JP6766955B2 - Beamforming antenna calibration circuit - Google Patents

Description

The present invention relates to wireless communication devices and antennas.

Conventionally, a wireless communication device (for example, a base station device) that realizes a beamforming function by using an array antenna has been proposed (for example, Patent Document 1). A wireless communication device that realizes a beamforming function by using such an array antenna has a plurality of communication systems including an antenna. Each communication system includes a transmission system and a reception system. Since there are individual differences in the functional parts (for example, up converter, down converter, amplifier, etc.) included in each communication system, even if the same transmission radio signal is input to multiple communication systems, for example, transmission at the antenna end The phase and amplitude of the radio signal may shift between multiple communication systems. Due to such a phase and amplitude shift, the beam direction of the radio wave radiated from the wireless communication device that realizes the beamforming function may shift from the desired direction. In order to form an antenna beam in a desired direction by using digital beamforming, it is necessary to match the phase and amplitude at each antenna end in advance. For this reason, an operation and mechanism called antenna calibration is required.

Therefore, conventionally, a calibration process (that is, a calibration process) is executed in a wireless communication device that realizes a beamforming function. For example, in the calibration process for a transmission system, a transmission calibration signal having a known pattern is input to each transmission system and passed through each transmission system. Then, using the transmission calibration signal that has passed through each transmission system as a feedback signal, the phase and amplitude deviation between the feedback signal and the original transmission calibration signal is detected. Then, the detected deviation is stored as an offset value, and when the radio signal is actually transmitted, this offset value is used as a correction value to correct the phase and amplitude of the transmission radio signal of each transmission system. As a result, it is possible to compensate for the phase and amplitude deviations at the antenna ends of a plurality of communication systems. Normally, the phase and amplitude deviations at the antenna ends of a plurality of communication systems change with the passage of temperature and time, so that the calibration process is performed periodically.

JP-A-2009-278529

By the way, when an obstacle (for example, a person or a bird) exists near the antenna, the antenna reflection loss (antenna return loss) may increase. In addition, an undesired wave (interference signal) may be received by the antenna.

If the antenna reflection loss increases and the reception of undesired waves occurs during the calibration period, accurate calibration may not be possible.

An object of the present invention is to provide a calibration circuit and a calibration method for a beamforming antenna, which enables accurate calibration.

The beamforming antenna calibration circuit according to the first aspect of the present invention is a calibration circuit that controls calibration for a plurality of communication systems of a wireless communication device that executes beamforming, and is a wireless communication of the wireless communication device. The adjustment control unit that executes the adjustment process for adjusting the correction value for at least one of the amplitude and the phase applied to the radio signal in the unit during the calibration period, and the antenna in each communication system during the calibration period. A detection unit that detects the level of the signal going to the wireless communication unit, and a suppression control unit that suppresses the adjustment process by the adjustment control unit when the signal level detected by the detection unit during the calibration period is equal to or higher than a predetermined level. , Equipped with.

The method for calibrating a beamforming antenna according to a second aspect of the present invention is a calibration method executed by a calibration circuit that controls calibration for a plurality of communication systems included in a wireless communication device that performs beamforming. In the process of detecting the level of the signal from the antenna to the wireless communication unit in each communication system during the period and adjusting the correction value for at least one of the amplitude and the phase applied to the wireless signal in the wireless communication unit. Therefore, the adjustment process executed during the calibration period is suppressed when the detected signal level is equal to or higher than a predetermined level.

INDUSTRIAL APPLICABILITY According to the present invention, it is possible to provide a calibration circuit and a calibration method of a beamforming antenna that enable accurate calibration.

It is a block diagram which shows an example of the wireless communication apparatus and calibration circuit of 1st Embodiment. It is a figure which provides the explanation of the processing operation of the calibration circuit of 1st Embodiment. It is a figure which provides the explanation of the processing operation of the calibration circuit of 1st Embodiment. It is a figure which provides the explanation of the processing operation of the calibration circuit of 1st Embodiment. It is a figure which provides for the explanation of the reflection of the transmission power in an antenna. It is a figure which provides the explanation of the flow of the external interference wave. It is a block diagram which shows an example of the wireless communication apparatus and the calibration circuit of 2nd Embodiment.

Hereinafter, embodiments will be described with reference to the drawings. In the embodiment, the same or equivalent elements are designated by the same reference numerals, and duplicate description is omitted.

<First Embodiment>
<Configuration example of calibration circuit>
FIG. 1 is a block diagram showing an example of the wireless communication device and the calibration circuit of the first embodiment. In this embodiment, four antennas are combined to perform beamforming. After passing through the signal processing unit 21 and the correction unit (phase / amplitude correction unit) 22 that generate the radio signal, the transmission signal is an upconverter 23-1 to 4, an amplifier (transmission amplifier) 24-1 to 4, and a switch (transmission amplifier). The transmission / reception changeover switch) 25-1 to 4 and the directional coupler 7-1 to 4 pass in this order, and are output by the antennas 3-1 to 4. After the received signal is input to the antennas 3-1 to 4, the directional coupler 7-1 to 4, the switch (transmission / reception switch) 25-1 to 4, the amplifier (reception amplifier) 27-1 to 4, down. After passing through the converters 26-1 to 4 and the correction unit (phase / amplitude correction unit) 22, the signal is sent to the signal processing unit 21. Further, in the directional couplers 7-1 to 4, the port on the transmission / reception circuit side is connected to the divider / combiner (DIV / COMB) 63, and the combined port of the divider / combiner 63 is a switch (transmission / reception changeover switch) 61. It is connected to the calibration signal generation / calibration signal processing unit 50 via the up converter 59 and the down converter 67. On the other hand, the ports on the antenna side of the directional couplers 7-1 to 4 are connected to the calibration signal generation / calibration signal processing unit 50 via the combine harvester (COMB) 69 and the detection unit (signal level detection circuit) 53. There is.

<Details of calibration circuit configuration example>
In FIG. 1, the wireless communication device 1 of the first embodiment includes a wireless communication unit 2, four antennas 3-1, 3-2, 3-3, 3-4, and a calibration circuit (calibration unit) 5. It has directional couplers 7-1, 7-2, 7-3, 7-4. The antennas 3-1, 3-2, 3-3, 3-4 are the "first communication system", the "second communication system", the "third communication system", and the "fourth communication system", which will be described later, respectively. Included in. In the following, antennas 3-1, 3-2, 3-3, 3-4 may be generically referred to simply as antenna 3. Further, the first communication system, the second communication system, the third communication system, and the fourth communication system may be collectively referred to as a communication system. Here, as an example, the number of antennas 3, that is, the number of communication systems is 4, but the number is not limited to this number.

The wireless communication unit 2 includes a signal processing unit 21, a correction unit 22, an upconverter 23-1,23-2,23-3,23-4, and an amplifier 24-1,24-2,24-3,24. -4, switches 25-1,25-2,25-3,25-4, downconverters 26-1,26-2,26-3,26-4, amplifiers 27-1,27-2, It has 27-3 and 27-4. The upconverter 23-1, the amplifier 24-1, and the switch 25-1 are included in the first transmission system, and the switch 25-1, the amplifier 27-1, and the downconverter 26-1 are included in the first reception system. Is done. These first transmission system and first reception system are included in the first communication system. Similarly, the upconverter 23-2, the amplifier 24-2, and the switch 25-2 are included in the second transmission system, and the switch 25-2, the amplifier 27-2, and the downconverter 26-2 are the second reception. Included in the system. These second transmission system and second reception system are included in the second communication system. Similarly, the upconverter 23-3, the amplifier 24-3, and the switch 25-3 are included in the third transmission system, and the switch 25-3, the amplifier 27-3, and the downconverter 26-3 are the third reception. Included in the system. These third transmission system and third reception system are included in the third communication system. Similarly, the upconverter 23-4, the amplifier 24-4, and the switch 25-4 are included in the fourth transmission system, and the switch 25-4, the amplifier 27-4, and the downconverter 26-4 are the fourth reception. Included in the system. These fourth transmission system and fourth reception system are included in the fourth communication system.

In the following, the upconverters 23-1,23-2,23-3,23-4 may be collectively referred to as the upconverter 23. In addition, amplifiers 24-1, 24-2, 24-3, 24-4 may be collectively referred to as amplifier 24. In addition, switches 25-1,25-2,25-3,25-4 may be collectively referred to as switch 25. Further, the down converters 26-1, 26-2, 26-3, and 26-4 are collectively referred to as the down converter 26. In addition, amplifiers 27-1, 27-2, 27-3, and 27-4 may be collectively referred to as amplifier 27.

The signal processing unit 21 inputs a transmission signal which is a baseband signal in the “transmission period” and converts the transmission signal into a transmission radio signal. Further, in the "reception period", the signal processing unit 21 converts the corrected reception radio signal into a reception signal which is a baseband signal, and outputs the obtained reception signal to the baseband processing unit (not shown). To do.

The correction unit 22 duplicates the transmission radio signal received from the signal processing unit 21 during the “transmission period” to form four transmission radio signals corresponding to each of the four transmission systems. Then, the correction unit 22 applies the first correction value set for each transmission system to each transmission radio signal in order to compensate for the phase and amplitude deviation at the antenna end. The phase and amplitude of the transmission radio signal of each transmission system are corrected.

Further, the correction unit 22 applies the second correction value set for each reception system to each reception radio signal after the reception radio processing in each reception system in the “reception period”. Correct the phase and amplitude of the received radio signal.

Further, the correction unit 22 duplicates the transmission calibration signal received from the calibration circuit 5 in the “transmission calibration period” to form four transmission calibration signals corresponding to each of the four transmission systems. Then, the correction unit 22 corrects the phase and amplitude of the transmission calibration signal of each transmission system by applying the first correction value set for each transmission system to each transmission calibration signal. Here, since the calibration processing for the four transmission systems is performed by shifting the timing for each transmission system, the correction unit 22 shifts the output timing for the four transmission systems and outputs the corrected transmission calibration signal. .. Here, for example, when the wireless communication device 1 communicates by time division duplex (TDD), the "transmission calibration period" is the reception period and the transmission period when switching from the reception period to the transmission period. It can be a period in between.

Further, the correction unit 22 receives the reception calibration signal transmitted from the calibration circuit 5 and passed through each reception system in the "reception calibration period", and receives the reception calibration signal received from each reception system to each reception system. By applying the second correction value set for the received calibration signal, the phase and amplitude of the received calibration signal are corrected. The received calibration signal after these corrections is output to the calibration circuit 5. For example, when the wireless communication device 1 communicates by time division duplex (TDD), the "reception calibration period" is the period between the transmission period and the reception period when switching from the transmission period to the reception period. Can be.

The switch 25-1 connects the amplifier 24-1 of the first transmission system and the directional coupler 7-1 in the “transmission period” and the “transmission calibration period”, while the “reception period” and the “reception calibration period”. In ", the amplifier 27-1 of the first receiving system and the directional coupler 7-1 are connected. The other switches 25-2, 25-3, 25-4 also perform the same switching as the switch 25-1.

The upconverter 23-1 and the amplifier 24-1 of the first transmission system perform transmission radio processing (that is, up-conversion and amplification) on the corrected transmission radio signal in the "transmission period" to perform transmission radio processing. The later transmission radio signal is output to the directional coupler 7-1 via the switch 25-1. This transmission radio signal is transmitted via the directional coupler 7-1 and the antenna 3-1. The second transmission system, the third transmission system, and the fourth transmission system are the same as those of the first transmission system.

Further, the upconverter 23-1 and the amplifier 24-1 of the first transmission system perform transmission radio processing (that is, up-conversion and amplification) on the corrected transmission calibration signal in the “transmission calibration period”. The transmission calibration signal after the transmission radio processing is output to the directional coupler 7-1 via the switch 25-1. The second transmission system, the third transmission system, and the fourth transmission system are the same as those of the first transmission system.

The amplifier 27-1 and the down converter 26-1 of the first receiving system perform reception radio processing (that is, amplification and down conversion) on the received radio signal received via the switch 25-1 during the “reception period”. Then, the received radio signal after the received radio processing is output to the correction unit 22. The second receiving system, the third receiving system, and the fourth receiving system are the same as those of the first receiving system.

Further, the amplifier 27-1 and the down converter 26-1 of the first reception system receive radio processing (that is, amplification and down conversion) for the reception calibration signal received via the switch 25-1 during the “reception calibration period”. ) Is applied, and the reception calibration signal after the reception radio processing is output to the correction unit 22. The second receiving system, the third receiving system, and the fourth receiving system are the same as those of the first receiving system.

The directional coupler 7-1 of the first communication system has four ports P11, P12, P13, and P14. The port P11 is connected to the switch 25-1 of the wireless communication unit 2. Port P12 is connected to antenna 3-1. Then, the port P11 and the port P12 are connected in the directional coupler 7-1. Further, the port P13 is coupled to the port P11 and is also connected to the divider / combiner 63 of the calibration circuit 5 described later. Further, the port P14 is coupled to the port P12 and is also connected to the combiner 69 of the calibration circuit 5 described later. That is, the reception calibration signal input to the port P13 is input to the wireless communication unit 2 via the port P11. Further, signals flowing from the port P12 toward the port P11 (for example, a signal reflected by the antenna 3-1 and an undesired signal received by the antenna 3-1) are sent to the combiner 69 via the port P14. It will be entered. The second communication system, the third communication system, and the fourth communication system are the same as those of the first communication system. That is, the directional coupler 7-2 of the second communication system has four ports P21, P22, P23, P24, and the directional coupler 7-3 of the third communication system has four ports P31, P32. , P33, P34, and the directional coupler 7-4 of the fourth communication system has four ports P41, P42, P43, P44, and these connection relationships are the ports of the first communication system. This is the same as P11, P12, P13, and P14. Hereinafter, ports P11, P21, P31, and P41 may be collectively referred to as port 1. Further, ports P12, P22, P32, and P42 may be generically referred to as port 2. Further, ports P13, P23, P33, and P43 may be generically referred to as port 3. Further, ports P14, P24, P34, and P44 may be generically referred to as port 4.

As shown in FIG. 1, the calibration circuit 5 of the first embodiment includes an adjustment control unit 51, a detection unit 53, a suppression control unit 55, a calibration signal transmission unit 57, an upconverter 59, a switch 61, and the like. It has a divider / combiner (DIV / COMB) 63, a calibration signal receiving unit 65, a down converter 67, and a combiner (COMB) 69. The adjustment control unit 51, the suppression control unit 55, the calibration signal transmission unit 57, and the calibration signal reception unit 65 are included in the calibration signal generation / calibration signal processing unit 50.

The calibration signal transmission unit 57 outputs the transmission calibration signal to the correction unit 22 during the “transmission calibration period”. Further, the calibration signal transmission unit 57 outputs the reception calibration signal to the upconverter 59 during the “reception calibration period”.

The upconverter 59 receives the reception calibration signal during the “reception calibration period”, upconverts the reception calibration signal, and sends the reception calibration signal to the divider / combiner 63 via the switch 61.

The switch 61 connects the upconverter 59 and the divider / combiner 63 in the “reception calibration period”, and connects the divider / combiner 63 and the downconverter 67 in the “transmission calibration period”.

The divider / combiner 63 is connected to ports P13, 23, 33, 43 of the directional couplers 7-1, 7-2, 7-3, 7-4, respectively. Then, the divider / combiner 63 receives the reception calibration signal via the switch 61 in the "reception calibration period", and receives the received calibration signal to the directional couplers 7-1, 7-2, 7-3, 7. Distribute to -4. The distributed reception calibration signal is sent to the first reception system, the second reception system, the third reception system, and the fourth reception via the directional couplers 7-1, 7-2, 7-3, and 7-4. It will pass through the system. Further, in the "transmission calibration period", the divider / combiner 63 transfers the transmission calibration signal that has passed through the first transmission system, the second transmission system, the third transmission system, and the fourth transmission system to the directional coupler 7. It is received via -1,7-2,7-3,7-4, and the received transmission calibration signal is output to the down converter 67 via the switch 61.

The down converter 67 down-converts the transmission calibration signal received via the switch 61 during the “transmission calibration period” and outputs the transmission calibration signal to the calibration signal receiving unit 65.

The calibration signal receiving unit 65 has passed through the first receiving system, the second receiving system, the third receiving system, the fourth receiving system, and the correction unit 22 in the “reception calibration period”, respectively. Receive a signal. Further, the calibration signal receiving unit 65 has passed through the correction unit 22 and the first transmission system, the second transmission system, the third transmission system, and the fourth transmission system in the “transmission calibration period”, respectively. The transmission calibration signal is received via the divider / combiner 63, the switch 61, and the down converter 67.

The adjustment control unit 51 executes a second adjustment process for adjusting the second correction value in the “reception calibration period”. Specifically, the adjustment control unit 51 receives the received calibration signal received by the calibration signal receiving unit 65 in the “reception calibration period” and has passed through each receiving system, and the source transmitted from the calibration signal transmitting unit 57. The second correction value corresponding to each reception system is adjusted by using the reception calibration signal of. The adjusted second correction value will be set in the correction unit 22.

Further, the adjustment control unit 51 executes the first adjustment process for adjusting the first correction value in the “transmission calibration period”. Specifically, the adjustment control unit 51 receives the transmission calibration signal received by the calibration signal receiving unit 65 in the "transmission calibration period" and has passed through each transmission system, and the source transmitted from the calibration signal transmitting unit 57. The first correction value corresponding to each transmission system is adjusted by using the transmission calibration signal of. The adjusted first correction value will be set in the correction unit 22.

The combiner 69 is connected to ports P14, 24, 34, 44 of the directional couplers 7-1, 7-2, 7-3, and 7-4, respectively. The combiner 69 outputs the signal received via each of the ports P14, 24, 34, 44 to the detection unit 53.

The detection unit 53 detects the level of the signal received via the combiner 69. That is, the detection unit 53 can detect the level of the signal from the antenna 3 to the wireless communication unit 2. The detected signal level may include the level of antenna reflection loss due to the signal reflected by the antenna 3 and the level of the undesired signal (interference signal) received by the antenna 3. In particular, during the "transmission calibration period", the level of antenna reflection loss is likely to be higher than the level of the undesired signal, which is a major factor in reducing the accuracy of calibration. On the other hand, in the "reception calibration period", the level of the undesired signal is likely to be higher than the level of the antenna reflection loss, which is a main factor for lowering the calibration accuracy.

When the signal level detected by the detection unit 53 is equal to or higher than a predetermined level, the suppression control unit 55 executes control for suppressing the adjustment process by the adjustment control unit 51 (that is, control for interrupting). That is, when the signal level detected by the detection unit 53 becomes a predetermined level or higher in the “transmission calibration period”, the suppression control unit 55 suppresses the first adjustment process by the adjustment control unit 51. Further, the suppression control unit 55 suppresses the second adjustment process by the adjustment control unit 51 when the signal level detected by the detection unit 53 becomes equal to or higher than a predetermined level in the “reception calibration period”. Due to the suppression of the first adjustment process, in the "transmission period" that comes after the transmission calibration period, the correction unit 22 uses the first correction value adjusted in the transmission calibration period before the transmission calibration period. The phase and amplitude of the transmitted radio signal will be corrected. Similarly, due to the suppression of the second adjustment process, in the "reception period" that comes after the reception calibration period, the correction unit 22 sets the second correction value adjusted in the reception calibration period before the reception calibration period. It will be used to correct the phase and amplitude of the received radio signal. By the suppression control of the suppression control unit 55, it is possible to prevent the calibration from being continued in a situation where the calibration accuracy may be lowered. As a result, it is possible to prevent the antenna from being calibrated out of order, so that accurate calibration is possible.

<Operation example of calibration circuit>
In this embodiment, a calibration operation similar to that of a general beam forming antenna is usually performed. In the present embodiment, since the wireless communication device 1 is a TDD device, the transmission period and the reception period are switched by time division, but the calibration on the transmission side and the calibration on the reception side are periodically performed by using the time in the gap. Is repeatedly executed.

As for the calibration on the transmitting side, the calibration is sequentially executed one by one for each of the four transmitting systems. The calibration signal generated by the calibration signal generation / calibration signal processing unit 50 is sent to the end of the antenna via the upconverter 23-1 and the amplifier (transmission amplifier) 24-1, but is sent by the directional coupler 7-1. A part is taken out and compared with the original calibration signal by the calibration signal generation / calibration signal processing unit 50 via the divider / combiner 63 and the down converter 67. Based on the result of sequentially comparing the four systems, the correction unit (phase amplitude correction unit) 22 adds or subtracts the correction value so that the phase amplitude at the antenna end is the same.

For calibration on the receiving side, a calibration signal is sent from the calibration signal generation / calibration signal processing unit 50, converted to a transmission frequency by the upconverter 59, and then the directional coupler of each receiving system is connected via the divider / combiner 63. It is injected into 7-1-4. The calibration signal of each receiving system is input to the calibration signal generation / calibration signal processing unit 50 via an amplifier (reception amplifier) 27-1 to 4 and a down converter 26-1 to 4. The calibration signal generation / calibration signal processing unit 50 is corrected by the correction unit (phase amplitude correction unit) 22 so that the input signal is compared with the original calibration signal and the phase amplitudes of the four receiving systems are aligned. Add or subtract the value.

<Details of operation example of calibration circuit>
The details of the processing operation of the wireless communication device 1 and the calibration circuit 5 of the first embodiment will be described.

<Processing operation during transmission calibration period>
When the "reception period" is switched to the "transmission calibration period", the four switches 25 are switched so that the amplifier 24 and the directional coupler 7 are connected to each other. Further, the switch 61 is switched so that the divider / combiner 63 and the down converter 67 are connected.

Next, the calibration signal transmission unit 57 outputs the transmission calibration signal to the correction unit 22. This transmission calibration signal is duplicated by the correction unit 22 into four transmission calibration signals, and the four transmission calibration signals are transmitted correction signals by applying the first correction value set in the corresponding transmission system. The phase and amplitude of are corrected. Then, the corrected transmission calibration signals are output to the four transmission systems with their output timings shifted from each other. That is, the timings of the calibration processes of the four transmission systems are staggered from each other. Then, the transmission calibration signal that has passed through each transmission system is sequentially received by the calibration signal receiving unit 65 after passing through the directional coupler 7, the divider / combiner 63, and the down converter 67.

The adjustment control unit 51 uses the transmission calibration signal that has passed through each transmission system received by the calibration signal reception unit 65 and the original transmission calibration signal transmitted from the calibration signal transmission unit 57, and is used for each transmission system. The first correction value corresponding to is adjusted.

However, when the signal level detected by the detection unit 53 is less than the predetermined level, the suppression control unit 55 continues the first adjustment process by the adjustment control unit 51, while the signal level detected by the detection unit 53 is predetermined. When the level is higher than the level, the first adjustment process by the adjustment control unit 51 is suppressed. Due to the suppression of the first adjustment process, in the "transmission period" that comes after the transmission calibration period, the correction unit 22 transmits using the first correction value adjusted in the transmission calibration period before the transmission calibration period. The phase and amplitude of the radio signal will be corrected.

2 and 3 are diagrams for explaining the processing operation of the calibration circuit of the first embodiment. In each of the upper figures of FIGS. 2 and 3, "RX" represents a reception period, "TX" represents a transmission period, "TX CAL" represents a transmission calibration period, and "RX CAL" represents a transmission calibration period. Represents the reception calibration period. Further, in the lower figures of FIGS. 2 and 3, examples of changes in the detection level are shown.

In the transition of the detection level shown in FIG. 2, the detection level is lower than the threshold value Th in both the transmission calibration period and the reception calibration period. Therefore, since the suppression control unit 55 does not suppress the adjustment process by the adjustment control unit 51, the adjustment control unit 51 executes (completes) the first adjustment process during the transmission calibration period and performs the second adjustment process during the reception calibration period. It is running (completed). The threshold value Th indicates a reference level.

On the other hand, in the transition of the detection level shown in FIG. 3, the detection level is larger than the threshold value in one transmission calibration period. Therefore, the suppression control unit 55 suppresses the first adjustment process during the transmission calibration period by the adjustment control unit 51. Due to the suppression of the first adjustment process, in the "transmission period" that comes after the transmission calibration period, the wireless communication unit 2 uses the first correction value adjusted in the transmission calibration period before the transmission calibration period. , The phase and amplitude of the transmitted radio signal will be corrected.

<Processing operation during reception calibration period>
When the "transmission period" is switched to the "reception calibration period", the four switches 25 are switched so that the amplifier 27 and the directional coupler 7 are connected to each other. Further, the switch 61 is switched so that the divider / combiner 63 and the upconverter 59 are connected.

Next, the calibration signal transmission unit 57 outputs the reception calibration signal to the upconverter 59. After being up-converted, the reception calibration signal is distributed to each of the four reception systems by the divider / combiner 63. Then, the reception calibration signal that has passed through each reception system is corrected in phase and amplitude by applying the second correction value set in each reception system by the correction unit 22, and then the calibration signal reception unit 65 corrects the phase and amplitude. Received.

The adjustment control unit 51 uses each reception system using the reception calibration signal received by the calibration signal reception unit 65 that has passed through each reception system and the original reception calibration signal transmitted from the calibration signal transmission unit 57. The second correction value corresponding to is adjusted.

However, when the signal level detected by the detection unit 53 is less than the predetermined level, the suppression control unit 55 continues the second adjustment process by the adjustment control unit 51, while the signal level detected by the detection unit 53 is predetermined. When the level is higher than the level, the second adjustment process by the adjustment control unit 51 is suppressed. Due to the suppression of the second adjustment process, in the "reception period" that comes after the reception calibration period, the correction unit 22 receives using the second correction value adjusted in the reception calibration period before the reception calibration period. The phase and amplitude of the radio signal will be corrected.

FIG. 4 is a diagram provided for explaining the processing operation of the calibration circuit of the first embodiment. In the upper figure of FIG. 4, "RX" represents a reception period, "TX" represents a transmission period, "TX CAL" represents a transmission calibration period, and "RX CAL" represents a reception calibration period. ing. Further, in the lower figure of FIG. 4, an example of the transition of the detection level is shown.

In the transition of the detection level shown in FIG. 4, the detection level is larger than the threshold value in one reception calibration period. Therefore, the suppression control unit 55 suppresses the second adjustment process during the reception calibration period by the adjustment control unit 51. Due to the suppression of the second adjustment process, in the "reception period" that comes after the reception calibration period, the wireless communication unit 2 uses the second correction value adjusted in the reception calibration period before the reception calibration period. , The phase and amplitude of the received radio signal will be corrected.

Here, consider a case where an obstacle such as a person or a bird approaches the vicinity of the antenna 3. At this time, the return loss of the antenna 3 deteriorates, so that the load of the amplifier 24 fluctuates. When the load of the amplifier 24 fluctuates, the characteristics of the amplifier change, so that the phase and amplitude are out of order. Generally, in order to carry out beamforming, practical characteristics cannot be obtained unless the phase fluctuation level is suppressed to several degrees and the amplitude fluctuation level is suppressed to the order of 1/10 decibel. Therefore, even a slight characteristic variation regarding the load variation of the amplifier 24 cannot be ignored.

When the return loss deteriorates, the reflection of the transmission power at the antenna 3 becomes large. In FIG. 5, the reflection of the transmitted power at the antenna is indicated by an arrow. The detection unit 53 can detect the reflection of this transmission power. Then, as described above, the suppression control unit 55 executes control for suppressing the adjustment process by the adjustment control unit 51 when the signal level detected by the detection unit 53 is equal to or higher than a predetermined level. That is, when the detection unit 53 detects a signal level equal to or higher than a predetermined level, it acts to interrupt the calibration operation. If the calibration is interrupted, use the previous calibration calibration value and do not change the phase amplitude correction value of the signal. In FIG. 5, for the sake of brevity, only the first communication system is shown, and the second communication system, the third communication system, and the fourth communication system are omitted.

Next, consider a case where an interference wave (undesired wave) is input from the outside of the wireless communication device 1. If an external interference wave is received through the antenna 3 during the reception calibration period, the phase and amplitude of the reception calibration signal will change due to the influence of the external interference wave, and accurate calibration will not be possible. When the interference wave level is high, the signal level flowing through the port P14 is also high. In FIG. 6, the flow of the external interference wave is indicated by an arrow. The detection unit 53 can detect the level of this external interference wave. Then, as described above, the suppression control unit 55 executes control for suppressing the adjustment process by the adjustment control unit 51 when the signal level detected by the detection unit 53 is equal to or higher than a predetermined level. That is, when the detection unit 53 detects a signal level equal to or higher than a predetermined level, it acts to interrupt the calibration operation. If the calibration is interrupted, use the previous calibration calibration value and do not change the phase amplitude correction value of the signal. In FIG. 6, for the sake of brevity, only the first communication system is shown, and the second communication system, the third communication system, and the fourth communication system are omitted.

As described above, according to the first embodiment, the wireless communication device 1 is provided between the antenna 3 and the wireless communication unit 2 in each communication system, and the port P1 and the antenna connected to the wireless communication unit 2 side. It has a directional coupler 7 including a port P2 connected to the side of 3, a port P3 coupled to the port P1, and a port P4 coupled to the port P2. Then, the calibration circuit 5 transmits a calibration signal transmission unit 57 that transmits a transmission calibration signal toward the port P1 during the transmission calibration period, and a transmission calibration signal that is transmitted from the calibration signal transmission unit 57 and has passed through the transmission system of the communication system. It has a calibration signal receiving unit 65 that receives the calibration signal via the port P3. Then, the adjustment control unit 51 adjusts the first correction value based on the original transmission calibration signal transmitted from the calibration signal transmission unit 57 and the transmission calibration signal received by the calibration signal reception unit 65. Execute the process. However, when the signal level detected by the detection unit 53 during the transmission calibration period is equal to or higher than a predetermined level, the suppression control unit 55 suppresses the first adjustment process by the adjustment control unit 51.

With this configuration of the calibration circuit 5, when the level of antenna reflection loss, which is a main factor for reducing the calibration accuracy during the transmission calibration period, becomes large, the first adjustment process by the adjustment control unit 51 can be suppressed. As a result, it is possible to prevent the calibration from being continued in a situation where the calibration accuracy may be lowered. As a result, it is possible to prevent the antenna from being calibrated out of order, so that accurate calibration is possible.

Further, in the calibration circuit 5, the calibration signal transmission unit 57 transmits a reception calibration signal toward the port P3 during the reception calibration period, and the calibration signal reception unit 65 is transmitted from the calibration signal transmission unit 57 and receives the communication system. Receives the reception calibration signal that has passed through the system. Then, the detection unit 53 detects the signal level received via the port P4 during the reception calibration period. Then, the adjustment control unit 51 executes a second adjustment process for adjusting the second correction value based on the original reception calibration signal transmitted from the calibration signal transmission unit 57 and the received reception calibration signal. However, when the signal level detected by the detection unit 53 during the reception calibration period is equal to or higher than a predetermined level, the suppression control unit 55 suppresses the second adjustment process by the adjustment control unit 51.

With this configuration of the calibration circuit 5, when the level of the undesired wave, which is the main factor for lowering the calibration accuracy during the reception calibration period, becomes high, the second adjustment process by the adjustment control unit 51 can be suppressed. As a result, it is possible to prevent the calibration from being continued in a situation where the calibration accuracy may be lowered. As a result, it is possible to prevent the antenna from being calibrated out of order, so that accurate calibration is possible.

<Second Embodiment>
The second embodiment relates to an embodiment in which an up converter and a down converter are also used between the wireless communication device and the calibration circuit.

FIG. 7 is a block diagram showing an example of the wireless communication device and the calibration circuit of the second embodiment. In FIG. 7, the wireless communication device 1 has switches 71, 72, 73, 74. Here, in the second embodiment, as compared with the first embodiment, the up converters 23-3, 23-4, the amplifiers 24-3, 24-4, and the down converters 26-3, 26-4 of the wireless communication device 1 are used. , And amplifiers 27-3 and 27-4 are also used with the calibration circuit 5. Therefore, the calibration circuit 5 of the second embodiment does not have the up converter 59, the switch 61, and the down converter 67 as compared with the first embodiment.

In the "transmission period", switches 71 and 72 connect the amplifier 24-3 of the third transmission system and the directional coupler 7-3, and switches 73 and 74 connect with the amplifier 24-4 of the fourth transmission system. Connect with the directional coupler 7-4.

In the "reception period", switches 71 and 72 connect the amplifier 27-3 of the third receiving system and the directional coupler 7-3, and switches 73 and 74 connect with the amplifier 27-4 of the fourth receiving system. Connect with the directional coupler 7-4.

The "transmission calibration period" of the second embodiment includes a "first transmission calibration partial period" and a "second transmission calibration partial period" after the first transmission calibration partial period, which do not overlap in time with each other. In the "first transmission calibration partial period", the switches 71 and 72 connect the amplifier 24-3 of the third transmission system and the directional coupler 7-3, while the switches 73 and 74 are the fourth reception system. The amplifier 27-4 of the above and the divider / combiner 63 are connected. As a result, the transmission calibration signal transmitted from the calibration signal transmission unit 57 passes through the first transmission system, the second transmission system, and the third transmission system, and then the directional couplers 7-1, 7-2, 7 -3, Divider / combiner 63, switches 73, 74, amplifier 27-4, and down converter 26-4 will be received by the calibration signal receiver 65.

Here, in the "first transmission calibration partial period", the calibration signal receiving unit 65 cannot receive the transmission calibration signal that has passed through the fourth transmission system. Therefore, in the "second transmission calibration partial period", the switches 71 and 72 connect the amplifier 27-3 of the third receiving system and the divider / combiner 63, while the switches 73 and 74 are the fourth transmitting system. The amplifier 24-4 and the directional combine harvester 7-4 are connected. As a result, the transmission calibration signal transmitted from the calibration signal transmission unit 57 passes through the first transmission system, the second transmission system, and the fourth transmission system, and then the directional couplers 7-1, 7-2, 7 It will be received by the calibration signal receiver 65 via the -4, the divider / combiner 63, the switches 71 and 72, the amplifier 27-3, and the down converter 26-3.

Similarly, the "reception calibration period" of the second embodiment includes a "first reception calibration partial period" and a "second reception calibration partial period" after the first reception calibration partial period, which do not overlap in time with each other. I'm out. In the "first reception calibration partial period", the switches 71 and 72 connect the amplifier 27-3 of the third reception system and the directional coupler 7-3, while the switches 73 and 74 are the fourth transmission system. The amplifier 24-4 and the divider / combiner 63 of the above are connected. As a result, the received calibration signal transmitted from the calibration signal transmission unit 57 to the upconverter 23-4 of the fourth transmission system is the upconverter 23-4, the amplifier 24-4, the switches 73, 74, the divider / combiner 63, and the like. And, after passing through the directional couplers 7-1, 7-2, and 7-3, they pass through the first receiving system, the second receiving system, and the third receiving system, respectively, and are received by the calibration signal receiving unit 65. Will be.

Here, in the "first reception calibration partial period", the calibration signal receiving unit 65 cannot receive the reception calibration signal that has passed through the fourth receiving system. Therefore, in the "second reception calibration partial period", the switches 71 and 72 connect the amplifier 24-3 of the third transmission system and the divider / combiner 63, while the switches 73 and 74 are the fourth reception system. The amplifier 27-4 and the directional combine harvester 7-4 are connected. As a result, the received calibration signal transmitted from the calibration signal transmission unit 57 to the upconverter 23-3 of the third transmission system is the upconverter 23-3, the amplifier 24-3, the switches 71, 72, the divider / combiner 63, and the like. And, after passing through the directional couplers 7-1, 7-2, and 7-4, they pass through the first receiving system, the second receiving system, and the fourth receiving system, respectively, and are received by the calibration signal receiving unit 65. Will be.

The same effect as that of the first embodiment can be obtained by the configuration of the wireless communication device 1 and the calibration circuit 5 of the second embodiment as described above. Further, according to the configuration of the wireless communication device 1 and the calibration circuit 5 of the second embodiment, the up converters 23-3, 23-4, the amplifiers 24-3, 24-4, and the down converter 26-3 of the wireless communication device 1 , 26-4, and amplifiers 27-3, 27-4 are also used with the calibration circuit 5, so that the device can be made compact.

Although the present invention has been described above with reference to the embodiments, the present invention is not limited to the above. Various changes that can be understood by those skilled in the art can be made within the scope of the invention in the configuration and details of the invention of the present application.

This application claims priority on the basis of Japanese application Japanese Patent Application No. 2017-0808874 filed on April 14, 2017, the entire disclosure of which is incorporated herein by reference.

1 Wireless communication device 2 Wireless communication unit 5 Calibration circuit 7 Directional coupler 21 Signal processing unit 22 Correction unit 23,59 Upconverter 24,27 Amplifier 25,61,71,72,73,74 Switch 26,67 Downconverter 50 Calibration signal generation / calibration signal processing unit 51 Adjustment control unit 53 Detection unit 55 Suppression control unit 57 Calibration signal transmission unit 63 Divider / combiner 65 Calibration signal receiver 69 Combiner P1, P2, P3, P4 ports

Claims (6)

A calibration circuit for a beamforming antenna that controls calibration for a plurality of communication systems of a wireless communication device that performs beamforming.
An adjustment control unit that executes an adjustment process for adjusting a correction value for at least one of amplitude and phase, which is applied to a wireless signal in the wireless communication unit of the wireless communication device, during a calibration period.
During the calibration period, a detection unit that detects the level of the signal from the antenna to the wireless communication unit in each communication system,
When the signal level detected by the detection unit during the calibration period is equal to or higher than a predetermined level, the suppression control unit that suppresses the adjustment processing by the adjustment control unit and the suppression control unit.
A calibration circuit provided with. The calibration period includes a transmission calibration period and a reception calibration period.
The adjustment control unit executes a first adjustment process for adjusting a first correction value applied to a transmission radio signal at the time of wireless transmission in the wireless communication unit during the transmission calibration period.
The suppression control unit suppresses the first adjustment process by the adjustment control unit when the signal level detected by the detection unit during the transmission calibration period is equal to or higher than a predetermined level.
The calibration circuit according to claim 1. The calibration period includes a transmission calibration period and a reception calibration period.
The adjustment control unit executes a second adjustment process for adjusting a second correction value applied to the received radio signal at the time of wireless reception in the wireless communication unit during the reception calibration period.
When the signal level detected by the detection unit during the reception calibration period is equal to or higher than a predetermined level, the suppression control unit suppresses the second adjustment process by the adjustment control unit.
The calibration circuit according to claim 1 or 2. The wireless communication device is provided between an antenna and a wireless communication unit in each communication system and is connected to the wireless communication unit side, a second port connected to the antenna side, and the first port. It has a directional coupler that includes a third port to be coupled with and a fourth port to be coupled to the second port.
The calibration circuit transmits a transmission calibration signal that transmits a transmission calibration signal toward the first port during the transmission calibration period, and a transmission calibration signal that is transmitted and passes through the transmission system of the communication system via the third port. Further equipped with a receiving unit for receiving,
The adjustment control unit adjusts the first correction value based on the transmitted transmission calibration signal and the received transmission calibration signal.
The detection unit detects the signal level received through the fourth port during the transmission calibration period.
The calibration circuit according to claim 2. The wireless communication device is provided between an antenna and a wireless communication unit in each communication system and is connected to the wireless communication unit side, a second port connected to the antenna side, and the first port. It has a directional coupler that includes a third port to be coupled with and a fourth port to be coupled to the second port.
The calibration circuit includes a transmission unit that transmits a reception calibration signal toward the third port during the reception calibration period, and a reception unit that receives the reception calibration signal that is transmitted and has passed through the reception system of the communication system. Further equipped
The adjustment control unit adjusts the second correction value based on the transmitted reception calibration signal and the received reception calibration signal.
The detection unit detects the signal level received through the fourth port during the reception calibration period.
The calibration circuit according to claim 3. It is a calibration method executed by a calibration circuit of a beamforming antenna that controls calibration for a plurality of communication systems of a wireless communication device that executes beamforming.
During the calibration period, the level of the signal from the antenna to the wireless communication unit is detected in each communication system.
The detected signal level is a predetermined level in the adjustment process that is applied to the wireless signal in the wireless communication unit to adjust the correction value for at least one of the amplitude and the phase and is executed in the calibration period. If it is above, deter,
Calibration method.

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