JP4812120B2 - Polarization-selective radio shutter - Google Patents

Description

  The present invention filters incoming radio waves by selectively transmitting radio waves having a polarization direction selected from two predetermined orthogonal directions, and supplies the filtered radio waves to a communication device having no polarization characteristics. The present invention relates to a polarization-selective radio wave shutter that can switch the electrically selected polarization direction.

  For example, when a wireless LAN (local area network) device that uses radio waves is provided with a network between buildings, a decrease in communication speed due to multipath may be a problem. This is because the transmitted radio wave is received after passing through a propagation path longer than the direct wave by being reflected by an adjacent building. Due to this difference in propagation distance, interference with the direct wave occurs, or a deviation from the data signal of the direct wave occurs and superposition with different data occurs, thereby causing an error due to transmission. In order to prevent such an error, the communication apparatus performs retransmission of data and a data transfer rate, and as a result, the communication speed decreases.

  In general, it is known that many reflected waves rotate in the direction of polarization compared to the time of transmission. For this reason, it is desirable to perform transmission and reception with polarization in a specific direction. Conventionally, such a configuration is realized by transmitting and receiving with an antenna having polarization characteristics or an antenna using a lattice-shaped polarization filter.

  In a communication environment where there is no rotation in the polarization direction on the transmission line, a wireless LAN using polarization multiplexing can be provided. Such polarization multiplexing is also realized by transmitting and receiving with an antenna having polarization characteristics and an antenna using a lattice polarization filter.

  As is well known, even if circularly polarized waves (right-handed and left-handed polarized waves) are used, the decrease in error rate can be suppressed and polarization multiplexing can be performed as described above. Is a polarization-selective radio wave shutter for linearly polarized waves.

[Conventional example 1]
In Patent Document 1, a radio wave having a frequency to be shielded is selectively absorbed, the thickness is made thinner than that of a conventional λ / 4 type radio wave absorber, and the electromagnetic wave reflection film of the radio wave absorber and the electromagnetic wave absorption are disclosed. By using a honeycomb structure for the dielectric layer used between the films, a lightweight wave absorber is provided, and radio waves other than the frequency to be shielded can be transmitted in both directions. A radio wave absorber that is unnecessary and has excellent workability is disclosed. This includes a resistor film layer and a honeycomb structure dielectric layer, and a radio wave reflection layer is formed on the surface of the dielectric layer opposite to the resistor film layer, and at least the resistor film layer and the radio wave reflection layer are formed. A phase adjusting layer is provided between the layers.

[Conventional example 2]
Patent Document 2 discloses a radio wave shielding control body capable of controlling electromagnetic wave permeability. This adjusts the temperature of various shielding materials placed in the propagation path of electromagnetic waves made of a material (referred to as resistance change material) whose electrical resistance changes (conductor → nonconductor or nonconductor → conductor) due to temperature change (heating) ), The conductivity of the shielding material is changed to control the electromagnetic wave permeability. Furthermore, in Patent Document 2, shield materials formed by forming a variable resistance material having the same ability to change resistance to temperature with a rod shape or a belt shape are arranged in a saddle shape or a lattice shape at the same interval under alternating arrangement. The maximum frequency (minimum wavelength) of the radio wave that exerts the shielding effect by changing the interval of the conductive material can be selected and changed by alternately adjusting (heating, cooling) the temperature of each shield material in the shape of a lattice or lattice. An electromagnetic wave shielding system having a variable shielding target frequency, which is characterized by the above, is disclosed.

  A configuration in which the above-described conventional example is used in two layers in two orthogonal directions determined in advance and is filtered by selectively transmitting a radio wave having a polarization direction in either of those directions. It is easy to realize. However, the above-mentioned radio wave absorber or electromagnetic wave shield system has a problem that even if it is a single unit, the thickness of the radio wave transmission direction is large, and it is difficult to make it thinner by using two layers.

JP 2005-79247 A JP 2001-210990 A

  A polarization-selective radio wave shutter capable of electrically switching the polarization direction of a transmitted radio wave from the outside to either one of two orthogonal directions is realized.

  By using this invention in front of a communication device having no polarization characteristics, the polarization direction received by the communication device can be electrically switched.

The present invention is directed to a linearly polarized radio wave, and relates to a polarization-selective radio wave shutter for controlling the transmissivity level from the outside for each orthogonal polarization direction. The polarization-selective radio wave shutter of the present invention uses four antenna conductors (A ₁ , A ₂ , A ₃ , A ₄ ) and four variable reactors (Z ₁ , Z ₂ , Z ₃ , Z ₄ ). Radio wave shutter configured,
In particular, the above-described variable reactor is a variable reactor having directionality and capable of electrically controlling reactance,
Each variable reactor is
When a potential difference is applied in the first direction, it shows low reactance,
When a potential difference is applied in a second direction opposite to the first direction, the high reactance is greater than the low reactance,
Having electrical connections circulating with A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z ₄ , A ₁ ,
The direction of the variable reactor is a certain direction along the circulation,
When A ₁ is regarded as A ₅ , for k from 1 to 4,
The connection of A _k , Z _k , and A _{k + 1} has a high transmittance with respect to a polarized wave having a predetermined frequency in the direction connecting A _k and A _{k + 1} when Z _k exhibits a high reactance. When Z ₁ indicates low reactance, it indicates a low transmittance lower than the high transmittance with respect to a polarized wave having a predetermined frequency in the direction connecting A _k and A _{k + 1} .
A ₁ is electrically connected to the first potential source through a resistor,
A ₂ is electrically connected to the second potential source through a resistor,
A ₃ is electrically connected to the first potential source through a resistor,
A ₄ is electrically connected to the second potential source through a resistor,
(1) By making the potential of the first potential source higher or lower than the potential of the second potential source,
The transmittance of the polarized wave having the above frequency in the direction connecting A ₁ and A ₂ and A ₂ and A ₃ can be electrically switched.

By electrically connecting the A ₁ and A ₃ of the through resistor may be electrically connected to the first potential source via the A ₁ and A ₃ resistor.

In the above configuration, four antenna conductors (A ₁ , A ₂ , A ₃ , A ₄ ) and four variable reactors (Z ₁ , Z ₂ , Z ₃ , Z ₄ ) are used. Furthermore, a polarization-selective radio wave shutter can be configured by using many things. That is, including antenna conductors arranged in an M × N matrix and a plurality of variable reactors,
(1) Four adjacent antenna conductors ( _{Aj, k} , _{Aj, k + 1} , _{Aj + 1, k} , _{Aj + 1, k + 1} ) at arbitrary positions in the matrix are The four antenna conductors (A ₁ , A ₂ , A ₃ , A ₄ ) and four variable reactors (Z ₁ , Z ₂ , Z ₃ , Z ₄ ) are used. . _{Also, A j, k, A j} , k + 1, A j + 1, k + 1, A j + 1, k corresponds to _{A 1, A 2, A 3} , A 4 , respectively, A _{j, k} , A _{j, k + 1} , A _{j + 1, k + 1} , A _{j + 1, k} are variable reactors corresponding to the variable reactors (Z ₁ , Z ₂ , Z ₃ , Z ₄ ). Shall be provided. The electrical connection A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z ₄ , A ₁ of the antenna conductor and the variable reactor is defined as the first circulation direction,
A ₁ is electrically connected to the first potential source through a resistor,
A ₂ is electrically connected to the second potential source through a resistor,
A ₃ is electrically connected to the first potential source through a resistor,
A ₄ is electrically connected to the second potential source through a resistor.
(2) Further, the antenna conductors (A _{j + 1, k} , A _{j + 1, k + 1} , A _{j + 2, k} , A _{j + 2, k + 1} ) correspond to the first aspect. A _{j + 1, k} , A _{j + 1, k + 1} , A _{j + 2, k + 1} , A _{j + 2, k} are respectively A ₁ , A ₂ , A ₃ , A ₄ . Correspondingly, the variable reactors (Z ₁ , Z ₂ , Z) are connected between A _{j + 1, k} , A _{j + 1, k + 1} , A _{j + 2, k + 1} , A _{j + 2, k. 3} , Z ₄ ), and the electrical connection between the antenna conductor and the variable reactor A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z in this case ₄ , the circulation direction of A ₁ is the second circulation direction opposite to the first circulation direction,
A ₁ is electrically connected to the second potential source through a resistor,
A ₂ is electrically connected to the first potential source through a resistor,
A ₃ is electrically connected to the second potential source through a resistor,
A ₄ is electrically connected to the first potential source through a resistor,
(3) Further, the antenna conductors ( _{Aj, k + 1} , _{Aj, k + 2} , _{Aj + 1, k + 1} , _{Aj + 1, k + 2} ) are the above four antenna conductors. (A ₁ , A ₂ , A ₃ , A ₄ ) and four variable reactors (Z ₁ , Z ₂ , Z ₃ , Z ₄ ) have a configuration corresponding to that, and A _{j, k + 1} , A _{j, k + 2} , A _{j + 1, k + 2} , A _{j + 1, k + 1} correspond to A ₁ , A ₂ , A ₃ , A ₄ , respectively, and A _{j, k + 1} , A _{j , K + 2} , A _{j + 1, k + 2} , A _{j + 1, k + 1} are provided with variable reactors corresponding to the variable reactors (Z ₁ , Z ₂ , Z ₃ , Z ₄ ). Shall. In this case, the electrical connection between the antenna conductor and the variable reactor A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z ₄ , A ₁ is circulated in the first circulation. A second circulation direction opposite to the direction,
A ₁ is electrically connected to the second potential source through a resistor,
A ₂ is electrically connected to the first potential source through a resistor,
A ₃ is electrically connected to the second potential source through a resistor,
A ₄ is electrically connected to the first potential source through a resistor,
Is.

Alternatively, by electrically connecting the A ₁ and A ₃ of the through resistor electrically connects to the first potential source via the A ₁ and A ₃ resistor is basically In the configuration,
Including antenna conductors arranged in an M × N matrix and a plurality of variable reactors,
(1) Four adjacent antenna conductors ( _{Aj, k} , _{Aj, k + 1} , _{Aj + 1, k} , _{Aj + 1, k + 1} ) at arbitrary positions in the above matrix are charged. A _{j, k} , A _{j, k + 1} , A _{j + 1, k + 1} , A _{j + 1, k} are A ₁ , A ₂ , A ₃ , respectively. A ₄ , A ₄ , A _{j, K 2} , A _{j, k + 1} , A _{j + 1, k + 1} , A _{j + 1, k} between the variable reactors (Z ₁ , Z ₂ , Z ₃ and a variable reactor corresponding to Z ₄ ). When the antenna conductor and the variable reactor in this case are (A ₁ , A ₂ , A ₃ , A ₄ ) and (Z ₁ , Z ₂ , Z ₃ , Z ₄ ), respectively, the antenna conductor and the variable reactor described above are used. The first circulation direction is the circulation direction of the electrical connections A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z ₄ , A ₁ ,
A ₁ is electrically connected to the first potential source through a resistor,
A ₂ is electrically connected to the second potential source through a resistor,
A ₃ is electrically connected to the first potential source through a resistor,
A ₄ is electrically connected to the second potential source via a resistor.
(2) Further, the antenna conductor (A _{j + 1, k} , A _{j + 1, k + 1} , A _{j + 2, k} , A _{j + 2, k + 1} ) corresponds to the second aspect. A _{j + 1, k} , A _{j + 1, k + 1} , A _{j + 2, k + 1} , A _{j + 2, k} are respectively A ₁ , A ₂ , A ₃ , A ₄ . Correspondingly, the variable reactors (Z ₁ , Z ₂ , Z) are connected between A _{j + 1, k} , A _{j + 1, k + 1} , A _{j + 2, k + 1} , A _{j + 2, k. 3} , equipped with a variable reactor corresponding to Z ₄ )
When the antenna conductor and the variable reactor in this case are (A ₁ , A ₂ , A ₃ , A ₄ ) and (Z ₁ , Z ₂ , Z ₃ , Z ₄ ), respectively,
Electrical connection A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z ₄ , A ₁ of the antenna conductor and the variable reactor is reverse to the first circulation direction. The second circulation direction of
A ₁ is electrically connected to the second potential source through a resistor,
A ₂ is electrically connected to the first potential source through a resistor,
A ₃ is electrically connected to the second potential source through a resistor,
A ₄ is electrically connected to the first potential source through a resistor,
(3) Further, the antenna conductors (A _{j, k + 1} , A _{j, k + 2} , A _{j + 1, k + 1} , A _{j + 1, k + 2} ) correspond to claim 2 A _{j, k + 1} , A _{j, k + 2} , A _{j + 1, k + 2} , A _{j + 1, k + 1} are respectively A ₁ , A ₂ , A ₃ , A ₄ . Correspondingly, the variable reactors (Z ₁ , Z ₂ , Z _{+ 1) are connected} between A _{j, k + 1} , A _{j, k + 2} , A _{j + 1, k + 2} , A _{j + 1, k + 1. 3} , equipped with a variable reactor corresponding to Z ₄ )
When the antenna conductor and the variable reactor in this case are (A ₁ , A ₂ , A ₃ , A ₄ ) and (Z ₁ , Z ₂ , Z ₃ , Z ₄ ), respectively,
Electrical connection A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z ₄ , A ₁ of the antenna conductor and the variable reactor is reverse to the first circulation direction. The second circulation direction of
A ₁ is electrically connected to the second potential source through a resistor,
A ₂ is electrically connected to the first potential source through a resistor,
A ₃ is electrically connected to the second potential source through a resistor,
A ₄ is electrically connected to the first potential source via a resistor.

In addition, the polarization selectivity formed by using the above four antenna conductors (A ₁ , A ₂ , A ₃ , A ₄ ) and four variable reactors (Z ₁ , Z ₂ , Z ₃ , Z ₄ ). A radio wave shutter is a structural unit, and a plurality of the structural units are used to form a matrix.
The structural units adjacent in the row or column direction are arranged so that the circulation direction of the electrical connection between the antenna conductor and the variable reactor is in a mirror image relationship,
The antenna conductors facing each other between adjacent structural units in the row or column direction may be electrically connected by a resistor.

The four antenna conductors (A ₁ , A ₂ , A ₃ , A ₄ ) and the four variable reactors (Z ₁ , Z ₂ , Z ₃ , Z ₄ ) are used, and A ₁ and A ₃ is composed of a polarization-selective radio wave shutter in which A ₁ and A ₃ are electrically connected to the first potential source via a resistor by electrically connecting to ₃ via a resistor. , Which is configured in a matrix using a plurality of the structural units,
The structural units adjacent in the row or column direction are arranged so that the circulation direction of the electrical connection between the antenna conductor and the variable reactor is in a mirror image relationship,
The antenna conductors facing each other between adjacent structural units in the row or column direction may be electrically connected by a resistor.

  The antenna conductor located on one side of the left end or the right end of the row of the above matrix or one side of the upper end or the lower end of the column alternately with the first potential source and the second potential source through the resistor. The polarization direction to be selected is selected.

In addition, for the antenna conductor located on one side of the left end or right end of the row of the above matrix or one side of the upper end or lower end of the column,
Connecting either the first antenna conductor or the second antenna conductor connected to the first antenna conductor via a resistor to the first potential source;
Either the third antenna conductor connected to the first antenna conductor or the second antenna conductor via a variable reactor, or the fourth antenna conductor connected to the third antenna conductor via a resistor The polarization direction to be selected is selected so as to be a two-potential source.

  Embodiments of the present invention will be described below in detail with reference to the drawings. In the following description, devices having the same function or similar functions are denoted by the same reference numerals unless there is a special reason.

First, the basic idea of the present invention will be described.
FIG. 1 is a circuit diagram showing an example of a radio wave shutter 1 that functions with respect to a specific polarization direction, where λ is the wavelength of the radio wave that controls the transmittance when it passes through. The radio wave shutter 1 includes a shutter body 2 disposed in a radio wave propagation path, a DC power source 3 that is a first potential source when a first potential and a second potential are applied to the shutter body 2, and a first potential. A switch 4 that selects a voltage to be applied from a source and a ground potential that is a second potential, and a grounding unit 5 that connects the shutter body 2 to a ground potential that is a third potential. Here, when the ground potential is selected by switching, the first electrical condition is applied, and when the DC power supply 3 is selected, the second electrical condition is applied.

  The shutter body 2 shown in FIG. 1 is configured by arranging a plurality of radio wave wing plates 21 substantially in parallel at intervals shorter than λ / 4 into a substantially rectangular sheet. In addition, each radio wave wing plate 21 is formed by connecting electric wires 22 formed to a length of about λ / 4 in series using variable reactors 23 and resistors alternately. Here, the electric wire 22 may be one of two conductors of a dipole antenna that resonates with a target radio wave. When a basic unit is a unit in which a variable reactor 23 is sandwiched between two electric wires 22 and connected in a column, the radio wave shutter uses a plurality of the basic units. As the antenna conductor, a linear or plate-like rectangle, circle, or star shape as shown in FIG. 14 may be used as long as it functions as a dipole antenna. A shape having symmetry is desirable. The transmissivity of the radio wave polarized in the direction connecting the antenna conductors is controlled by controlling the reactance of the variable reactor 23 sandwiched between the antenna conductors. A plurality of the basic units are arranged in a connected manner via a resistor 24 having an impedance much larger than the impedance value of the variable reactor, and are electrically connected. This is for applying a voltage to the variable reactor 23 and serves to block high-frequency coupling between the basic units. That is, the resistor 24 is a resistor for high-frequency signals, and an inductor having almost no DC resistance can be used in addition to a resistor for DC current.

  The variable reactor 23 is a variable reactor capable of electrically controlling reactance, and an example is shown in FIG. The variable reactor 23 of (a) makes its reactance variable by series connection of a coil which is an inductor 232 having a fixed inductive reactance and a variable capacitance diode 231. It can also be said that the radio wave shutter is in a shielding state when the resonance condition in the variable reactor is satisfied, and is in a transmission state when the positive reactance value is significantly deviated from the resonance condition. In this example, the variable capacitance diode 231 and the inductor 232 are connected in series, but as shown in (b), a coil which is the inductor 232 connected in series with the capacitor 234 and the variable capacitance diode 231 are connected in parallel. Can also be used. The reactance of the capacitor 234 is sufficiently small. In this case, it can be said that the radio wave shutter is set to the transmission state when the resonance condition of the variable reactor 23 is satisfied, and is set to the shielding state when the variable reactor 23 is greatly deviated from the resonance condition. 3A or 3B, when the impedance of the variable reactor 23 increases, the current flowing through the antenna conductor sandwiching the variable reactor 23 is suppressed, and when the impedance is zero or small, the antenna conductor is suppressed. Make current flow well. For incident radio waves, the antenna conductor is relatively transmissive when the current of the antenna conductor is suppressed, and is relatively shielded when the current flows.

  As is well known, there is a possibility that the first variable capacitance diode 231 of the variable reactor 23 has a problem that the reverse bias from the DC power supply 3 is not divided evenly due to variations in element characteristics. Therefore, as shown in FIG. 3, when a high resistance 233 is connected in parallel with the first variable capacitance diode 231, in the case of a cascade connection, the reactance of each variable reactor 23 is made uniform, and radio wave transmission is achieved. It is desirable to suppress the generation of the state portion and the radio wave shielding state portion.

  In order to maximize the transmittance at which the radio wave passes through the radio wave shutter, in the case of FIG. 3A, the reactance value of the series sum of the inductive reactance and the capacitive reactance is set to an appropriate positive value. It is good to realize the maximum reactance at a DC voltage of 0V. The configuration (b) can be regarded as a parallel resonant circuit. In this case, the inductive reactance and the capacitance are selected so as to resonate at a desired frequency.

  Conversely, in order to increase the shielding effect, in the case of FIG. 3A, the inductive reactance and the capacitive reactance are made to satisfy the resonance condition and become almost zero. In the case of (b), the impedance of the parallel sum of the inductive reactance and the capacitive reactance is made as small as possible. This should be realized when the DC voltage is 0V.

FIG. 4A shows a case where the current is interrupted so as to correspond to the case where the impedance between the antenna conductors is infinite, but the current is interrupted, but the integrated value of the current distribution does not become zero. FIG. 4B shows a case where an appropriate positive reactance is loaded, and the current between the antenna conductors is not cut off, but the integrated value of the current distribution becomes almost zero.

  In general, the variable capacitance diode exhibits a smaller capacitance as the reverse bias voltage is larger. Since the inductive reactance is a fixed value, in the configuration shown in FIG. 3A, the impedance is minimized under the resonance condition, and a positive reactance value is obtained when the capacitance is larger than that. For this reason, it is desirable to adjust the reactance by the variable capacitance diode, to minimize the transmittance when a large reverse bias voltage is applied, and to maximize the transmittance when the reverse bias voltage is almost 0V. This is the setting. In FIG. 3, (b) is easier to control the resonance Q-value than (a), and therefore it is easier to control the shielding band.

  The optimum value of reactance for maximizing the transmittance that passes through the radio wave shutter depends on the thickness of the electric wire 22 and the interval between the radio wave blades 21. For example, when the diameter of the electric wire 22 is 0.02λ and the conductor is λ / 4, it is 550Ω, and when the interval is λ / 12, about 640Ω is the optimum value. This is an example of a condition for obtaining a reactance at which the current integral value of the basic unit becomes almost zero when a predetermined first electrical condition is applied.

In addition, when the reactance or impedance value of the variable reactor or the resistor between the antenna conductors is alternately infinite and X, and is a cylindrical electric wire 22,
When the distance d is larger than λ / 10, W is the width (thickness) of the line, and the optimum reactance value X is
X≈1200exp (−37 W / λ) [Ω],
Degree.
In addition, when the reactance or impedance value of the variable reactor or the resistor between the antenna conductors is alternately infinite and X, and is a flat wire 22,
When the distance d is larger than λ / 10, W is the width (thickness) of the line, and the optimum reactance value X is
X≈1200exp (−16 W / λ) [Ω],
Degree.
Also, when the variable reactors between the antenna conductors are uniformly arranged with the same reactance value, and in the case of the cylindrical electric wire 22,
When the distance d is larger than λ / 10, W is the width (thickness) of the line, and the optimum reactance value X is
X≈1200exp (−17 W / λ) [Ω],
Degree.

FIG. 2 shows a circuit example in which two of the basic units are electrically connected by a resistor 24. FIG. 2A shows a radio wave transmission state (high transmittance), and FIG. 2B shows a radio wave shielding state (low transmittance). The radio wave blade 21 is connected in series with the first electric wire 22a, the variable reactor 23, and the second electric wire 22b, and the second electric wire 22b and the third electric wire 22c are connected with the resistor 24, and the third electric wire 22c and the variable reactor are connected. 23 and the fourth electric wire 22d are connected in series. As shown in FIG. 3A, the variable reactor 23 is configured by a series connection of a first variable capacitance diode 231 having a capacitive reactance X _{C1 and} a first inductor 232 having an inductive reactance X _L1 .

The capacitance of the first variable capacitance diode 231 is C _X1 and the capacitive reactance is X _C1 . Although the capacitive reactance X _C1 has a negative value on the imaginary axis, the capacitive reactance X _C1max when the reverse bias is not applied to the first variable capacitance diode 231 is the reverse bias applied to the first variable capacitance diode 231. Note that the absolute value is smaller than the capacitive reactance X _C1min at the time. First, in FIG. 2A, a ground level bias is applied by the switch 4. At this time, if the series connection portion of the first electric wire 22a, the variable reactor 23, and the second electric wire 22b is designed so as to have an appropriate positive reactance value, the current distribution corresponding to the schematic diagram (b) of FIG. Thus, the integral amount of the current flowing through the upper and lower electric wires becomes almost zero, and the electrical transparency condition is satisfied.

  Similarly, the electrically transparent condition is also established at the cascade connection portion of the third electric wire 22c, the variable reactor 23, and the fourth electric wire 22d. For the resistor 24, a resistance value or reactance value larger than the impedance value of the variable reactor for maximizing the transmittance of the radio wave shutter is set. For example, it should be 10 kΩ or more. In this case, the conductors connected via the resistor 24 can be regarded as open, and no current flows between the second electric wire 22b and the third electric wire 22c. In other words, although the current flows locally due to the incoming radio wave, the radio wave wing plate 21 has an integration amount of zero, and therefore, it is possible to realize a radio wave transmission state without hindering radio wave transmission.

On the other hand, in the case of FIG. 2B, the reverse bias potential is selected from the DC power source 3 by the switch 4, and the capacitance of the first variable capacitance diode 231 becomes a predetermined value. At this time, _assuming that the capacitive reactance is X _C1min , the value of the imaginary part of the impedance of the variable reactor 23 (= X _L1 + X _C1min ) is set to be _{substantially} zero, so that the first electric wire 22a and the second electric wire 22a The electric wire 22b, and the fourth electric wire 22c and the fourth electric wire 22d are short-circuited. This state corresponds to a state in which short-circuited dipoles are connected in cascade. In other words, the radio wave wing plate 22 has a good current flow due to the incoming radio wave, so that the radio wave transmittance is reduced. As a result, a radio wave shielding state is realized.

  When a plurality of the basic units are used as shown in FIG. 1 or FIG. 2, a divided voltage is applied to each constituent unit, so that it is necessary to increase the voltage according to the configuration. .

  In this way, the impedance of the variable reactor shown in FIG. 3A is such that the first electrical condition (that is, the low reverse bias voltage) is applied when the predetermined second electrical condition (that is, the high reverse bias voltage) is applied. The reverse bias voltage) is smaller than that in the above case, and ideally, it can have an impedance of almost zero.

  On the other hand, when the variable reactor shown in FIG. 3B is used, the first electrical condition (in this case, the high reverse bias) is applied when the second electrical condition (in this case, the low reverse bias voltage) is applied. The voltage) is smaller than the above-mentioned case, and ideally, it can have an impedance of almost zero.

  Next, means for applying such electrical conditions will be described. As shown in FIG. 1, the high potential sides of the radio wave slats 21 are connected to each other via a high resistance R1, and each is connected to a switch 4 that is a potential selection means via a resistor. . Further, the low potential sides of the respective radio wave wing plates 21 are connected to each other via a high resistance R2, and each is connected to a ground serving as a reference via a resistor. R1 and R2 prevent the radio frequency (RF) current from flowing between the radio wave slats 21 and a high reactance inductor may be connected instead of the high resistances R1 and R2. With this configuration, when the first electrical condition is applied, the first transmittance is shown with respect to the target radio wave, and when the second electrical condition is applied, It is possible to show a second transmittance lower than the first transmittance with respect to the radio wave to be transmitted. This difference in transmittance is used as a radio wave shutter.

  Further, in the radio wave shutter 1 of FIG. 1, no RF current flows in a direction orthogonal to the radio wave blade 21, so there is no reflection or attenuation, and polarized waves orthogonal to the radio wave vane 21 always pass through the shutter body 2. To Penetrate.

  In the above configuration, the direction of polarization is predetermined, but the present invention increases the transmittance of either polarization for each of two predetermined polarizations, Control is performed to lower the other.

FIG. 5 is a diagram showing an example of the basic unit of the polarization selective radio wave shutter of the present invention.
This is a radio wave shutter composed of four antenna conductors 7 (A ₁ , A ₂ , A ₃ , A ₄ ) and four variable reactors 8 (Z ₁ , Z ₂ , Z ₃ , Z ₄ ). is there. As a matter of course, wiring for electrically controlling the variable reactor 8 is also necessary. Here, the variable reactor is a variable reactor 8 having directionality and capable of electrically controlling reactance. Each variable reactor 8 has a low reactance when a potential difference is applied in the first direction. When a potential difference is applied in the second direction opposite to the first direction, the high reactance is larger than the low reactance. However, unlike the one shown in FIG. 3, the one used in the present invention has a resistor for limiting the current flowing through the variable reactor 8 when a forward bias is applied.

  FIG. 7 shows an example of a variable reactor used in the present invention in a dashed box. 7A and 7B show a variable capacitance diode and a coil that is an inductive reactor connected in series. (A) is a case where the variable capacitance diode is biased by power supply via a resistor, and (b) is a case where power supply is performed via a coil. In these cases, when the capacitive reactance of the variable capacitance diode is small, the impedance of the variable reactor becomes almost zero, and when the capacitive reactance of the variable capacitance diode is large, the reactance value of the variable reactor is an appropriate positive value. Set to be the value of.

  FIG. 7C shows a variable capacitance diode and a coil that is an inductive reactor connected in parallel. In this case, the resonance condition of the variable reactor is satisfied when the capacitive reactance of the variable capacitance diode is an appropriate value, and the reactance value of the variable reactor is an appropriate positive value. When the reactive reactance deviates from an appropriate value, it is set so that the impedance of the variable reactor becomes almost zero by removing from the resonance condition. It has the feature that it is easy to design the band characteristics by controlling the Q value of the parallel resonance.

  FIG. 7D shows a reactor having a configuration in which a series connection and a parallel connection of a variable capacitance diode and a coil which is an inductive reactor are selectively used by a switch. As the switch, a transistor switch, a relay switch, or the like can be used. By switching with this switch, the connection condition between the variable capacitance diode and the coil, that is, the series connection and the parallel connection can be switched to reversely set the bias condition for transmission or shielding.

  The fixed-capacitance capacitors (a) to (d) described above are for cutting off a direct current flowing through the variable-capacitance diode by a forward bias. The resistor R1 is used to absorb the variation in the leakage current of the variable capacitance diode, and a resistor that flows a current larger than the leakage current is used. If the variation in voltage drop due to leakage current does not matter, it can be omitted. The resistor R2 is for limiting the direct current flowing through the variable capacitance diode by the forward bias.

As shown in FIG. 5, the connection between the antenna conductor 7 and the variable reactor 8 circulates with A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z ₄ , A ₁ . Use electrical connection. The direction of the variable reactor is a constant direction along the circulation. For simplicity, let A ₁ be considered A ₅ . Here, for k from 1 to 4, the connection of A _k , Z _k , and A _{k + 1} is determined in advance in the direction connecting A _k and A _{k + 1} when Z _k indicates high reactance. When the polarization having a predetermined frequency shows high transmittance and Z _k shows a value close to zero, the high transmission is obtained for the polarization having a predetermined frequency in the direction connecting A _k and A _{k + 1.} The low transmittance is lower than the transmittance.

Connection to each antenna conductor 7 is as follows. That is, A ₁ is electrically connected to the first potential source via the resistor, A ₂ is electrically connected to the second potential source via the resistor, and A ₃ is connected via the resistor. electrically connected to the first potential source Te, a ₄ is electrically connected to the second potential source through a resistor. In FIG. 5, the first potential source is ground, and the second potential source is a potential source of potential V (V1 or V2).

  Further, the term "resistor" as used herein refers to a resistor for radio waves that is the subject of the present invention and through which a direct current flows. In addition to a normal resistor, an inductor may be used as shown in FIG. However, a capacitor that does not flow a direct current cannot be used as a resistor.

(1) When the variable reactor shown in FIG. 7A or 7B is used (the triangle representing the variable capacitance diode and the triangle representing the variable reactor have the same direction), the potential of the first potential source is is made lower than the second potential source potential, the a ₁ and a _2, also the transmittance of the polarization direction of the frequency connecting the a ₃ and a ₄ and the low permeability, a ₁ and The transmittance of the polarized wave having the above frequency in the direction connecting A ₄ and A ₂ and A ₃ can be set to a high transmittance higher than the above low transmittance.

  For example, when V = + V is applied in FIG. 5, a reverse bias is applied to the variable reactors Z1 and Z3, and a forward bias is applied to the variable reactors Z2 and Z4. For this reason, the impedances of Z1 and Z3 are small, the impedances of Z2 and Z4 are large, and appropriate positive reactance values are obtained. As a result, the arrangement of A1, Z1, and A2 is the same, but the transmittance of polarization along the arrangement of A3, Z3, and A4 is low, and the arrangement of A2, Z2, and A3 is the same. The transmittance of polarization along Z4 and A1 is increased.

  However, if the variable reactor of FIG. 7 (c) is used, conversely, the transmittance of the polarization along A1, Z1, and A2 is high, and the transmittance of the polarization along the sequence of A2, Z2, and A3 is high. Becomes lower.

(2) If the variable reactor of FIG. 7A or 7B is used, the potential of the second potential source is made lower than the potential of the first potential source, so that A ₁ and A ₂ , And the polarization transmittance of the above-mentioned frequency in the direction connecting A ₃ and A ₄ is set to a high transmittance, and A ₁ and A ₄ are connected in the direction connecting A ₂ and A _3. The transmittance of polarized light having a frequency of 1 is set to a low transmittance lower than the above-described high transmittance.

  For example, when V = −V is applied in FIG. 5, a forward bias is applied to the variable reactors Z1 and Z3, and a reverse bias is applied to the variable reactors Z2 and Z4. For this reason, the reactance values of Z1 and Z3 are positive values, and the impedances of Z2 and Z4 are small. As a result, the transmittance of polarization along the alignment of A1, Z1, and A2, A3, Z3, and A4 is high, and the transmittance of polarization along the alignment of A2, Z2, and A3, and alignment of A4, Z4, and A1. Becomes lower.

  However, if the variable reactor of FIG. 7 (c) is used, conversely, the transmittance of the polarization along the sequence of A1, Z1, and A2 is low, and the transmittance of the polarization along the sequence of A2, Z2, and A3 is low. Becomes higher.

In the case shown in FIG. 5, R3 = R and R4 = R in FIG.
(1) When a reverse bias voltage is applied to the variable capacitance diode, the voltage is divided by R1, R2, R3, and R4. However, by setting R1 >> R2 >> R3, R4, the first potential source And the potential difference between the second potential source and the second potential source are approximately divided by R1, and this voltage is applied to the variable capacitance diode. Also,
(2) When a forward bias voltage is applied to the variable capacitance diode, the voltage is divided by R2, R3, and R4. By setting R2 >> R3, R4, the voltage drop due to R3 or R4 is very high. Can be small.

  In this way, by setting R1 >> R2 >> R3, R4, the potential of the antenna conductor can be regarded as the ground level or substantially equal to V1 or V2 in the configuration of FIG. Specific values of R1, R2, R3, and R4 are, for example, 100 MΩ, 1 MΩ, 10 kΩ, and 10 kΩ, respectively. As described above, if R1 can be omitted because the leakage current of the variable capacitance diode is minute or variation is small, specific values of R2, R3, and R4 are, for example, 10 MΩ, 10 kΩ, 10 kΩ, and variations in voltage drop can be suppressed as compared with the above.

  Instead of the resistor shown in FIG. 5, an inductor can be used as shown in FIG. 6 or FIG. In this case, it can be handled that there is almost no voltage drop. In this case, R1, R2, and specific values are, for example, 1 MΩ and 10 kΩ, respectively.

  In FIG. 8, power is supplied to A1 from A3 through a resistor. This is a configuration for suppressing the number of antenna conductors used for feeding. In this case, in the route of A4, Z4, A1, and A3, R3 = R and R4 = 2R in FIG. 7A, but by setting R2 >> R3 and R4, the antenna shown in FIG. The electric potential of the conductor can be regarded as the ground level or substantially equal to V1 or V2. In the configuration of FIG. 9, power is supplied to A1 from A3 via a variable reactor. In this case, there is almost no voltage drop of the DC voltage due to the variable reactor.

In the above configuration, four antenna conductors (A ₁ , A ₂ , A ₃ , A ₄ ) and four variable reactors (Z ₁ , Z ₂ , Z ₃ , Z ₄ ) are used. Furthermore, a polarization-selective radio wave shutter can be configured by using many things. FIG. 10 is a view cut out from the array (j, k) of the antenna conductors arranged in an M × N matrix so that a plurality of antenna conductors are included on the right or below. Here, (1), (2), and (3) in FIG. 10 correspond to the descriptions in the following (1), (2), and (3).
(1) Four adjacent antenna conductors ( _{Aj, k} , _{Aj, k + 1} , _{Aj + 1, k} , _{Aj + 1, k + 1} ) at arbitrary positions in the matrix are The four antenna conductors (A ₁ , A ₂ , A ₃ , A ₄ ) and four variable reactors (Z ₁ , Z ₂ , Z ₃ , Z ₄ ) are used. _{A j, k, A j,} k + 1, A j + 1, k + 1, A j + 1, k corresponds to _{A 1, A 2, A 3} , A 4 , _{respectively,} A _{j, k,} A _{Since j, k + 1} , A _{j + 1, k + 1} , A _{j + 1, k} are provided with variable reactors corresponding to the variable reactors (Z ₁ , Z ₂ , Z ₃ , Z ₄ ). The antenna conductor and the variable reactor are denoted by A ₁ , A ₂ , A ₃ , A ₄ , Z ₁ , Z ₂ , Z ₃ , and Z _{4 respectively} . Further, the circulation direction of the electrical connection A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z ₄ , A ₁ between the antenna conductor and the variable reactor is defined as the first circulation direction. To do. The wiring in this case applies a voltage to each variable reactor as follows.
A ₁ is electrically connected to the first potential source through a resistor,
A ₂ is electrically connected to the second potential source through a resistor,
A ₃ is electrically connected to the first potential source through a resistor,
A ₄ is electrically connected to the second potential source via a resistor.
(2) Further, the antenna conductor (A _{j + 1, k} , A _{j + 1, k + 1} , A _{j + 2, k} , A _{j + 2, k + 1} ) has the configuration shown in FIG. has, corresponding to _{a j + 1, k, a} j + 1, k + 1, a j + 2, k + 1, a j + 2, k are each _{a 1, a 2, a 3} , a 4, Between A _{j + 1, k} , A _{j + 1, k + 1} , A _{j + 2, k + 1} , A _{j + 2, k} , the variable reactors (Z ₁ , Z ₂ , Z ₃ , Z ₄ ) equipped with a variable reactor corresponding to Here, too, they are denoted by A ₁ , A ₂ , A ₃ , A ₄ , Z ₁ , Z ₂ , Z ₃ , and Z ₄ , respectively. In this case, the electrical connection between the antenna conductor and the variable reactor A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z ₄ , A ₁ is circulated in the first circulation. The second circulation direction is opposite to the direction. The wiring in this case applies a voltage to each variable reactor as follows.
A ₁ is electrically connected to the second potential source through a resistor,
A ₂ is electrically connected to the first potential source through a resistor,
A ₃ is electrically connected to the second potential source through a resistor,
A ₄ is electrically connected to the first potential source through a resistor,
(3) Further, the antenna conductors ( _{Aj, k + 1} , _{Aj, k + 2} , _{Aj + 1, k + 1} , _{Aj + 1, k + 2} ) are the above four antenna conductors. (A ₁ , A ₂ , A ₃ , A ₄ ) and four variable reactors (Z ₁ , Z ₂ , Z ₃ , Z ₄ ) have a configuration corresponding to that, and A _{j, k + 1} , A _{j, k + 2} , A _{j + 1, k + 2} , A _{j + 1, k + 1} correspond to A ₁ , A ₂ , A ₃ , A ₄ , respectively, and A _{j, k + 1} , A _{j , K + 2} , A _{j + 1, k + 2} , A _{j + 1, k + 1} are provided with variable reactors corresponding to the variable reactors (Z ₁ , Z ₂ , Z ₃ , Z ₄ ). . Here, too, they are denoted by A ₁ , A ₂ , A ₃ , A ₄ , Z ₁ , Z ₂ , Z ₃ , and Z ₄ , respectively. In this case, the electrical connection between the antenna conductor and the variable reactor A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z ₄ , A ₁ is circulated in the first circulation. The second circulation direction is opposite to the direction. The wiring in this case applies a voltage to each variable reactor as follows.
A ₁ is electrically connected to the second potential source through a resistor,
A ₂ is electrically connected to the first potential source through a resistor,
A ₃ is electrically connected to the second potential source through a resistor,
A ₄ is electrically connected to the first potential source via a resistor.

  In the wiring for applying a bias voltage to each reactor in FIG. 10, in block (1), V1 or V2 is applied to the array element on the left-handed diagonal line, and the array element on the right-handed diagonal line is To the ground level. Also, the blocks (2) and (3) are reversed from the case of the block (1). Furthermore, it is clear that the power supply to each array element can be reversed.

Further, FIG. 11, using the four antenna conductors _{(A 1, A 2, A} 3, A 4) and four variable reactors _{(Z 1, Z 2, Z} 3, Z 4), further, A ₁ And A ₃ are electrically connected via a resistor, whereby A ₁ and A ₃ are electrically connected to the first potential source via the resistor, as shown in FIG. The shutter is a constituent unit, and a plurality of the constituent units are used to form a matrix.
Here, the structural units adjacent in the row or column direction are arranged so that the circulation direction of the electrical connection between the antenna conductor and the variable reactor is in a mirror image relationship,
The antenna conductors facing each other between adjacent structural units in the row or column direction may be electrically connected by a resistor.
As shown in FIG. 11, antenna conductors located on one side of the left end or right end of a row or one side of the upper end or lower end of a column are sequentially connected via a resistor to a first potential source and a second potential. Connect alternately with the source.

  The polarization-selective radio wave shutter shown in FIG. 12 is configured in a matrix by using the polarization-selective radio wave shutter shown in FIG. The structural units adjacent to each other in the row or column direction, that is, (1) and (2) or (1) and (3) in FIG. 12 are mirror images of the circulation direction of the electrical connection between the antenna conductor and the variable reactor. The antenna conductors that are arranged in such a manner as to face each other between structural units adjacent in the row or column direction are electrically connected by a resistor. Also in this case, since the resistor may be a resistor against radio waves, an inductor can be used in addition to a normal resistor.

  In addition, in FIG. 12, in the block (1), wiring for applying a bias voltage to each reactor is such that V1 or V2 is applied to the array elements on the right-handed diagonal line, and the left-handed diagonal array is placed. The element is at the ground level. Also, the blocks (2) and (3) are reversed from the case of the block (1). Furthermore, it is clear that the power supply to each array element can be reversed.

  The polarization-selective radio wave shutter shown in FIG. 13 is configured in a matrix by using the polarization-selective radio wave shutter shown in FIG. The structural units adjacent to each other in the row or column direction, that is, (1) and (2) or (1) and (3) in FIG. 13 are mirror images of the circulation direction of the electrical connection between the antenna conductor and the variable reactor. The antenna conductors that are arranged in such a manner as to face each other between structural units adjacent in the row or column direction are electrically connected by a resistor. Also in this case, since the resistor may be a resistor against radio waves, an inductor can be used in addition to a normal resistor.

  In addition, as shown in FIG. 13, the antenna conductors located on one side of the left end or right end of the row or one side of the upper end or lower end of the column are alternately arranged through the resistors in order. These are alternately connected to the potential source, the second potential source,..., Or alternately to the second potential source, the first potential source,.

  Since the above-described polarization-selective radio wave shutter has a gap between wires, it is configured on a transparent insulating plate, for example, a glass plate, and this is used for a window, so that the polarization-selective radio wave that can be used for lighting is used. It can be a shutter. In addition, by configuring on a mesh plate or film, a polarization-selective radio wave shutter having daylighting and air permeability can be realized.

  As described above, the polarization-selective radio wave shutter according to the present invention has been described based on some embodiments. However, the present invention is not limited only to these embodiments, and has the configuration described in the claims. All polarization-selective radio wave shutters that can be realized without change are included in the scope of rights. Further, the radio wave transmittance is not limited to the control of the two states of transmission and shielding, but includes the case of continuously controlling the transmittance of polarized waves in each direction.

  Further, by providing the polarization selective radio wave shutter according to the present invention in front of the antenna having no polarization selectivity, the polarization selectivity can be provided. Therefore, when fading due to multipath with rotation of the polarization plane occurs, the present invention is provided in front of the communication antenna to select an appropriate polarization, and when the fading state changes In some cases, the influence can be reduced by switching the polarization plane to be selected.

  Further, as shown in FIG. 15, when two wireless terminal stations are provided in almost the same direction when a wireless LAN is provided between buildings, an antenna having polarization selectivity is used for the above terminal stations, and their polarizations are changed. Communication between the terminal station and the key station is performed by setting the wave directions to be orthogonal and using an antenna having no polarization selectivity via the polarization-selective radio wave shutter of the present invention in the key station. Can be performed stably using the respective polarized waves. Since the polarization-selective radio wave shutter of the present invention can be switched at high speed, the communication speed does not decrease.

It is a schematic block diagram of the electromagnetic wave shutter for demonstrating this invention. It is a principle explanatory view of a radio wave shutter for explaining the present invention. It is a block diagram which shows the structural example of the variable reactor used for the electromagnetic wave shutter for demonstrating this invention. It is a figure which shows the electric current distribution on the antenna conductor in the electromagnetic wave shutter for demonstrating this invention. It is a figure which shows the example of the basic unit of the polarization selective radio wave shutter of this invention. It is a figure which shows the example which used the inductor for the resistor in the example of the basic unit of the polarization selective radio wave shutter of this invention. The example of the variable reactor used by this invention is shown. FIG. It is a figure which shows the example of the basic unit of the polarization selective radio wave shutter of this invention. It is a figure which shows the example of the basic unit of the polarization selective radio wave shutter of this invention. It is a figure which shows the example of the polarization selective radio wave shutter of this invention arrange | positioned at matrix form. It is a figure which shows the example of the polarization selective radio wave shutter of this invention arrange | positioned at matrix form. It is a figure which shows the example of the polarization selective radio wave shutter of this invention arrange | positioned at matrix form. It is a figure which shows the example of the polarization selective radio wave shutter of this invention arrange | positioned at matrix form. It is a figure which shows the example of a shape of the antenna conductor applicable to this invention. It is a figure which shows the example of a utilization form of a polarization selective radio wave shutter.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Radio wave shutter 2 Shutter body 21 Radio wave blade 22 Electric wire 23 Variable reactor 231 1st variable capacitance diode 232 1st inductor 24 Resistor 26 Branch feed line 27 Grounding induction line 3 DC power supply 4 Switch 5 Grounding part 6 Polarization selective radio wave Shutter 7 Antenna conductor 8 Variable reactor

Claims (8)

A radio wave shutter composed of four antenna conductors (A ₁ , A ₂ , A ₃ , A ₄ ) and four variable reactors (Z ₁ , Z ₂ , Z ₃ , Z ₄ ),
The above-described variable reactor is a variable reactor having directionality and capable of electrically controlling reactance.
Each variable reactor is
When a potential difference is applied in the first direction, it shows low reactance,
When a potential difference is applied in a second direction opposite to the first direction, the high reactance is greater than the low reactance,
Having electrical connections circulating with A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z ₄ , A ₁ ,
The direction of the variable reactor is a certain direction along the circulation,
When A ₁ is regarded as A ₅ , for k from 1 to 4,
The connection of A _k , Z _k , A _{k + 1} is
When Z _k indicates high impedance, it indicates high transmittance for a polarized wave having a predetermined frequency in the direction connecting A _k and A _{k + 1} .
When Z ₁ indicates a low impedance, it indicates a low transmittance lower than the high transmittance for a polarized wave having a predetermined frequency in the direction connecting A _k and A _{k + 1} ,
A ₁ is electrically connected to the first potential source through a resistor,
A ₂ is electrically connected to the second potential source through a resistor,
A ₃ is electrically connected to the first potential source through a resistor,
A ₄ is electrically connected to the second potential source through a resistor,
By making the potential of the first potential source higher or lower than the potential of the second potential source, the polarization of the above-mentioned frequency in the direction connecting A ₁ and A ₂ and A ₂ and A ₃ is increased. A polarization-selective radio wave shutter characterized in that the transmittance can be electrically switched. By electrically connecting the A ₁ and A ₃ via a resistor, to claim 1 that features be electrically connected to the first potential source via the A ₁ and A ₃ resistor The polarization selective radio wave shutter described. Including antenna conductors arranged in an M × N matrix and a plurality of variable reactors,
(1) Four adjacent antenna conductors ( _{Aj, k} , _{Aj, k + 1} , _{Aj + 1, k} , _{Aj + 1, k + 1} ) at arbitrary positions in the above matrix are charged. A _{j, k} , A _{j, k + 1} , A _{j + 1, k + 1} , A _{j + 1, k} are A ₁ , A ₂ , A ₃ , respectively. A ₄ , A ₄ , A _{j, K 2} , A _{j, k + 1} , A _{j + 1, k + 1} , A _{j + 1, k} between the variable reactors (Z ₁ , Z ₂ , Z ₃ , Z ₄ ), and the electrical connection between the antenna conductor and the variable reactor A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z ₄ , A ₁ is the first circulation direction,
A ₁ is electrically connected to the first potential source through a resistor,
A ₂ is electrically connected to the second potential source through a resistor,
A ₃ is electrically connected to the first potential source through a resistor,
When A ₄ is to be electrically connected to the second potential source through a resistor,
(2) Further, the antenna conductors (A _{j + 1, k} , A _{j + 1, k + 1} , A _{j + 2, k} , A _{j + 2, k + 1} ) correspond to the first aspect. A _{j + 1, k} , A _{j + 1, k + 1} , A _{j + 2, k + 1} , A _{j + 2, k} are respectively A ₁ , A ₂ , A ₃ , A ₄ . Correspondingly, the variable reactors (Z ₁ , Z ₂ , Z) are connected between A _{j + 1, k} , A _{j + 1, k + 1} , A _{j + 2, k + 1} , A _{j + 2, k. 3} , Z ₄ ), and the electrical connection between the antenna conductor and the variable reactor A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z in this case ₄ , the circulation direction of A ₁ is the second circulation direction opposite to the first circulation direction,
A ₁ is electrically connected to the second potential source through a resistor,
A ₂ is electrically connected to the first potential source through a resistor,
A ₃ is electrically connected to the second potential source through a resistor,
A ₄ is electrically connected to the first potential source through a resistor,
(3) Further, the antenna conductors ( _{Aj, k + 1} , _{Aj, k + 2} , _{Aj + 1, k + 1} , _{Aj + 1, k + 2} ) correspond to the first aspect. A _{j, k + 1} , A _{j, k + 2} , A _{j + 1, k + 2} , A _{j + 1, k + 1} are respectively A ₁ , A ₂ , A ₃ , A ₄ . Correspondingly, the variable reactors (Z ₁ , Z ₂ , Z _{+ 1) are connected} between A _{j, k + 1} , A _{j, k + 2} , A _{j + 1, k + 2} , A _{j + 1, k + 1. 3} , Z ₄ ), and the electrical connection between the antenna conductor and the variable reactor A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z in this case ₄ , the circulation direction of A ₁ is the second circulation direction opposite to the first circulation direction,
A ₁ is electrically connected to the second potential source through a resistor,
A ₂ is electrically connected to the first potential source through a resistor,
A ₃ is electrically connected to the second potential source through a resistor,
A ₄ is electrically connected to the first potential source through a resistor,
A polarization-selective radio wave shutter. Including antenna conductors arranged in an M × N matrix and a plurality of variable reactors,
(1) Four adjacent antenna conductors ( _{Aj, k} , _{Aj, k + 1} , _{Aj + 1, k} , _{Aj + 1, k + 1} ) at arbitrary positions in the above matrix are charged. A _{j, k} , A _{j, k + 1} , A _{j + 1, k + 1} , A _{j + 1, k} are A ₁ , A ₂ , A ₃ , respectively. A ₄ , A ₄ , A _{j, K 2} , A _{j, k + 1} , A _{j + 1, k + 1} , A _{j + 1, k} between the variable reactors (Z ₁ , Z ₂ , Z ₃ , equipped with a variable reactor corresponding to Z ₄ )
When the antenna conductor and the variable reactor in this case are (A ₁ , A ₂ , A ₃ , A ₄ ) and (Z ₁ , Z ₂ , Z ₃ , Z ₄ ), respectively,
The electrical connection A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z ₄ , A ₁ of the antenna conductor and the variable reactor is defined as the first circulation direction,
A ₁ is electrically connected to the first potential source through a resistor,
A ₂ is electrically connected to the second potential source through a resistor,
A ₃ is electrically connected to the first potential source through a resistor,
When A ₄ is to be electrically connected to the second potential source through a resistor,
(2) Further, the antenna conductor (A _{j + 1, k} , A _{j + 1, k + 1} , A _{j + 2, k} , A _{j + 2, k + 1} ) corresponds to the second aspect. A _{j + 1, k} , A _{j + 1, k + 1} , A _{j + 2, k + 1} , A _{j + 2, k} are respectively A ₁ , A ₂ , A ₃ , A ₄ . Correspondingly, the variable reactors (Z ₁ , Z ₂ , Z) are connected between A _{j + 1, k} , A _{j + 1, k + 1} , A _{j + 2, k + 1} , A _{j + 2, k. 3} , equipped with a variable reactor corresponding to Z ₄ )
When the antenna conductor and the variable reactor in this case are (A ₁ , A ₂ , A ₃ , A ₄ ) and (Z ₁ , Z ₂ , Z ₃ , Z ₄ ), respectively,
Electrical connection A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z ₄ , A ₁ of the antenna conductor and the variable reactor is reverse to the first circulation direction. The second circulation direction of
A ₁ is electrically connected to the second potential source through a resistor,
A ₂ is electrically connected to the first potential source through a resistor,
A ₃ is electrically connected to the second potential source through a resistor,
A ₄ is electrically connected to the first potential source through a resistor,
(3) Further, the antenna conductors (A _{j, k + 1} , A _{j, k + 2} , A _{j + 1, k + 1} , A _{j + 1, k + 2} ) correspond to claim 2 A _{j, k + 1} , A _{j, k + 2} , A _{j + 1, k + 2} , A _{j + 1, k + 1} are respectively A ₁ , A ₂ , A ₃ , A ₄ . Correspondingly, the variable reactors (Z ₁ , Z ₂ , Z _{+ 1) are connected} between A _{j, k + 1} , A _{j, k + 2} , A _{j + 1, k + 2} , A _{j + 1, k + 1. 3} , equipped with a variable reactor corresponding to Z ₄ )
When the antenna conductor and the variable reactor in this case are (A ₁ , A ₂ , A ₃ , A ₄ ) and (Z ₁ , Z ₂ , Z ₃ , Z ₄ ), respectively,
Electrical connection A ₁ , Z ₁ , A ₂ , Z ₂ , A ₃ , Z ₃ , A ₄ , Z ₄ , A ₁ of the antenna conductor and the variable reactor is reverse to the first circulation direction. The second circulation direction of
A ₁ is electrically connected to the second potential source through a resistor,
A ₂ is electrically connected to the first potential source through a resistor,
A ₃ is electrically connected to the second potential source through a resistor,
A ₄ is electrically connected to the first potential source through a resistor,
A polarization-selective radio wave shutter. The polarization selective radio wave shutter according to claim 1 is used as a constituent unit, and a plurality of the constituent units are used to form a matrix,
The structural units adjacent in the row or column direction are arranged so that the circulation direction of the electrical connection between the antenna conductor and the variable reactor is in a mirror image relationship,
A polarization-selective radio wave shutter, wherein antenna conductors facing each other between structural units adjacent in a row or column direction are electrically connected by a resistor. The polarization selective radio wave shutter according to claim 2 is used as a structural unit, and a plurality of the structural units are used to form a matrix.
The structural units adjacent in the row or column direction are arranged so that the circulation direction of the electrical connection between the antenna conductor and the variable reactor is in a mirror image relationship,
A polarization-selective radio wave shutter, wherein antenna conductors facing each other between structural units adjacent in a row or column direction are electrically connected by a resistor.   5. The antenna conductor according to claim 4, wherein the antenna conductor located on one side of the left end or right end of the row or one side of the upper end or lower end of the column is sequentially connected to the first potential source, the second potential source, Alternatively, the polarization-selective radio wave shutter, wherein the second potential source and the first potential source are alternately connected. In Claim 6, for the antenna conductor located on one side of the left or right end of the row or one side of the upper or lower end of the column,
Connecting either the first antenna conductor or the second antenna conductor connected to the first antenna conductor via a resistor to the first potential source;
Either the third antenna conductor connected to the first antenna conductor or the second antenna conductor via a variable reactor, or the fourth antenna conductor connected to the third antenna conductor via a resistor A polarization-selective radio wave shutter that is connected to a two-potential source.

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