseband signal. This converter operation may be performed in a plurality of transmission/reception circuits 20 instead of the digital unit 10.

The digital unit 10 may perform a digital pre-distortion (DPD) function. The DPD function pre-distorts the signal in response to the nonlinearity of the power amplifier in the transmission/reception circuit. Specifically, the input signal and output signal of the power amplifier may have a non-linear relationship. This non-linear relationship can cause interference in wireless channels. In order to reduce the nonlinearity of the power amplifier, the digital unit 10 determines the gain and phase characteristics of the power amplifier and adjusts the transmission signal based on the determined characteristics. The DPD operation of the digital unit 10 produces results similar to those in which the power amplifier in the transmission/reception circuit is linearized. This can improve the efficiency of the power amplifier.

The digital unit 10 may perform an operation to reduce the crest factor or peak to average ratio (PAR) of the digital signal. Here, the crest factor is a measure of the waveform calculated by dividing the size of the signal waveform by the RMS (root mean square) value of the waveform. In wireless communication systems, transmitted signals may have high crest factors due to other influences. A high crest factor can reduce the efficiency of the power amplifier included in the plurality of transmission and reception circuits 200. The digital unit 10 can reduce the crest factor of the signal by detecting and removing the peak value of the transmission signal.

The digital unit 10 may be implemented with various digital circuits, such as a Field Programmable Gate Array (FPGA) or a Digital Signal Processor (DSP) including at least one processor.

The digital unit 10 according to an embodiment of the present invention includes a defect detecting unit 11. The defect detection unit 11 determines whether the plurality of filter-antenna element pairs 30 are defective. In FIG. 1, the defect detection unit 11 is shown as being included in the digital unit 10, but in another embodiment, the defect detection unit 11 may be included in each of the plurality of transmission and reception circuits 20.

The plurality of transmitting and receiving circuits 20 convert the digital signal received from the digital unit 10 into an analog signal, process the analog signal, and transmit it to the outside through a plurality of filter-antenna element pairs 30.

The plurality of transmitting and receiving circuits 20 include various RF elements for processing analog signals. A portion of each of the plurality of transmitting and receiving circuits 20 may be implemented as a Radio Frequency Integrated Circuit (RFIC). This is explained in detail in Figure 2.

A plurality of transmitting and receiving circuits 20 are connected to a plurality of filter-antenna element pairs 30. The plurality of transmitting and receiving circuits 20 may be connected to the plurality of filter-antenna element pairs 30 through a standardized RF interface such as a coaxial connector. The plurality of transmitting and receiving circuits 20 may be connected one-to-one with the plurality of filter-antenna element pairs 30. Each of the plurality of transmitting and receiving circuits 20 and the plurality of filter-antenna element pairs 30 may be 32 or 64.

The plurality of filter-antenna element pairs 30 radiate signals received from the plurality of transmission and reception circuits 20 and transmit signals received from the outside to the plurality of transmission and reception circuits 20.

According to one embodiment of the present invention, a plurality of filter-antenna element pairs 30 are inspected for defects in the antenna system.

Figure 2 is a configuration diagram showing a radio unit according to an embodiment of the present invention.

Referring to FIG. 2, a radio unit (not shown) includes a transmission/reception circuit 200 and a filter-antenna element pair 300. The transmitting and receiving circuit 200 includes an RFIC 210, a power amplifier 220, a first coupler 230, a circulator 240, a second coupler 250, and a low noise amplifier (LNA) 260. , and a termination resistor 270. The filter-antenna element pair 300 includes a filter 310 and an antenna element 320.

The transmitting and receiving circuit 200 includes a transmitting circuit and a receiving circuit. The transmission circuit includes a digital-analog converter (DAC) 211, a first mixer 213, a first variable gain amplifier 215, a first transformer 217, a power amplifier 220, and a circuit. Includes radar 240. The receiving circuit includes a circulator 240, a low-noise amplifier 260, a termination resistor 270, a second transformer 212, a second variable gain amplifier 214, a second mixer 216, and an analog-to-digital converter ( Includes Analog-Digital Converter (ADC; 218). The transmitting circuit and the receiving circuit are each connected to the filter-antenna element pair 300 and share a connection with the filter-antenna element pair 300. That is, the path between the circulator 240 and the filter 310 is shared.

In Figure 2, the transmission signal is a service signal for the antenna system provided in the base station to send to an external terminal. The received signal is a signal that the antenna system receives from an external terminal. Meanwhile, in another embodiment, when an antenna system is provided in a terminal, the transmission signal is a signal to be sent to the base station and the reception signal is a signal received from the base station.

Below, the RF elements included in the radio unit will be described.

The DAC 211 converts a transmission signal, which is a digital signal, into an analog signal. The DAC 211 converts a digital signal into an analog signal according to a predetermined sampling frequency to avoid interference between signals of different frequencies.

The first mixer 213 may up-convert the baseband transmission signal into an intermediate frequency band or RF band signal by multiplying the baseband transmission signal by a signal of a specific frequency.

The first variable gain amplifier 215 adjusts the amplitude or strength of the transmission signal. Based on the gain of the first variable gain amplifier 215, the strength of the transmission signal can be increased or decreased. The gain of the first variable gain amplifier 215 may be determined by the digital unit 10 or the defect detection unit 11.

The first transformer 217 transfers the transmission signal within the RFIC 210 to the power amplifier 220. The first transformer 217 may block physical contact between the first variable gain amplifier 215 and the power amplifier 220.

The power amplifier 220 amplifies the power of the transmission signal. Considering the attenuation of the signal propagating in the wireless channel, the power amplifier 220 amplifies the power of the transmission signal. The power amplifier 220 can increase the distance the signal reaches or the signal gain by amplifying the power of the transmission signal. Meanwhile, the power amplifier 220 may be turned on and off according to the enable (EN) signal of the defect detection unit 11.

The first coupler 230 captures the transmission signal between the power amplifier 220 and the circulator 240. The transmission signal captured by the first coupler 230 may be used as a feedback signal. For example, the captured transmission signal can be used for digital pre-distortion.

The circulator 240 outputs a signal input through one port through one output port among at least two output ports.

The circulator 240 outputs the transmitted signal input from the power amplifier 220 to the filter-antenna element pair 300, and outputs the received signal input from the filter-antenna element pair 300 to the low noise amplifier 260. do. As a result, the circulator 240 can prevent the inflow of signals flowing backward through the transmission path.

The second coupler 250 captures the transmission signal between the circulator 240 and the filter 310. The transmission signal captured by the second coupler 250 may be used for calibration of the transmission path. Here, calibration means uniformly adjusting deviations in phase, gain, delay, etc. of signals that occur due to deviations or noise of RF elements on multiple transmission and reception paths.

Furthermore, the second coupler 250 captures the received signal between the circulator 240 and the filter 310. The received signal captured by the second coupler 250 may be used for calibration of the receive path.

The second coupler 250 may be a single coupler that captures both the transmitted signal and the received signal, but may also be composed of two couplers that respectively capture the transmitted signal and the received signal. If the second coupler 250 is one coupler that captures both the transmit signal and the receive signal, the transmit path calibration (Tx Cal) port and the receive path calibration (Rx Cal) port are the same port.

The filter 310 performs a frequency selection function by passing only desired frequency components among various frequency components of the input signal and attenuating the remaining frequency components. The filter 310 may filter transmitted signals and received signals. Filter 310 may be a band pass filter.

The antenna element 320 radiates a transmission signal to the outside or receives a reception signal from the outside.

The received signal received by the antenna element 320 is transmitted to the low noise amplifier 260 through the filter 310 and the circulator 240.

The low-noise amplifier 260 amplifies the strength of the received signal on the receive path. Generally, the strength of the received signal is very low, so a low noise amplifier 260 that amplifies the strength of the received signal is required.

The low-noise amplifier 260 is designed to minimize noise mixing in the process of amplifying the strength of the received signal.

Low noise amplifier 260 includes an internal power amplifier 262 and switch 264.

The switch 264 receives the received signal and transfers the received signal to either the low noise amplifier 260 or the termination resistor 270.

Specifically, the switch 264 has a Single Pole Double Throw (SPDT) structure, with the single pole connected to the circulator 240 and the double throw connected to the internal power amplifier 262 and the termination resistor 270, respectively. do.

In the downlink section, which is a section in which the base station transmits a transmission signal to the terminal, the switch 264 connects the filter 310 and the termination resistor 270. In the uplink section, which is a section in which the base station receives a reception signal from the terminal, the switch 264 connects the filter 310 and the internal power amplifier 262. If the transmission signal is reflected and flows into the reception path, it may damage the RF elements located in the reception path. Therefore, the switch 264 allows the reception signal to flow to the termination resistor 270 during the downlink section, so that the transmission signal is reflected and enters the reception path. prevent it from flowing into. The switch 264 sends the received signal to the internal power amplifier 262 so that the strength of the received signal is amplified during the uplink section.

The switching operation of the switch 264 is performed in a guard period between the downlink time period and the uplink time period.

The internal power amplifier 262 amplifies the strength of the received signal and transmits it to the RFIC 210. The gain of the internal power amplifier 262 may be set by the digital unit 10 or the defect detection unit 11. The internal power amplifier 262 may be turned on and off according to the enable signal of the defect detection unit 11.

The second transformer 212 transfers the received signal to the second variable gain amplifier 220.

The second variable gain amplifier 214 adjusts the amplitude or strength of the received signal. The gain of the second variable gain amplifier 214 may be determined by the digital unit 10 or the defect detection unit 11.

The second mixer 216 can down-convert the received signal in the intermediate frequency band or RF band to a baseband signal by multiplying it by a signal of a specific frequency.

The ADC 218 converts the received signal, which is an analog signal, into a digital signal. The received signal converted into a digital signal is transmitted to the digital unit 10.

Figure 3 is a configuration diagram of a radio unit to explain a defect detection process of a filter-antenna element pair according to an embodiment of the present invention.

Referring to FIG. 3, the defect detection unit 11 according to an embodiment of the present invention transmits a test signal as a transmission signal to the filter-antenna element pair 300 through the transmission and reception circuit 200, and the filter-antenna element pair 300 transmits a test signal as a transmission signal. The reflected signal reflected by 300 is received through a receiving circuit, and a defect in the filter-antenna element pair 300 is detected based on the strength of the reflected signal. In FIG. 3, the test signal is distinguished from the service signal mentioned in FIG. 2 and may have the form of a continuous wave. The antenna system can detect defects in the filter-antenna element pair 300 using the radio unit of the base station without a separate VSWR measurement circuit.

Specifically, when both the filter 310 and the antenna element 320 are in an ideal state, the test signal is not reflected and is transmitted to the outside. However, if either the filter 310 or the antenna element 320 is defective, the test signal is reflected. Here, defect may mean a failure of the filter 310 or the antenna element 320 or a failure of impedance matching. Depending on the defects of the filter 310 and the antenna element 320, the test signal may be totally reflected. The antenna system measures RSSI (Received Signal Strength Indicator), which indicates the strength of the reflected signal. The antenna system can measure the RSSI of the reflected signal input to the ADC 218 or the RSSI of the reflected signal output from the ADC 218. RSSI measurement functionality may be embedded in RFIC 210. The antenna system can determine whether the filter 310 and the antenna element 320 are defective based on the RSSI value of the reflected signal.

Meanwhile, the strength of the test signal must be determined based on the rated voltage, rated current, or rated capacity of the RF receiving elements included in the receiving circuit. If the strength of the test signal is not lowered, the strength of the reflected signal increases, which may damage the receiving circuit. To prevent damage to the receiving circuit, the antenna system transmits a test signal of low intensity. Nevertheless, the intensity of the reflected signal may be greater than the acceptable range of the receiving circuit.

The antenna system according to an embodiment of the present invention connects the switch 264 to the termination resistor 270 and detects defects in the filter 310 and the antenna element 320 using the strength of the reflected signal leaking from the switch. can do. Specifically, when the switch 264 is an ideal switch and is connected to the termination resistor 270, the reflected signal input to the switch 264 is not input to the internal power amplifier 262. On the other hand, if the switch 264 is a non-ideal switch, the reflected signal input to the switch 264 flows into the internal power amplifier 262. At this time, because the reflected signal is minutely introduced, the internal power amplifier 262 receives a signal having a smaller intensity than the intensity of the reflected signal input to the switch 264. When switch 264 does not couple internal power amplifier 262 to the filter, internal power amplifier 262 amplifies the weak strength of the reflected signal leaking from switch 264. Because of this, it is possible to prevent RF receiving elements located after the output terminal of the switch 264 from being damaged.

Meanwhile, the defect detection unit 11 determines whether the filter 310 and the antenna element 320 are defective based on the strength of the leaked reflected signal.

The defect detection unit 11 according to an embodiment of the present invention can determine whether the filter 310 and the antenna element 320 are defective by comparing the intensity of the reflected signal with a preset value. If the intensity of the reflected signal is greater than a preset value, the defect detection unit 11 may determine that at least one of the filter 310 and the antenna element 320 is defective. Here, the preset value may be a value set by the defect detection unit 11 or an average value of the intensities of reflected signals.

According to another embodiment of the present invention, the defect detection unit 11 detects defects in a plurality of filter-antenna element pairs corresponding to the plurality of transmission and reception circuits by comparing the intensities of reflected signals measured by the plurality of transmission and reception circuits. It can be detected. For example, reflected signals may be received through a plurality of transmitting and receiving circuits. At this time, when the strength of the first reflected signal is measured by the first transmission and reception circuit and the strength of the second reflection signal is measured by the second transmission and reception circuit, the defect detection unit 11 determines that the strength of the first reflection signal is measured by the second reflection signal. If the signal strength is greater than the preset value added, it may be determined that at least one of the first filter and the first antenna element connected to the first transmission/reception circuit is defective. The first reflected signal and the second reflected signal may be randomly selected from among a plurality of reflected signals. Otherwise, the second reflected signal may be a signal with the lowest intensity among the reflected signals.

Meanwhile, even if the RSSI of the reflected signal input to the ADC 218 is abnormally large, it may be caused by RF elements other than the filter 310 and the antenna element 320. Accordingly, in order to determine whether the filter 310 and the antenna element 320 are defective based on the strength of the reflected signal, the antenna system needs to check whether the transmitting circuit and the receiving circuit are defective.

The antenna system can detect defects in the transmission circuit and reception circuit using transmission path calibration and reception path calibration.

Hereinafter, it will be described that the defect detection unit 11 performs a calibration function, but in another embodiment, the digital unit 10 may perform the calibration function and the defect detection unit 11 may use the results.

For transmission path calibration, the defect detection unit 11 captures the transmission signal using the second coupler 250. The defect detection unit 11 checks changes in the transmission signal according to the transmission circuit based on the transmission signal input to the transmission circuit and the captured transmission signal. The defect detection unit 11 checks changes in transmission signals for each of the plurality of transmission circuits and compares deviations between the plurality of transmission circuits based on the changes in the transmission signals. The defect detection unit 11 may detect defects in the transmission circuits based on the deviation between the plurality of transmission circuits.

Additionally, for receiving path calibration, the defect detection unit 11 inputs a pilot signal to the second coupler 250. Pilot signals are distinguished from test signals and service signals. The defect detection unit 11 receives a pilot signal through a receiving circuit. The defect detection unit 11 checks changes in the pilot signal according to the receiving circuit based on the pilot signal input to the second coupler 250 and the pilot signal received at the output terminal of the receiving circuit. The defect detection unit 11 checks the change in the pilot signal for each of the plurality of receiving circuits and compares the deviation between the plurality of receiving circuits based on the changes in the pilot signals. The defect detection unit 11 may detect defects in the receiving circuits based on the deviation between the plurality of receiving circuits.

In addition, the transmission signal captured by the first coupler 230 may be used to detect a defect in the power amplifier 220. For example, when the intensity of the captured transmission signal is small or large, the defect detection unit 11 may determine that the power amplifier 220 is defective.

In this way, when the transmission/reception circuit 200 is determined to be normal, the antenna system can determine whether the filter 310 and the antenna element 320 are defective based on the strength of the reflected signal.

Figure 4 is a control timing diagram according to an embodiment of the present invention.

The antenna system according to an embodiment of the present invention can detect defects in filters and antenna elements within a guard period. This is because in order for the antenna system to detect defects in filters and antenna elements during uplink (UL) or downlink (DL), communication services must be stopped. Therefore, the antenna system according to an embodiment of the present invention can prevent communication service provision from being interrupted by detecting defects in the filter and antenna elements within the protection interval. For this purpose, appropriate control of the transmission signal, power amplifier, and low noise amplifier is required within the protection interval.

Referring to Figure 4, a control timing diagram for the transmit radio signal (TX RF), power amplifier enable signal (PA EN), low noise amplifier enable signal (LNA EN), and low noise amplifier switch signal (LNA SW) is shown. It is done.

TX RF indicates the type of transmission signal transmitted through the transmission circuit. PA EN indicates the on/off state of the power amplifier. LNA EN indicates the on/off status of the internal power amplifier included in the low noise amplifier. LNA SW indicates the connection status of the switch included in the low noise amplifier. When the LNA SW is off, one end of the switch is connected to the circulator and the other end is connected to the termination resistor. When the LNA SW is on, the other end of the switch is connected to the internal power amplifier.

Within the downlink section, the digital unit transmits a service signal as a transmission signal. At this time, the power amplifier on the transmission path is in an on state to amplify the service signal. On the other hand, the internal power amplifier on the receiving path is off, and the switch is connected to the termination resistor.

Within the protection interval, the defect detection unit transmits a test signal as a transmission signal. The power amplifier is in the on state while the test signal is transmitted. Additionally, when the test signal is transmitted, the internal power amplifier changes from the off state to the on state. However, the switch connection is maintained. Because of this, the internal power amplifier amplifies the reflected signal leaking from the switch.

When the transmission of the test signal ends within the protection period, the power amplifier is turned off. This is because a power amplifier is not needed in the uplink section. Meanwhile, the internal power amplifier remains on. Additionally, the switch is connected to an internal power amplifier rather than a termination resistor.

During the uplink period, no transmission signal is transmitted and the power amplifier is in the off state. On the other hand, the low-noise amplifier receives the received signal in the on state and amplifies the received signal.

According to the control timing diagram shown in FIG. 4, the defect detection unit can detect defects in the filter and antenna elements within the protection section.

Meanwhile, a method for detecting a defect in an antenna according to an embodiment of the present invention is the same as the operation of the defect detection unit described in FIGS. 1 to 5.

Specifically, the defect detection method transmits test signals to inspection objects including antenna elements and filters through a plurality of transmission and reception circuits. The defect detection method transmits each test signal to each transmission/reception circuit within the protection interval. The defect detection method may transmit test signals at different frequencies and transmission times.

The defect detection method applies an enable signal to each of the internal power amplifiers of the low-noise amplifiers included in the transmission and reception circuits along with the transmission of test signals. At this time, each switch is connected to each termination resistor.

Thereafter, the defect detection method obtains the intensities of reflected signals from which test signals are reflected by the inspection objects. The defect detection method may measure the intensity of a reflected signal received from each transmission/reception circuit, or may obtain the intensity of the reflection signal measured by each transmission/reception circuit.

The defect detection method detects defects in inspection objects based on the strengths of reflected signals. The defect detection method detects defects in the filter and antenna elements corresponding to each of the transmitting and receiving circuits based on the RSSI value of each reflected signal. The defect detection method may be determined based on at least one of the difference between the RSSI value of each reflected signal and a preset value or the difference between the RSSI values of the reflected signals.

In the defect detection method, when the transmission of the test signal is terminated, the power amplifier on the transmission circuit is turned off and one end of the switch in the low noise amplifier is connected to the internal power amplifier.

FIGS. 5A, 5B, and 5C are diagrams for explaining a method of transmitting test signals according to an embodiment of the present invention.

In FIGS. 5A, 5B, and 5C, the antenna system is described as a system including 32 antenna devices. However, in other embodiments, the number of antenna devices may be configured differently. Here, the antenna device corresponds to the radio unit in FIG. 1.

Referring to FIG. 5A, the defect detection unit according to an embodiment of the present invention may simultaneously transmit test signals of the same frequency to the antenna devices ANT1 to ANT32. Specifically, the defect detection unit simultaneously transmits the first test signal 500 to the 32nd test signal 504 for the first to 32nd antenna devices ANT1 to ANT32. At this time, the test signals all have the same frequency of 3750 MHz.

However, if test signals having the same frequency are transmitted simultaneously, interference between adjacent antenna devices may occur. For example, as the first test signal 500 of the first antenna device ANT1 flows into the antenna element of the second antenna device ANT2, the intensity of the reflected signal of the second antenna device ANT2 may be measured to be high. You can. This is because, even though the filter and antenna element of the second antenna device (ANT2) are not defective, the defect detection unit may incorrectly determine that the filter and antenna element are defective.

Referring to FIG. 5B, the defect detection unit according to an embodiment of the present invention may transmit test signals of the same frequency to the antenna devices ANT1 to ANT32 at different times. Specifically, the first test signals 510 to 32nd test signals 520 of the first to third antenna devices ANT1 to ANT32 are sequentially transmitted over time. At this time, the test signals all have the same frequency of 3750 MHz. While testing the filter and antenna element of the first antenna device (ANT1) for defects, the switch in the low noise amplifier of the other antenna devices may be connected to a termination resistor, and the power amplifier of the other antenna devices may be in an off state. Through this, it is possible to prevent incorrect determination of defects in filters and antenna elements due to the inflow of test signals from adjacent antenna devices.

Referring to FIG. 5C, the defect detection unit according to an embodiment of the present invention may simultaneously transmit test signals of different frequencies for the antenna devices ANT1 to ANT32. The defect detection unit may detect defects in the filter and antenna elements based on each reflected signal having a frequency component assigned to each antenna device. Specifically, the first test signals 530 to 32 test signals 520 of the first to 32nd antenna devices ANT1 to ANT32 are transmitted simultaneously. At this time, the first test signal 530 has a frequency of 3701 MHz, the second test signal 532 has a frequency of 3702 MHz, and the 32nd test signal 534 has a frequency of 3732 MHz. Even if the first test signal 530 flows into the second antenna device ANT2, the defect detector may distinguish the reflected signal of the second antenna device ANT2 using the frequencies of the test signals. Through this, it is possible to prevent incorrect determination of defects in filters and antenna elements due to the inflow of test signals from adjacent antenna devices.

In addition, the defect detection unit according to an embodiment of the present invention may sequentially transmit test signals having different frequencies.

Various implementations of the systems and techniques described herein may include digital electronic circuits, integrated circuits, field programmable gate arrays (FPGAs), application specific integrated circuits (ASICs), computer hardware, firmware, software, and/or these. It can be realized through combination. These various implementations may include being implemented as one or more computer programs executable on a programmable system. The programmable system includes at least one programmable processor (which may be a special purpose processor) coupled to receive data and instructions from and transmit data and instructions to a storage system, at least one input device, and at least one output device. or may be a general-purpose processor). Computer programs (also known as programs, software, software applications or code) contain instructions for a programmable processor and are stored on a "computer-readable medium."

Computer-readable recording media include all types of recording devices that store data that can be read by a computer system. These computer-readable recording media are non-volatile or non-transitory such as ROM, CD-ROM, magnetic tape, floppy disk, memory card, hard disk, magneto-optical disk, and storage device. It may be a medium, and may further include a transitory medium such as a data transmission medium. Additionally, the computer-readable recording medium may be distributed in a computer system connected to a network, and the computer-readable code may be stored and executed in a distributed manner.

In the flowchart/timing diagram of this specification, each process is described as being executed sequentially, but this is merely an illustrative explanation of the technical idea of an embodiment of the present disclosure. In other words, a person skilled in the art to which an embodiment of the present disclosure pertains may change the order described in the flowchart/timing diagram and execute one of the processes without departing from the essential characteristics of the embodiment of the present disclosure. Since the above processes can be modified and modified in various ways by executing them in parallel, the flowchart/timing diagram is not limited to a time series order.

The above description is merely an illustrative explanation of the technical idea of the present embodiment, and those skilled in the art will be able to make various modifications and variations without departing from the essential characteristics of the present embodiment. Accordingly, the present embodiments are not intended to limit the technical idea of the present embodiment, but rather to explain it, and the scope of the technical idea of the present embodiment is not limited by these examples. The scope of protection of this embodiment should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of rights of this embodiment.

10: Digital unit
20: Multiple transmitting and receiving circuits
30: Plurality of filter-antenna element pairs

Claims (9)

In an antenna system that detects defects in an antenna element and a filter connected to the antenna element,
A plurality of transmission and reception circuits connected to inspection objects including antenna elements and filters, each transmission and reception circuit connected to one inspection object and including a transmission circuit and a reception circuit sharing a connection with the inspection object; and
Transmitting a test signal through the transmission circuit, receiving a reflection signal of the test signal reflected by the inspection object through the reception circuit, and detecting a defect in the inspection object based on the strength of the reflection signal. Defect detection unit that detects
An antenna system comprising: According to paragraph 1,
The defect detection unit,
An antenna system that compares the intensities of reflected signals received through receiving circuits included in the plurality of transmitting and receiving circuits to determine whether the inspection objects are defective. According to paragraph 1,
The defect detection unit,
An antenna system that determines defects in the inspection target by comparing the intensity of the reflected signal with a preset value. According to paragraph 1,
The defect detection unit,
An antenna system that transmits the test signal within a protection interval between an uplink time interval and a downlink time interval. According to paragraph 4,
The defect detection unit,
An antenna system that transmits test signals at the same frequency and at the same time. According to paragraph 4,
The defect detection unit,
An antenna system that transmits test signals at different frequencies at the same time. According to paragraph 4,
The defect detection unit,
An antenna system that transmits test signals at different times at the same frequency. According to paragraph 1,
The receiving circuit includes a low noise amplifier (LNA),
The low noise amplifier is,
It includes a switch that receives a reflected signal, and an internal power amplifier connected to the filter according to the operation of the switch,
When the switch does not connect the internal power amplifier and the filter, the internal power amplifier amplifies the intensity of the reflected signal leaked from the switch. In a method for detecting defects in an antenna element and a filter connected to the antenna element,
Transmitting test signals to inspection objects including antenna elements and filters through a plurality of transmission and reception circuits, each transmission and reception circuit connected to one inspection object, and a transmission circuit and reception sharing a connection with the inspection object. Contains circuits;
obtaining intensities of reflected signals where the test signals are reflected by the inspection objects; and
Detecting defects in the inspection objects based on the intensities of the reflected signals
How to include .

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