JP2017003361A - Signal processor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable adaptive array processing to be executed by an operation with a lower load, and to prevent reduction in gain of main lobe of an antenna pattern and azimuth deviation.SOLUTION: There is provided a load data acquisition part 24 acquiring load data corresponding to determination results of an interference radio wave entrance presence determination part 21 and a beam azimuth of a phased array antenna from load data stored in a load data storage part 23. A DBF processing part 25 multiplies digital signals output from AD converters 13-1 to 13-M by DBF load wto wshown by the load data acquired by the load data acquisition part 24.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a signal processing apparatus that combines received signals of a plurality of subarrays constituting a phased array antenna by a DBF (Digital Beam Forming) method.

In recent years, signal processing apparatuses that use the DBF method are often used.
The DBF method is a method in which an AD converter is provided for each sub-array constituting the phased array antenna, the received signals of the plurality of sub-arrays are converted into digital signals, and the plurality of digital signals are combined with the digital signal processing. It is.
In the DBF method, by performing array signal synthesis, the gain of a desired signal can be increased, and a null forming process, which is a process for bringing the gain of an unnecessary signal close to 0, is also possible.

Non-Patent Document 1 below discloses an adaptive array process in which a Null is formed according to received signals of a plurality of subarrays. By performing the adaptive array process, even if the state of the unwanted wave changes, the Null can be formed following the change.
This adaptive array processing is realized by calculating a load vector used in the DBF method from received signals of a plurality of subarrays, and multiplying the received signals of the plurality of subarrays by a load indicated by the load vector.
The calculation of the load vector is performed by generating a correlation matrix in the received signals of a plurality of subarrays, inverse matrix calculation, or the like.

“Adaptive Antenna Technology” by Nobuyoshi Kikuma 2003 Published by Ohm

Since the conventional signal processing apparatus is configured as described above, even if the state of the unwanted wave changes, the Null can be formed following the change. However, when performing adaptive array processing for forming a null according to the received signals of a plurality of subarrays, it is necessary to calculate the load vector used in the DBF method from the received signals of the plurality of subarrays. In order to do this, there is a problem that it is necessary to perform operations with high loads such as generation of a correlation matrix and inverse matrix operation.
In addition, depending on the relationship between the arrival direction and power of the desired signal and the arrival direction, number of arrivals, and power of unwanted waves, the main lobe gain may be reduced or the orientation may be shifted in the antenna pattern obtained by adaptive array processing. There was a problem.

  The present invention has been made to solve the above-described problems, and can perform adaptive array processing with a low load calculation and prevent a main lobe gain decrease and azimuth misalignment in an antenna pattern. An object of the present invention is to obtain a signal processing apparatus capable of

  The signal processing apparatus according to the present invention includes a phased array antenna in which a plurality of subarrays each including one or more element antennas are arranged, and a received signal of the subarray includes interference radio waves radiated from a known interference source. Interfering radio wave incident presence / absence determining unit that determines whether or not the interfering radio wave is incident and multiplying the reception signals of the plurality of subarrays constituting the phased array antenna for each combination of the presence or absence of the interference radio wave and the beam orientation of the phased array antenna Corresponds to the load data storage unit that stores the load data indicating the load to be performed and the load data stored in the load data storage unit, the determination result of the interference radio wave incident presence determination unit and the beam orientation of the phased array antenna A load data acquisition unit for acquiring the load data to be transmitted, and the digital beam forming processing unit The load indicating load data acquired by the acquisition unit is that so as to multiply the reception signals of a plurality of sub-arrays.

  According to the present invention, the load data acquisition unit that acquires the load data corresponding to the determination result of the interference radio wave incident presence determination unit and the beam orientation of the phased array antenna from the load data stored in the load data storage unit. The digital beam forming processing unit is configured to multiply the received signals of the plurality of subarrays by the load indicated by the load data acquired by the load data acquiring unit, so that the adaptive array processing is performed with a low load calculation. In addition, it is possible to prevent the main lobe gain from being lowered and the azimuth misalignment in the antenna pattern.

BRIEF DESCRIPTION OF THE DRAWINGS It is a block diagram which shows the signal processing apparatus by Embodiment 1 of this invention. It is a hardware block diagram which shows the digital signal processing part 2 of the signal processing apparatus by Embodiment 1 of this invention. It is a hardware block diagram in case the digital signal processing part 2 is comprised with a computer. It is a flowchart which shows the processing content of the signal processing apparatus by Embodiment 1 of this invention. FIG. 2 is a configuration diagram showing an interference wave incident presence / absence determining unit 21 of the digital signal processing unit 2. It is a block diagram which shows the signal processing apparatus by Embodiment 2 of this invention. It is a hardware block diagram which shows the digital signal processing part 2 of the signal processing apparatus by Embodiment 2 of this invention. FIG. 3 is a configuration diagram showing an interference wave incident presence / absence determination unit 60 of the digital signal processing unit 2. It is a block diagram which shows the signal processing apparatus by Embodiment 3 of this invention. It is a hardware block diagram which shows the digital signal processing part 2 of the signal processing apparatus by Embodiment 3 of this invention. FIG. 4 is a configuration diagram showing an interference wave incident presence / absence determination unit 80 of the digital signal processing unit 2. It is a block diagram which shows the signal processing apparatus by Embodiment 4 of this invention. It is a hardware block diagram which shows the digital signal processing part 2 of the signal processing apparatus by Embodiment 4 of this invention. It is a block diagram which shows the signal processing apparatus by Embodiment 5 of this invention. It is a hardware block diagram which shows the digital signal processing part 2 of the signal processing apparatus by Embodiment 5 of this invention. It is a block diagram which shows the signal processing apparatus by Embodiment 6 of this invention. It is a hardware block diagram which shows the digital signal processing part 2 of the signal processing apparatus by Embodiment 6 of this invention.

  Hereinafter, in order to describe the present invention in more detail, modes for carrying out the present invention will be described with reference to the accompanying drawings.

Embodiment 1 FIG.
1 is a block diagram showing a signal processing apparatus according to Embodiment 1 of the present invention, and FIG. 2 is a hardware block diagram showing a digital signal processing unit 2 of the signal processing apparatus according to Embodiment 1 of the present invention.
This signal processing device is assumed to be used as a radar device. As an unnecessary wave incident on the signal processing device, it is radiated from another radar device or a known fixed radio wave source such as a radio tower. And a ground clutter, which is a signal reflected from a building or a mountain, is assumed.
Although only the signal reception system is shown in the signal processing apparatus of FIG. 1, this signal processing apparatus also includes a signal transmission system and performs signal transmission processing. However, in this signal processing apparatus, the signal transmission process is not an essential process and may be performed by another signal processing apparatus.

In FIG. 1 and FIG. 2, the signal processing device includes an antenna device 1 and a digital signal processing unit 2.
The antenna device 1 includes subarrays 11-1 to 11-M, RF units 12-1 to 12-M, and AD converters 13-1 to 13-M. M is an integer of 1 or more.
The subarrays 11-1 to 11-M are composed of at least one element antenna, and a combined signal of signals received by each element antenna is output as a reception signal of the subarrays 11-1 to 11-M. .
In the example of FIG. 1, M subarrays 11-1 to 11-M are arranged one-dimensionally, and the M subarrays 11-1 to 11-M constitute a phased array antenna.
Although FIG. 1 shows an example in which M subarrays 11-1 to 11-M are arranged one-dimensionally, M subarrays 11-1 to 11-M are arranged two-dimensionally or three-dimensionally. It may be.

The RF units 12-1 to 12-M convert the received signal frequencies of the subarrays 11-1 to 11-M into baseband signal frequencies.
The AD converters 13-1 to 13-M convert the received signals whose frequencies have been converted by the RF units 12-1 to 12-M into digital signals, and output the digital signals to the digital signal processing unit 2. It is a converter.

The digital signal processing unit 2 includes an interference radio wave incident presence / absence determination unit 21, a beam direction information reception unit 22, a load data storage unit 23, a load data acquisition unit 24, a DBF processing unit 25, and a radar signal processing unit 26.
The interference wave incident presence / absence determination unit 21 is realized by a determination processing circuit 31 including, for example, a semiconductor integrated circuit or a one-chip microcomputer on which a CPU (Central Processing Unit) is mounted. A process of determining whether or not the digital signal output from the device 13-m includes an interference radio wave radiated from a known interference source is performed.
FIG. 1 illustrates an example in which the interference radio wave incident presence / absence determination unit 21 receives a digital signal output from the mth AD converter 13-m. Of the AD converters 13-1 to 13-M, It is only necessary to receive the digital signal output from any one AD converter 13, and the present invention is not limited to the one that receives the digital signal output from the mth AD converter 13-m.

The beam direction information receiving unit 22 is realized by a network device 32 that is an interface to a transmission path such as the Internet or a LAN (Local Area Network). For example, a beam indicating the beam direction from an external device via the transmission path. When the azimuth information is received, the beam azimuth information is output to the load data acquisition unit 24.
The load data storage unit 23 is realized by a storage device 33 such as a RAM or a hard disk. The load data storage unit 23 is a beam that is electronically switched by the DBF processing unit 25 and the presence / absence of incident interference waves radiated from a known interference source. Load data indicating a load to be multiplied with the digital signal output from the AD converters 13-1 to 13-M is stored for each combination with the direction.

  The load data acquisition unit 24 is realized by a data acquisition processing circuit 34 configured by, for example, a semiconductor integrated circuit mounted with a CPU or a one-chip microcomputer, and the load stored in the load data storage unit 23. From the data, a process of acquiring load data corresponding to the beam direction indicated by the determination result of the interference wave incident presence / absence determination unit 21 and the beam direction information output from the beam direction information reception unit 22 is performed.

The DBF processing unit (digital beamforming processing unit) 25 is realized by, for example, a DBF processing circuit 35 configured by a semiconductor integrated circuit or a one-chip microcomputer mounted with a CPU. DBF processing for multiplying the digital signal output from the AD converters 13-1 to 13 -M by the load indicated by the acquired load data is performed.
The radar signal processing unit 26 is realized by a radar signal processing circuit 36 configured by, for example, a semiconductor integrated circuit mounted with a CPU or a one-chip microcomputer. The digital signal after the DBF processing by the DBF processing unit 25 is performed. As a general radar signal processing, a target detection process, a distance to the target, and a process of angle measurement are performed.

In the example of FIG. 1, an interference radio wave incident presence / absence determination unit 21, a beam direction information reception unit 22, a load data storage unit 23, a load data acquisition unit 24, a DBF processing unit 25, and a radar signal, which are components of the digital signal processing unit 2. Although it is assumed that each of the processing units 26 is configured by dedicated hardware, the digital signal processing unit 2 may be configured by a computer.
FIG. 3 is a hardware configuration diagram when the digital signal processing unit 2 is configured by a computer.
When the digital signal processing unit 2 is configured by a computer, the load data storage unit 23 is configured on the memory 41 of the computer, and the interference wave incident presence / absence determination unit 21, the beam direction information reception unit 22, the load data acquisition unit 24, A program describing the processing contents of the DBF processing unit 25 and the radar signal processing unit 26 may be stored in the memory 41, and the processor 42 of the computer may execute the program stored in the memory 41.
FIG. 4 is a flowchart showing the processing contents of the signal processing apparatus according to Embodiment 1 of the present invention.

FIG. 5 is a configuration diagram illustrating the interference wave incident presence / absence determination unit 21 of the digital signal processing unit 2.
In FIG. 5, the frequency spectrum calculation unit 51 performs a process of calculating the frequency spectrum of the received signal of the subarray 11-m by performing a Fourier transform on the digital signal output from the mth AD converter 13-m.
The interference radio frequency spectrum storage unit 52 stores the frequency spectrum of the received signal of the subarray 11-m when the interference radiowave radiated from a known interference source is received by the subarray 11-m.

The evaluation function calculation unit 53 uses a determination evaluation function for determining whether or not an interference radio wave is incident from the frequency spectrum calculated by the frequency spectrum calculation unit 51 and the frequency spectrum stored in the interference radio wave frequency spectrum storage unit 52. Perform the calculation process.
The determination processing unit 54 uses the determination evaluation function calculated by the evaluation function calculation unit 53 to perform processing for determining whether or not an interference radio wave is incident.

Next, the operation will be described.
In the first embodiment, when an interference radio wave is radiated from a known interference source, it is assumed that a null is formed by the DBF method in the direction from which the interference radio wave is radiated. Is a radar, the direction of the radio wave radiated from the interference source changes every moment, and the radio wave may not be incident on the phased array antenna of the signal processing apparatus.
When Null is formed by the DBF method, if an observation target is present in the Null formation direction, a desired signal that is an incoming signal from the observation target is suppressed. For this reason, it is desirable not to form the null under the situation where the radio wave radiated from the interference source is not incident on the phased array antenna.

In the first embodiment, each combination of the presence / absence of incidence of interference radio waves radiated from known N (N is an integer of 1 or more) interference sources and the beam orientation electronically switched by the DBF processing unit 25. In addition, load data indicating DBF loads w _{NULL, 1 to} w _{NULL, M} to be multiplied with the digital signals output from the AD converters 13-1 to 13-M are calculated in advance, and load data for each combination is calculated. Is stored in the load data storage unit 23 of the digital signal processing unit 2 (step ST1 in FIG. 4).
Here, since the number of known interference sources is N, if the number of beam azimuths switched electronically by the DBF processing unit 25 is P, N × P load data is calculated. Then, N × P load data is tabulated.
The method for generating the DBF load table is not particularly limited. For example, there is a method as shown below.

(1) First generation method Signals received by the subarrays 11-1 to 11-M using information on the positions of known interference sources and terrain data indicating the positions of the ground clutter sources, that is, The reception signals x ₁ ′ (t) to x _M ′ (t) in which interference waves and ground clutter are mixed are simulated and included in the reception signals x ₁ ′ (t) to x _M ′ (t). DBF loads w _{NULL, 1 to} w _{NULL, M in} which the interference wave and the ground clutter are sufficiently suppressed, the gain of the main lobe in the antenna pattern is sufficiently high, and the orientation of the main lobe coincides with the desired orientation. calculate.
The DBF load table is calculated by calculating the DBF loads w _{NULL, 1 to} w _{NULL, M} for all combinations of the respective DBF beam orientations and the presence / absence of incidence of interference radio waves radiated from the respective interference sources. Generate.

As a process for calculating the DBF loads w _{NULL, 1 to} w _{NULL, M} from the simulated received signals x ₁ ′ (t) to x _M ′ (t), an existing adaptive array processing algorithm can be used. . For example, DCMP (Directly Constrained Minimization of Power) described in Non-Patent Document 1 or a projection method described in Non-Patent Document 2 below can be used.
[Non-Patent Document 2]
Kihei Kazunari et al., “Adaptive Array Antenna for Radar Using Signal Subspace Blind Extraction,” Science B, Vol.J88-B, ° No.9, pp.1752-1759, 2005.

(2) Second generation method Received signals x ₁ ′ (t) to x _M ′ (t) in which interference waves radiated from known interference sources and ground clutter are mixed are actually received and received. DBF loads w _{NULL, 1 to} w _{NULL, M} are calculated from the signals x ₁ ′ (t) to x _M ′ (t).
However, the reception processing of the reception signals x ₁ ′ (t) to x _M ′ (t) in which interference waves and ground clutter are mixed needs to be performed in a situation where the observation target does not exist in the radar observation region.
The DBF load table is calculated by calculating the DBF loads w _{NULL, 1 to} w _{NULL, M} for all combinations of the respective DBF beam orientations and the presence / absence of incidence of interference radio waves radiated from the respective interference sources. Generate.

A method combining the first generation method and the second generation method can also be used.
For example, the reception signal is received in a situation where only the ground clutter is received, and the reception signal is simulated and calculated from the information on the installation position of the known interference source, both reception signals are synthesized, and the DBF is synthesized from the synthesized signal. Some calculate the load w _{NULL, 1 to} w _{NULL, M.}

式（１）において、ｘ_ｍ（ｔ）はｍ番目のサブサレー１１−ｍの受信信号を示しており、添字のＴは転置を表している。 When this signal processing device or another signal processing device transmits a radar signal, the reflected wave of the radar signal reflected by the observation target or the like is received by the subarrays 11-1 to 11-M constituting the phased array antenna. (Step ST2).
If the interference radio wave radiated from the interference source is incident, the interference radio wave is received by the subarrays 11-1 to 11-M together with the reflected wave of the radar signal (step ST2).
The reception signals x ₁ (t) to x _M (t) of the subarrays 11-1 to 11-M are expressed as the following formula (1).

In Expression (1), x _m (t) represents the received signal of the m-th sub-sales 11-m, and the subscript T represents transposition.

RF unit 12-1 to 12-M, the sub-array 11-1 to 11-M reception signals _x 1 receives a (t) _~x M (t) of the received signal _{x 1 (t) ~x M (} t ) Is converted into the frequency of the baseband signal, and the received signals x ₁ (t) to x _M (t) after the frequency conversion are output to the AD converters 13-1 to 13 -M.
When the AD converters 13-1 to 13 -M receive the received signals x ₁ (t) to x _M (t) after frequency conversion from the RF units 12-1 to 12 _-M , the received signals x ₁ (t ) To x _M (t) are converted into digital signals, and the digital signals are output to the digital signal processing unit 2.

When receiving the digital reception signal x _m (t) output from the mth AD converter 13-m, the interference wave incident presence / absence determination unit 21 of the digital signal processing unit 2 receives the digital reception signal x _m (t). It is determined whether or not an interference radio wave radiated from a known interference source is included. That is, it is determined whether or not an interference radio wave radiated from a known interference source is incident on the phased array antenna (step ST3).
Hereinafter, the determination process of the interference wave incident presence / absence determination unit 21 will be described in detail.
In the first embodiment, the process of determining whether or not the number of known interference sources is N and the interference radio wave radiated from the nth interference source is incident on the phased array antenna will be described.

式（２）において、ＦＴ［］はフーリエ変換を表している。 When the frequency spectrum calculation unit 51 of the interference wave incident presence / absence determination unit 21 receives the digital reception signal x _m (t) from the m-th AD converter 13-m, the digital reception signal x _m (t) is Fourier-transformed. By performing the conversion, the frequency spectrum X _m (f) of the digital received signal x _m (t) is calculated.

In equation (2), FT [] represents the Fourier transform.

In the first embodiment, the interference radio frequency spectrum storage unit 52 stores the frequency spectrum R of the received signal of the subarray 11-m when the interference radiowave radiated from the nth interference source is received by the subarray 11-m. _{Assume that n} (f) is stored.
The frequency spectrum R _n (f) can be generated by numerical calculation from information such as the waveform and frequency of the interference radio wave radiated from the interference source. In addition, if an interference radio wave radiated from the interference source is received, it can be generated from the received signal of the interference radio wave.

式（３）において、ＦＴ^−１［］は逆フーリエ変換、添字の＊は複素共役を表している。 When the frequency spectrum calculation unit 51 calculates the frequency spectrum X _m (f) of the received signal x _m (t), the evaluation function calculation unit 53 stores the frequency spectrum X _m (f) and the interference radio frequency spectrum storage unit 52. From the frequency spectrum R _n (f), as shown in the following formula (3), the evaluation function for determination g _m, for determining whether or not the interference radio wave radiated from the n th interference source is incident _{, n} (t) is calculated.

In equation (3), FT ⁻¹ [] represents inverse Fourier transform, and the subscript * represents complex conjugate.

式（４）において、Ｅ［］は判定用評価関数ｇ_ｍ，ｎ（ｔ）の信号強度である。 When the evaluation function calculation unit 53 calculates the evaluation function for determination g _{m, n} (t), the determination processing unit 54 calculates the signal strength (or power) of the evaluation function for determination g _{m, n} (t), As shown in the following equation (4), if the signal strength of the evaluation function for determination g _{m, n} (t) is equal to or higher than a preset threshold value α _n , an interference radio wave radiated from the n th interference source Is determined to be incident. On the other hand, if the signal strength of the evaluation function for determination g _{m, n} (t) is less than the threshold value α _n , it is determined that the interference radio wave radiated from the n-th interference source is not incident.

In Equation (4), E [] is the signal strength of the evaluation function for determination g _{m, n} (t).

The processing using the above equations (3) and (4) uses the fact that the interference source is a known radio wave source, and forms a matched filter for the interference radio wave radiated from the interference source. This is a process for determining whether or not an interference radio wave radiated from the interference source is incident based on the intensity or power of the output signal of the matched filter.
The processing using the equations (3) and (4) is a calculation about complex Fourier transform and complex product-sum operation. For example, fast Fourier transform (FFT), which is fast Fourier transform, is used. Is possible. Compared with generation of a correlation matrix or inverse matrix calculation in received signals of a plurality of subarrays performed by conventional adaptive array processing, the calculation load is small.
Here, an example is shown in which a matching filter is used to determine whether or not an interference wave radiated from the nth interference source is incident. For example, the signal passes through a signal band of the interference wave radiated from the interference wave source. A simple configuration may be employed in which a BPF (Band Pass Filter) that is a bandpass filter is generated, and the presence or absence of an interference radio wave radiated from the nth interference source is determined using the output power of the BPF. .

When the beam direction information receiving unit 22 of the digital signal processing unit 2 receives, for example, beam direction information indicating the beam direction from an external device via a transmission path, the beam direction information is output to the load data acquisition unit 24 (step S40). ST4).
The load data acquisition unit 24 of the digital signal processing unit 2 is output from the determination result of the interference wave incident presence / absence determination unit 21 and the beam direction information reception unit 22 from the load data stored in the load data storage unit 23. Load data corresponding to the beam direction indicated by the beam direction information is acquired (step ST5).
For example, the determination result of the interference wave incident presence / absence determining unit 21 indicates that only interference waves radiated from the second and fifth interference sources among the interference waves radiated from N interference sources are incident. If the beam azimuth indicated by the beam azimuth information is θ, the second and fifth interference sources are selected from 2 ^N × P load data stored in the load data storage unit 23. Load data corresponding to the beam azimuth θ is acquired when the radiated interference radio waves are incident (interference radio waves radiated from other interference sources are not incident).

式（５）において、添字のＨは複素共役転置を表している。
なお、実際のＤＢＦ処理では、複数の方位に並列処理的にＤＢＭビームを形成することもある。その場合には、各ビーム方位に対応するＤＢＦ荷重ｗ_{ＮＵＬＬ，１}〜ｗ_{ＮＵＬＬ，Ｍ}を取得することで、並列処理で複数のＤＢＦ処理後の信号ｙ（ｔ）を生成することも可能である。
なお、図４においては、既知の干渉源から放射された干渉電波の入射の有無の判定処理からＤＢＦ処理までの一連の処理をセミアダプティブアレー処理と呼んでいる。 When the load data acquisition unit 24 acquires the load data, the DBF processing unit 25 of the digital signal processing unit 2 converts the DBF loads w _{NULL, 1 to} w _{NULL, M} indicated by the load data into AD converters 13-1 to 13-. DBF processing for multiplying the digital received signals x ₁ (t) to x _M (t) output from M, that is, the received signal x (t) represented by the equation (1) is performed (step ST6).
By performing this DBF processing, as shown in the following equation (5), a signal y (t) after DBF processing in which unnecessary waves are suppressed is generated.

In the formula (5), the subscript H represents complex conjugate transposition.
In actual DBF processing, a DBM beam may be formed in a plurality of directions in parallel processing. In that case, it is also possible to generate a plurality of DBF-processed signals y (t) by parallel processing by acquiring DBF loads w _{NULL, 1 to} w _{NULL, M} corresponding to each beam direction. .
In FIG. 4, a series of processing from determination processing for presence / absence of incidence of interference radio waves radiated from a known interference source to DBF processing is referred to as semi-adaptive array processing.

When the DBF processing unit 25 generates the signal y (t) after the DBF processing, the radar signal processing unit 26 uses the signal y (t) after the DBF processing to perform target detection processing as general radar signal processing. Then, the distance to the target and the process of angle measurement are performed (step ST7).
The contents of this radar signal processing vary depending on the operational purpose of the radar apparatus itself using this apparatus.
Thereafter, in the signal processing device, the processes of steps ST2 to ST7 are repeatedly performed.

As apparent from the above, according to the first embodiment, from the load data stored in the load data storage unit 23, the determination result of the interference radio wave incident presence / absence determination unit 21 and the beam direction information reception unit 22 are used. A load data acquisition unit 24 that acquires load data corresponding to the beam direction indicated by the output beam direction information is provided, and the DBF processing unit 25 displays the DBF load w _NULL, indicated by the load data acquired by the load data acquisition unit 24 _{. 1 to} w _{NULL, M} are configured to multiply the digital reception signals x ₁ (t) to x _M (t) output from the AD converters 13-1 to 13 _-M , so that an operation with a low load can be performed. An adaptive array process can be performed, and an effect of preventing a decrease in main lobe gain and an azimuth shift in the antenna pattern is achieved.
That is, the load data stored in the load data storage unit 23 sufficiently suppresses interference waves and ground clutter included in the received signals x ₁ (t) to x _M (t) and Since the DBF load w _{NULL, 1 to} w _{NULL, M in} which the main lobe gain is sufficiently high and the main lobe azimuth matches the desired azimuth is calculated in advance, the desired signal and unwanted waves are not generated. Even if it changes, the gain of the main lobe and the azimuth shift in the antenna pattern do not occur.

Embodiment 2. FIG.
In the first embodiment, the interference radio wave incident presence / absence determination unit 21 determines whether the interference radio wave is incident by paying attention to the frequency spectrum of the reception signal of the sub-array 11-m. The presence / absence of an interference radio wave may be determined by paying attention to the azimuth.

6 is a block diagram showing a signal processing apparatus according to Embodiment 2 of the present invention, and FIG. 7 is a hardware block diagram showing a digital signal processing unit 2 of the signal processing apparatus according to Embodiment 2 of the present invention.
6 and FIG. 7, the same reference numerals as those in FIG. 1 and FIG.
The interference wave incident presence / absence determination unit 60 is realized by a determination processing circuit 71 including, for example, a semiconductor integrated circuit mounted with a CPU, a one-chip microcomputer, and the like, and AD converters 13-1 to 13-M. A process of determining whether or not an interference radio wave radiated from a known interference source is included in the digital signal output from is performed.

In the example of FIG. 6, the interference wave incident presence / absence determination unit 60, the beam direction information reception unit 22, the load data storage unit 23, the load data acquisition unit 24, the DBF processing unit 25, and the radar signal, which are components of the digital signal processing unit 2. Although it is assumed that each of the processing units 26 is configured by dedicated hardware, the digital signal processing unit 2 may be configured by a computer.
When the digital signal processing unit 2 is configured by a computer, the load data storage unit 23 is configured on the memory 41 of the computer shown in FIG. 3, and the interference radio wave incident presence / absence determination unit 60, the beam direction information reception unit 22, load data If a program describing the processing contents of the acquisition unit 24, the DBF processing unit 25, and the radar signal processing unit 26 is stored in the memory 41, and the processor 42 of the computer executes the program stored in the memory 41. Good.

FIG. 8 is a configuration diagram showing the interference wave incident presence / absence determining unit 60 of the digital signal processing unit 2.
In FIG. 8, the load vector storage unit 61 stores load vectors w _{1 to} w _N corresponding to the directions of N known interference sources.
The evaluation function calculation unit 62 receives the digital received signals x ₁ (t) to x _M (t) output from the AD converters 13-1 to 13 _-M and the load vector w ₁ stored in the load vector storage unit 61. A process of calculating evaluation functions for determination f ₁ (t) to f _N (t) for determining whether or not an interference radio wave radiated from a known interference source is incident is performed from ˜w _N.
The determination processing unit 63 uses the determination evaluation functions f ₁ (t) to f _N (t) calculated by the evaluation function calculation unit 62 to perform processing for determining whether or not an interference radio wave is incident.

Next, the operation will be described.
However, since the components other than the interference radio wave incident presence / absence determining unit 60 are the same as those in the first embodiment, only the processing contents of the interference radio wave incident presence / absence determining unit 60 will be described.
Here, for convenience of explanation, a process for determining whether or not an interference radio wave radiated from the n-th interference source is incident will be described.

式（６）において、ｄ_１〜ｄ_Ｍはサブアレー１１−１〜１１−Ｍの位置ベクトル、λは波長である。
また、ｕ_ｎはｎ番目の干渉源から放射される干渉電波の方位ベクトルであり、ｎ番目の干渉源は既知の電波源であるため、干渉電波の方位ベクトルｕ_ｎも既知である。 The load vector storage unit 61 of the interference wave incident existence determining section 60, the load vector w _n corresponding to the orientation of the n-th interferer, as shown in the following equation (6) is pre-stored.

In the formula _(6), d 1 ~d _M is the position vector of the subarray 11-1 to 11-M, lambda is the wavelength.
Also, u _n is the orientation vector of the interfering radio waves radiated from the n-th interferer, n-th interferer is because it is known radio sources, orientation vector u _n interference radio wave is also known.

When the evaluation function calculation unit 62 receives the digital reception signals x ₁ (t) to x _M (t) from the AD converters 13-1 to 13 _-M , that is, the reception signal x represented by Expression (1). Upon receiving a (t), from the weight vector w _n corresponding to the orientation of the n-th interference source that the received signal x (t) stored in the load vector storage unit 61, emitted from the n-th interferer A determination evaluation function f _n (t) for determining whether or not an interference radio wave is incident is calculated.

式（８）において、Ｅ［］は判定用評価関数ｆ_ｎ（ｔ）の信号強度である。 When the evaluation function calculation unit 62 calculates the evaluation function f _n (t) for determination, the determination processing unit 63 calculates the signal strength (or power) of the evaluation function f _n (t) for determination, and the following formula ( As shown in 8), if the signal strength of the evaluation function for determination f _n (t) is equal to or higher than a preset threshold value β _n , the interference radio wave emitted from the n-th interference source is incident. judge. On the other hand, if the signal strength of the evaluation function f _n (t) for determination is less than the threshold value β _n , it is determined that the interference radio wave radiated from the nth interference source is not incident.

In Equation (8), E [] is the signal intensity of the evaluation function for determination f _n (t).

Embodiment 3 FIG.
In the first embodiment, the interference radio wave incident presence / absence determination unit 21 determines whether or not the interference radio wave is incident by paying attention to the frequency spectrum of the reception signal of the sub-array 11-m. The incident presence / absence determination unit 60 has been shown to determine the presence / absence of an interference radio wave by paying attention to the direction of a known interference source, but paying attention to both the frequency spectrum and the direction of the interference source, The presence or absence of incidence may be determined.

9 is a block diagram showing a signal processing apparatus according to Embodiment 3 of the present invention, and FIG. 10 is a hardware block diagram showing a digital signal processing unit 2 of the signal processing apparatus according to Embodiment 3 of the present invention.
9 and 10, the same reference numerals as those in FIGS. 1 and 2 indicate the same or corresponding parts, and thus description thereof is omitted.
The interference wave incident presence / absence determination unit 80 is realized by a determination processing circuit 72 including, for example, a semiconductor integrated circuit on which a CPU is mounted, a one-chip microcomputer, and the like, and AD converters 13-1 to 13-M. The digital reception signals x ₁ (t) to x _M (t) output from the receiver include a process for determining whether or not an interference radio wave radiated from a known interference source is included.

In the example of FIG. 9, the interference wave incident presence / absence determination unit 80, the beam direction information reception unit 22, the load data storage unit 23, the load data acquisition unit 24, the DBF processing unit 25, and the radar signal, which are components of the digital signal processing unit 2. Although it is assumed that each of the processing units 26 is configured by dedicated hardware, the digital signal processing unit 2 may be configured by a computer.
When the digital signal processing unit 2 is configured by a computer, the load data storage unit 23 is configured on the memory 41 of the computer shown in FIG. 3, and the interference wave incident presence / absence determination unit 80, the beam direction information reception unit 22, load data If a program describing the processing contents of the acquisition unit 24, the DBF processing unit 25, and the radar signal processing unit 26 is stored in the memory 41, and the processor 42 of the computer executes the program stored in the memory 41. Good.

FIG. 11 is a block diagram showing the interference wave incident presence / absence determining unit 80 of the digital signal processing unit 2.
In FIG. 11, the same reference numerals as those in FIGS. 5 and 8 indicate the same or corresponding parts, and the description thereof is omitted.
The determination processing unit 81 uses the determination evaluation function calculated by the evaluation function calculation unit 53 and the determination evaluation function calculated by the evaluation function calculation unit 62 to determine whether or not an interference radio wave is incident.
In the third embodiment, the evaluation function calculation unit 53 constitutes a first evaluation function calculation unit, and the evaluation function calculation unit 62 constitutes a second evaluation function calculation unit.

Next, the operation will be described.
When the frequency spectrum calculation unit 51 of the interference wave incident presence / absence determination unit 80 receives digital reception signals x ₁ (t) to x _M (t) from the AD converters 13-1 to 13 _-M , the digital reception signal x ₁ and (t) _~x M (t) by Fourier transform, calculating a frequency spectrum _{X 1 (f) ~X M (} f) of the received signal _x 1 of the digital (t) _~x M (t) To do.
In the first embodiment, but is calculated only frequency spectrum of the m-th received signal _{x m X} m (f), in the third embodiment, M pieces of received signals _x 1 (t) ~x _M The difference is that the frequency spectra X ₁ (f) to X _M (f) of (t) are calculated.

In the third embodiment, the interference radio frequency spectrum storage unit 52 stores the frequency spectrum R of the received signal of the subarray 11-m when the interference radiowave radiated from the nth interference source is received by the subarray 11-m. Not only _n (f) is stored, but also the frequency spectrum R _n (f) of the received signals of the subarrays 11-1 to 11-M when received by the M subarrays 11-1 to 11-M. It is assumed that

When the frequency spectrum calculation unit 51 calculates the frequency spectra X ₁ (f) to X _M (f) of the reception signals x ₁ (t) to x _M (t), the evaluation function calculation unit 53 calculates the frequency spectrum X ₁ ( f) to X _M (f) and the frequency spectrum R _n (f) stored in the interference radio frequency spectrum storage unit 52 for determining whether or not the interference radio wave emitted from the nth interference source is incident. Determination evaluation functions g _{1, n} (t) to g _{M, n} (t) are calculated. The calculation process itself of the evaluation function for determination g _{1, n} (t) to g _{M, n} (t) is the same as that in the first embodiment, and is calculated using Expression (3).
When the evaluation function calculation unit 53 calculates M evaluation functions for determination g _{1, n} (t) to g _{M, n} (t), as shown in the following equation (9), M evaluation evaluations are performed. The evaluation function for determination g _n (t) is calculated from the functions g _{1, n} (t) to g _{M, n} (t).

When the evaluation function calculation unit 62 receives the digital reception signals x ₁ (t) to x _M (t) from the AD converters 13-1 to 13 _-M , that is, the reception signal x represented by Expression (1). When (t) is received, similarly to the second embodiment, the received signal x (t) and the direction of the nth interference source stored in the load vector storage unit 61 are set using Equation (7). from the corresponding weight vector w _n, and calculates the n-th for determination for determining the presence or absence of incident radiation interference wave from the interference source evaluation function f _n a _(t).

When the evaluation function calculation unit 53 calculates the evaluation function for determination g _n (t) and the evaluation function calculation unit 62 calculates the evaluation function for determination f _n (t), the determination processing unit 81 calculates the following equation (10). As shown, the final evaluation function h _n (t) is calculated from the determination evaluation function g _n (t) and the determination evaluation function f _n (t).

式（１１）において、Ｅ［］は判定用評価関数ｈ_ｎ（ｔ）の信号強度である。 When the final determination evaluation function h _n (t) is calculated, the determination processing unit 81 calculates the signal strength (or power) of the determination evaluation function h _n (t), and the following equation (11) is calculated. As shown, if the signal strength of the evaluation function for determination h _n (t) is equal to or greater than a preset threshold value γ _n , it is determined that an interference radio wave radiated from the n-th interference source is incident. On the other hand, if the signal strength of the evaluation function h _n (t) for determination is less than the threshold value γ _n , it is determined that the interference radio wave radiated from the nth interference source is not incident.

In equation (11), E [] is the signal strength of the evaluation function h _n (t) for determination.

  As apparent from the above, according to the third embodiment, the presence or absence of the interference radio wave is determined by paying attention to both the frequency spectrum and the direction of the interference source. , 2 has an effect of improving the determination accuracy of the presence / absence of interference radio waves.

Embodiment 4 FIG.
In the first to third embodiments, DBF unit 25 is DBF load _{w NULL, 1 ~w NULL,} the received signal of the digital output of the _M from the AD converter _{13-1~13-M x 1 (t)} ~ Although the case where the beam orientation of the phased array antenna is electronically controlled by performing DBF processing that multiplies x _M (t) has been shown, in addition to the one that electronically controls the beam orientation, the phased array antenna A mechanism for physically controlling the antenna aperture may be mounted.

12 is a block diagram showing a signal processing apparatus according to Embodiment 4 of the present invention, and FIG. 13 is a hardware block diagram showing a digital signal processing unit 2 of the signal processing apparatus according to Embodiment 4 of the present invention.
12 and 13, the same reference numerals as those in FIGS. 9 and 10 indicate the same or corresponding parts, and thus the description thereof is omitted.
The opening direction control unit 90 includes a drive mechanism such as a motor that mechanically drives the phased array antenna, and controls the opening direction of the phased array antenna.
As the drive mechanism provided in the opening azimuth control unit 90, for example, a one-dimensional rotation mechanism with respect to the azimuth angle direction, a two-dimensional drive mechanism, or the like can be considered.

The load data storage unit 91 is realized by a storage device 73 such as a RAM or a hard disk, for example. For each combination of the azimuth and the aperture azimuth of the phased array antenna, the load multiplied by the digital received signals x ₁ (t) to x _M (t) output from the AD converters 13-1 to 13 _-M is shown. Load data is stored.
The load data acquisition unit 92 is realized by a data acquisition processing circuit 74 configured by, for example, a semiconductor integrated circuit mounted with a CPU or a one-chip microcomputer, and the load stored in the load data storage unit 91. Among the data, the determination result of the interference wave incident presence / absence determination unit 80, the beam direction indicated by the beam direction information output from the beam direction information reception unit 22, and the load data corresponding to the aperture direction controlled by the aperture direction control unit 90 Execute the process to acquire.

  The signal processing device of FIG. 12 shows an example in which the opening direction control unit 90, the load data storage unit 91, and the load data acquisition unit 92 are applied to the signal processing device of FIG. The opening direction control unit 90, the load data storage unit 91, and the load data acquisition unit 92 may be applied to the signal processing device of FIG.

In the example of FIG. 12, the interference wave incidence presence / absence determination unit 80, the beam direction information reception unit 22, the load data storage unit 91, the load data acquisition unit 92, the DBF processing unit 25, and the radar signal, which are components of the digital signal processing unit 2. Although it is assumed that each of the processing units 26 is configured by dedicated hardware, the digital signal processing unit 2 may be configured by a computer.
When the digital signal processing unit 2 is configured by a computer, the load data storage unit 91 is configured on the memory 41 of the computer shown in FIG. 3, and the interference radio wave incident presence / absence determination unit 80, the beam direction information reception unit 22, load data If a program describing the processing contents of the acquisition unit 92, the DBF processing unit 25, and the radar signal processing unit 26 is stored in the memory 41, the processor 42 of the computer executes the program stored in the memory 41. Good.

Next, the operation will be described.
The opening direction control unit 90 includes a drive mechanism such as a motor that mechanically drives the phased array antenna, and controls the opening direction of the phased array antenna.
The opening direction control unit 90 controls the opening direction of the phased array antenna, so that the beam direction of the phased array antenna changes.
Therefore, in the fourth embodiment, the beam orientation of the phased array antenna is electronically changed by the execution of the DBF processing by the DBF processing unit 25, and the opening orientation of the phased array antenna by the opening orientation control unit 90 is physically changed. The beam direction of the phased array antenna is changed by the control.

Therefore, AD conversion is performed for each combination of the presence / absence of interference radio waves radiated from known N interference sources, the beam orientation electronically switched by the DBF processing unit 25, and the aperture orientation of the phased array antenna. Load data indicating DBF loads w _{NULL, 1 to} w _{NULL, M} to be multiplied with digital reception signals x ₁ (t) to x _M (t) output from the devices 13-1 to 13-M are calculated in advance. It is assumed that a DBF load table indicating load data for each combination is stored in the load data storage unit 91 of the digital signal processing unit 2.
Here, since the number of known interference sources is N, the number of beam azimuths switched electronically by the DBF processing unit 25 is P, and the aperture azimuth switching switched by the aperture azimuth control unit 90 is performed. If the number is Q, 2 ^N × P × Q pieces of load data are calculated, and 2 ^N × P × Q pieces of load data are tabulated.

The load data acquisition unit 92 of the digital signal processing unit 2 outputs the determination result of the interference radio wave incident presence / absence determination unit 80 from the load data stored in the load data storage unit 91 and the beam direction information reception unit 22. Load data corresponding to the beam azimuth indicated by the beam azimuth information and the aperture azimuth controlled by the aperture azimuth control unit 90 is acquired.
For example, the determination result of the interference wave incident presence / absence determining unit 80 indicates that only the interference wave radiated from the third interference source among the interference waves radiated from the N interference sources is incident. If the beam azimuth indicated by the beam azimuth information is θ and the aperture azimuth controlled by the aperture azimuth control unit 90 is φ, N × P × Q stored in the load data storage unit 91. Interference radio waves radiated from the third interference source are incident (interference radio waves radiated from other interference sources are not incident) from the individual load data, and correspond to the beam azimuth θ and the aperture azimuth φ. Get load data.
Since other processes are the same as those in the first to third embodiments, detailed description thereof is omitted.

  As is apparent from the above, according to the fourth embodiment, the load data acquisition unit 92 determines from the load data stored in the load data storage unit 91 the determination result of the interference radio wave incident presence / absence determination unit 80, Since the load data corresponding to the beam azimuth indicated by the beam azimuth information output from the beam azimuth information receiving unit 22 and the aperture azimuth controlled by the aperture azimuth control unit 90 is acquired, the aperture azimuth of the phased array antenna is determined. Even in the case of physical control, as in the first to third embodiments, adaptive array processing can be performed with low-load calculation, and a main lobe gain reduction and azimuth shift in the antenna pattern can be prevented. The effect which can be done is produced.

Embodiment 5. FIG.
In the first to fourth embodiments, the load data stored in the load data storage units 23 and 91 in advance is shown. However, the load data stored in the load data storage units 23 and 91 is corrected. You may do it.

14 is a block diagram showing a signal processing apparatus according to Embodiment 5 of the present invention, and FIG. 15 is a hardware block diagram showing a digital signal processing unit 2 of the signal processing apparatus according to Embodiment 5 of the present invention.
14 and FIG. 15, the same reference numerals as those in FIG. 12 and FIG.
The clutter map generation unit 93 is realized by a map generation processing circuit 75 configured by, for example, a semiconductor integrated circuit mounted with a CPU or a one-chip microcomputer, and is executed by the DBF processing unit 25 or the opening direction control unit 90. Each time the beam direction of the phased array antenna is switched, digital received signals x ₁ (t) to x _M (t) output from the AD converters 13-1 to 13 _-M are acquired, and a plurality of beam directions are obtained. A process of generating a clutter map from the received signals x ₁ (t) to x _M (t) is performed.

The load data correction unit 94 is realized by a data correction processing circuit 76 configured by, for example, a semiconductor integrated circuit mounted with a CPU or a one-chip microcomputer, and the clutter map generated by the clutter map generation unit 93. The received signals x ₁ ′ (t) to x _M ′ (t) of the plurality of sub-arrays are simulated from the power distribution of the sub-array, and the simulated received signals x ₁ ′ (t) to x _M ′ (t) are used to load The process which corrects the load data memorize | stored in the data storage part 91 is implemented.

  The signal processing device of FIG. 14 shows an example in which a clutter map generation unit 93 and a load data correction unit 94 are applied to the signal processing device of FIG. 12, but FIG. 1, FIG. 6, or FIG. The clutter map generation unit 93 and the load data correction unit 94 may be applied to the signal processing device.

In the example of FIG. 14, the interference wave incident presence / absence determination unit 80, the beam direction information reception unit 22, the load data storage unit 91, the load data acquisition unit 92, the DBF processing unit 25, and the radar signal, which are components of the digital signal processing unit 2. Although it is assumed that each of the processing unit 26, the clutter map generation unit 93, and the load data correction unit 94 is configured by dedicated hardware, the digital signal processing unit 2 may be configured by a computer.
When the digital signal processing unit 2 is configured by a computer, the load data storage unit 91 is configured on the memory 41 of the computer shown in FIG. 3, and the interference radio wave incident presence / absence determination unit 80, the beam direction information reception unit 22, load data A program describing the processing contents of the acquisition unit 92, the DBF processing unit 25, the radar signal processing unit 26, the clutter map generation unit 93, and the load data correction unit 94 is stored in the memory 41, and the processor 42 of the computer stores the program in the memory 41. The stored program may be executed.

Next, the operation will be described.
Except for the point that the clutter map generation unit 93 and the load data correction unit 94 are mounted, the processing is the same as in the fourth embodiment, and only the processing contents of the clutter map generation unit 93 and the load data correction unit 94 will be described.

Each time the DBF processing unit 25 or the aperture direction control unit 90 switches the beam direction of the phased array antenna, the clutter map generation unit 93 receives the digital reception signal x ₁ output from the AD converters 13-1 to 13 -M. (T) to x _M (t) are acquired, and a clutter map is generated from the received signals x ₁ (t) to x _M (t) related to a plurality of beam directions.
Since the process itself for generating the clutter map from the received signals x ₁ (t) to x _M (t) related to a plurality of beam azimuths is a known technique, detailed description thereof is omitted.
Here, every time the clutter map generator 93 switches the beam direction of the phased array antenna, the digital received signals x ₁ (t) to x _M (t) output from the AD converters 13-1 to 13 -M are displayed. ) And generating a clutter map from the received signals x ₁ (t) to x _M (t) related to a plurality of beam directions, each time the beam direction of the phased array antenna is switched, A signal y (t) after the DBF processing by the DBF processing unit 25 may be acquired, and a clutter map may be generated from the signals y (t) after the DBF processing related to a plurality of beam directions.
However, when the clutter map is generated from the signal y (t) after the DBF processing related to a plurality of beam directions, the null forming processing is performed even if the gain of the main lobe in the antenna pattern is increased by the DBF processing. Shall not. That is, when performing the process of correcting the load data stored in the load data storage unit 91, it is assumed that the null forming process is not performed by the DBF processing unit 25.

When the clutter map generation unit 93 generates the clutter map, the load data correction unit 94 simulates the reception signals x ₁ ′ (t) to x _M ′ (t) of the plurality of subarrays from the power distribution of the clutter map.
From this clutter map, the installation position of the known interference source and the position of the ground clutter source can be known. Therefore, the received signal x ₁ ′ (t) ˜ in which the interference wave radiated from the known interference source and the ground clutter are mixed. x _M '(t) can be simulated.
Load data correction unit 94, when simulating calculates the reception signal _{x 1 '(t) ~x M} ' (t) , the interference wave contained in the received signal _{x 1 '(t) ~x M} ' (t) The DBF load w _{NULL, 1 to} w _{NULL, M} is calculated so that the ground clutter is sufficiently suppressed, the gain of the main lobe in the antenna pattern is sufficiently high, and the orientation of the main lobe coincides with the desired orientation.
The DBF load table is calculated by calculating the DBF loads w _{NULL, 1 to} w _{NULL, M} for all combinations of the respective DBF beam orientations and the presence / absence of incidence of interference radio waves radiated from the respective interference sources. Generate.

When the load data correction unit 94 generates a DBF load table, the load data correction unit 94 overwrites and saves the DBF load table in the load data storage unit 91.
Incidentally, the simulated calculated received signal _{x 1 (t) ~x M (} t) from DBF load _{w NULL, 1 to w NULL,} as a process of computing the _M, it is possible to use the algorithm of the existing adaptive array processing. For example, the DCMP described in Non-Patent Document 1 above, the projection method described in Non-Patent Document 2 above, or the like can be used.

As is apparent from the above, according to the fifth embodiment, each time the beam direction of the phased array antenna is switched by the DBF processing unit 25 or the aperture direction control unit 90, the AD converters 13-1 to 13-M get the received signals _x 1 output digital _{(t) ~x M (t)} , clutter map generation for generating a clutter map from the received signal _x 1 of the plurality of beam azimuth (t) _~x M (t) The load data correction unit 94 simulates the reception signals x ₁ ′ (t) to x _M ′ (t) of the plurality of subarrays from the power distribution of the clutter map generated by the clutter map generation unit 93. as with simulated received signal _{x 1 '(t) ~x M} ' (t), since it is configured to modify the load data stored in the load data storage unit 91, from the fourth embodiment Using a high-precision load data, an effect that may be implemented DFB process. Therefore, it is possible to further suppress the interference wave and the ground clutter, and to improve the gain of the main lobe in the antenna pattern.

Embodiment 6 FIG.
In the fifth embodiment, the simulation is performed by the radar signal processing unit 26, which simulates the reception signals x ₁ ′ (t) to x _M ′ (t) of a plurality of subarrays from the power distribution of the clutter map. An azimuth distribution of incoming signal power, which is a measured angle spectrum, may be acquired, and the received signals x ₁ ′ (t) to x _M ′ (t) of a plurality of subarrays may be simulated from the azimuth distribution.

FIG. 16 is a block diagram showing a signal processing apparatus according to Embodiment 6 of the present invention, and FIG. 17 is a hardware block diagram showing a digital signal processing unit 2 of the signal processing apparatus according to Embodiment 6 of the present invention.
16 and FIG. 17, the same reference numerals as those in FIG. 12 and FIG.
The azimuth distribution acquisition unit 95 is realized by an azimuth distribution acquisition processing circuit 77 composed of, for example, a semiconductor integrated circuit mounted with a CPU or a one-chip microcomputer, and the radar signal processing unit 26 measures the observation target. A process of acquiring the azimuth distribution of the incoming signal power, which is the angle measurement spectrum generated when the angle process is performed, is performed.
The load data correction unit 96 is realized by a data correction processing circuit 78 configured by, for example, a semiconductor integrated circuit mounted with a CPU or a one-chip microcomputer, and the arrival signal acquired by the orientation distribution acquisition unit 95. Simulating received signals x ₁ ′ (t) to x _M ′ (t) of a plurality of subarrays from the azimuth distribution of power, and using the simulated received signals x ₁ ′ (t) to x _M ′ (t), The process which corrects the load data memorize | stored in the load data memory | storage part 91 is implemented.

  The signal processing device of FIG. 16 shows an example in which the orientation distribution acquisition unit 95 and the load data correction unit 96 are applied to the signal processing device of FIG. 12, but FIG. 1, FIG. 6, or FIG. The orientation distribution acquisition unit 95 and the load data correction unit 96 may be applied to the signal processing device.

In the example of FIG. 16, the interference wave incident presence / absence determination unit 80, the beam direction information reception unit 22, the load data storage unit 91, the load data acquisition unit 92, the DBF processing unit 25, the radar signal, which are components of the digital signal processing unit 2. Although it is assumed that each of the processing unit 26, the orientation distribution acquisition unit 95, and the load data correction unit 96 is configured by dedicated hardware, the digital signal processing unit 2 may be configured by a computer.
When the digital signal processing unit 2 is configured by a computer, the load data storage unit 91 is configured on the memory 41 of the computer shown in FIG. 3, and the interference radio wave incident presence / absence determination unit 80, the beam direction information reception unit 22, load data A program describing the processing contents of the acquisition unit 92, DBF processing unit 25, radar signal processing unit 26, orientation distribution acquisition unit 95, and load data correction unit 96 is stored in the memory 41, and the processor 42 of the computer stores the program in the memory 41. The stored program may be executed.

Next, the operation will be described.
Except for the fact that the orientation distribution acquisition unit 95 and the load data correction unit 96 are implemented, the processing is the same as in the fourth embodiment, and therefore only the processing contents of the orientation distribution acquisition unit 95 and the load data correction unit 96 will be described.

The azimuth distribution acquisition unit 95 acquires the azimuth distribution of the incoming signal power, which is the angle measurement spectrum generated when the radar signal processing unit 26 performs the angle measurement processing of the observation target.
Since it is common in radar signal processing that the angle measurement spectrum is generated when the observation target angle measurement processing is performed, detailed description of the angle measurement spectrum generation processing is omitted.
The angle spectrum is an azimuth distribution indicating the signal intensity and power of a signal arriving from each beam azimuth.
In the sixth embodiment, it is assumed that the null forming process is not performed by the DBF processing unit 25 when the process of correcting the load data stored in the load data storage unit 91 is performed. Therefore, the radar signal processing unit 26 performs the angle measurement process of the observation target using the signal y (t) after the DBF process that is not subjected to the Null formation process, and generates the angle measurement spectrum.

When the azimuth distribution acquisition unit 95 acquires the azimuth distribution of the incoming signal power that is an angle measurement spectrum, the load data correction unit 96 receives the received signals x ₁ ′ (t) to x _M ′ (t ) And the simulated received signals x ₁ ′ (t) to x _M ′ (t).
From this azimuth distribution of the incoming signal power, the installation position of the known interference source and the position of the ground clutter source can be known, so the received signal x ₁ ′ in which the interference wave radiated from the known interference source and the ground clutter are mixed. _{(t) ~x M '(t} ) can be simulated calculations.
Load data correction unit 96, when simulating calculates the reception signal _{x 1 '(t) ~x M} ' (t) , the interference wave contained in the received signal _{x 1 '(t) ~x M} ' (t) The DBF load w _{NULL, 1 to} w _{NULL, M} is calculated so that the ground clutter is sufficiently suppressed, the gain of the main lobe in the antenna pattern is sufficiently high, and the orientation of the main lobe coincides with the desired orientation.
The DBF load table is calculated by calculating the DBF loads w _{NULL, 1 to} w _{NULL, M} for all combinations of the respective DBF beam orientations and the presence / absence of incidence of interference radio waves radiated from the respective interference sources. Generate.

When the load data correction unit 96 generates the DBF load table, the load data correction unit 96 overwrites and saves the DBF load table in the load data storage unit 91.
Incidentally, the simulated calculated received signal _{x 1 (t) ~x M (} t) from DBF load _{w NULL, 1 to w NULL,} as a process of computing the _M, it is possible to use the algorithm of the existing adaptive array processing. For example, the DCMP described in Non-Patent Document 1 above, the projection method described in Non-Patent Document 2 above, or the like can be used.

As is apparent from the above, according to the sixth embodiment, the azimuth distribution of the incoming signal power, which is the angle measurement spectrum generated when the angle measurement process of the observation target is performed by the radar signal processing unit 26, is acquired. Azimuth distribution acquisition unit 95 is provided, and the load data correction unit 96 receives the received signals x ₁ ′ (t) to x _M ′ (t) of the plurality of subarrays from the azimuth distribution of the incoming signal power acquired by the azimuth distribution acquisition unit 95. ) And the load data stored in the load data storage unit 91 is corrected using the simulated received signals x ₁ ′ (t) to x _M ′ (t). As compared with the fourth aspect, there is an effect that the DFB processing can be performed using highly accurate load data. Therefore, it is possible to further suppress the interference wave and the ground clutter, and to improve the gain of the main lobe in the antenna pattern.

  In the present invention, within the scope of the invention, any combination of the embodiments, or any modification of any component in each embodiment, or omission of any component in each embodiment is possible. .

  DESCRIPTION OF SYMBOLS 1 Antenna apparatus, 2 Digital signal processing part, 11-1 to 11-M subarray, 12-1 to 12-M RF part, 13-1 to 13-M AD converter, 21 Interference electric wave incident presence determination part, 22 Beam Direction information receiving unit, 23 Load data storage unit, 24 Load data acquisition unit, 25 DBF processing unit, 26 Radar signal processing unit, 31 judgment processing circuit, 32 network device, 33 storage device, 34 data acquisition processing circuit, 35 DBF processing Circuit, 36 radar signal processing circuit, 41 memory, 42 processor, 51 frequency spectrum calculation unit, 52 interference radio frequency spectrum storage unit, 53 evaluation function calculation unit (first evaluation function calculation unit), 54 determination processing unit (second Evaluation function calculation unit), 60 interference wave incidence presence / absence determination unit, 61 load vector storage unit, 62 evaluation function calculation unit, 63 determination processing unit, 71, 72 determination processing circuit, 73 storage device, 74 data acquisition processing circuit, 75 map generation processing circuit, 76 data correction processing circuit, 77 orientation distribution acquisition processing circuit, 78 data correction processing circuit, 80 interference radio wave Incident presence / absence determination unit, 81 determination processing unit, 90 aperture direction control unit, 91 load data storage unit, 92 load data acquisition unit, 93 clutter map generation unit, 94 load data correction unit, 95 direction distribution acquisition unit, 96 load data correction Department.

Claims (11)

A phased array antenna in which a plurality of subarrays composed of one or more element antennas are arranged;
An interference radio wave incident presence / absence determining unit that determines whether or not an interference radio wave radiated from a known interference source is included in the reception signal of the sub-array,
A load storing load data indicating a load to be multiplied to a reception signal of a plurality of subarrays constituting the phased array antenna for each combination of presence / absence of the interference radio wave and a beam direction of the phased array antenna A data storage unit;
From the load data stored in the load data storage unit, a load data acquisition unit that acquires load data corresponding to the determination result of the interference radio wave incident presence determination unit and the beam orientation of the phased array antenna,
A signal processing apparatus comprising: a digital beamforming processing unit that multiplies the reception signals of the plurality of subarrays by a load indicated by the load data acquired by the load data acquisition unit. The interference radio wave incident presence determination unit is
A frequency spectrum calculation unit for calculating a frequency spectrum of a received signal of the sub-array;
An interference radio frequency spectrum storage unit that stores a frequency spectrum of a reception signal of the subarray when an interference radio wave radiated from a known interference source is received by the subarray;
Evaluation function calculation for calculating an evaluation function for determination for determining whether the interference radio wave is incident from the frequency spectrum calculated by the frequency spectrum calculation unit and the frequency spectrum stored in the interference radio wave frequency spectrum storage unit And
The signal processing device according to claim 1, further comprising: a determination processing unit that determines whether or not the interference radio wave is incident using the determination evaluation function calculated by the evaluation function calculation unit. The interference radio wave incident presence determination unit is
A load vector storage unit storing a load vector corresponding to a known interference source orientation;
An evaluation function calculation unit that calculates an evaluation function for determination for determining whether or not the interference radio wave is incident from a received signal of the subarray and a load vector stored in the load vector storage unit;
The signal processing device according to claim 1, further comprising: a determination processing unit that determines whether or not the interference radio wave is incident using the determination evaluation function calculated by the evaluation function calculation unit. The interference radio wave incident presence determination unit is
A frequency spectrum calculation unit for calculating a frequency spectrum of a received signal of the sub-array;
An interference radio frequency spectrum storage unit that stores a frequency spectrum of a reception signal of the subarray when an interference radio wave radiated from a known interference source is received by the subarray;
From the frequency spectrum calculated by the frequency spectrum calculation unit and the frequency spectrum stored in the interference radio frequency spectrum storage unit, a first evaluation function for determining whether or not the interference radio wave is incident is calculated. A first evaluation function calculation unit;
A load vector storage unit storing a load vector corresponding to a known interference source orientation;
A second evaluation function calculation unit that calculates a second evaluation function for determination for determining whether or not the interference radio wave is incident from the received signal of the sub-array and the load vector stored in the load vector storage unit; ,
A determination processing unit that determines whether or not the interference radio wave is incident by using the first and second evaluation function for determination calculated by the first and second evaluation function calculation units. The signal processing apparatus according to claim 1, wherein: Comprising an opening azimuth control unit for controlling the opening azimuth of the phased array antenna;
The load data storage unit receives a plurality of subarrays constituting the phased array antenna for each combination of the presence / absence of the interference radio wave, the beam direction of the phased array antenna, and the opening direction of the phased array antenna. Load data indicating the load multiplied by the signal is stored,
The load data acquisition unit is controlled by the determination result of the interference wave incident presence / absence determination unit, the beam direction of the phased array antenna, and the aperture direction control unit from among the load data stored in the load data storage unit. 5. The signal processing device according to claim 1, wherein load data corresponding to the opening direction is acquired. Each time the beam direction of the phased array antenna is switched, the reception signals of the plurality of subarrays constituting the phased array antenna are acquired, and the clutter map is generated from the reception signals of the plurality of subarrays related to the plurality of beam directions. A clutter map generation unit,
The reception signals of the plurality of subarrays are simulated from the power distribution of the clutter map generated by the clutter map generation unit, and the load data stored in the load data storage unit is corrected using the simulated reception signals. The signal processing apparatus according to claim 1, further comprising: a load data correction unit. A radar signal processing unit that generates a measured angle spectrum when performing angle measurement processing of an observation target using the digital signal after DBF processing by the DBF processing unit;
An azimuth distribution acquisition unit for acquiring an azimuth distribution of incoming signal power which is an angle measurement spectrum generated by the radar signal processing unit;
Load data correction for simulating the reception signals of the plurality of sub-arrays from the azimuth distribution acquired by the azimuth distribution acquisition unit, and correcting the load data stored in the load data storage unit using the simulated reception signals The signal processing device according to claim 1, further comprising: a unit.   8. The signal processing apparatus according to claim 1, further comprising a plurality of analog-digital converters that convert the received signal of the subarray into a digital signal. 9.   The signal processing apparatus according to claim 1, wherein a plurality of subarrays constituting the phased array antenna are arranged one-dimensionally.   The signal processing apparatus according to claim 1, wherein a plurality of subarrays constituting the phased array antenna are two-dimensionally arranged.   The signal processing apparatus according to claim 1, wherein a plurality of subarrays constituting the phased array antenna are arranged three-dimensionally.

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