JP6058475B2 - Phase variable device, antenna device, diplexer, and multiplexer - Google Patents

Description

  Embodiments described herein relate generally to a phase variable device used for phase control of transmission and reception signals in, for example, a radar or a communication system, and an antenna device, a diplexer, and a multiplexer suitable for use with this phase variable device.

  2. Description of the Related Art Conventionally, phase shifters that are used for transmission / reception of radars, communication systems, and the like and control the phase of an input signal include phase shifters of various configurations.

  For example, a mechanical phase shifter is known in which the phase is varied by physically changing the length of a line for inputting a signal. As a mechanical phase shifter, there is a trombone-shaped phase shifter provided with a coaxial line whose length can be adjusted coaxially with a line for inputting a signal. This phase shifter changes the phase of a signal by physically changing the length of the line by a coaxial line and causing a phase delay in the signal.

  In addition, there is a phase shifter that includes a plurality of lines having different lengths and switches a line through which a signal is input using a switch. This phase shifter electrically switches each switch on and off at high speed, switches a plurality of lines having different lengths, and causes a signal to generate a phase delay corresponding to the switched line length. Change the phase.

  In addition, a phase shifter using an active element such as a transistor with little amplitude fluctuation, or a filter capable of extracting a predetermined frequency component from an input signal and changing a transfer function for arbitrarily setting the phase characteristic of the extracted frequency component. There is a phase shifter that varies the phase by providing a feedback circuit and changing the transfer function of the filter.

JP 2007-13750 A

  However, a phase shifter that switches a plurality of lines having different lengths by a conventional phase shifter or switch that physically changes the length of the line is a transmission line or a plurality of switches of a certain length in order to change the phase. It is necessary to provide. For this reason, the phase shifter has a problem that the insertion loss increases due to the loss caused by the provided transmission line or switch, and the amplitude varies depending on the phase to be set. Further, when the phase is largely changed, the conventional phase shifter requires a transmission line for greatly changing the phase, and there is a problem that the circuit becomes large. On the other hand, a phase shifter that changes the phase of a signal by changing the transfer function of the filter requires a plurality of adders, and when implemented with a high-frequency circuit, there is a problem that the circuit configuration of the phase shifter becomes complicated.

  Accordingly, an object of the present invention is to provide a phase variable device that can vary the phase with a low loss and a simple configuration, and an antenna device, a diplexer, and a multiplexer that are suitable using the phase variable device.

  According to this embodiment, the phase variable device includes a plurality of resonators, a plurality of coupling lines, a bypass coupling line, a coupling switching unit, an input terminal, and an output terminal. At least three or more resonators are provided. A plurality of coupled lines serially couple the plurality of resonators. The bypass coupling line bypass-couples the resonators with at least one resonator among the plurality of resonators coupled in series by the plurality of coupling lines. The coupling switching means is provided in the bypass coupling line and selectively turns on and off the bypass coupling. The input terminal is connected to the input terminal of the first stage of the plurality of resonators. The output terminal is connected to the output terminal of the collective group of the plurality of resonators.

The block diagram which shows the structure of the phase variable apparatus which concerns on embodiment. The block diagram which shows the structure of the phase variable apparatus which concerns on 1st Embodiment. The figure which shows the amplitude characteristic and phase characteristic in the phase variable apparatus which concerns on 1st Embodiment. The block diagram which shows the structural example 1 of the phase variable apparatus shown in FIG. The block diagram which shows the structural example 2 of the phase variable apparatus shown in FIG. The block diagram which shows the structural example 3 of the phase variable apparatus shown in FIG. The block diagram which shows the structure of the phase variable apparatus which concerns on 2nd Embodiment. The block diagram which shows the structural example 1 of the phase variable apparatus shown in FIG. The block diagram which shows the structural example 2 of the phase variable apparatus shown in FIG. The block diagram which shows the structural example 3 of the phase variable apparatus shown in FIG. The block diagram which shows the structure of the antenna apparatus which concerns on 3rd Embodiment. The block diagram which shows the structure of the antenna apparatus which concerns on 4th Embodiment. The block diagram which shows the structure of the antenna device which concerns on 5th Embodiment. The block diagram which shows the structure of the antenna device which concerns on 6th Embodiment. The block diagram which shows the structure of the antenna apparatus which concerns on 7th Embodiment. The block diagram which shows the structure of the antenna apparatus which concerns on 8th Embodiment. The block diagram which shows the structure of the antenna apparatus which concerns on 9th Embodiment. The block diagram which shows the structure of the antenna apparatus which concerns on 10th Embodiment. The block diagram which shows the structure of the antenna apparatus which concerns on 11th Embodiment. The block diagram which shows the structure of the diplexer which concerns on 12th Embodiment. The block diagram which shows the structure of the multiplexer concerning 13th Embodiment.

  Hereinafter, embodiments will be described with reference to the drawings.

  FIG. 1 is a block diagram illustrating a configuration of a phase variable device according to an embodiment.

Phase variable device, a plurality of resonators 11 to 13 shown in FIG. 1, a plurality of coupling lines _{k 12, k 23,} the bypass coupling line _{k 13,} input line _{Q e1,} the input terminal In, the output lines _{Q e2} , An output terminal Out, a coupling switching unit 2 and a switching control unit 3.

The plurality of resonators 1-1 to 1-3 are circuits that enter a resonance state at a predetermined frequency. A plurality of resonators 11 to 13 are provided at least three or more, are coupled serially by coupling line _{k 12, k 23.} The resonator 1-1 is connected to the input terminal In by the input line _Qe1 . The resonator 1-3 is connected to the output terminal Out by the output line _Qe2 .

Bypass coupling line _{k 13,} among the plurality of resonators 11 to 13 that are coupled serially by a plurality of coupling lines _{k 12, k 23,} a resonator together in between the at least one resonator Bypass coupling. In the embodiment, the resonator 1-1 and the resonator 1-3 are bypass-coupled. The bypass coupling line k ₁₃ is coupled so that the signal passing through the coupling lines k ₁₂ and k ₂₃ and the signal passing through the bypass coupling line k ₁₃ are in phase.

Further, a bypass coupling line k ₁₃ has a coupling switching unit 2 for selectively turning on and off the coupling of the resonators 1-1 and the resonator 1-3. When you turn the coupling switching section 2, the signal input to the input terminal In is branched in the resonator 1-1, through the coupling line _{k 12, k 23} and the bypass coupling line _{k 13,} resonator 1 3 and then output to the output terminal Out. However, binding of the bypass coupling line _{k 13} is sensitive than binding of the binding line by coupling line _{k 12, k 23,} much of the signal to the coupled line _{k 12, k 23} is transmitted. When the coupling switching unit 2 is turned off, a signal input to the input terminal In is output to the output terminal Out via the coupling lines k ₁₂ and k ₂₃ . That is, since all signals when the coupling switching unit 2 is turned off pass through the coupling lines k ₁₂ and k ₂₃ , the phase is delayed as compared with the signal when the coupling switching unit 2 is turned on.

  Here, in the embodiment, the coupling switching unit 2 includes, for example, switch means such as a diode switch, a MEMS (Micro Electro Mechanical Systems) switch, and an FET (Field Effect Transistor) switch, a variable capacitance diode, a ferroelectric ceramic, and the like. The coupling control means is used.

  The on / off of the coupling switching unit 2 is controlled by the switching control unit 3.

According to the above configuration, the phase variable device according to the embodiment, by controlling on and off of coupling switching unit 2 in the switching control unit 3, by varying the coupling of the bypass coupling line k _13, changing the transmission line of the signal . As a result, the signal passing through the circuit has a phase difference between when the coupling switching unit 2 is on and when it is off. Therefore, the phase varying device can vary the phase of the signal passing through the circuit.

(First embodiment)
FIG. 2 is a block diagram illustrating a configuration of the phase variable device according to the first embodiment. In the first embodiment, that binds to a serial four resonators 11 to 14 by a plurality of coupling lines _{k 12, k 23, k 34} . The resonators 1-1 and 1-4 are coupled by a switch 2-1.

  FIG. 3 is a diagram illustrating amplitude characteristics and phase characteristics in the phase variable device according to the first embodiment. 3A and 3B show the amplitude characteristic and phase characteristic of the signal passing through the filter circuit, respectively. FIG. 3C is an enlarged view of the phase characteristic shown in FIG.

  As shown in FIG. 3, when the coupling switching unit 2 is turned off, the insertion loss and frequency bandwidth of the filter are not changed and the phase of the input signal is varied by about 10 degrees compared to the case where the coupling switching unit 2 is turned on. It is possible.

Here, coupling of the bypass coupling line _{k 13} is coupled line _{k 12,} k _23, weaker than the bonds of the coupling line by _{k 34,} the current flowing through the bypass coupling line _{k 13} small, the loss of the switch 2-1 Even if it is affected, the influence on the passage loss of the filter is small. That is, the phase varying device can vary the phase without greatly affecting the loss of the filter even if the switch 2-1 shown in FIG. 2 is used.

  Furthermore, since the phase variable device according to the first embodiment is in the form of a filter, it is possible to simultaneously limit the band. Thereby, in a circuit that requires a filter and a phase shifter, the number of parts can be reduced.

Here, since the phase variable device requires at least three resonators 1-1 to 1-3, there is a problem that loss increases as the number of stages increases. Accordingly, the phase variable device superconductivity, a plurality of resonators 1-1 to 1-4, a plurality of coupling lines _{k 12, k 23, k 34} , the bypass coupling line _{k 13,} as an input line _{Q e1} and an output line _{Q e2} The material is used and cooled to a cryogenic temperature by a cooling device or the like until a superconducting state is obtained. As a result, the phase variable device can suppress an increase in loss due to the multi-stage using the low loss property of the superconductive material. Therefore, the phase variable device can realize a low-loss phase variable device while realizing a large phase change.

  The filter constructed of the superconducting material can have various structures such as a strip line and a coplanar line in addition to the microstrip line. Furthermore, not limited to the above, various resonators such as a dielectric resonator and a cavity resonator can be used. In the case of a planar filter, it can be made of a conductive material formed on an insulating substrate as a dielectric substrate. The insulating substrate has a ground conductor on one side and a line conductor on the opposite side. The conductive material includes a metal such as copper or gold, a superconductor such as niobium or niobium tin, and a Y-based copper oxide high-temperature superconductivity. The substrate is a variety of suitable materials such as magnesium oxide, sapphire or lanthanum aluminate.

  In the first embodiment, the case where the switch 2-1 is used as the coupling switching unit 2 has been described as an example. However, the present invention is not limited to this. As shown in FIGS. 4 and 5, the coupling switching unit 2 may use a diode switch 2-2, a variable capacitor 2-3, and the like. As shown in FIG. 4, when the diode switch 2-2 is used, the phase variable device operates as a 1-bit phase shifter due to a phase change caused by on / off. Further, the phase variable device can perform a 2-bit operation when two circuits using the diode switch 2-2 are used.

  On the other hand, as shown in FIG. 5, when the variable capacitor 2-3 is used, the phase variable device can change the coupling amount itself. For this reason, the phase varying device can continuously change the phase with respect to the coupling change. As a result, the phase variable device can finely adjust the phase.

The phase variable device according to the first embodiment is attached the resonators 1-1 and 1-4 by a bypass coupled line k ₁₄ and a coupling switching section 2, but is not limited thereto. As shown in FIG. 6, the resonators 1-1 and 1-3 may be coupled by a bypass coupling line k ₁₃ , and the switching control unit 5 may control the on / off of the coupling switching units 2 and 4. Thereby, the phase variable device can realize a plurality of phase variations according to the on / off of the coupling switching units 2 and 4.

(Second Embodiment)
FIG. 7 is a block diagram illustrating a configuration of the phase varying device according to the second embodiment.

The phase variable device shown in FIG. 7 has a plurality of resonators 1-1 to 1-3, a plurality of coupled lines k ₁₂ , k ₂₃ , k ₃₄ , a bypass, like the phase variable device shown in the first embodiment. It has a coupling line k ₁₃ , an input line Q _e1 , an input terminal In, an output line Q _e2 , an output terminal Out, a coupling switching unit 2 and a switching control unit 3.

  The band pass filter 6 is provided in the front stage or the rear stage of the plurality of resonators 1-1 to 1-4. The band pass filter 6 has a frequency band narrower than the frequency band, and allows a desired frequency band component to pass from the input signal.

  The phase varying device shown in FIG. 7 varies the phase of an input signal using the above circuit. Further, the phase variable device passes the frequency band component of the necessary signal using the band pass filter 6. As a result, the phase of the signal that has passed through the circuit can be varied, and the band can be limited by the band-pass filter 6.

  As described above, the phase variable device according to the second embodiment can realize the effects of the narrowband filter characteristics and the phase variable on the same device.

  Here, the phase variable circuit used in the phase variable device according to the second embodiment and the band limiting bandpass filter 6 are superconducting filters constructed of a superconducting material. Cool to cryogenic temperature until it reaches a state. Thereby, the phase variable device according to the second embodiment can realize a phase variable device that combines the steep filter characteristics that can be realized by the superconducting filter and the characteristics of the low-loss phase shifter. Become.

  In the second embodiment, the case where the switch 2-1 is used as the coupling switching unit 2 has been described as an example. However, the present invention is not limited to this. As illustrated in FIGS. 8 and 9, the coupling switching unit 2 may use a diode switch 2-2, a variable capacitor 2-3, and the like. As shown in FIG. 8, when the diode switch 2-2 is used, the phase variable device operates as a 1-bit phase shifter due to a phase change caused by on / off. Further, the phase variable device can perform a 2-bit operation when two filter circuits using the diode switch 2-2 are used.

  On the other hand, as shown in FIG. 9, when the variable capacitor 2-3 is used, the phase variable device can vary the coupling amount itself. For this reason, the phase varying device can continuously change the phase with respect to the coupling change. As a result, the phase variable device can finely adjust the phase.

The phase variable device according to the first embodiment is attached the resonators 1-1 and 1-4 by a bypass coupled line k ₁₄ and a coupling switching section 2, but is not limited thereto. As shown in FIG. 10, the resonators 1-1 and 1-3 may be coupled by a bypass coupling line k ₁₃ , and the switching control unit 5 may control the on / off of the coupling switching units 2 and 4. Thereby, the phase variable device can realize a plurality of phase variations according to the on / off of the coupling switching units 2 and 4.

(Third embodiment)
FIG. 11 is a block diagram illustrating a configuration of the antenna device according to the third embodiment. The antenna device shown in FIG. 7 is an antenna device that uses the phase variable device according to the first embodiment as a receiver. In addition, the same code | symbol is attached | subjected to the same part in subsequent figures, the detailed description is abbreviate | omitted, and a different part is mainly described. In the following embodiments, the same description is omitted.

  The antenna device shown in FIG. 11 includes antennas 10-1 to 10-n (n is a natural number) shared between transmission and reception, transmission / reception switching devices 11-1 to 11-n, a transmission unit, a reception unit, and a cooling device.

  The transmission / reception switching devices 11-1 to 11-n are for switching and connecting the transmission unit and the reception unit to the antennas 10-1 to 10-n, respectively. For example, the transmission / reception switching devices 11-1 to 11-n use circulators, coaxial switches, or the like.

  The transmission unit is a path for outputting a transmission signal radiated from the antennas 10-1 to 10-n to the space, and includes a distributor 12, transmission phase shifters 13-1 to 13-n, and transmission amplifiers 14-1 to 14-14. -N and transmission band-pass filters 15-1 to 15-n (hereinafter collectively referred to as transmission filters 15-1 to 15-n).

  The distributor 12 receives a transmission signal generated by a transmission signal generator (not shown) and distributes the input transmission signal to a plurality of paths.

  The transmission phase shifters 13-1 to 13-n receive the transmission signal distributed by the distributor 12, and perform desired phase control on the input transmission signal.

  The transmission amplifiers 14-1 to 14-n receive the transmission signals output from the transmission phase shifters 13-1 to 13-n, and amplify the power of the input transmission signals with a desired gain.

  The transmission filters 15-1 to 15-n receive the transmission signals output from the transmission amplifiers 14-1 to 14-n, and pass a desired transmission frequency band component from the input transmission signals.

  The receiving unit is a path for inputting an antenna reception signal received by the antennas 10-1 to 10-n, and includes limiters 16-1 to 16-n and reception band-pass filters 17-1 to 17-n (hereinafter, Receiving filters 17-1 to 17-n), low noise amplifiers (LNA) 18-1 to 18-n, receiving phase varying devices 19-1 to 19-n, and a combiner 20.

  The limiters 16-1 to 16-n input the antenna reception signal, limit the signal level of the input antenna reception signal, and perform over-input protection to the subsequent circuit.

  The reception filters 17-1 to 17-n receive the reception signals output from the limiters 16-1 to 16-n, and pass a desired reception frequency band component from the input reception signals. The reception filters 17-1 to 17-n are constructed of a superconducting material.

  The low noise amplifiers 18-1 to 18-n receive the reception signals output from the reception filters 17-1 to 17-n and amplify the input reception signals with low noise.

  The reception phase varying devices 19-1 to 19-n receive the reception signals output from the low noise amplifiers 18-1 to 18-n, and perform desired phase control on the input reception signals. In the third embodiment, by using the reception phase varying devices 19-1 to 19-n with small amplitude fluctuation due to phase change, the signal level difference generated when setting the phase in each system can be reduced. Therefore, signal adjustment at the time of synthesis becomes easy. The circuits provided in the receiving phase varying devices 19-1 to 19-n are constructed of a superconductive material.

  The combiner 20 combines the reception signals output from the reception phase varying devices 19-1 to 19-n and outputs the combined signals as reception beams.

  The cooling device includes a vacuum vessel 21-1 and a cooling unit 21-2.

  The vacuum vessel 21-1 insulates and heats the contents by making the inside vacuum. This vacuum vessel 21-1 is a vessel for insulating the surroundings where the superconducting material is disposed in a vacuum state for the purpose of efficiently maintaining a cryogenic temperature. For this reason, at least the periphery where the superconducting material is disposed has an airtight structure.

  The cooling part 21-2 cools what is accommodated in the vacuum vessel 21-1 to a cryogenic temperature.

  The cooling device houses the receiving unit in the vacuum vessel 21-1, and cools it to a cryogenic temperature by the cooling unit 21-2. Thereby, the antenna device can reduce a loss during reception.

  The processing operation of the antenna device will be described below.

  First, at the time of transmission, the transmission / reception switching devices 11-1 to 11-n are switched to the transmission side. As a result, the transmission signal generated by the transmission signal generator is subjected to phase control according to the excitation distribution of the transmission beam by the transmission phase shifters 13-1 to 13-n, and the transmission amplifiers 14-1 to 14- After the signal is amplified by n, unnecessary wave components are suppressed by the transmission filters 15-1 to 15-n and output to the antennas 10-1 to 10-n via the transmission / reception switching devices 11-1 to 11-n. .

  At the time of reception, the transmission / reception switching devices 11-1 to 11-n are switched to the reception side. As a result, the antenna reception signals received by the antennas 10-1 to 10-n are input to the reception unit via the transmission / reception switching devices 11-1 to 11-n, and the amplitudes are limited by the limiters 16-1 to 16-n. Then, unnecessary wave components are suppressed by the reception filters 17-1 to 17-n, low noise amplification is performed by the low noise amplifiers 18-1 to 18-n, and reception beams are received by the reception phase varying devices 19-1 to 19-n. Are output after being subjected to phase control in accordance with the directivity characteristics of the signal, synthesized by the synthesizer 20, and outputted as a received beam.

(Fourth embodiment)
FIG. 12 is a block diagram illustrating a configuration of an antenna device according to the fourth embodiment. The antenna device shown in FIG. 12 is an antenna device that uses the phase variable device according to the second embodiment as a receiver.

  In the fourth embodiment, the antenna device uses the receiving phase variable devices 22-1 to 22-n with small amplitude fluctuations due to the phase change according to the second embodiment in the receiving unit. Since the signal level difference generated when setting the phase can be reduced, signal adjustment at the time of synthesis is facilitated.

  In the antenna device, the reception filters 17-1 to 17-n and the reception phase varying devices 19-1 to 19-n are shared by the reception phase varying devices 22-1 to 22-n. Thereby, the antenna apparatus can simplify the circuit configuration of the receiving unit.

  The filter circuits and bandpass filters provided in the reception phase varying devices 22-1 to 22-n are superconducting filters constructed of a superconducting material, and the cooling device includes a receiving unit in the vacuum vessel 21-1. And is cooled to an extremely low temperature by the cooling unit 21-2. Thereby, the antenna device can reduce a loss during reception.

(Fifth embodiment)
FIG. 13 is a block diagram illustrating a configuration of an antenna device according to the fifth embodiment. The antenna device shown in FIG. 13 is an antenna device that uses the phase variable device according to the first embodiment for a transmitter.

  In the fifth embodiment, the antenna device uses the transmission phase variable devices 23-1 to 23-n with small amplitude fluctuations due to the phase change according to the first embodiment in the transmission unit. Since the signal level difference generated when setting the phase can be reduced, signal adjustment during distribution is facilitated.

  The filter circuits provided in the transmission filters 15-1 to 15-n and the transmission phase varying devices 23-1 to 23-n use superconducting filters constructed of a superconducting material, and the cooling device is a vacuum vessel. The transmission filters 15-1 to 15-n, the transmission phase varying devices 23-1 to 23-n, and the reception unit are accommodated in 21-1, and cooled to an extremely low temperature by the cooling unit 21-2. As a result, the antenna device can reduce loss during transmission and reception.

(Sixth embodiment)
FIG. 14 is a block diagram illustrating a configuration of an antenna device according to the fifth embodiment. The antenna device shown in FIG. 14 is an antenna device that uses the phase variable device according to the second embodiment as a transmission unit.

  In the sixth embodiment, the antenna device uses the transmission phase variable devices 25-1 to 25-n with small amplitude fluctuations due to the phase change according to the second embodiment in the transmission unit. Since the signal level difference generated when setting the phase can be reduced, signal adjustment during distribution is facilitated.

  Further, the antenna device shares the transmission filters 15-1 to 15-n and the transmission phase varying devices 23-1 to 23-n with the phase varying devices 25-1 to 25-n. In general, when transmission phase shifters 13-1 to 13-n are provided at the subsequent stage of a power amplifier, the phase shifters 13-1 to 13-n themselves are required to have power durability. For this reason, a phase shifter is provided in front of the power amplifier. However, when the transmission phase varying devices 25-1 to 25-n according to the sixth embodiment are used, a transmission filter that requires power resistance is used. Since the portion can be provided with a phase adjustment function, the circuit configuration of the transmission unit can be simplified.

  Further, the filter circuit and the bandpass filter provided in the transmission phase varying devices 25-1 to 25-n use a superconducting filter constructed of a superconducting material, and the cooling device is sent into the vacuum vessel 21-1. The credit phase varying devices 25-1 to 25-n and the receiving unit are accommodated and cooled to a cryogenic temperature by the cooling unit 21-2. As a result, the antenna device can reduce loss during transmission and reception.

(Seventh embodiment)
FIG. 15 is a block diagram illustrating a configuration of an antenna device according to the seventh embodiment. The antenna device shown in FIG. 15 is an antenna device that uses the phase variable device according to the first embodiment as a receiver, and uses the phase variable device according to the second embodiment as a transmitter.

  In the seventh embodiment, the antenna device includes reception phase varying devices 19-1 to 19-n and transmission phase varying devices 25-1 to 25-n having small amplitude fluctuations due to phase changes in the reception unit and the transmission unit, respectively. By using, the signal level difference generated when setting the phase in each system can be reduced, so that signal adjustment at the time of synthesis and distribution becomes easy.

  In the antenna device, the transmission filters 15-1 to 15-n and the transmission phase varying devices 23-1 to 23-n are shared by the transmission phase varying devices 25-1 to 25-n. In general, when transmission phase shifters 13-1 to 13-n are provided at the subsequent stage of a power amplifier, the phase shifters 13-1 to 13-n themselves are required to have power durability. For this reason, a phase shifter is provided in front of the power amplifier. However, when the transmission phase varying devices 25-1 to 25-n according to the sixth embodiment are used, a transmission filter that requires power resistance is used. Since the portion can be provided with a phase adjustment function, the circuit configuration of the transmission unit can be simplified.

  Also, the reception filters 17-1 to 17-n, the filter circuits included in the reception phase varying devices 19-1 to 19-n, the filter circuits included in the transmission phase varying devices 25-1 to 25-n, and the band pass. The filter uses a superconducting filter constructed of a superconducting material, and the cooling device accommodates the transmission phase varying devices 25-1 to 25-n and the receiving unit in the vacuum vessel 21-1, and the cooling unit 21- 2 to cool to cryogenic temperature. As a result, the antenna device can reduce loss during transmission and reception.

(Eighth embodiment)
FIG. 16 is a block diagram illustrating a configuration of an antenna device according to the eighth embodiment. The antenna device shown in FIG. 16 is an antenna device that uses the phase variable device according to the second embodiment as a receiver, and uses the phase variable device according to the first embodiment as a transmitter.

  In the eighth embodiment, the antenna device includes reception phase variable devices 22-1 to 22-n and transmission phase variable devices 23-1 to 23-n with small amplitude fluctuations due to phase changes in the reception unit and the transmission unit, respectively. By using, the signal level difference generated when setting the phase in each system can be reduced, so that signal adjustment at the time of synthesis and distribution becomes easy.

  In the antenna device, the reception filters 17-1 to 17-n and the reception phase varying devices 19-1 to 19-n are shared by the reception phase varying devices 22-1 to 22-n. Thereby, the antenna apparatus can simplify the circuit configuration of the receiving unit.

  Also, transmission filters 15-1 to 15-n, filter circuits included in the transmission phase varying devices 23-1 to 23-n, reception filters 17-1 to 17-n, and reception phase varying devices 22-1 to 22 are provided. The filter circuit provided in −n uses a superconducting filter constructed of a superconducting material, and the cooling device includes the transmission filters 15-1 to 15-n and the transmission phase varying device 23− in the vacuum vessel 21-1. 1-23-n and a receiving part are accommodated, and it cools to cryogenic temperature by the cooling part 21-2. As a result, the antenna device can reduce loss during transmission and reception.

(Ninth embodiment)
FIG. 17 is a block diagram showing the configuration of the antenna device according to the ninth embodiment. The antenna device shown in FIG. 17 is an antenna device that uses the phase variable device according to the first embodiment for a reception unit and a transmission unit.

  In the ninth embodiment, the antenna device includes reception phase variable devices 19-1 to 19-n and transmission phase variable devices 23-1 to 23-n with small amplitude fluctuations due to phase changes in the reception unit and the transmission unit, respectively. By using, the signal level difference generated when setting the phase in each system can be reduced, so that signal adjustment at the time of synthesis and distribution becomes easy.

  Also, transmission filters 15-1 to 15-n, filter circuits included in the transmission phase varying devices 23-1 to 23-n, reception filters 17-1 to 17-n, and reception phase varying devices 19-1 to 19-19. The filter circuit provided in −n uses a superconducting filter constructed of a superconducting material, and the cooling device includes the transmission filters 15-1 to 15-n and the transmission phase varying device 23− in the vacuum vessel 21-1. 1-23-n and a receiving part are accommodated, and it cools to cryogenic temperature by the cooling part 21-2. As a result, the antenna device can reduce loss during transmission and reception.

(Tenth embodiment)
FIG. 18 is a block diagram showing the configuration of the antenna device according to the tenth embodiment. The antenna device shown in FIG. 18 is an antenna device that uses the phase variable device according to the second embodiment for a reception unit and a transmission unit.

  In the tenth embodiment, the antenna apparatus includes reception phase varying devices 22-1 to 22-n and transmission phase varying devices 25-1 to 25-n having small amplitude fluctuations due to phase changes in the reception unit and the transmission unit, respectively. Is used. As a result, the antenna device can reduce a signal level difference generated when setting the phase in each system, so that signal adjustment at the time of synthesis and distribution becomes easy.

  In the antenna device, the reception filters 17-1 to 17-n and the reception phase varying devices 19-1 to 19-n are shared by the reception phase varying devices 22-1 to 22-n. Thereby, the antenna apparatus can simplify the circuit configuration of the receiving unit. In the antenna device, the transmission filters 15-1 to 15-n and the transmission phase varying devices 23-1 to 23-n are shared by the transmission phase varying devices 25-1 to 25-n. In general, when transmission phase shifters 13-1 to 13-n are provided at the subsequent stage of a power amplifier, the phase shifters 13-1 to 13-n themselves are required to have power durability. For this reason, a phase shifter is provided in front of the power amplifier. However, when the transmission phase varying devices 25-1 to 25-n are used, the transmission filter portion that requires power resistance has a phase adjustment function. Therefore, the circuit configuration of the transmission unit can be simplified.

  Further, the antenna device includes a filter circuit and a band pass filter provided in the reception phase varying devices 19-1 to 19-n, and a filter circuit and a band pass filter provided in the transmission phase varying devices 23-1 to 23-n. Is a superconducting filter constructed of a superconducting material. The cooling device accommodates the transmission phase varying devices 25-1 to 25-n and the receiving unit in the vacuum vessel 21-1, and the cooling unit 21- 2 to cool to cryogenic temperature. As a result, the antenna device can reduce loss during transmission and reception.

(Eleventh embodiment)
FIG. 19 is a block diagram showing the configuration of the antenna device according to the eleventh embodiment. The antenna device illustrated in FIG. 19 is an antenna device that uses the phase variable device according to the second embodiment for a reception unit and a transmission unit.

  In the tenth embodiment, the phase shifter for transmission / reception and the filter for transmission / reception are shared by the phase variable devices 26-1 to 26-n, and the phase variable devices 26-1 to 26-n are further used as the antennas 10-1 to 10-10. -N and the transmission / reception switching devices 11-1 to 11-n. Thereby, the antenna device can further simplify the circuit configurations of the transmission unit and the reception unit.

  The antenna device uses phase variable devices 26-1 to 26-n that have small amplitude fluctuations due to phase changes. As a result, the antenna device can reduce a signal level difference generated when setting the phase in each system, so that signal adjustment at the time of synthesis and distribution becomes easy.

  In addition, the antenna device uses a superconducting filter constructed of a superconducting material for the filter circuit and the bandpass filter provided in the phase variable devices 26-1 to 26-n, and the cooling device is in the vacuum vessel 21-1. The phase variable devices 26-1 to 26-n and the receiving unit are accommodated in the cooling unit 21 and cooled to a very low temperature by the cooling unit 21-2. As a result, the antenna device can reduce loss during transmission and reception.

  Although the antenna device is described in the third to eleventh embodiments, the distributor 12 and the combiner 20 are included as n = 1 (when the antenna has one configuration). The present invention can also be applied to an antenna device having no configuration. Further, an antenna may be provided for each of the transmission unit and the reception unit, and the transmission antenna and the reception antenna may be configured.

(Twelfth embodiment)
FIG. 20 is a block diagram illustrating a configuration of the diplexer 27 according to the twelfth embodiment. The diplexer 27 shown in FIG. 20 is used when the antenna 10-1 is shared when different frequency band components are used during transmission and reception. The diplexer 27 is a diplexer that uses the phase variable device according to the second embodiment in the transmission unit and the reception unit.

  The diplexer 27 illustrated in FIG. 16 generates a transmission signal in the transmission unit 28-1, inputs the generated transmission signal to the transmission amplifier 14-1, and power-amplifies the input transmission signal. The diplexer 27 inputs the amplified transmission signal to the transmission phase varying device 25-1 having the center frequency f1, changes the phase of the input transmission signal, and passes a desired frequency band component from the transmission signal with the variable phase. . The diplexer 27 radiates the transmission signal output from the transmission phase varying device 25-1 from the antenna 10-1 to the space.

  Further, the diplexer 27 inputs the reception signal received by the antenna 10-1 to the reception phase varying device 22-1 having the center frequency f2, changes the phase of the input reception signal, and changes the phase from the reception signal having a variable phase. A desired frequency band component is passed. The diplexer 27 low-amplifies the reception signal output from the reception phase varying device 22-1 with the low-noise amplifier 18-1, and then processes the reception signal with the reception unit 29-1. In the diplexer 29, the transmission side filter is matched at the time of transmission, but the reception side filter needs to be adjusted so as not to be reflected and influenced. Therefore, the phase is adjusted by providing a transmission line and a phase variable device for adjusting the phase on one or both of the transmission side and the reception side, and matching is performed.

  As described above, the diplexer 27 uses the transmission phase variable device 25-1 and the reception phase variable device 22-1, so that the filter and transmission for limiting the passband of a desired signal and changing the phase of the signal are transmitted. It is possible to simplify the circuit configuration by sharing the line.

(13th Embodiment)
FIG. 21 is a block diagram showing a configuration of the multiplexer 30 according to the thirteenth embodiment. The multiplexer 30 shown in FIG. 21 is used when a plurality of receiving units 29-1 to 29-n having different frequency band components to pass through share an antenna. A multiplexer 30 illustrated in FIG. 17 is a multiplexer that uses the phase variable device according to the second embodiment for each of the receiving units 29-1 to 29-n.

  The multiplexer 30 shown in FIG. 17 demultiplexes the received signal received by the antenna 10-1, and the demultiplexed received signal has a plurality of reception phase varying devices 22-1 to 22-n having different center frequencies f1 to fn. The phase of the input received signal is varied, and a desired frequency band component is passed from the received signal having the varied phase. The multiplexer 30 amplifies the received signals that have passed through the low noise amplifiers 18-1 to 18-n with low noise, and then processes the received signals at the receiving units 29-1 to 29-n.

  In the multiplexer 30, since it is necessary to adjust matching of a plurality of filters at the receiving unit of each frequency band, a matching circuit using a transmission line or the like becomes complicated. Therefore, the multiplexer 30 uses a plurality of receiving phase varying devices 22-1 to 22-n. As a result, the multiplexer 30 shares the filter and the transmission line for limiting the passband of the desired signal and changing the phase of the signal, and further simplifies the frequency adjustment after installation. Therefore, the multiplexer 30 can simplify the circuit configuration.

According to the above configuration, the phase variable device includes a filter circuit, by controlling the on-off binding switching unit 2 in the switching control unit 3, by varying the coupling of the bypass coupling line k _13, changing the transmission line of the signal Let As a result, a signal passing through the filter circuit has a phase difference between when the coupling switching unit 2 is on and when it is off. For this reason, the phase varying device can vary the phase of the signal passing through the filter circuit.

  Therefore, the phase varying device can vary the phase with a low loss and a simple configuration. Moreover, a suitable antenna device, diplexer, and multiplexer can be provided using this phase variable device.

  The antenna device can be applied to any phased array antenna having a phase shifter for each antenna element or subarray. Further, the present invention can be applied to both passive arrays and active arrays.

  Although some embodiments have been described above, these embodiments are presented as examples 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 changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the invention described in the claims and equivalents thereof as well as included in the scope and gist of the invention.

1 ... resonator, 2,4 ... binding switcher, 3,5 ... switching control _{unit, k} 12, k _{23 ...} coupled line, k _{13 ...} bypass coupling line, Q _{e1 ...} input line, an In ... input _{terminal, Q e2} ... Output line, Out ... Output terminal, 6 ... Band pass filter, 10-1 to 10-n ... Antenna, 11-1 to 11-n ... Transmission / reception switching device, 12 ... Distributor, 13-1 to 13-n ... Transmission phase shifter, 14-1 to 14-n ... transmission amplifier, 15-1 to 15-n ... transmission bandpass filter (BPF), 16-1 to 16-n ... limiter, 17-1 to 17- n: reception band-pass filter, 18-1 to 18-n ... low noise amplifier (LNA), 19-1 to 19-n, 22-1 to 22-n ... reception phase variable device, 20 ... synthesizer, 21-1 ... Vacuum container, 21-2 ... Cooling section, 23-1 to 23-n, 25-1 to 25- n ... transmission phase variable device, 24-1 to 24-n ... reception phase shifter, 26-1 to 26-n ... phase variable device, 27 ... diplexer, 28-1 ... transmission unit, 29-1 to 29 -N: receiving unit, 30 ... multiplexer.

Claims (55)

A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An output terminal connected to an output terminal of a final stage of the plurality of resonators.   2. The phase varying apparatus according to claim 1, further comprising control means for controlling on / off of the coupling switching means.   2. The phase variable device according to claim 1, wherein the coupling switching means is one of a diode switch, a MEMS switch, a FET switch variable capacitance diode, and a ferroelectric ceramic.   2. The phase variable device according to claim 1, wherein the plurality of resonators, the plurality of coupled lines, and the bypass coupled line are constructed of a superconducting material and disposed in an environment cooled to a cryogenic temperature that is in a superconducting state.   The phase variable device according to claim 1, further comprising a band-pass filter that is provided before or after the plurality of resonators and that passes a desired frequency band component of an input signal.   The phase-variable device according to claim 5, wherein the band-pass filter is constructed of a superconducting material and disposed in an environment cooled to a cryogenic temperature that is in a superconducting state. In an antenna device including a receiving unit that performs signal processing on a reception signal received by an antenna,
The receiver is
A reception filter that passes a desired frequency band component from the received signal;
A low noise amplifier that amplifies the received signal that has passed through the reception filter with low noise;
A reception phase varying device that performs desired phase control on the reception signal in a reception processing path of the reception filter and a low noise amplifier;
The reception phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An antenna device comprising: an output terminal connected to an output terminal of a final stage of the plurality of resonators.   8. The antenna apparatus according to claim 7, further comprising control means for controlling on / off of the coupling switching means.   The antenna device according to claim 7, wherein the plurality of resonators, the plurality of coupled lines, and the bypass coupled line are constructed of a superconducting material and disposed in an environment cooled to a cryogenic temperature that is in a superconducting state. In an antenna device including a receiving unit that performs signal processing on a reception signal received by an antenna,
The receiver is
A receiving phase varying device for performing desired phase control on the received signal;
A low noise amplifier that amplifies the received signal that has passed through the receiving phase varying device with low noise;
The reception phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An output terminal connected to the output terminal of the final stage of the plurality of resonators,
An antenna device further comprising a reception band-pass filter that is provided before or after the plurality of resonators and allows a desired frequency band component of the reception signal to pass therethrough.   The antenna device according to claim 10, further comprising control means for controlling on / off of the coupling switching means.   11. The plurality of resonators, the plurality of coupled lines, the bypass coupled line, and the band-pass filter for reception are constructed of a superconducting material and disposed in an environment cooled to a cryogenic temperature that is in a superconducting state. Antenna device. The antenna is an array antenna comprising a plurality of antenna elements,
The antenna device according to claim 7, wherein the receiving unit is provided corresponding to each of the plurality of antenna elements. In an antenna device including a transmission unit that outputs a transmission signal radiated from an antenna to space,
The transmitter is
A transmission amplifier for inputting the transmission signal and amplifying the input transmission signal with a desired gain;
A transmission filter that passes a desired frequency band component from the transmission signal amplified by the transmission amplifier;
A transmission phase varying device that performs desired phase control on the transmission signal in a transmission processing path of the transmission amplifier and the transmission filter;
The transmission phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An antenna device comprising: an output terminal connected to an output terminal of a final stage of the plurality of resonators.   15. The antenna device according to claim 14, further comprising control means for controlling on / off of the coupling switching means.   The antenna device according to claim 14, wherein the plurality of resonators, the plurality of coupled lines, and the bypass coupled line are constructed of a superconducting material and disposed in an environment cooled to a cryogenic temperature that is in a superconducting state. In an antenna device including a transmission unit that outputs a transmission signal radiated from an antenna to space,
The transmitter is
A transmission amplifier for amplifying the power of the transmission signal with a desired gain;
A transmission phase variable device that inputs a transmission signal amplified by the transmission amplifier and performs desired phase control on the input transmission signal,
The transmission phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An output terminal connected to the output terminal of the final stage of the plurality of resonators,
An antenna device further comprising a transmission band-pass filter that is provided upstream or downstream of the plurality of resonators and allows a desired frequency band component of the transmission signal to pass therethrough.   18. The antenna device according to claim 17, further comprising control means for controlling on / off of the coupling switching means.   18. The plurality of resonators, the plurality of coupled lines, the bypass coupled line, and the transmission bandpass filter are constructed of a superconducting material and disposed in an environment cooled to a cryogenic temperature that is in a superconducting state. Antenna device. The antenna is an array antenna comprising a plurality of antenna elements,
The antenna device according to claim 14, wherein the transmission unit is provided corresponding to each of the plurality of antenna elements. A transmission unit that outputs a transmission signal radiated from the antenna to the space, a reception unit that performs signal processing on a reception signal received by the antenna, and the transmission unit and the reception unit to the antenna according to a transmission and reception switching instruction In an antenna device comprising a transmission / reception switching device for switching connection,
The transmitter is
A transmission phase shifter for inputting the transmission signal and performing desired phase control on the input transmission signal;
A transmission amplifier that inputs a transmission signal phase-controlled by the transmission phase shifter and amplifies the power of the input transmission signal with a desired gain;
A transmission filter that passes a desired frequency band component from the transmission signal amplified by the transmission amplifier;
The receiver is
A reception filter that passes a desired frequency band component from the received signal;
A low noise amplifier that amplifies the received signal that has passed through the reception filter with low noise;
A reception phase varying device for performing desired phase control on a reception signal in a reception processing path of the reception filter and the low noise amplifier,
The reception phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
And an output terminal connected to an output terminal of a final stage of the plurality of resonators.   The antenna device according to claim 21, further comprising control means for controlling on / off of the coupling switching means.   The antenna device according to claim 21, wherein the plurality of resonators, the plurality of coupled lines, and the bypass coupled line are constructed of a superconducting material and disposed in an environment cooled to a cryogenic temperature that is in a superconducting state. A transmission unit that outputs a transmission signal radiated from the antenna to the space, a reception unit that performs signal processing on a reception signal received by the antenna, and the transmission unit and the reception unit to the antenna according to a transmission and reception switching instruction In an antenna device comprising a transmission / reception switching device for switching connection,
The transmitter is
A transmission phase shifter for inputting the transmission signal and performing desired phase control on the input transmission signal;
A transmission amplifier that inputs a transmission signal phase-controlled by the transmission phase shifter and amplifies the power of the input transmission signal with a desired gain;
A transmission filter that passes a desired frequency band component from the transmission signal amplified by the transmission amplifier;
The receiver is
A receiving phase varying device for performing desired phase control on the received signal;
A low noise amplifier for amplifying the received signal phase-controlled by the receiving phase varying device with low noise,
The reception phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An output terminal connected to the output terminal of the final stage of the plurality of resonators,
An antenna device further comprising a reception band-pass filter that is provided before or after the plurality of resonators and allows a desired frequency band component of the reception signal to pass therethrough.   25. The antenna device according to claim 24, further comprising control means for controlling on / off of the coupling switching means.   25. The plurality of resonators, the plurality of coupled lines, the bypass coupled line, and the reception band-pass filter are constructed of a superconducting material and disposed in an environment cooled to a cryogenic temperature that is in a superconducting state. Antenna device. The antenna is an array antenna comprising a plurality of antenna elements,
27. The antenna device according to claim 21, wherein the receiving unit is provided corresponding to each of the plurality of antenna elements. A transmission unit that outputs a transmission signal radiated from the antenna to the space, a reception unit that performs signal processing on a reception signal received by the antenna, and the transmission unit and the reception unit to the antenna according to a transmission and reception switching instruction In an antenna device comprising a transmission / reception switching device for switching connection,
The transmitter is
A transmission amplifier for inputting the transmission signal and amplifying the input transmission signal with a desired gain;
A transmission filter that passes a desired frequency band component from the transmission signal amplified by the transmission amplifier;
A transmission phase varying device that performs desired phase control on the transmission signal in a transmission processing path of the transmission amplifier and the transmission filter;
The receiver is
A reception filter that passes a desired frequency band component from the received signal;
A low noise amplifier that amplifies the received signal that has passed through the reception filter with low noise;
A receiving phase shifter for performing desired phase control on the received signal amplified by the low noise amplifier,
The transmission phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
And an output terminal connected to an output terminal of a final stage of the plurality of resonators.   29. The antenna device according to claim 28, further comprising control means for controlling on / off of the coupling switching means.   29. The antenna device according to claim 28, wherein the plurality of resonators, the plurality of coupled lines, and the bypass coupled line are constructed of a superconducting material and disposed in an environment cooled to a cryogenic temperature that is in a superconducting state. A transmission unit that outputs a transmission signal radiated from the antenna to the space, a reception unit that performs signal processing on a reception signal received by the antenna, and the transmission unit and the reception unit to the antenna according to a transmission and reception switching instruction In an antenna device comprising a transmission / reception switching device for switching connection,
The transmitter is
A transmission amplifier for amplifying the power of the transmission signal with a desired gain;
A transmission phase variable device for inputting a transmission signal amplified by the transmission amplifier and performing desired phase control on the input transmission signal;
The receiver is
A reception filter that passes a desired frequency band component from the received signal;
A low noise amplifier that amplifies the received signal that has passed through the reception filter with low noise;
A receiving phase shifter for performing desired phase control on the received signal amplified by the low noise amplifier,
The transmission phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An output terminal connected to the output terminal of the final stage of the plurality of resonators,
An antenna device further comprising a transmission band-pass filter that is provided upstream or downstream of the plurality of resonators and allows a desired frequency band component of the transmission signal to pass therethrough.   32. The antenna device according to claim 31, further comprising control means for controlling on / off of the coupling switching means.   32. The plurality of resonators, the plurality of coupled lines, the bypass coupled line, and the transmission band-pass filter are constructed of a superconducting material and disposed in an environment cooled to a cryogenic temperature that is in a superconducting state. Antenna device. A transmission unit that outputs a transmission signal radiated from the antenna to the space, a reception unit that performs signal processing on a reception signal received by the antenna, and the transmission unit and the reception unit to the antenna according to a transmission and reception switching instruction In an antenna device comprising a transmission / reception switching device for switching connection,
The transmitter is
A transmission amplifier for inputting the transmission signal and amplifying the input transmission signal with a desired gain;
A transmission phase varying device that performs desired phase control on the transmission signal amplified by the transmission amplifier;
The receiver is
A reception filter that passes a desired frequency band component from the received signal;
A low noise amplifier that amplifies the received signal that has passed through the reception filter with low noise;
A reception phase varying device that performs desired phase control on the reception signal in a reception processing path of the reception filter and low-noise amplifier;
The transmission phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An output terminal connected to the output terminal of the final stage of the plurality of resonators,
A transmission band-pass filter that is provided in a front stage or a rear stage of the plurality of resonators and that passes a desired frequency band component of the transmission signal;
The reception phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
And an output terminal connected to an output terminal of a final stage of the plurality of resonators.   35. The antenna apparatus according to claim 34, further comprising control means for controlling on / off of the coupling switching means.   The plurality of resonators, the plurality of coupled lines, the bypass coupled line, and the transmission band-pass filter are constructed of a superconducting material and disposed in an environment cooled to a cryogenic temperature that is in a superconducting state. The antenna device described. A transmission unit that outputs a transmission signal radiated from the antenna to the space, a reception unit that performs signal processing on a reception signal received by the antenna, and the transmission unit and the reception unit to the antenna according to a transmission and reception switching instruction In an antenna device comprising a transmission / reception switching device for switching connection,
The transmitter is
A transmission amplifier for inputting the transmission signal and amplifying the input transmission signal with a desired gain;
A transmission filter that passes a desired frequency band component from the transmission signal amplified by the transmission amplifier;
A transmission phase varying device that performs desired phase control on the transmission signal in a transmission processing path of the transmission amplifier and the transmission filter;
The receiver is
A receiving phase varying device for performing desired phase control on the received signal;
A low noise amplifier for amplifying the received signal phase-controlled by the receiving phase varying device with low noise,
The transmission phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An output terminal connected to the output terminal of the final stage of the plurality of resonators,
The reception phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An output terminal connected to the output terminal of the final stage of the plurality of resonators,
An antenna device further comprising a reception band-pass filter that is provided before or after the plurality of resonators and allows a desired frequency band component of the reception signal to pass therethrough.   38. The antenna apparatus according to claim 37, further comprising control means for controlling on / off of the coupling switching means.   38. The plurality of resonators, the plurality of coupled lines, the bypass coupled line, and the reception bandpass filter are constructed of a superconducting material and disposed in an environment cooled to a cryogenic temperature that is in a superconducting state. Antenna device. A transmission unit that outputs a transmission signal radiated from the antenna to the space, a reception unit that performs signal processing on a reception signal received by the antenna, and the transmission unit and the reception unit to the antenna according to a transmission and reception switching instruction In an antenna device comprising a transmission / reception switching device for switching connection,
The transmitter is
A transmission amplifier for inputting the transmission signal and amplifying the input transmission signal with a desired gain;
A transmission filter that passes a desired frequency band component from the transmission signal amplified by the transmission amplifier;
A transmission phase varying device that performs desired phase control on the transmission signal in a transmission processing path of the transmission amplifier and the transmission filter;
The receiver is
A reception filter that passes a desired frequency band component from the received signal;
A low noise amplifier that amplifies the received signal that has passed through the reception filter with low noise;
A reception phase varying device that performs desired phase control on the reception signal in a reception processing path of the reception filter and low-noise amplifier;
The transmission phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An output terminal connected to the output terminal of the final stage of the plurality of resonators,
The reception phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
And an output terminal connected to an output terminal of a final stage of the plurality of resonators.   41. The antenna device according to claim 40, further comprising control means for controlling on / off of said coupling switching means.   41. The antenna device according to claim 40, wherein the plurality of resonators, the plurality of coupled lines, and the bypass coupled line are constructed of a superconducting material and disposed in an environment cooled to a cryogenic temperature that is in a superconducting state. A transmission unit that outputs a transmission signal radiated from the antenna to the space, a reception unit that performs signal processing on a reception signal received by the antenna, and the transmission unit and the reception unit to the antenna according to a transmission and reception switching instruction In an antenna device comprising a transmission / reception switching device for switching connection,
The transmitter is
A transmission phase varying device for inputting the transmission signal and performing desired phase control on the input transmission signal;
A transmission amplifier that amplifies the transmission signal phase-controlled by the transmission phase varying device with a desired gain, and
The receiver is
A receiving phase varying device for performing desired phase control on the received signal;
A low noise amplifier for amplifying the received signal phase-controlled by the receiving phase varying device with low noise,
The transmission phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An output terminal connected to the output terminal of the final stage of the plurality of resonators,
A transmission band-pass filter that is provided in a front stage or a rear stage of the plurality of resonators and that passes a desired frequency band component of the transmission signal;
The reception phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An output terminal connected to the output terminal of the final stage of the plurality of resonators,
An antenna device further comprising a reception band-pass filter that is provided before or after the plurality of resonators and allows a desired frequency band component of the reception signal to pass therethrough.   44. The antenna device according to claim 43, further comprising control means for controlling on / off of said coupling switching means.   The plurality of resonators, the plurality of coupling lines, the bypass coupling line, the transmission band-pass filter and the reception band-pass filter are constructed of a superconducting material and arranged in an environment cooled to a cryogenic temperature that is in a superconducting state. 44. The antenna device according to claim 43. A transmission unit that outputs a transmission signal radiated from the antenna to the space, a reception unit that performs signal processing on a reception signal received by the antenna, and the transmission unit and the reception unit to the antenna according to a transmission and reception switching instruction In an antenna device comprising a transmission / reception switching device for switching connection,
The transmission unit includes a transmission amplifier that amplifies the transmission signal with a desired gain,
The receiver comprises a low noise amplifier that amplifies the received signal with low noise,
A phase variable that inputs a transmission signal output from the transmission unit, performs a desired phase control on the input transmission signal, inputs a reception signal received by the antenna, and performs a desired phase control on the input reception signal Further comprising a device,
The phase varying device includes:
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An output terminal connected to the output terminal of the final stage of the plurality of resonators,
An antenna device further comprising a band-pass filter that is provided before or after the plurality of resonators and allows a desired frequency band component of the transmission signal and the reception signal to pass therethrough.   The antenna device according to claim 46, further comprising control means for controlling switching of said coupling switching means.   The antenna according to claim 46, wherein the plurality of resonators, the plurality of coupled lines, the bypass coupled line, and the band pass filter are constructed of a superconducting material and disposed in an environment cooled to a cryogenic temperature that is in a superconducting state. apparatus. The antenna is an array antenna comprising a plurality of antenna elements,
49. The antenna device according to claim 28, wherein the transmitting unit and the receiving unit are provided corresponding to each of the plurality of antenna elements. It is used in an antenna device including a transmission unit that outputs a transmission signal radiated from an antenna to a space and a reception unit that performs signal processing on a reception signal received by the antenna. In a diplexer sharing an antenna,
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An output terminal connected to the output terminal of the final stage of the plurality of resonators,
A transmission phase varying device further provided with a transmission band-pass filter that is provided in a front stage or a rear stage of the plurality of resonators and passes a desired frequency band component of the transmission signal;
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An output terminal connected to the output terminal of the final stage of the plurality of resonators,
A diplexer comprising a reception phase varying device further provided with a reception band-pass filter that is provided before or after the plurality of resonators and passes a desired frequency band component of the reception signal.   51. The diplexer according to claim 50, further comprising control means for controlling on / off of said coupling switching means.   The plurality of resonators, the plurality of coupling lines, the bypass coupling line, the transmission band-pass filter and the reception band-pass filter are constructed of a superconducting material and arranged in an environment cooled to a cryogenic temperature that is in a superconducting state. 51. A diplexer as claimed in claim 50. A plurality of reception units that are used in an antenna device including a reception unit that performs signal processing on a reception signal received by an antenna, demultiplexes the reception signal, and extracts different frequency band components from the demultiplexed reception signals. In the multiplexer that shares the antenna,
A plurality of resonators provided with at least three or more;
A plurality of coupled lines for serially coupling the plurality of resonators;
Among the plurality of resonators coupled in series by the plurality of coupling lines, a bypass coupling line that bypass-couples the resonators with at least one resonator interposed therebetween,
Coupling switching means provided in the bypass coupling line, for selectively turning on and off the bypass coupling;
An input terminal connected to an input terminal of a first stage of the plurality of resonators;
An output terminal connected to the output terminal of the final stage of the plurality of resonators,
A multiplexer comprising a plurality of reception phase varying devices further provided with a reception band-pass filter that is provided before or after the plurality of resonators and passes a desired frequency band component of the reception signal.   54. The multiplexer according to claim 53, further comprising control means for controlling on / off of said coupling switching means.   54. The plurality of resonators, the plurality of coupled lines, the bypass coupled line, and the bandpass filter for reception are constructed of a superconducting material and disposed in an environment cooled to a cryogenic temperature that is in a superconducting state. Multiplexer.

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