JP7191712B2 - Transmission system and transmission method - Google Patents

Description

Embodiments of the present invention relate to transmission systems and methods.

It is preferable that the transmitted radio signal interferes with other devices or systems as little as possible. Antennas are used for transmission. However, installation of radio wave barriers requires space, and it is sometimes difficult to install radio wave barriers. When an array antenna is used as an antenna having directivity, amplitude and phase control is performed according to the directivity of the array element (Non-Patent Document 1). However, it may be difficult to suppress interference while maintaining the transmission direction (main lobe) of the radio signal. Also, even if an antenna other than an array antenna is used for transmission, interference may occur due to side lobes. In this way, interference with other devices or systems caused by transmission of radio signals may not be sufficiently suppressed, and there is room for improvement in reducing interference.

Yoshida, "Revised Radar Technology", The Institute of Electronics, Information and Communication Engineers, 1996, pp. 124-125 Nobuyoshi Kikuma, "Adaptive Signal Processing by Array Antenna", Science and Technology Press, 2004, pp. 67-78 Yasuo Suzuki and Taneaki Chiba, "Side Lobe Suppression with Phase Weight Only", The transactions of the IEICE, vol. E73, No. 2, pp.245-249, February 1990 Robert A. Monzingo and Thomas W. Miller, "Introduction to Adaptive Arrays", Jhon Wiley & Sons inc., pp.390-404, 1980

The problem to be solved by the present invention is to provide a transmission system and a transmission method capable of reducing interference to other devices or systems caused by transmission of radio signals.

A transmission system according to an embodiment has a transmission antenna, an auxiliary antenna, a monitor antenna, and a controller. A transmit antenna and an auxiliary antenna transmit signals. The monitor antenna is located farther from the transmitting antenna than the auxiliary antenna. The controller controls the phase, or the phase and amplitude of the signal transmitted from the auxiliary antenna, based on the received signal when the signal transmitted from the transmission antenna and the auxiliary antenna is received by the monitor antenna. The monitor antenna is arranged in a direction in which it is desired to suppress interference of transmission by the transmitting antenna.

FIG. 2 is a diagram showing a configuration example of a receiving system that suppresses unwanted waves contained in received signals; 1 is a diagram showing a configuration example of a transmission system according to an embodiment; FIG. 1 is a block diagram showing a configuration example of a transmission system according to a first embodiment; FIG. FIG. 4 is a diagram showing an arrangement example of monitor antennas according to the first embodiment; FIG. 4 is a diagram showing the level relationship of angular responses between a transmitting antenna and an auxiliary antenna in the first embodiment; FIG. 2 is a block diagram showing a configuration example of a transmission system according to a second embodiment; FIG. The figure which shows the example of arrangement|positioning of the monitor antenna in 3rd Embodiment. FIG. 11 is a diagram showing another arrangement example of monitor antennas in the third embodiment; FIG. 12 is a block diagram showing a configuration example of a transmission system according to a fourth embodiment; FIG. The figure which shows an example of switching control with respect to the switching device in 4th Embodiment.

Hereinafter, a transmission system and a transmission method according to embodiments will be described with reference to the drawings. In the following embodiments, it is assumed that constituent elements with the same reference numerals perform the same operations, and overlapping descriptions will be omitted as appropriate.

First, the signal processing used in the transmission system of the embodiment and its outline will be described. FIG. 1 is a diagram showing a configuration example of a receiving system that suppresses unwanted waves contained in received signals. The receiving system shown in FIG. 1 includes a receiving antenna, a receiver, an auxiliary antenna, an auxiliary receiver, a weight controller, and a correlation calculator. A reception system suppresses unwanted waves contained in a reception signal received by a reception antenna by combining a signal received by an auxiliary antenna and a reception signal. The receiving system generates a beam output Y (=Y0−W·X) by synthesizing a signal W·X obtained by multiplying the output X of the auxiliary antenna by a complex weight W and the output Y0 of the receiving antenna.

A weight controller controls the weight W based on the correlation between the signal X and the beam output Y so as to minimize the unwanted wave contained in the beam output Y when the receiving system receives the unwanted wave. For the adaptive calculation for calculating the weight W that minimizes the unwanted wave in the beam output Y, the method described in Non-Patent Document 2 can be used. By using the calculated weight W for reception by the auxiliary antenna, the reception system can form a reception null in the direction from which unwanted waves arrive (unwanted wave direction). The reception system can perform reception with reduced unwanted waves by directing the reception null in the direction of the unwanted waves. The transmitting system of the embodiment utilizes the adaptive arithmetic used in the receiving system shown in FIG.

FIG. 2 is a diagram illustrating a configuration example of a transmission system according to an embodiment; The transmission system shown in FIG. 2 includes a transmission antenna, a transmitter, an auxiliary antenna, an auxiliary transmitter, a weight controller, a correlation calculator, and a monitor antenna. By transmitting signals from the auxiliary antenna, the transmission system reduces interference that transmission signals transmitted from the transmission antennas give to other devices or systems. Auxiliary antennas of a transmission system are used to create transmission nulls in directions in which it is desired to reduce interference of transmission signals transmitted from the transmission antennas.

A monitor antenna is placed in a direction that forms a transmission null. The monitor antenna receives the transmission signal Y0 transmitted from the transmission antenna and the signal W·X transmitted from the auxiliary antenna. A signal received by the monitor antenna is a synthesized signal Y (=Y0-W·X) of signals transmitted from the transmitting antenna and the auxiliary antenna. That is, the monitor antenna output corresponds to the beam output in FIG. It should be noted that the sign of the signal W·X is made negative in line with the receiving system shown in FIG. The weight controller controls the weight W based on the correlation between the signal X to be transmitted and the synthesized signal Y so that the level of the synthesized signal Y is minimized. The computation for calculating the weight W that minimizes the composite signal Y received by the monitor antenna is the same as the adaptive computation described above.

The transmission system can reduce interference in the direction in which the monitor antenna is arranged by controlling the weight for the signal transmitted from the auxiliary antenna and forming a transmission null in that direction. The transmission system eliminates the need to install radio barriers and can form transmission nulls in desired directions to reduce interference with other devices or systems. Moreover, since the directivity of the transmitting antenna is not changed, the influence on the main lobe of the transmitting antenna can be suppressed. The transmission system uses a weight W to control the phase or phase and amplitude of the signal transmitted from the auxiliary antenna by feedback using the signal received by the monitor antenna. By using such control, the transmission system can form a stable transmission null even if the directivity changes due to temperature changes and aging of each element. Moreover, according to the transmission system, it is possible to easily form a transmission null in a desired direction without accurately grasping the directivity of the transmission antenna. Hereinafter, more specific configuration examples of the transmission system will be described as first to fourth embodiments.

(First embodiment)
FIG. 3 is a block diagram showing a configuration example of the transmission system 100 according to the first embodiment. The transmission system 100 features the techniques described above for forming the transmission nulls. The transmission system 100 includes a signal generator 1, a modulator 2, a frequency converter 3, a pulse modulator 4, a divider 5, multipliers 6, 6a, high power amplifiers (HPAs) 7, 7a, a transmission antenna 8, an auxiliary antenna. 8a, a coupler 9, a monitor antenna 10, low noise amplifiers (LNA) 11, 11a, frequency converters 12, 12a, analog-to-digital (AD) converters 13, 13a, a maximum amplitude selector 14, and a control unit 15.

The transmission system 100 includes N transmission antennas 8 (8-1, ..., 8-N), M auxiliary antennas 8a (8a-1, ..., 8a-M) and P monitor antennas 10 (10- 1, . . . , 10-P). The N transmitting antennas 8 form an array antenna. The array antenna may be a linear array in which the transmitting antennas 8 are arranged on a straight line, or may be a planar array in which the transmitting antennas 8 are arranged on a plane. A part of the antenna elements of the array antenna may be used as the auxiliary antenna 8a. The transmission system 100 comprises a multiplier 6 and an HPA 7 for each transmit antenna 8 . The transmission system 100 also includes a multiplier 6a, an HPA 7a, a coupler 9, an LNA 11a, a frequency converter 12a, and an AD converter 13a for each auxiliary antenna 8a. The transmission system 100 also includes an LNA 11, a frequency converter 12, and an AD converter 13 for each monitor antenna 10 (10-1, . . . , 10-P).

A signal generator 1 generates a predetermined transmission pulse and supplies the transmission pulse to a modulator 2 . The modulator 2 modulates each pulse included in the transmission pulse with a code sequence to generate a modulated signal, and supplies the modulated signal to the frequency converter 3 . Code sequences used for modulation include, for example, PN (Pseudo random noise) sequences, Gold sequences, M (Maximal length) sequences, and the like. The frequency converter 3 converts the modulated signal into a high frequency signal in the RF (Radio Frequency) band and supplies the high frequency signal to the pulse modulator 4 . The pulse modulator 4 generates a transmission signal by modulating one or both of the width and height of each pulse contained in the high-frequency signal. The pulse modulator 4 supplies the generated transmission signal to the distributor 5 .

The distributor 5 includes multipliers 6 (6-1, . . . , 6-N) respectively corresponding to the N transmitting antennas 8 and multipliers 6a (6a-1, . , 6-M). Each multiplier 6 multiplies a transmission signal by a weight corresponding to the directivity direction of an array antenna composed of transmission antennas 8 , and supplies the transmission signal multiplied by the weight to HPA 7 . Each HPA 7 amplifies the transmission signal supplied from the multiplier 6 and transmits it from the transmission antenna 8 . Each multiplier 6a multiplies the transmission signal by the transmission weight W supplied from the control unit 15, and supplies the transmission signal multiplied by the transmission weight W to the HPA 7a. Each HPA 7a amplifies the transmission signal supplied from the multiplier 6a to a high output and transmits it from the auxiliary antenna 8a. Each coupler 9 is attached to a transmission line connecting the HPA 7a and the auxiliary antenna 8a, extracts a transmission signal transmitted from the auxiliary antenna 8a, and supplies it to the LNA 11a.

Each LNA 11a amplifies the extracted transmission signal and supplies it to the frequency converter 12a. Each frequency converter 12a converts the transmission signal supplied from the frequency converter 12a into an intermediate frequency signal, and supplies the intermediate frequency signal to the AD converter 13a. The AD converter 13 a converts the intermediate frequency signal into a digital signal and supplies the digital signal to the controller 15 .

Each monitor antenna 10 is arranged around the transmitting antenna 8 and at a position farther from the transmitting antenna 8 than the auxiliary antenna 8a. The monitor antenna 10 is arranged in a direction in which it is desired to reduce interference due to transmission signals when viewed from the phase center of the array antenna composed of the transmission antennas 8 . In other words, the monitor antenna 10 is placed in the direction in which it is desired to form a transmission null in the transmission system. A received signal received by each monitor antenna 10 is supplied to the LNA 11 . LNA 11, frequency converter 12 and AD converter 13 operate in the same manner as LNA 11a, frequency converter 12a and AD converter 13a.

The maximum amplitude selector 14 is supplied with a digital signal obtained by amplifying, frequency converting and AD converting the received signal. The maximum amplitude selector 14 selects the digital signal having the maximum amplitude among the digital signals supplied from the AD converter 13 and supplies the selected digital signal to the control section 15 as the maximum amplitude signal. The selection of the digital signal by the maximum amplitude selector 14 corresponds to the operation of selecting the received signal with the maximum amplitude among the received signals received by the P monitor antennas 10 . That is, it is preferable that the amplitude characteristics of the LNA 11, the frequency converter 12, and the AD converter 13 corresponding to each of the P monitor antennas 10 match. If there is a difference in their amplitude characteristics, the maximum amplitude selector 14 selects the digital signal corresponding to the received signal having the maximum amplitude among the P received signals based on the difference in characteristics as the maximum amplitude signal. good too.

The control unit 15 calculates the correlation between the maximum amplitude signal selected by the maximum amplitude selector 14 and the digital signal supplied from each AD converter 13a. Based on the calculated correlation, the control unit 15 calculates the transmission weight W to be supplied to each multiplier 6a so that the components of the transmission signals transmitted from the N transmission antennas 8 are minimized in the maximum amplitude signal. . The control unit 15 supplies the transmission weight W calculated for each multiplier 6a. Based on the maximum amplitude signal selected by the maximum amplitude selector 14, the control unit 15 sequentially calculates transmission weights W for each of the auxiliary antennas 8a. That is, the control unit 15 calculates the transmission weight W based on the amplitude (reception level) when the signal transmitted from the transmission antenna 8 and the auxiliary antenna 8a is received by the monitor antenna 10, It controls the phase or phase and amplitude of the signal transmitted from the auxiliary antenna 8a. The control unit 15 calculates each transmission weight W so as to reduce the amplitude of the signal received by the monitor antenna 10 .

When the digital signal having the maximum amplitude is changed to another digital signal by updating the transmission weight W, the maximum amplitude selector 14 switches the digital signal to be selected as the maximum amplitude signal. By repeating the updating of the transmission weight W and the selection of the maximum amplitude selector 14, the reception level of the reception signal at each monitor antenna 10 gradually decreases. By repeating these operations, the transmission system 100 can form a transmission null in the direction in which the monitor antenna 10 is arranged, and reduce interference of transmission signals in the direction in which the transmission null is formed.

The transmission system 100 has a configuration in which the maximum amplitude selector 14 selects the signal having the maximum amplitude among the signals received by each monitor antenna 10 . Since the signal received by the monitor antenna 10 is the signal transmitted by the transmission antenna 8 and the auxiliary antenna 8a, the output of each monitor antenna 10 has a high correlation. Therefore, when the outputs of the monitor antennas 10 are vector-combined, the outputs may cancel each other out. In such a case, correlation with the digital signal corresponding to the auxiliary antenna 8a cannot be obtained, and a transmission null cannot be formed. By including the maximum amplitude selector 14, the transmission system 100 can stably calculate the transmission weight W and form a transmission null.

FIG. 4 is a diagram showing an arrangement example of the monitor antenna 10 in the first embodiment. FIG. 4 shows a configuration in which some of the antenna elements forming the planar array antenna are used as the auxiliary antenna 8a and the other antenna elements are used as the transmitting antenna 8. As shown in FIG. The normal line of the surface on which the antenna elements of the array antenna are arranged faces the zenith direction, and the monitor antenna 10 is arranged around the array antenna. For example, each monitor antenna 10 may be arranged on a concentric circle around the phase center of the array antenna. The monitor antenna 10 may be arranged in a direction in which side lobes are generated when the main lobe is directed in a desired direction in the array antenna. The monitor antenna 10 may be moved according to the direction in which the main lobe of the array antenna is directed. By arranging the monitor antenna 10 around the array antenna in this manner, the transmission system 100 can reduce interference occurring in the planar direction of the array antenna.

The configuration of connecting the monitor antenna 10 and the LNA 11 with a wired cable has been described with reference to FIG. However, the monitor antenna 10, the LNA 11, and the frequency converter 12 may be formed as one module, and the module and the AD converter 13 may be connected with an IF cable. Alternatively, an AD converter 13 may be added to the module to transmit digital signals. Further, transmission using millimeter waves or optical signals may be performed instead of transmission using a wired cable.

FIG. 5 is a diagram showing the angular response level relationship between the transmitting antenna 8 and the auxiliary antenna 8a in the first embodiment. In FIG. 5, the horizontal axis indicates the pointing direction of the transmitting antenna 8, and the vertical axis indicates the level of the transmitted signal. In the transmission system 100, the level of the signal transmitted from the transmission antenna 8 and the level of the signal transmitted from the auxiliary antenna 8a must satisfy the following relationship. In the directivity direction (main lobe area) formed by the N transmitting antennas 8, the level of the signal transmitted by the transmitting antenna 8 is higher than the level of the signal transmitted by the auxiliary antenna 8a. That is, the product PtGt(main) of the transmission power Pt of the transmission antenna 8 and the transmission angle response Gt is greater than the product PtGt(aux) of the transmission power Pt of the auxiliary antenna 8a and the transmission angle response Gt. On the other hand, in directions (sidelobe regions) other than the directivity directions formed by the N transmitting antennas 8, the level of the signal transmitted by the transmitting antennas 8 (product PtGt(main)) is transmitted by the auxiliary antenna 8a. less than the level of the signal (the product PtGt(aux)). By satisfying these relationships, the interference generated in the direction in which the side lobe of the transmitting antenna 8 is generated can be reduced by the transmission of the auxiliary antenna 8a. The amplitude of the signal transmitted from the transmitting antenna 8 is proportional to PtGt(main), and the amplitude of the signal transmitted from the auxiliary antenna 8a is proportional to PtGt(aux). PtGt represents power and its square root represents amplitude.

Next, the calculation of the transmission weight W of the auxiliary antenna 8a based on the correlation between the maximum amplitude signal selected by the maximum amplitude selector 14 and the digital signal supplied from each AD converter 13a is formulated. For example, when the steepest descent method is used to calculate the transmission weight W, the transmission weight W (adaptive weight W) for the auxiliary antenna 8a is given by Equation (1).

式（１）において、iterは反復回数を表す。Ｗ（iter）は、第iter回目に算出される各補助アンテナ８ａに対するウェイトｗｍを要素とするベクトル［ｗ１，ｗ２，…，ｗＭ］^ｔである。ｙｍａｘ（iter）は、第iter回目におけるＰ個のモニタアンテナ１０の出力のうち最大の振幅を有するディジタル信号を表す。Ｘ（iter）は、Ｍ個の補助アンテナ８ａから送信される信号ｘｍを要素とするベクトル［ｘ１，ｘ２，…，ｘＭ］^ｔである。μは、送信ウェイトＷのステップサイズを表す。ｚｅｒｏは、要素数Ｍのゼロベクトルを表す。ベクトル［・］^ｔの右肩のｔは、ベクトルの転置を表す。

In Equation (1), iter represents the number of iterations. W(iter) is a vector [w1, ^w2 , . ymax(iter) represents the digital signal having the maximum amplitude among the outputs of the P monitor antennas 10 at the iter-th time. X(iter) is a vector [x1, ^x2 , . μ represents the step size of the transmission weight W; zero represents a zero vector with M elements. The superscript t of vector [·] ^t represents the transpose of the vector.

Although the above shows the case where the transmission weight W is represented by a complex number, when only the phase is controlled by the transmission weight, the transmission weight φ is given by Equation (2) (Non-Patent Document 3).

式（２）において、φ（iter）は、第iter回目に算出される各補助アンテナ８ａに対するウェイトφｍを要素とするベクトル［φ１，φ２，…，φＭ］^ｔである。Ｉｍ［・］は、虚数部を表す。他の変数等については、式（１）と同様である。

In equation (2), φ(iter) is a vector [φ1, ^φ2 , . Im[·] represents the imaginary part. Other variables and the like are the same as in formula (1).

Another technique for calculating transmission weights is the RLS (Recursive Least Square) method (Non-Patent Document 2). The RLS method is a method of calculating the inverse matrix calculation of the correlation matrix of the signal of the auxiliary antenna 8a using a recurrence formula, and is expressed by Equation (3).

式（３）におけるＲｘｘ^－１（iter）は、式（４）で与えられる。

Rxx ⁻¹ (iter) in equation (3) is given by equation (4).

式（３）及び式（４）におけるＲｘｘはベクトルＸの相関行列を表し、Ｒｘｘ^－１はＲｘｘの逆行列を表す。ベクトルＸ^Ｈの右肩のＨは、ベクトルＸのエルミート転置（共役転置）を表す。ａは忘却係数を表し、０＜ａ＜１を満たす実数である。他の変数等については、式（１）及び（２）と同様である。

Rxx in equations (3) and (4) represents the correlation matrix of vector X, and Rxx ^-1 represents the inverse matrix of Rxx. The H on the right shoulder of vector X ^H represents the Hermitian transpose (conjugate transpose) of vector X. a represents a forgetting factor and is a real number that satisfies 0<a<1. Other variables and the like are the same as in formulas (1) and (2).

By using the RLS method, even when forming a plurality of transmission nulls, the control unit 15 can calculate the transmission weight W for each auxiliary antenna 8a faster than the steepest descent method or the like.

Another technique for calculating transmission weights is the random search method (Non-Patent Document 4). In the random search method, the transmission weight is changed by a random amount, and the amount of change in the output of the monitor antenna 10 is observed to approximate the optimum transmission weight. In this case, the phase may be controlled by the transmission weight, or the phase and amplitude may be controlled. If the random search method is formulated, it is represented by Formula (5).

式（５）において、ΔＷ（iter）は、送信ウェイトのランダム変化分を表す。他の変数等については、式（１）～（４）と同様である。

In Equation (5), ΔW(iter) represents the random variation of the transmission weight. Other variables and the like are the same as in formulas (1) to (4).

One of the characteristics of the transmission system 100 according to the first embodiment is calculation of the transmission weight W based on the signal having the maximum amplitude among the outputs of the plurality of monitor antennas 10 . Although several methods applicable to calculation of the transmission weight W by the control unit 15 have been described, the control unit 15 may calculate transmission weights using other methods without being limited to these.

(Second embodiment)
In the first embodiment, a configuration has been described in which the auxiliary antenna 8a and the transmitting antenna 8 are included in the same array antenna, and the distributor 5 supplies transmission signals to the transmitting antenna 8 and the auxiliary antenna 8a. The system for supplying signals to the auxiliary antenna 8a and the system for supplying signals to the transmitting antenna 8 may be different without being limited to the configuration described in the first embodiment. For example, when the transmitting antenna 8 is a parabolic antenna, a horn antenna, or the like other than an array antenna, the auxiliary antenna 8a may be attached to or arranged around the transmitting antenna 8 . That is, an auxiliary antenna 8a may be provided separately from the transmitting antenna 8. FIG. In the second embodiment, a configuration will be described in which an auxiliary antenna 8a is provided separately from the transmitting antenna 8, and a system for supplying a transmission signal is provided for each of the transmitting antenna 8 and the auxiliary antenna 8a.

FIG. 6 is a block diagram showing a configuration example of a transmission system 200 according to the second embodiment. The transmission system 200 includes signal generators 1, 1a, modulators 2, 2a, frequency converters 3, 3a, pulse modulators 4, 4a, distributors 5, 5a, multipliers 6, 6a, and high power amplifiers (HPAs). 7, 7a, transmitting antenna 8, auxiliary antenna 8a, coupler 9, monitor antenna 10, low noise amplifier (LNA) 11, 11a, frequency converters 12, 12a, analog-to-digital (AD) converters 13, 13a, maximum amplitude A selector 14 and a control unit 15 are provided. The transmission system 200 includes a signal generator 1 a to a distributor 5 a for the M auxiliary antennas 8 a as a signal processing system independent of the signal processing system for supplying transmission signals to the N transmitting antennas 8 . The transmission signal generated in the system from the signal generator 1a to the distributor 5a is the same as the transmission signal generated in the system from the signal generator 1 to the distributor 5. FIG. That is, the signals transmitted from the transmission antenna 8 and the auxiliary antenna 8a are the same transmission signal although there is a difference in phase or amplitude according to the transmission weight W. FIG.

The transmission system 200 has a signal processing system that supplies transmission signals to the M auxiliary antennas 8 a independently of the system to the transmission antennas 8 . Thereby, even when the transmitting antenna 8 is a parabolic antenna or a horn antenna other than an array antenna, a transmission null can be formed in the direction in which the monitor antenna 10 is arranged. That is, the transmission system 200 can form a transmission null in a desired direction (direction in which the monitor antenna 10 is arranged) regardless of the type and structure of the antenna used as the transmission antenna 8 .

If the transmission signal supplied to the transmission antenna 8 can be branched and supplied to the auxiliary antenna 8a, the transmission system 200 does not need to include the configuration from the signal generator 1a to the distributor 5a. In addition, even for existing transmission devices, a stable transmission null can be formed by applying a feedback loop based on the received signal received by the monitor antenna 10, regardless of the type and structure of the antenna. can.

(Third embodiment)
In the first and second embodiments, configurations were described in which the monitor antenna 10 is arranged in a position or direction that forms a transmission null. If the range in which the monitor antenna 10 can be placed is narrow and the distance between the transmitting antenna 8 and the monitor antenna 10 is short, the reception level will decrease at the position of the monitor antenna 10 and its vicinity, but in the direction in which the monitor antenna 10 is placed. A transmit null may not form. In such cases, the interference of other devices or systems cannot be sufficiently reduced. In the third embodiment, a transmission system that can more reliably form transmission nulls will be described.

The transmission system according to the third embodiment is characterized by the placement of the monitor antenna 10 . FIG. 7 is a diagram showing an arrangement example of the monitor antenna 10 in the third embodiment. In the arrangement example shown in FIG. 7, a certain angular width is determined with respect to a direction in which a transmission null is to be formed, and a plurality of monitor antennas 10 are arranged in an area corresponding to the angular width. In addition to arranging the monitor antenna 10 in the direction in which it is desired to form a transmission null, another monitor antenna 10 is also arranged in the vicinity of the monitor antenna 10 concerned. For example, by arranging a plurality of monitor antennas 10 in an area corresponding to an angular width including a direction in which a transmission null is desired to be formed, the transmission system can more reliably form a transmission null in a desired direction.

FIG. 8 is a diagram showing another arrangement example of the monitor antenna 10 in the third embodiment. In the arrangement example shown in FIG. 8, a plurality of monitor antennas 10 are arranged along the direction in which it is desired to form a transmission null. In other words, another monitor antenna 10 is arranged in a direction connecting the phase center of the transmission antenna 8 with the monitor antenna 10 arranged in the direction in which the transmission null is desired to be formed. By arranging a plurality of monitor antennas 10 in this way, it is possible to prevent the reception level from being locally reduced in one monitor antenna 10 arranged in a direction in which a transmission null is to be formed, and the transmission system can operate in a desired direction. is easier to form a transmit null more reliably.

7 and 8 show examples of the arrangement of the monitor antennas 10, but the arrangement is not limited to these examples. A transmit null may be formed. Also, when a plurality of monitor antennas 10 are arranged, the intervals between the monitor antennas 10 may be determined based on the antenna aperture length of the transmission antenna 8 or the frequency of the transmission signal. The greater the antenna aperture length and the higher the frequency, the greater the change in the transmission angular response Gt. Therefore, by narrowing the interval between the monitor antennas 10 as the antenna aperture length increases or as the frequency increases, the transmission system can more reliably form a transmission null in a desired direction.

(Fourth embodiment)
In the first and second embodiments, a configuration in which the transmission system includes reception processing systems (systems from the LNA 11 to the AD converter 13) corresponding to each of the plurality of auxiliary antennas 8a and the plurality of monitor antennas 10 has been described. . When this configuration is used, the number of reception processing systems increases as the number of monitor antennas 10 increases, leading to an increase in hardware scale. In the fourth embodiment, a transmission system capable of forming a transmission null while suppressing an increase in hardware scale will be described.

FIG. 9 is a block diagram showing a configuration example of a transmission system 300 according to the fourth embodiment. The transmission system 300 includes a signal generator 1, a modulator 2, a frequency converter 3, a pulse modulator 4, a distributor 5, multipliers 6, 6a, high power amplifiers (HPAs) 7, 7a, a transmission antenna 8, an auxiliary antenna. 8 a , coupler 9 , monitor antenna 10 , switch 16 , low noise amplifier (LNA) 11 , frequency converter 12 , analog-digital (AD) converter 13 , selector/switch 17 and controller 15 . The difference between the transmission system 300 and the transmission system 100 of the first embodiment is the number of LNAs 11, frequency converters 12 and AD converters 13, the absence of the maximum amplitude selector 14, the switch 16 and the selection - The switch 17 is provided.

The number of LNAs 11, frequency converters 12, and AD converters 13 in the transmission system 300 is larger than the number (M) of auxiliary antennas 8a and smaller than the sum (M+P) of the numbers of auxiliary antennas 8a and monitor antennas 10. be. The number (L) of LNAs 11, frequency converters 12 and AD converters 13 is equal to or greater than (M+1) and less than (M+P).

In the transmission system 100 of the first embodiment, a reception processing system from the LNA 11 to the AD converter 13 is provided for each of the auxiliary antenna 8a and the monitor antenna 10. FIG. That is, reception processing for (M+P) signals is always performed in parallel. On the other hand, the transmission system 300 has a configuration that does not require a reception processing system for each monitor antenna 10 by performing reception processing on a reception signal received by each monitor antenna 10 in a time-sharing manner. The transmission system 300 includes a switcher 16 and a selector/switcher 17 in order to perform reception processing related to the monitor antenna 10 in a time-division manner.

The switch 16 inputs the transmission signals extracted by the M couplers 9 corresponding to the auxiliary antennas 8a and the reception signals received by the P monitor antennas 10 . The switch 16 outputs a signal selected from the (M+P) input signals to the LNA 11 under the control of the selector/switch 17 . The signal selected by the switch 16 is converted into a digital signal by signal processing by the LNA 11, the frequency converter 12 and the AD converter 13. The selector/switcher 17 outputs the digital signal input from the AD converter 13 to the controller 15 . The selector/switcher 17 also controls the switcher 16 to switch the signal output to the LNA 11 from the (M+P) signals input to the switcher 16 .

FIG. 10 is a diagram showing an example of switching control for the switching device 16 in the fourth embodiment. In FIG. 10, the horizontal axis indicates time, and the vertical axis indicates signal amplitude. The transmission signal indicates the amplitude (presence or absence) of transmission in the transmission antenna 8 and the auxiliary antenna 8a. Auxiliary antennas #1 to #M and monitor antennas #1 to #P indicate the presence/absence of a signal output from switch 16 among the corresponding signals. During the maximum value selection period set when the transmission signal is transmitted from the transmission antenna 8 and the auxiliary antenna 8a, the selector/switcher 17 switches so that the signals received by the monitor antenna 10 are sequentially output one by one. control device 16;

The selector/switcher 17 selects the digital signal having the maximum amplitude among the digital signals input during the maximum value selection period, and switches the monitor antenna 10-p (1≤p≤P) corresponding to the selected digital signal. Identify. That is, the selector/switcher 17 sequentially measures the amplitude of the received signal received by each monitor antenna 10, and selects the digital signal (received signal) having the maximum amplitude based on the measurement results. The selector/switcher 17 controls the switcher 16 so as to output the reception signal of the monitor antenna 10 specified after the maximum value selection period and the transmission signal extracted by the coupler 9 . In this manner, the selector/switcher 17 selects the digital signal having the maximum amplitude by the maximum amplitude selector 14 of the first embodiment by controlling the switcher 16 .

Based on the (M+1) digital signals output from the selector/switcher 17 after the maximum value selection period, the control unit 15 sets the transmission weight W for each of the auxiliary antennas 8a in the same manner as in the first embodiment. calculate. The selector/switcher 17 may select the monitor antenna 10 by setting the maximum value selection period each time the transmission weight W is updated. The operation performed by the selector/switcher 17 and the control of the switcher 16 may be performed by the controller 15 .

In the switching control shown in FIG. 10, the operation of sequentially selecting one received signal during the maximum value selection period has been described, but two or more received signals may be sequentially selected. Even when two or more received signals are selected in the maximum value selection period, the switcher is used to use the reception processing system for the transmission signals from the M couplers 9 for the reception signal of the monitor antenna 10. 16, the number L of reception processing systems included in the transmission system 300 may be set to (M+1). By providing a plurality of received signals output from the switch 16 during the maximum value selection period, the time required to select the digital signal having the maximum amplitude can be shortened.

If the amplitude of the transmission pulse contained in the transmission signal changes greatly over time, the calculation accuracy of the transmission weight W may deteriorate. However, in most cases, since the amplitude of the transmitted signal can be considered to be substantially constant, even if the received signal is monitored by time division, its influence is small. Also, the time during which the switch 16 outputs each received signal in the maximum value selection period may be one or more transmission pulses. By setting the output time of the switch 16 to be longer than one transmission pulse, it is possible to suppress the influence of the amplitude change in the transmission pulse.

In addition, in the fourth embodiment, the configuration of the transmission system 300 has been described in comparison with the transmission system 100 of the first embodiment. However, the configuration described in the fourth embodiment may be applied to the transmission system 200 of the second embodiment.

The transmission system in the above embodiment includes a CPU (Central Processing Unit), a memory, an auxiliary storage device, and the like connected by a bus. A process of calculating may be performed. The CPU may perform some or all of the operations in the transmission system by executing programs stored in the auxiliary storage device. Also, all or part of the operations in the transmission system may be implemented using hardware such as ASIC (Application Specific Integrated Circuit), PLD (Programmable Logic Device), FPGA (Field Programmable Gate Array), and the like. The program may be recorded on a computer-readable recording medium. Computer-readable recording media are portable media such as flexible disks, magneto-optical disks, ROMs and CD-ROMs, and non-temporary storage media such as hard disks built into computer systems. The program may be transmitted over telecommunications lines.

According to at least one embodiment described above, the phase or phase and amplitude of the signal transmitted from the auxiliary antenna is based on the reception level when the signal transmitted from the transmission antenna and the auxiliary antenna is received by the monitor antenna can form a transmission null in the direction in which the monitor antenna is arranged, and can reduce interference with other devices or systems caused by the transmission of radio signals.

While several embodiments of the invention have been described, these embodiments have been presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and modifications can be made without departing from the scope of the invention. These embodiments and their modifications are included in the scope and spirit of the invention, as well as the scope of the invention described in the claims and equivalents thereof.

1, 1a... signal generator, 2, 2a... modulator, 3, 3a... frequency converter, 4, 4a... pulse modulator, 5, 5a... distributor, 6, 6a... multiplier, 7, 7a... HPA , 8... Transmitting antenna, 8a... Auxiliary antenna, 9... Coupler, 10... Monitor antenna, 11, 11a... LNA, 12, 12a... Frequency converter, 13, 13a... AD converter, 14... Maximum amplitude selector, 15 ... control unit, 16 ... switcher, 17 ... selector/switcher

Claims (8)

a transmitting antenna and an auxiliary antenna for transmitting signals;
a monitor antenna arranged at a position farther from the transmitting antenna than the auxiliary antenna;
a control unit that controls the phase or the phase and amplitude of the signal transmitted from the auxiliary antenna based on the received signal when the signal transmitted from the transmission antenna and the auxiliary antenna is received by the monitor antenna;
, wherein the monitor antenna is arranged in a direction in which it is desired to suppress interference of transmission by the transmission antenna. a transmitting antenna and an auxiliary antenna for transmitting signals;
a monitor antenna arranged at a position farther from the transmitting antenna than the auxiliary antenna;
a control unit that controls the phase or the phase and amplitude of the signal transmitted from the auxiliary antenna based on the received signal when the signal transmitted from the transmission antenna and the auxiliary antenna is received by the monitor antenna;
with
a plurality of the monitor antennas,
The control unit controls the phase or the phase and amplitude of the signal transmitted from the auxiliary antenna based on the received signal having the maximum amplitude among the received signals obtained by the plurality of monitor antennas, A transmission system for reducing a received signal when the signal transmitted from the transmission antenna and the auxiliary antenna is received by the monitor antenna. Other monitor antennas are arranged in the vicinity of at least one of the monitor antennas,
3. The transmission system of claim 2 . Another monitor antenna is arranged in a direction connecting at least one of the monitor antennas and the transmitting antenna;
3. The transmission system of claim 2 . The control unit sequentially measures the amplitude of each received signal by using a reception processing system for the received signals received by the plurality of monitor antennas in a time division manner, and selects the received signal having the maximum amplitude based on the measurement results. Identify,
3. The transmission system of claim 2 . The transmitting antenna has a plurality of antenna elements,
the transmit antenna and the auxiliary antenna form an array antenna;
Transmission system according to any one of claims 1 to 5 . A transmission method in a transmission system comprising a transmission antenna and an auxiliary antenna for transmitting signals, and a monitor antenna arranged at a position farther from the transmission antenna than the auxiliary antenna,
A control step of controlling the phase or the phase and amplitude of the signal transmitted from the auxiliary antenna based on the received signal when the signal transmitted from the transmission antenna and the auxiliary antenna is received by the monitor antenna;
and the monitor antenna is arranged in a direction in which interference with transmission by the transmitting antenna is desired to be suppressed.
Send method. A transmission method in a transmission system comprising a transmission antenna and an auxiliary antenna for transmitting signals, and a monitor antenna arranged at a position farther from the transmission antenna than the auxiliary antenna,
A control step of controlling the phase or the phase and amplitude of the signal transmitted from the auxiliary antenna based on the received signal when the signal transmitted from the transmission antenna and the auxiliary antenna is received by the monitor antenna;
has
a plurality of the monitor antennas,
In the control step, based on the received signal having the maximum amplitude among the received signals obtained by the plurality of monitor antennas, the phase or the phase and amplitude of the signal transmitted from the auxiliary antenna is controlled, Reducing the received signal when the signal transmitted from the transmission antenna and the auxiliary antenna is received by the monitor antenna
Send method.

Images