JP4606378B2 - Dielectric waveguide device, phase shifter including the same, high frequency switch and attenuator, and high frequency transmitter, high frequency receiver, high frequency transmitter / receiver, radar apparatus, and array antenna apparatus - Google Patents

Description

  The present invention relates to a dielectric waveguide device used in a high frequency band such as a microwave, a quasi-millimeter wave band, and a millimeter wave band, a phase shifter including the dielectric waveguide device, a high frequency switch and an attenuator, a high frequency transmitter, a high frequency receiver, The present invention relates to a high-frequency transceiver, a radar device, and an array antenna device.

  A phase shifter is known as a dielectric waveguide device that controls the phase of a high-frequency signal. This phase shifter is used to adjust the reflection and transmission characteristics of high-frequency signals in high-frequency circuits, and is expected to be applied to highly functional devices such as modulators, high-frequency switches, and phased array antennas. Device.

  The first prior art phase shifter includes a non-radiative dielectric line, and the end of the dielectric line of the non-radiative dielectric line is located close to the conductor strip. A rotating body including a dielectric is rotatably arranged, and the phase is changed by rotating the rotating body (see, for example, Patent Document 1).

  The phase shifter of the second prior art controls the phase by controlling the dielectric constant of a part of the dielectric of the non-radiative dielectric line (for example, see Patent Document 2).

JP 2002-314302 A JP-A-8-102604

In which is one phase shifter dielectric waveguide device of the first prior art, for example, an attempt to obtain a sufficient amount of phase change such as ± π (rad), the device is likely to cause turned into large-small There is a problem that it is difficult to mold . There also, by rotating the rotating body, since mechanically varying the length of the transmission path, the device or itself increases, a problem that mechanism is not suitable for mass production or accidentally complicated . When the device becomes larger, there is a problem that the mountability is remarkably poor as compared with other electronic components whose surface mounting is progressing.

In the phase shifter which is one of the dielectric waveguide devices of the second prior art, the device can be easily downsized , but it is difficult to surface-mount on a planar circuit board such as a printed circuit board, and the phase shifter and the planar There is a problem that it is difficult to connect to a transmission line formed on the circuit board.

An object of the present invention is therefore, a small mold, good a phase control possible, and suitable for surface mounting to a planar circuit board dielectric waveguide device, the phase shifter including the same, high frequency switch and attenuator And a high-frequency transmitter, a high-frequency receiver, a high-frequency transmitter / receiver, a radar device, and an array antenna device.

The dielectric waveguide device of the present invention includes a changing portion whose dielectric constant changes according to an applied electric field, a dielectric line through which electromagnetic waves propagate, and a pair of flat plate conductor portions that sandwich the dielectric line. A radioactive dielectric line;
Provided along the dielectric line, in a state perpendicular to the direction in which the dielectric line and the pair of flat plate conductors overlap, with a gap narrower than the gap between the pair of flat plate conductors. A pair of electrodes for sandwiching the dielectric line and applying an electric field to the changing portion;
A dielectric part provided on a surface part opposite to the dielectric line of either one of the pair of flat conductor parts;
A strip conductor portion provided on the surface portion of the dielectric portion opposite to the flat conductor portion, and a part of which is overlapped with the dielectric line;
The flat plate conductor part is formed with a through hole at a position where a part of the dielectric line and a part of the strip conductor part overlap each other.

In the dielectric waveguide device of the present invention, it is preferable that the pair of electrodes are formed to be thinner than a skin thickness with respect to electromagnetic waves propagating through the dielectric line, and sandwich the dielectric line .

In the dielectric waveguide device of the present invention, it is preferable that a pair of the electrodes is connected to the different flat conductor portions .

The dielectric waveguide device of the present invention is provided between the pair of flat plate conductor portions, sandwiches the dielectric line and the electrode, and has a dielectric constant lower than the dielectric constant of the dielectric line. It is preferable to include a dielectric part .

The phase shifter of the present invention comprises the dielectric waveguide device,
By varying the previous SL changes part of the dielectric constant depending on the electric field applied to the varying portion, it is preferable to change the phase of an electromagnetic wave propagating through the transmission line.

Moreover, the high frequency switch of the present invention comprises the dielectric waveguide device,
By pre-Symbol changing part of the dielectric constant varies according to an electric field applied to the varying portion, the cut-off frequency in the transmission line, the low made propagation conditions than the frequency of the electromagnetic wave propagating through the transmission line, high It is preferable that the cut-off state can be switched .

The attenuator of the present invention comprises a dielectric waveguide device,
By changing the dielectric constant of the front Symbol changing portion according to an electric field applied to the varying portion, it is preferable to attenuate electromagnetic waves propagating through the transmission line.

The high frequency transmitter of the present invention includes a high frequency oscillator that generates a high frequency signal,
A transmission line connected to the high-frequency oscillator and transmitting a high-frequency signal from the high-frequency oscillator;
An antenna connected to the transmission line and emitting a high-frequency signal;
The phase shifter inserted into the transmission line such that a high-frequency signal passes through the dielectric line;
It is preferable that at least one of the upstream side and the downstream side of the phase shifter in the transmission direction of the high-frequency signal includes a stub provided on the transmission line .

The high frequency receiver of the present invention includes an antenna that captures a high frequency signal,
A transmission line connected to the antenna and transmitting a high-frequency signal captured by the antenna;
A high-frequency detector connected to the transmission line and detecting a high-frequency signal transmitted to the transmission line;
The phase shifter inserted into the transmission line such that a high-frequency signal passes through the dielectric line;
It is preferable that at least one of the upstream side and the downstream side of the phase shifter in the transmission direction of the high-frequency signal includes a stub provided on the transmission line .

The high frequency transceiver of the present invention includes a high frequency oscillator for generating a high frequency signal,
A first transmission line that is connected to the high-frequency oscillator and transmits a high-frequency signal; and first, second, and third terminals; the first terminal is connected to the first transmission line and applied to the first terminal A branching device that selectively outputs a high-frequency signal to be output to the second terminal or the third terminal;
A second transmission line connected to the second terminal and transmitting a high-frequency signal applied from the second terminal;
A fourth, fifth, and sixth terminal that outputs a high-frequency signal applied to the fourth terminal via the second transmission line to the fifth terminal, and a high-frequency signal applied to the fifth terminal; A duplexer that outputs to the sixth terminal;
A third transmission line connected to the fifth terminal for transmitting a high-frequency signal output from the fifth terminal and transmitting the high-frequency signal to the fifth terminal;
An antenna connected to the third transmission line for radiating and capturing high-frequency signals;
A fourth transmission line connected to the third terminal and transmitting a high-frequency signal output from the third terminal;
A fifth transmission line connected to the sixth terminal for transmitting a high-frequency signal output from the sixth terminal;
A mixer that is connected to the fourth and fifth transmission lines, mixes high-frequency signals given from the fourth and fifth transmission lines, and outputs an intermediate frequency signal;
It is preferable that the phase shifter is inserted into at least one of the first to fifth transmission lines so that a high-frequency signal passes through the dielectric line .

The high frequency transmitter of the present invention includes a high frequency oscillator that generates a high frequency signal,
A high-frequency transmission line connected to the high-frequency oscillator and transmitting a high-frequency signal from the high-frequency oscillator;
An antenna connected to the high-frequency transmission line and emitting a high-frequency signal;
The high-frequency signal inserted into the high-frequency transmission line is transmitted through the high-frequency transmission line by setting the propagation state, and the high-frequency signal transmitted to the high-frequency transmission line is blocked by setting the cutoff state. The high-frequency switch is preferably included.

The high frequency transceiver of the present invention includes a high frequency oscillator for generating a high frequency signal,
A first high-frequency transmission line that is connected to the high-frequency oscillator and transmits a high-frequency signal; and first, second, and third terminals; the first terminal is connected to the first high-frequency transmission line; A branching device that selectively outputs a high-frequency signal given to the second terminal or the third terminal;
A second high frequency transmission line connected to the second terminal and transmitting a high frequency signal applied from the second terminal;
A high-frequency signal having fourth, fifth, and sixth terminals, outputting a high-frequency signal supplied to the fourth terminal via the second high-frequency transmission line to the fifth terminal, and supplied to the fifth terminal A duplexer that outputs to the sixth terminal;
A third high-frequency transmission line that is connected to the fifth terminal, transmits a high-frequency signal output from the fifth terminal, and transmits a high-frequency signal to the fifth terminal;
An antenna connected to the third high-frequency transmission line for radiating and capturing high-frequency signals;
A fourth high-frequency transmission line connected to the third terminal and transmitting a high-frequency signal output from the third terminal;
A fifth high-frequency transmission line connected to the sixth terminal and transmitting a high-frequency signal output from the sixth terminal;
A mixer that is connected to the fourth and fifth high-frequency transmission lines, mixes high-frequency signals given from the fourth and fifth high-frequency transmission lines, and outputs an intermediate frequency signal;
The branching device includes two high-frequency switches, and the first high-frequency switch transmits the high-frequency signal between the first terminal and the second terminal and sets the cutoff state by setting the propagation state. The high frequency signal is cut off between the first terminal and the second terminal, and the second high frequency switch transmits the high frequency signal between the first terminal and the third terminal by being in the propagation state, and It is preferable to cut off a high frequency signal between the first terminal and the third terminal by setting the cutoff state .

The high frequency transceiver of the present invention includes a high frequency oscillator for generating a high frequency signal,
A first high-frequency transmission line that is connected to the high-frequency oscillator and transmits a high-frequency signal; and first, second, and third terminals; the first terminal is connected to the first high-frequency transmission line; A branching device that selectively outputs a high-frequency signal given to the second terminal or the third terminal;
A second high frequency transmission line connected to the second terminal and transmitting a high frequency signal applied from the second terminal;
A high-frequency signal having fourth, fifth, and sixth terminals, outputting a high-frequency signal supplied to the fourth terminal via the second high-frequency transmission line to the fifth terminal, and supplied to the fifth terminal A duplexer that outputs to the sixth terminal;
A third high-frequency transmission line that is connected to the fifth terminal, transmits a high-frequency signal output from the fifth terminal, and transmits a high-frequency signal to the fifth terminal;
An antenna connected to the third high-frequency transmission line for radiating and capturing high-frequency signals;
A fourth high-frequency transmission line connected to the third terminal and transmitting a high-frequency signal output from the third terminal;
A fifth high-frequency transmission line connected to the sixth terminal and transmitting a high-frequency signal output from the sixth terminal;
A mixer that is connected to the fourth and fifth high-frequency transmission lines, mixes high-frequency signals given from the fourth and fifth high-frequency transmission lines, and outputs an intermediate frequency signal;
The duplexer includes two high-frequency switches, and the third high-frequency switch transmits the high-frequency signal between the fourth terminal and the fifth terminal by setting the propagation state, and the cutoff state The high frequency signal is cut off between the fourth terminal and the fifth terminal by doing, the fourth high frequency switch transmits the high frequency signal between the fifth terminal and the sixth terminal by being in the propagation state, In addition, it is preferable that the high-frequency signal is blocked between the fifth terminal and the sixth terminal by setting the cutoff state .

The high frequency transceiver of the present invention includes a high frequency oscillator for generating a high frequency signal,
A first high-frequency transmission line that is connected to the high-frequency oscillator and transmits a high-frequency signal; and first, second, and third terminals; the first terminal is connected to the first high-frequency transmission line; A branching device that selectively outputs a high-frequency signal given to the second terminal or the third terminal;
A second high frequency transmission line connected to the second terminal and transmitting a high frequency signal applied from the second terminal;
A high-frequency signal having fourth, fifth, and sixth terminals, outputting a high-frequency signal supplied to the fourth terminal via the second high-frequency transmission line to the fifth terminal, and supplied to the fifth terminal A duplexer that outputs to the sixth terminal;
A third high-frequency transmission line that is connected to the fifth terminal, transmits a high-frequency signal output from the fifth terminal, and transmits a high-frequency signal to the fifth terminal;
An antenna connected to the third high-frequency transmission line for radiating and capturing high-frequency signals;
A fourth high-frequency transmission line connected to the third terminal and transmitting a high-frequency signal output from the third terminal;
A fifth high-frequency transmission line connected to the sixth terminal and transmitting a high-frequency signal output from the sixth terminal;
A mixer that is connected to the fourth and fifth high-frequency transmission lines, mixes high-frequency signals given from the fourth and fifth high-frequency transmission lines, and outputs an intermediate frequency signal;
It is preferable that the high-frequency switch is inserted into at least one of the first to third transmission lines so that a high-frequency signal passes through the dielectric line when in the propagation state .

In the high frequency transmitter / receiver according to the present invention, the duplexer is preferably formed by a hybrid circuit or a circulator .

The radar apparatus of the present invention includes the high frequency transmitter / receiver,
It is preferable to include a distance detector that detects a distance from the high-frequency transmitter / receiver to the detection target based on an intermediate frequency signal from the high-frequency transmitter / receiver .

The array antenna apparatus of the present invention is preferably configured by arranging a plurality of antennas with phase shifters each having an antenna element and the phase shifter .

The radar device of the present invention includes the array antenna device,
It is preferable to include a high-frequency transmitter / receiver connected to the array antenna device, for supplying a high-frequency signal to the array antenna device, and receiving a high-frequency signal captured by the array antenna device .

According to the present invention, the dielectric line of the non-radiative dielectric line includes the changing portion whose dielectric constant changes according to the applied electric field, and an electric field can be applied to the changing portion by the electrode. The non-radiative dielectric line is an NRD guide. By applying an electric field to change unit, the changing unit dielectric constant changes in, or to change the electromagnetic wave phase propagating through the dielectric waveguide, or by changing the cut-off frequency, to attenuate electromagnetic waves propagating through the transmission line Can be. The electrode sandwiches the dielectric line in a direction perpendicular to the direction in which the dielectric line and the pair of flat plate conductors overlap, with a gap narrower than the gap between the pair of flat plate conductor parts, Since it is provided along the body line, it is possible to apply an electric field with a higher electric field strength than to apply a voltage to a pair of flat conductor portions and apply an electric field to the dielectric changing portion, and the dielectric constant of the changing portion it is possible to stably change. Even if the voltage applied to the electrodes to apply an electric field to the changing part is reduced, an electric field having a large electric field strength is applied to the changing part, and even if the transmission line length is short, an electric field having a large electric field strength is applied to the changing part. Therefore, it is possible to realize a dielectric waveguide device such as a phase shifter, a high-frequency switch, and an attenuator that is small and can be operated at a low voltage.

  A dielectric portion is provided on a surface portion of one of the pair of flat plate conductor portions on the side opposite to the dielectric line, and the side of the dielectric portion opposite to the flat plate conductor portion is provided. A strip conductor portion is provided on the surface portion. In the flat conductor part, a through hole is formed at a position where a part of the dielectric line and a part of the strip conductor part overlap each other, so that the electromagnetic wave propagating through the dielectric line is transmitted to the strip conductor part, the dielectric part and the dielectric part. It can couple | bond with the plane line formed including the flat conductor part in which a body part is provided, and can be propagated to this plane line. Since the dielectric part and the strip conductor part function as a surface mounting part, the dielectric part and the planar circuit board are formed by surface-mounting this part on a planar circuit board such as a printed circuit board. The transmission line can be suitably connected.

The Oite the present invention, a pair of electrodes is formed thinner than the skin depth for the electromagnetic wave propagating through the dielectric waveguide, provided on both sides of the dielectric waveguide which may sandwich the dielectric waveguide. In this case, since the electromagnetic wave propagating through the dielectric line can pass through the electrode, the electromagnetic wave can be propagated without being cut off, and transmission loss caused when the electrode is brought close to the dielectric line is reduced. In a suppressed state, an electric field having a large electric field strength can be applied to the dielectric change portion by the electrode.

The dielectric waveguide device of the present invention may have a characteristic that the phase change with respect to the frequency is large in the vicinity of the cutoff of the LSE mode propagating through the non-radiative dielectric line . If this characteristic is used, the phase of the LSE mode high-frequency signal propagating through the dielectric line can be greatly changed by the pair of electrodes sandwiching the dielectric line. Therefore, when a dielectric waveguide device is used as a phase shifter, a sufficient amount of phase change can be obtained with a low driving voltage even if the line length is short, so that it is small and good phase control is possible. A phase shifter is realized.

The Oite the present invention, a pair of electrodes may each be connected to different flat conductor section. In this case , the potential difference can be applied between the pair of electrodes only by applying a potential difference to the pair of flat conductor portions. Since the flat conductor portion also serves as a wiring for applying a potential to the electrode, it is not necessary to separately form a wiring for applying a potential to the electrode.

The Oite the present invention, the second dielectric portion, which may act as a support member for supporting the flat conductor section. In this case , the flat conductor portion can be manufactured using a thin film forming technique, a thick film printing technique, a sheet-like ceramic technique, or the like, and a dielectric waveguide device suitable for miniaturization is realized in manufacturing. be able to. The second dielectric portion has a dielectric constant lower than the dielectric constant of the portion having the lowest dielectric constant among the changed portions. That is, the second dielectric part has a dielectric constant of a part having the lowest dielectric constant among the changing parts when an electric field is applied to the changing part and when no electric field is applied to the changing part. Has a lower dielectric constant. Thereby, the wavelength of the electromagnetic wave propagating in the second dielectric part can be made smaller than the wavelength when the electromagnetic wave propagates through the air, and thereby the dielectric waveguide device can be miniaturized.

The dielectric waveguide device according to the present invention can be used as a dielectric waveguide device constituting a phase shifter. According to this transfer device, even if the voltage applied to the electrode to apply an electric field to the changing portion is reduced, an electric field having a large electric field strength is given to the changing portion, and even if the transmission line length is short, it is large. Since the phase change can be obtained, it is possible to realize a phase shifter that is small and can be operated at a low voltage. Moreover, since there is no mechanical drive part, a highly reliable phase shifter with excellent durability can be realized.

The dielectric waveguide device according to the present invention can be used as a dielectric waveguide device constituting a high-frequency switch. According to this high frequency switch, the cut-off frequency in the transmission line is lower than the frequency of the electromagnetic wave propagating through the dielectric portion, and the cut is higher than the frequency of the electromagnetic wave, depending on the electric field applied to the changing portion. Since the OFF state can be switched, the propagation state and the cutoff state can be easily switched by changing the voltage applied to the electrode. When the switching mode is in the OFF state, the cut-off state is entered, so that an essentially high ON / OFF ratio can be obtained. In addition, since there is no mechanical drive part, it is possible to realize a highly reliable high-frequency switch having excellent durability. Even if the voltage applied to the electrodes to apply an electric field to the changing part is reduced, an electric field having a large electric field strength is applied to the changing part, and even if the transmission line length is short, an electric field having a large electric field strength is applied to the changing part. Therefore, a high-frequency switch that is small and can be operated at a low voltage can be realized. In addition, since there is no mechanical drive part, it is possible to realize a highly reliable high-frequency switch having excellent durability.

The dielectric waveguide device according to the present invention can be used as a dielectric waveguide device constituting an attenuator. According to this attenuator, even if the voltage applied to the electrode to apply an electric field to the changing part is reduced, an electric field having a large electric field strength is given to the changing part, and even if the transmission line length is short, it is large. Since attenuation is obtained, an attenuator that is small and can be operated at a low voltage can be realized. Moreover, since there is no mechanical drive part, a highly reliable attenuator with excellent durability can be realized.

The dielectric waveguide device according to the present invention is a high-frequency transmitter including a transfer device that is inserted into a transmission line so that a high-frequency signal passes through the dielectric line, and is a dielectric waveguide device that constitutes the transfer device. Can be used. According to this high-frequency transmitter, a stub is provided in the middle of the high-frequency oscillator and the antenna so that mismatches in the connection portion of the high-frequency oscillator to the high-frequency transmission line and the connection portion of the antenna to the high-frequency transmission line can be matched. Therefore, reflection at the connection portion can be suppressed to be small, stable oscillation characteristics can be obtained, and insertion loss can be suppressed to a small value, so that a high transmission output can be obtained. However, it is not possible to achieve uniform matching due to, for example, variations in the shape of wires and bumps for connecting a high-frequency oscillator and variations in the wiring width of high-frequency transmission lines. In the present invention, the phase shifter is inserted into the high frequency transmission line so that the electromagnetic wave of the high frequency signal transmitted through the high frequency transmission line passes through the dielectric line. The phase shift caused by the high-frequency transmission line can be individually adjusted and matched due to variations in the shape of the wires and bumps and the wiring width of the high-frequency transmission line. Since the insertion loss is kept small, a high-frequency transmitter having a high transmission output can be realized. Further, since the phase shifter can be operated with a small size and a low voltage as described above, a high frequency transmitter can be formed in a small size even if a phase shifter is provided, and a voltage is applied to the phase shifter. Therefore, it is possible to suppress the complicated configuration.

The dielectric waveguide device according to the present invention is a high-frequency receiver including a transfer device that is inserted into a transmission line so that a high-frequency signal passes through the dielectric line, and is a dielectric waveguide device that constitutes the transfer device. Can be used. According to this high frequency receiver, the high frequency signal captured by the antenna is transmitted to the transmission line and detected by the high frequency detector. A stub is provided in the middle of the antenna and the high-frequency detector so that mismatching can be matched in the connection portion of the high-frequency detector to the high-frequency transmission line and the connection portion of the antenna to the high-frequency transmission line. As a result, reflection at the connecting portion can be suppressed to a small level, and stable detection characteristics can be obtained. Further, since the insertion loss is suppressed to a low level, a high detection output can be obtained. However, for example, it cannot be matched uniformly due to variations in the shapes of wires and bumps for connecting a high-frequency detector, variations in the wiring width of the high-frequency transmission line, and the like. In the present invention, the phase shifter is inserted into the high frequency transmission line so that the electromagnetic wave of the high frequency signal transmitted through the high frequency transmission line passes through the dielectric line. The phase shift caused by the high-frequency transmission line can be individually adjusted due to variations in the shape of the wires and bumps and the wiring width of the high-frequency transmission line. At the same time, since the insertion loss is kept small, a high-frequency receiver having a high detection output can be realized. In addition, since the phase shifter can be operated with a small voltage and a low voltage as described above, a high frequency receiver can be formed in a small size even if a phase shifter is provided, and a voltage is applied to the phase shifter. Therefore, it is possible to suppress the complicated configuration.

In addition, the dielectric waveguide device according to the present invention includes a high-frequency transceiver including a transfer device that is inserted into at least one of the first to fifth transmission lines so that a high-frequency signal passes through the dielectric line. In the above, it can be used as a dielectric waveguide device constituting the transfer device. According to this high frequency transmitter / receiver , the high frequency signal generated by the high frequency oscillator is transmitted to the first transmission line and given to the first terminal of the branching device, and given from the second terminal of the branching device to the second transmission line, The signal is given to the fourth terminal of the duplexer, is given to the third transmission line from the fifth terminal of the duplexer, and is radiated from the antenna. The high-frequency signal received by the antenna is given to the third transmission line, given to the fifth terminal of the duplexer, given from the sixth terminal of the duplexer to the fifth transmission line, and given to the mixer. . In addition, a high frequency signal generated by the high frequency oscillator is supplied as a local signal from the third terminal of the branching unit to the mixer via the fourth transmission line. The mixer mixes the high-frequency signal generated by the high-frequency oscillator and the high-frequency signal received by the antenna and outputs an intermediate frequency signal, thereby obtaining information contained in the received high-frequency signal.

  By inserting the phase shifter into at least one of the first to fifth transmission lines so that a high-frequency signal passes through the dielectric line, transmission is performed due to, for example, variations in wiring width. By adjusting the phase of the high-frequency signal that changes undesirably due to the line, for example, it is possible to realize a high-frequency transceiver with stable oscillation characteristics and high transmission output because the insertion loss is kept small In addition, for example, it has a stable oscillation characteristic, and the insertion loss can be suppressed to be small, so that a high frequency transmitter / receiver having a high detection output can be realized, and the reliability of the received high frequency signal can be improved. For example, the reliability of the intermediate frequency signal generated by the mixer can be improved. In addition, since the phase shifter can be operated with a small voltage and a low voltage as described above, a high frequency transmitter / receiver can be formed in a small size even if a phase shifter is provided, and a voltage is applied to the phase shifter Therefore, it is possible to suppress the complicated configuration.

Also, the dielectric waveguide device according to the present invention is inserted into the high-frequency transmission line, transmits a high-frequency signal transmitted to the high-frequency transmission line by setting the propagation state, and transmits to the high-frequency transmission line by setting the cutoff state. In a high-frequency transmitter including a high-frequency switch that cuts off a high-frequency signal that is generated, it can be used as a dielectric waveguide device that constitutes the high-frequency switch. According to this high-frequency transmitter, when the high-frequency switch is in a propagation state, the high-frequency signal generated by the high-frequency oscillator is transmitted through the high-frequency switch, so that it is transmitted through the high-frequency transmission line to the antenna and radiated as a radio wave. Further, when the high frequency switch is in the cut-off state, the high frequency signal generated by the high frequency oscillator does not pass through the high frequency switch, and therefore is cut off and is not radiated from the antenna. By switching the propagation state and cut-off state of the high-frequency switch, a pulse signal wave can be radiated from the antenna. A high-reliability high-frequency transmitter can be realized by using a high-reliability high-frequency switch with excellent durability and high ON / OFF ratio.

The dielectric waveguide device according to the present invention can be used as a dielectric waveguide device constituting each high frequency switch in a high frequency transmitter / receiver including a first high frequency switch and a second high frequency switch. According to this high frequency transmitter / receiver , the high frequency signal generated by the high frequency oscillator is transmitted to the first high frequency transmission line and given to the first terminal of the branching device, and given from the second terminal of the branching device to the second high frequency transmission line. The signal is given to the fourth terminal of the duplexer, given from the fifth terminal of the duplexer to the third high-frequency transmission line, and radiated from the antenna. The high-frequency signal received by the antenna is given to the third high-frequency transmission line, given to the fifth terminal of the duplexer, given from the sixth terminal of the duplexer to the fifth high-frequency transmission line, and sent to the mixer. Given. In addition, a high-frequency signal generated by the high-frequency oscillator is supplied as a local signal from the third terminal of the branching unit to the mixer via the fourth high-frequency transmission line. The mixer mixes the high-frequency signal generated by the high-frequency oscillator and the high-frequency signal received by the antenna and outputs an intermediate frequency signal, thereby obtaining information contained in the received high-frequency signal.

  The branching device includes two high-frequency switches, and the first high-frequency switch transmits the high-frequency signal between the first terminal and the second terminal by setting the propagation state, and sets the cutoff state. The high-frequency signal is cut off between the first terminal and the second terminal by the second high-frequency switch, and the second high-frequency switch transmits the high-frequency signal between the first terminal and the third terminal by setting the propagation state, and By setting the cut-off state, the high-frequency signal is blocked between the first terminal and the third terminal. When the first high-frequency switch is in the propagation state, the second high-frequency switch is set in the cut-off state, and when the first high-frequency switch is in the cut-off state, the second high-frequency switch is set in the propagation state. The high frequency signal can be selectively output from the second and third terminals. A high ON / OFF ratio can be obtained, and a high-frequency transmitter / receiver with high reliability can be realized by configuring a branching device using a high-reliability high-frequency switch having excellent durability.

The dielectric waveguide device according to the present invention can be used as a dielectric waveguide device constituting each high frequency switch in a high frequency transmitter / receiver including a third high frequency switch and a fourth high frequency switch. According to this high frequency transmitter / receiver , the high frequency signal generated by the high frequency oscillator is transmitted to the first high frequency transmission line and given to the first terminal of the branching device, and given from the second terminal of the branching device to the second high frequency transmission line. The signal is given to the fourth terminal of the duplexer, given from the fifth terminal of the duplexer to the third high-frequency transmission line, and radiated from the antenna. The high-frequency signal received by the antenna is given to the third high-frequency transmission line, given to the fifth terminal of the duplexer, given from the sixth terminal of the duplexer to the fifth high-frequency transmission line, and sent to the mixer. Given. In addition, a high-frequency signal generated by the high-frequency oscillator is supplied as a local signal from the third terminal of the branching unit to the mixer via the fourth high-frequency transmission line. The mixer mixes the high-frequency signal generated by the high-frequency oscillator and the high-frequency signal received by the antenna and outputs an intermediate frequency signal, thereby obtaining information contained in the received high-frequency signal. The duplexer includes two high-frequency switches, and the third high-frequency switch transmits the high-frequency signal between the fourth terminal and the fifth terminal by setting the propagation state, and the cutoff state The high frequency signal is cut off between the fourth terminal and the fifth terminal by doing, the fourth high frequency switch transmits the high frequency signal between the fifth terminal and the sixth terminal by being in the propagation state, And by setting it as the said cut-off state, a high frequency signal is interrupted | blocked between the said 5th terminal and the said 6th terminal. When the third high-frequency switch is in the propagation state, the fourth high-frequency switch is set in the cutoff state, and when the third high-frequency switch is in the cutoff state, the fourth high-frequency switch is set in the propagation state, thereby inputting from the fourth terminal. The high frequency signal to be output can be output from the fifth terminal, and the high frequency signal input from the fifth terminal can be output to the sixth terminal. A high ON / OFF ratio can be obtained, and a high-frequency transmitter / receiver with high reliability can be realized by configuring a branching device using a high-reliability high-frequency switch having excellent durability.

In addition, the dielectric waveguide device according to the present invention includes a high frequency switch inserted into at least one of the first to third transmission lines so that a high frequency signal passes through the dielectric line when in a propagation state. The high-frequency transmitter / receiver provided can be used as a dielectric waveguide device constituting the high-frequency switch. According to this high-frequency transmitter / receiver, the high-frequency signal generated by the high-frequency oscillator is set to the first state by setting all of the high-frequency switches inserted in at least one of the first to third high-frequency transmission lines to the propagation state. The signal is transmitted to the high frequency transmission line and supplied to the first terminal of the branching device, is supplied from the second terminal of the branching device to the second high frequency transmission line, and is supplied to the fourth terminal of the branching filter. The signal is given from the 5 terminals to the third high-frequency transmission line and radiated from the antenna. In addition, if even one of the high-frequency switches inserted into at least one of the first to third high-frequency transmission lines is cut off, the high-frequency signal generated by the high-frequency oscillator does not pass through the high-frequency switch. It is not radiated from the antenna. By switching the propagation state and cut-off state of the high-frequency switch, a pulse signal wave can be radiated from the antenna. A high-frequency transmitter / receiver with high reliability can be realized by using a high-reliability high-frequency switch excellent in durability and having a large ON / OFF ratio. The high-frequency signal received by the antenna is given to the third high-frequency transmission line, given to the fifth terminal of the duplexer, given from the sixth terminal of the duplexer to the fifth high-frequency transmission line, and sent to the mixer. Given. In addition, a high-frequency signal generated by the high-frequency oscillator is supplied as a local signal from the third terminal of the branching unit to the mixer via the fourth high-frequency transmission line. The mixer mixes the high-frequency signal generated by the high-frequency oscillator and the high-frequency signal received by the antenna and outputs an intermediate frequency signal, thereby obtaining information contained in the received high-frequency signal.

The dielectric waveguide device according to the present invention can be used as the above-described high-frequency transmitter / receiver, and as a dielectric waveguide device constituting a high-frequency transmitter / receiver in which a duplexer is formed by a hybrid circuit or a circulator. In this high-frequency transceiver, the duplexer may be formed by a hybrid circuit or a circulator. The hybrid circuit is a directional coupler and is realized by a magic T, a hybrid ring, or a rat race.

The dielectric waveguide device according to the present invention can be used as a dielectric waveguide device constituting the high-frequency transceiver in a radar apparatus including the high-frequency transceiver. According to this radar apparatus, since the distance detector detects the distance from the high-frequency transmitter / receiver to the detection target based on the intermediate frequency signal from the high-frequency transmitter / receiver, the distance to the detection target can be accurately detected. A radar device capable of

The dielectric waveguide device according to the present invention, the dielectric constituting the array antenna system constituted by arranging a plurality of antennas with the phase shifter formed by adding the phase shifter to the antenna element, the conveying device It can be used as a body waveguide device. According to this array antenna apparatus, by adjusting the phase of the radio wave radiated from each antenna element by shifting the phase of the high-frequency signal supplied to the antenna element by the phase shifter added to each antenna element, The radiation beam can be tilted in a predetermined direction from the front of the array antenna. Phase shifter, it is possible to operate with a small type and low voltage, have never array antenna apparatus is increased in size. In addition, the array antenna apparatus can change the direction of the radiation beam as described above by providing the phase shifter, thereby changing the direction of the radiation beam without mechanically operating the antenna element. It is possible to improve convenience.

The dielectric waveguide device according to the present invention includes the array antenna device, a high frequency signal connected to the array antenna device, a high frequency signal applied to the array antenna device, and a high frequency signal received by the array antenna device. in configured radar system and a transceiver, it can be used as a dielectric waveguide device constituting the array antenna device. According to this radar apparatus , the radar apparatus can be easily changed without increasing the size of the radar apparatus, and a highly convenient radar apparatus can be realized.

  FIG. 1 is a cross-sectional view schematically showing a configuration of a phase shifter 1 according to an embodiment of the present invention, and is a cross-sectional view taken along a cutting plane line II in FIG. FIG. 2 is a plan view of the phase shifter 1. FIG. 3 is a cross-sectional view taken along section line III-III in FIG.

  The phase shifter 1 includes a non-radiative dielectric line (NRD guide) 2, first and second electrodes 3 a and 3 b, and a mounting portion 4.

  The non-radiative dielectric line 2 includes a dielectric line 5 through which electromagnetic waves propagate and a pair of flat conductor parts 6a and 6b that sandwich the dielectric line 5, that is, are provided on both sides of the dielectric line 5. Is done. Hereinafter, the pair of flat plate conductor portions 6a and 6b are referred to as first and second flat plate conductor portions 6a and 6b, respectively.

  The dielectric line 5 extends in a predetermined direction. The dielectric line 5 has a rectangular cross section perpendicular to the extending direction X of the dielectric line 5. The cross-sectional shape of the dielectric line 5 may be slightly deviated from a perfect rectangle, but at least the surfaces in contact with the first and second plate conductor portions 6a and 6b are as flat as possible and have high parallelism. Is desirable. In the present embodiment, the dielectric line 5 is formed in a rectangular parallelepiped shape.

Dielectric waveguide 5 is made of a dielectric, permittivity is formed to include a change part that changes depending on the applied electric field. In the present embodiment, the dielectric line 5 includes a changing portion, for example, Ba _(1-x) Sr _x TiO ₃ (abbreviation BST), Mg _(1-x) Ca _x TiO ₃ , Zn _(1-x) Sn. _x TiO ₃ , BaO—PbO—Nd ₂ O ₃ —TiO ₃ , Bi _1.5 Zn _1.0 Nb _1.5 O ₇ , or the like. The dielectric line 5 has a lower dielectric constant as the applied electric field increases, that is, as the applied electric field strength increases.

The first and second flat plate conductor portions 6a and 6b are formed in a plate shape and are provided with a predetermined interval L1. In the present embodiment, the first and second flat plate conductor portions 6a and 6b are formed to have the same size, and are provided so that their thickness directions coincide and face each other. The surfaces of the first and second flat conductor portions 6a and 6b facing each other are formed in a plane. First and second plate conductor parts 6a, 6b are arranged parallel to as possible, is adhered first and second plate conductor parts 6a, the surfaces facing each other of 6b the dielectrics line 5 Is preferred.

Previously prescribed distance L1, the first and second flat conductor section 6a, the portion excluding the dielectrics line 5 Chi sac regions sandwiched 6b, the first and second plate conductor parts 6a, from among 6b, The electromagnetic wave polarized in parallel with the first and second flat plate conductor portions 6a and 6b is set to be blocked. Sunawa Chi, first and second plate conductor parts 6a, in portion excluding the dielectrics line 5 Chi sac regions sandwiched 6b, i.e. the wavelength of an electromagnetic wave propagating flat between dielectric portion 9 to be described later 2 It is chosen to be less than 1 / min.

The width of the dielectric line 5 is selected so that the cutoff frequency of the LSE mode is less than the frequency of the electromagnetic wave to be propagated , that is, the operating frequency. The dielectric line 5 is formed in a rectangular shape in which a cross section perpendicular to the extending direction X has a short side in contact with the first and second flat plate conductor portions 6a and 6b. The length L2 of the long side in the rectangular cross section of the dielectric line 5 is equal to the predetermined interval L1. The ratio of the length L2 of the long side to the length L3 of the short side in the rectangular cross section of the dielectric line 5 is reduced by decreasing the length L3 of the short side or increasing the length L2 of the long side. Thus, the LSM mode is increased until the LSM mode is cut off and only the LSE mode propagates. The ratio of the long side length L2 to the short side length L3 in the rectangular cross section of the dielectric line 5, ie, L 2 / L 3 is preferably made as large as possible to cut off the LSE mode. It is desirable to set to propagate in the vicinity.

The first and second flat plate conductors 6a and 6b are formed of a good conductor having a volume resistivity of 10 ⁻⁴ Ω · m or less, preferably 10 ⁻⁵ Ω · m or less. For example, gold (Au), copper (Cu ), Aluminum (Al), platinum (Pt), titanium (Ti), silver (Ag), palladium (Pd), zinc (Zn) and chromium (Cr), or the group An alloy containing at least two selected from the above or a laminate thereof, or ITO
It is formed of an oxide conductor such as (Indium Tin Oxide), tin oxide, iridium oxide, or SrRuO ₃ .

  The first and second flat plate conductor portions 6a and 6b are perpendicular to the extending direction X and the stacking direction Z in which the first and second flat plate conductor portions 6a and 6b and the dielectric line 5 are stacked. In the width direction Y, the dielectric line 5 extends from the end in the width direction Y to a position of a predetermined distance L4 outward. The predetermined distance L4 is selected to be larger than the length at which the electromagnetic wave attenuation becomes 1/10.

  The first and second flat plate conductor portions 6 a and 6 b extend from the first end face 8 in the extending direction X of the dielectric line 5 to a position of a predetermined distance L5 in the extending direction X. The predetermined distance L5 is selected to be larger than the length at which the attenuation of electromagnetic waves becomes 1/10.

  The first and second electrodes 3 a and 3 b are provided to apply an electric field to the changing portion, that is, to apply an electric field to the dielectric line 5. The first and second electrodes 3a and 3b are provided along the dielectric line 5, and are spaced in the width direction Y smaller than the distance L1 between the first and second plate conductor portions 6a and 6b. In this state, the dielectric line 5 is provided. The first and second electrodes 3 a and 3 b sandwich the dielectric line 5, and are provided on the both end surfaces of the dielectric line 5 in the width direction Y, respectively. The first and second electrodes 3a and 3b are formed to have a predetermined length L6 in the extending direction X. The predetermined length L6 is selected so as to obtain a necessary phase change.

  The first and second electrodes 3a and 3b are connected to different flat plate conductor portions 6a and 6b, respectively. In the present embodiment, the first electrode 3a is connected to the first flat plate conductor portion 6a, and the second electrode 3b is connected to the second flat plate conductor portion 6b. The first and second electrodes 3a and 3b have a rectangular parallelepiped shape and are formed in a plate shape.

  The first electrode 3a is provided in the stacking direction Z at a predetermined distance L7 from the second flat plate conductor portion 6b. Further, the second electrode 3b is provided in the stacking direction Z at a predetermined distance L7 from the first flat plate conductor portion 6a. The predetermined distance L7 is selected such that the first electrode 3a and the second flat plate conductor portion 6b are not in contact with each other, and the second electrode 3b and the first flat plate conductor portion 6a are not in contact with each other. It is selected from 1 μm to 100 μm.

  The first and second electrodes 3a and 3b are made of the same material as the first and second flat plate conductors 6a and 6b described above, or silicon (Si), germanium (Ge) and gallium arsenide (GaAs). ) Or a high resistance material such as tantalum nitride and NiCr alloy.

  The thickness L8 of the first and second electrodes 3a and 3b is selected to be less than the skin thickness with respect to the electromagnetic wave to be propagated through the dielectric line 5. When the skin thickness is “δ”, the magnetic permeability is “μ”, the electrical conductivity is “σ”, and the angular frequency is “ω”, the skin thickness is expressed by Equation (1). Note that ω = 2πf (f is a frequency). When electromagnetic waves enter the conductor, the amplitude becomes 1 / e at the skin thickness.

  Thereby, even if the first and second electrodes 3a and 3b are provided in contact with the dielectric line 5, the electromagnetic wave propagating through the dielectric line 5 can pass through the first and second electrodes 3a and 3b. Therefore, the first and second electromagnetic waves can be propagated without being cut off, and the first and second electrodes can be transmitted in a state in which transmission loss caused when the first and second electrodes 3a and 3b are brought close to the dielectric line 5 is suppressed. An electric field having a large electric field strength can be applied to the dielectric line 5 by the electrodes 3a and 3b, and the phase of the electromagnetic wave can be changed stably. Since the phase shifter 1 has a characteristic that the phase change with respect to the frequency is large in the vicinity of the cutoff of the LSE mode propagating through the non-radiative dielectric line 2, if this characteristic is used, the phase shifter 1 is provided on both sides of the dielectric line 5. The phase of the LSE mode high-frequency signal propagating through the dielectric line 5 can be greatly changed by the first and second electrodes 3 a and 3 b sandwiching the dielectric line 5. Therefore, since a sufficient amount of phase change can be obtained with a low drive voltage even if the line length is short, a small phase shifter capable of good phase control is realized.

The volume resistivity of the first and second electrodes 3a and 3b in the present embodiment is selected to be 10 ⁻⁵ Ω · m or more, preferably 10 ⁻⁴ Ω · m or more. However, if the first and second electrodes 3a and 3b are made too thin, electric charges are difficult to move in the first and second electrodes 3a and 3b, and an electric field is uniformly distributed between the first and second electrodes 3a and 3b. since hardly takes, the first and second electrodes 3a, 3b, these first and second electrodes 3a, without hindering the movement of charge in 3b, the first and second electrodes 3a, between 3b It is formed to have a predetermined thickness or more so that an electric field can be uniformly applied throughout.

The resistivity of the first and second electrodes 3a and 3b is preferably selected to be 10 ⁻⁵ Ω · m or more and 10 ⁸ Ω · m or less. When the resistivity of the first and second electrodes 3a and 3b is less than 10 ⁻⁵ Ω · m, the electromagnetic wave in the electrode is greatly attenuated and loss is increased, which is not preferable. If the resistivity of the first and second electrodes 3a and 3b is further smaller than 10 ⁻⁵ Ω · m, the desired mode is cut off and does not propagate. Conversely, if the resistivity of the first and second electrodes 3a, 3b exceeds 10 ⁸ Ω · m and becomes too large, the difference in resistivity with the dielectric sandwiched between the first and second electrodes 3a, 3b is small. Therefore, a desired voltage cannot be applied to the dielectric due to the voltage drop.

The thickness of the first and second electrodes 3a and 3b is determined by the resistivity of the material used for the first and second electrodes 3a and 3b. If the thickness is too thick, the loss increases, and if the thickness is further increased, the desired mode is cut off. Will not be transmitted. If it is too thin, a desired voltage cannot be applied to the dielectric due to a voltage drop. For example, the first and second electrodes 3a and 3b have a resistivity of 1 × 10 ⁻⁴ (Ω · m) (assuming TaN is used as the material) and a resistivity of 1 × 10 ⁻³ (Ω · m). Table 1 shows the loss due to the electrode per 1 mm with respect to the electromagnetic wave of 77 GHz when the electromagnetic field analysis is performed.

From the results of electromagnetic field analysis shown in Table 1 and Table 2, it is preferable that the electrode has a resistivity of 1 × 10 ⁻⁴ (Ω · m) and the electrode thickness is practically 30 nm or less. Is practically preferable to be 320 nm or less of the electrode in the case where the resistivity is 1 × 10 ⁻³ (Ω · m). Here, the standard that is practically preferable is 3 dB loss.

The non-radiative dielectric line 2 is provided between the first and second flat plate conductor portions 6a and 6b, sandwiches the dielectric line 5 and the first and second electrodes 3a and 3b, and the dielectric line 5 and the first The inter-plate dielectric part 9 which is a 2nd dielectric part provided on both sides of 1 and 2nd electrode 3a, 3b is comprised. The inter-plate dielectric portion 9 is formed of a dielectric having a low dielectric constant, and is formed of glass, single crystal, ceramics, or resin. As glass, quartz glass, crystallized glass, or the like is used. As the single crystal, quartz, sapphire, MgO, LaAlO ₃ or the like is used. As the ceramic, alumina, forsterite, cordierite, or the like is used. As the resin, an epoxy resin, a fluorine-containing resin, a liquid crystal polymer, or the like is used.

  The inter-plate dielectric portion 9 is formed between the first and second flat conductor portions 6a and 6b on both sides of the dielectric line 5 in the width direction Y and the first end face 8 in the extending direction X of the dielectric line 5. Of the regions provided outside and sandwiched between the first and second flat plate conductor portions 6a and 6b, the remaining regions excluding the region where the dielectric line 5 and the first and second electrodes 3a and 3b are formed It is provided buried.

The inter-plate dielectric part 9 has a dielectric constant lower than that of the dielectric line 5. The inter-plate dielectric portion 9 has the highest dielectric constant among the dielectric lines 5 when an electric field is applied to the dielectric line 5 and when no electric field is applied to the dielectric line 5. Has a lower dielectric constant than the dielectric constant of the lower portion. The inter-plate dielectric portion 9 is provided in contact with the first and second flat conductor portions 6a and 6b , the dielectric line 5 , and the first and second electrodes 3a and 3b. By providing the inter-plate dielectric part 9, the wavelength of the electromagnetic wave propagating in the part excluding the dielectric line 5 among the parts sandwiched between the first and second flat conductor parts 6a and 6b is changed to the wavelength in the air. it can be shortened as compared with, whereby the nonradiative dielectric line 2 can be formed in a small mold. In addition, since the first and second flat conductor portions 6a and 6b are mechanically supported by the inter-plate dielectric portion 9, the mechanical strength can be improved.

  The mounting portion 4 includes a mounting dielectric portion 11 that is a dielectric portion, a strip conductor portion 12, a ground conductor portion 13, and a through conductor portion 14.

  The mounting dielectric part 11 is the opposite side of the first flat conductor part 6a from the dielectric line 5, that is, the opposite side of the first flat conductor part 6a from the second flat conductor part 6b in the stacking direction Z. Is provided on the front surface portion 15. The mounting dielectric portion 11 is provided so as to be laminated on the surface portion 15 and is formed over the entire area of the surface portion 15.

The mounting dielectric part 11 is formed in a rectangular parallelepiped shape. As the material of the mounting dielectric part 11, a material having high insulation and a small dielectric loss tangent to a high frequency signal is suitable. The mounting dielectric part 11 is formed of, for example, silicon dioxide (SiO ₂ ), alumina (Al ₂ O ₃ ), aluminum nitride (AlN), magnesium oxide (MgO), or the like. The mounting dielectric portion 11 is formed to a predetermined thickness L9.

  The strip conductor portion 12 is provided on the surface portion 16 of the mounting dielectric portion 11 opposite to the first flat plate conductor portion 6a. The strip conductor portion 12 is provided by being laminated on the surface portion 16, and is formed over the entire area of the surface portion 16.

  The strip conductor portion 12 is formed in a rectangular parallelepiped shape. The strip conductor portion 12 is formed of the same material as the above-described inter-plate dielectric portion 9 described above.

  The strip conductor portion 12 is provided so as to partially overlap the dielectric line 5 in the stacking direction Z. The strip conductor portion 12 extends in parallel with the extending direction X. The strip conductor portion 12 is formed to a predetermined thickness L10. The length L11 in the width direction Y of the strip conductor portion 12 is selected so that the matching state with a high-frequency signal in a through hole 19 described later is good. In the case of a two-port circuit, the matching state means that the reflection is small and the transmission amount is secured. In a 1-port circuit, the reflection is small. Quantitatively, if reflection is −10 dB or less, about 90% of the transmitted electromagnetic wave does not return, so it can be said that the matching state is good. Further, bumps used for surface mounting can be mounted, that is, selected so that the bumps do not protrude from the strip conductor portion 12 when the bumps are mounted on the strip conductor portion 12.

  The strip conductor portion 12 is provided so that the first end portion 17 in the extending direction X overlaps the first end portion 18 in the extending direction X of the dielectric line 5. The first end portion 17 of the strip conductor portion 12 and the first end portion 18 of the dielectric line 5 are formed to overlap with a predetermined length L12 in the extending direction X.

  A through hole 19 is formed in the first flat conductor portion 6a at a position where the first end portion 18 of the dielectric line 5 and the first end portion 17 of the strip conductor portion 12 overlap. The through hole 19 is formed so as to penetrate the first flat plate conductor portion 6a in the stacking direction Z. The through hole 19 is formed such that a cross section perpendicular to the stacking direction Z of the inner peripheral surface 21 of the first flat plate conductor portion 6a facing the through hole 19 is rectangular. The inner peripheral surface 21 is parallel to the width direction Y or the extending direction X. The through hole 19 is formed in a portion where the electric field of the standing wave in the LSE mode is maximized.

  Further, the through hole 19 constitutes a coupling portion for coupling a high frequency signal between the non-radiative dielectric line 2 and the microstrip line including the strip conductor portion 12. The non-radiative dielectric line 2 is formed at a position where the electric field of the standing wave in the LSE mode is maximized. In the connection part between the non-radiative dielectric line 2 and the microstrip line including the strip conductor part 12, as viewed from the high-frequency signal input port of the microstrip line having the strip conductor part 12, the non-radiative dielectric line from the through hole 19. A structure with good matching with a high-frequency signal in the propagation characteristic to 2 is desirable, and the reflection characteristic is −10 dB or less, and it is desirable to have a structure that can suppress the connection loss as low as possible. For this reason, between the virtual plane that is perpendicular to the extending direction X and includes the central axis extending in the stacking direction Z of the through hole 19 and the end face of the first end 18 that is the open end of the dielectric line 5. The distance L13 is selected to be (2n-1) / 4 (n is a natural number) of the wavelength of the electromagnetic wave propagating through the non-radiative dielectric line 2. Further, between a virtual plane that is perpendicular to the extending direction X and includes a central axis extending in the stacking direction Z of the through-hole 19, and an end surface of the first end portion 17 that is an open end of the strip conductor portion 12. The distance L14 is selected to be (2m-1) / 4 (m is a natural number) of the wavelength of the electromagnetic wave propagating between the strip conductor portion 12 and the first flat conductor portion 6a. The length L12 is selected as a value obtained by adding the distance L13 and the distance L14. In this way, by selecting the distance L13 and the distance L14, the reflected wave is reflected at the junction between the non-radiative dielectric line 2 and the microstrip line formed by the strip conductor part 12 and the mounting dielectric part 11. Can be canceled out and connection loss can be reduced.

  The inner dimension L15 in the extending direction X of the inner peripheral surface 21 facing the through hole 19 and the inner dimension L16 in the width direction Y are determined so that the input impedance viewed from the strip conductor can be matched. The

  In FIG. 2, the configuration at the first end portion in the extending direction X of the non-radiative dielectric line 2 is shown, but the same penetration is also performed at the second end portion in the extending direction X of the non-radiative dielectric line 2. A hole 19 is formed, and the mounting portion 4 is provided. As a result, the high frequency signal to be phase-controlled from the strip conductor portion 12 on the input side is coupled to the dielectric line 5 of the non-radiative dielectric line 2 and the phase of the high frequency signal is propagated through the dielectric line 5. , The phase-controlled high-frequency signal is coupled to the output-side strip conductor portion 12, and the phase-controlled high-frequency signal is extracted from the output-side strip conductor portion 12.

  The ground conductor portion 13 is provided at a predetermined distance L17 on both sides in the width direction Y of the strip conductor portion 12, and is separated from the first end portion 17 of the strip conductor portion 12 by a predetermined distance L18. Formed. The mounting portion 4 functions as a high-frequency signal transmission line between the strip conductor portion 12, the ground conductor portion 13, and the first flat conductor portion 6a. For this reason, the thickness L9 of the mounting dielectric part 11, the thickness L10 of the strip conductor part 12, the predetermined distance L17, the predetermined distance L18, and the dielectric constant of the mounting dielectric part 11 are the specific impedance of the nonradiative dielectric line 2. So that the characteristic impedance is set in advance. Of the ground conductor portion 13, portions formed on both sides in the width direction Y of the strip conductor portion 12 are formed in parallel to the strip conductor portion 12. Of the ground conductor portion 13, portions formed on both sides in the width direction Y of the strip conductor portion 12 are formed over the end portion in the width direction Y of the mounting dielectric portion 11. The length of the ground conductor portion 13 in the stacking direction Z is selected to be equal to the length L10 of the strip conductor portion 12 in the stacking direction Z.

The through conductor portion 14 is provided so as to penetrate the mounting dielectric portion 11 in the stacking direction Z. Through conductor portion 14 is formed by the same material as the flat plate between the dielectric part 9 which is pre-mentioned. The through conductor portion 14 electrically connects the strip conductor portion 12 and the ground conductor portion 13. A plurality of through conductor portions 14 are provided, and are connected to the center in the width direction Y of the portions of the ground conductor portion 13 formed on both sides in the width direction Y of the strip conductor portion 12 and extend in the stacking direction Z. Since the ground conductor portion 13 and the flat conductor portion 6a can be electrically connected by the through conductor portion 14, when the phase shifter 1 is mounted on a planar circuit board such as a printed circuit board, the ground conductor portion A potential can be applied to the first electrode 3 a via 13. This eliminates the need for a wiring for separately connecting the first electrode 3a to the wiring provided on the substrate, so that the mountability can be improved.

  The phase shifter 1 is mounted on the planar circuit board via bumps or the like with the ground conductor part 13 and the strip conductor part 12 facing the planar circuit board. The ground conductor portion 13 and the through conductor portion 14 function as a ground conductor for the strip conductor portion 12 and also function as one terminal for applying a voltage to the first and second electrodes 3a and 3b. By providing the ground conductor portion 13 and the through conductor portion 14, one terminal to which a voltage is applied for phase control is easily connected to a wiring formed on a planar circuit board to be surface-mounted via a bump or the like. be able to. In the surface-mounted state, the second flat conductor portion 6b that is separated from the planar circuit board functions as the other terminal for applying a voltage for phase control. The second flat conductor portion 6b is connected to the wiring on the planar circuit board by a bonding wire or the like.

  The phase shifter 1 further includes a voltage applying unit 23. The voltage applying means 23 is realized by an electric circuit that applies a voltage in a predetermined range between the pair of first and second electrodes 3a and 3b. The voltage applying means 23 is electrically connected to the ground conductor portion 13 and the second flat plate conductor portion 6b, and applies a predetermined potential to the ground conductor portion 13 and the second flat plate conductor portion 6b. A voltage can be applied between the second electrodes 3a and 3b. The potential applied to the ground conductor portion 13 is a ground potential. Thus, an electric field is applied to the dielectric line 5 sandwiched between the first and second electrodes 3a and 3b. The voltage applying unit 23 includes, for example, a voltage divider, and applies the voltage divided by the voltage divider to the first and second electrodes 3a and 3b. The voltage applying means 23 can apply a plurality of levels of voltages to the ground conductor portion 13 and the second flat plate conductor portion 6b. The voltage applying means 23 applies an AC voltage having a frequency lower than the frequency of the propagating electromagnetic wave or a DC voltage to the ground conductor portion 13 and the second flat conductor portion 6b. The voltage applying means 23 applies a voltage corresponding to the phase amount to be shifted to the ground conductor portion 13 and the second flat conductor portion 6b.

  The voltage application means 23 applies a voltage between the first and second electrodes 3a and 3b, and changes the magnitude of the applied voltage within a predetermined range, thereby allowing the phase of the electromagnetic wave guided through the dielectric line 5 to vary. Can be changed according to the magnitude of the applied voltage, that is, the magnitude of the applied electric field. The dielectric forming the dielectric line 5 has a lower dielectric constant when the applied electric field is increased, and thereby the phase of the electromagnetic wave guided through the dielectric line 5 can be changed.

The cutoff frequency fc of the non-radiative dielectric line 2 in the phase shifter 1 is the dielectric constant of the dielectric forming the dielectric line 5 and the size of the dielectric line 5 (cross-sectional dimension perpendicular to the extending direction X). The distance (L3) between the first and second electrodes 3a and 3b, the distance L1 between the first and second flat plate conductor portions 6a and 6b, and the dielectric constant of the dielectric forming the inter-plate dielectric portion 9 are determined. The size of the dielectric line 5 is selected so that the cut-off frequency is less than the frequency (use frequency) of the electromagnetic wave to be propagated. The cutoff frequency when a predetermined voltage is applied to the first and second electrodes 3a and 3b to reduce the dielectric constant of the dielectric line 5 is fc, and the operating frequency, that is, the electromagnetic wave propagating through the dielectric line 5 is transmitted. When the frequency is f, 1.03 <f / fc <1.5, preferably 1.03 <f / fc <1.2. The distance (L3) between the second electrodes 3a and 3b, the distance L1 between the first and second flat plate conductor portions 6a and 6b , and the dielectric constant of the dielectric forming the inter-plate dielectric portion 9 are set. When the phase shifter 1 is manufactured, first, the dielectric that forms the dielectric line 5 and the inter-plate dielectric portion 9 is determined, and then the size of the dielectric line 5 is determined. An interval L4 between the second electrodes 3a and 3b is determined, and finally an interval L1 between the first and second flat conductor portions 6a and 6b is determined.

Or the phase shifter 1 is as can be formed in a small mold, it is possible to perform phase control well, and a mounting dielectric portion 11, the planar circuit mounting portion 4 and a strip conductor portion 12 By surface mounting on the substrate, the phase shifter 1 and the transmission line formed on the planar circuit board can be suitably connected. Further, since the inter-plate dielectric portion 9 functions as a support member for supporting the first and second flat plate conductor portions 6a and 6b, the first and second flat plate conductor portions 6a and 6b are formed into a thin film forming technique and a thick film printing technique. Alternatively, the phase shifter 1 can be manufactured by using a sheet-like ceramic technique, and the phase shifter 1 suitable for miniaturization can be realized in the manufacturing.

In another embodiment of the present invention, in the phase shifter 1 described above, the first and second electrodes 3 a and 3 b may be embedded in the dielectric line 5. The first and second electrodes 3 a and 3 b are provided so that an electric field can be applied to the dielectric line 5. The thicknesses of the first and second electrodes 3 a and 3 b are selected to be less than the skin thickness with respect to the electromagnetic wave propagating through the dielectric line 5. Accordingly, when the first and second electrodes 3a and 3b are embedded in the dielectric line 5, loss due to the first and second electrodes 3a and 3b can be reduced. Even with such a configuration, the same effect as that of the phase shifter 1 can be achieved, and the first and second electrodes 3a and 3b are provided closer to each other than the phase shifter 1 described above. Therefore, the switch can be driven with a lower voltage. The volume resistivity of the first and second electrodes 3a and 3b in the present embodiment is selected to be 10 ⁻⁵ Ω · m or more, preferably 10 ⁻⁴ Ω · m or more.

  When the first and second electrodes 3a and 3b are embedded in the dielectric line 5, the plurality of first and second electrodes 3a and 3b are separated from the first electrode 3a by a predetermined interval in the width direction Y. The second electrodes 3b may be formed so as to be alternately stacked in the width direction Y. Each first electrode 3a is connected to the first flat plate conductor portion 6a, and each second electrode 3b is connected to the second flat plate conductor portion 6b.

Increasing the number of the first electrodes 3a and the second electrodes 3b is preferable because the applied electric field strength increases, so that the switch can be operated at a lower voltage. However, the first electrode 3a and the second electrode 3b are preferred. Increasing the number increases the loss. When the electrodes are stacked, the loss is determined by the total thickness of the electrodes. In the case where the resistivity of the electrode is 1 × 10 ⁻⁴ (Ω · m), it is practically preferable that the total thickness of the electrodes is 30 nm or less, and the resistivity of the electrode is 1 × 10 ⁻³ (Ω · m). In the case of m), it is practically preferable that the total thickness of the electrodes is 320 nm or less.

  In the phase shifter 1 of the above-described embodiment, the dielectric line 5 is made of a material whose dielectric constant changes. In still another embodiment of the present invention, the dielectric line 5 has a dielectric constant that changes. What is necessary is just the structure containing the change part which consists of a substance to do. The changing portion is preferably formed in a portion where the electric field strength is high, for example, in the central portion in the width direction Y and the thickness direction Z. With such a configuration, it is obtained when a phase shifter is manufactured with the same size according to the ratio of the changed portion in the dielectric line 5 and the region of the dielectric line 5 where the changed portion is formed. The phase change amount is determined, and the phase change amount is smaller than that in the case where the entire dielectric line 5 is made of a material whose dielectric constant changes, but a small phase shifter is provided as in the above-described embodiment. can do.

FIG. 4 is a schematic diagram showing a configuration of the high-frequency transmitter 60 according to the embodiment of the present invention. The high frequency transmitter 60 includes the phase shifter 1 of the embodiment shown in FIG. 1 described above, a high frequency oscillator 61, a transmission line 62, a transmission antenna 63, and a stub 64. The high-frequency oscillator 61 is a Gunn oscillator using a Gunn diode, an Impat oscillator using an Impat diode, or an MMIC (FET) (Field Effect Transistor).
Microwave Monolithic Integrated Circuit) Generates high frequency signals. The transmission line 62 is configured by a microstrip line, a strip line, or a coplanar line. A first end 62 a of the transmission line 62 in the transmission direction of the high frequency signal is connected to the high frequency oscillator 61, and a second end 62 b of the transmission line 62 in the transmission direction of the high frequency signal is connected to the transmitting antenna 63. The transmitting antenna 63 is realized by a patch antenna or a horn antenna. The transmission direction of the high frequency signal is the propagation direction of the electromagnetic wave.

  The phase shifter 1 is inserted into the transmission line 62 so that the high-frequency signal passes through the dielectric line 5. The stub 64 is realized by an open stub, for example, and functions as a characteristic adjustment circuit of the high-frequency oscillator 61. The stub 64 is provided on the transmission line 62 on at least one of the upstream side and the downstream side of the phase shifter 1 in the high-frequency signal transmission direction.

  More specifically, the transmission line 62 includes first and second transmission lines 68 and 69. A first end 68 a of the first transmission line 68 in the high-frequency signal transmission direction is connected to the high-frequency oscillator 61, and a second end 68 b of the first transmission line 68 in the high-frequency signal transmission direction is connected to the phase shifter 1. Connected to the first input / output terminal 2a. The first end 69a of the second transmission line 69 in the high-frequency signal transmission direction is connected to the second input / output terminal 2b of the phase shifter 1, and the second end of the second transmission line 69 in the high-frequency signal transmission direction. 69 b is connected to the transmitting antenna 63.

  A high frequency signal generated by the high frequency oscillator 61 passes through the first transmission line 68, the dielectric line 5 of the phase shifter 1, and the second transmission line 69, and is given to the transmission antenna 63. As radiated.

  In the high-frequency transmitter 60, a stub 64 is provided in the middle of the high-frequency oscillator 61 and the transmission antenna 63, and there is no connection between the connection portion of the high-frequency oscillator 61 to the transmission line 62 and the connection portion of the transmission antenna 63 to the transmission line 62. Alignment can be matched. As a result, reflection at the connection portion can be suppressed to be small, stable oscillation characteristics can be obtained, and insertion loss can be suppressed to be small, so that a high transmission output can be obtained. However, even if the stub 64 is provided, it cannot be uniformly matched due to, for example, variations in the shape of wires and / or bumps for connecting a high-frequency oscillator and variations in the wiring width of the transmission line 62. In the high-frequency transmitter 60, the phase shifter 1 is inserted into the transmission line 62 so that the electromagnetic wave of the high-frequency signal transmitted through the transmission line 62 passes through the dielectric line 5. The phase shift caused by the transmission line 62 due to variations in the shape of the wires and / or bumps and the wiring width of the transmission line, etc. can be individually adjusted to achieve matching and stable oscillation A high-frequency transmitter 60 having characteristics and a high transmission output can be realized because the insertion loss is suppressed to be small. Since the phase shifter 1 is small and can be operated at a low voltage as described above, the high-frequency transmitter 60 can be made small even if the phase shifter 1 is provided. It is possible to prevent the configuration for applying a voltage from becoming complicated.

  In the high-frequency transmitter 60, the phase shifter 1 is used, but any one of the phase shifters of the above-described embodiments may be used. Even if comprised in this way, the same effect can be achieved. In the high-frequency transmitter 60, the transmission line 62 may be realized by a coplanar line, a grounded coplanar line, a slot line, a waveguide, a dielectric waveguide, or the like, in addition to the microstrip line and the strip line. .

  FIG. 5 is a schematic diagram showing the configuration of the high-frequency receiver 70 according to the embodiment of the present invention. Components similar to those of the high-frequency transmitter 60 of the above-described embodiment shown in FIG. 5 are denoted by the same reference numerals and description thereof may be omitted.

  The high frequency receiver 70 includes the phase shifter 1 of the above-described embodiment, the high frequency detector 71, the transmission line 62, the stub 64, and the receiving antenna 73. The high-frequency detector 71 is realized by, for example, a Schottky barrier diode detector, a video detector, a mixer MMIC, or the like.

  A first end 62 a of the transmission line 62 in the transmission direction of the high frequency signal is connected to the high frequency detector 71, and a second end 62 b of the transmission line 62 in the transmission direction of the high frequency signal is connected to the receiving antenna 73. . The receiving antenna 73 is realized by a patch antenna or a horn antenna.

  The phase shifter 1 is inserted into the transmission line 62 so that the high-frequency signal passes through the dielectric line 5. The stub 64 is provided on the transmission line 62 on at least one of the upstream side and the downstream side of the phase shifter 1 in the high-frequency signal transmission direction.

  When a radio wave arriving from the outside is captured by the reception antenna 73, the reception antenna 73 gives a high-frequency signal based on the radio wave to the transmission line 62, passes through the dielectric line 5 of the phase shifter 1, and passes to the high-frequency detector 71. A received high frequency signal is provided. The high frequency detector 71 detects a high frequency signal and detects information included in the high frequency signal.

  In the high frequency receiver 70, the high frequency signal captured by the receiving antenna 73 is transmitted to the transmission line 62 and detected by the high frequency detector 71. A stub 64 is provided in the middle of the receiving antenna 73 and the high-frequency detector 71, and mismatching at the connection portion of the high-frequency detector 71 to the transmission line 62 and the connection portion of the receiving antenna 73 to the transmission line 62 can be matched. It is like that. As a result, reflection at the connection portion can be suppressed to a small level, and stable detection characteristics can be obtained. Further, since the insertion loss is suppressed to a low level, a high detection output can be obtained. Even if the stub is provided, it cannot be uniformly matched due to, for example, variations in the shape of wires and / or bumps for connecting the high-frequency oscillator and variations in the wiring width of the transmission line 62. In the high frequency receiver 70, the phase shifter 1 is inserted into the transmission line 62 so that the electromagnetic wave of the high frequency signal transmitted through the transmission line 62 passes through the dielectric line 5. The phase shift caused by the transmission line 62 due to variations in the shape of wires and / or bumps for connecting 71 and variations in the wiring width of the transmission line can be individually adjusted to achieve matching. The high-frequency receiver 70 having a stable detection characteristic and a high detection output can be realized because the insertion loss is suppressed to a low level. Further, since the phase shifter 1 is small and can be operated at a low voltage as described above, the high-frequency receiver 70 can be made small even if the phase shifter 1 is provided. It is possible to prevent the configuration for applying a voltage from becoming complicated.

  In the high-frequency receiver 70, the phase shifter 1 is used, but any one of the phase shifters of the above-described embodiments may be used instead of the phase shifter. Even if comprised in this way, the same effect can be achieved. In the high-frequency receiver 70, the transmission line 62 may be realized by a coplanar line, a grounded coplanar line, a slot line, a waveguide, a dielectric waveguide, or the like, in addition to the microstrip line and the strip line. .

  FIG. 6 is a schematic diagram illustrating a configuration of a radar apparatus 90 including the high-frequency transmitter / receiver 80 according to the embodiment of this invention. In the radar apparatus 90, the same reference numerals are given to the same components as those of the high-frequency transmitter 60 and the high-frequency receiver 70 of the above-described embodiment shown in FIGS. 4 and 5, and the description thereof may be omitted. is there. The radar device 90 includes a high frequency transmitter / receiver 80 and a distance detector 91.

  The high frequency transmitter / receiver 80 includes the phase shifter 1 of the above-described embodiment, the high frequency oscillator 61, the first to fifth transmission lines 81, 82, 83, 84, 85, the branching device 86, and the branching filter 87. A transmission / reception antenna 88, a mixer 89, and a stub 64. The transmission / reception antenna 88 is realized by a patch antenna or a horn antenna. The first to fifth transmission lines 81, 82, 83, 84, 85 have the same configuration as the transmission line 62 described above.

  The first end 81 a of the first transmission line 81 in the high-frequency signal transmission direction is connected to the high-frequency oscillator 61, and the second end 81 b of the first transmission line 81 in the high-frequency signal transmission direction is connected to the branching device 86. Is done. The phase shifter 1 is inserted into the first transmission line 81 so that the high-frequency signal passes through the dielectric line 5. The stub 64 is provided in the first transmission line 81 on at least one of the upstream side and the downstream side of the phase shifter 1 in the high-frequency signal transmission direction.

  The branching device (switching device) 86 has first, second, and third terminals 86a, 86b, 86c, and a high-frequency signal applied to the first terminal 86a is selectively applied to the second terminal 86b and the third terminal 86c. Output to. The branching device 86 is realized by, for example, a high frequency switching element. The branching device 86 is supplied with a control signal from a control unit (not shown), and selectively connects the first terminal 86a and the second terminal 86b or the first terminal 86a and the third terminal 86c based on the control signal. The radar device 90 is realized by a pulse radar. The control unit connects the first terminal 86a and the second terminal 86b, outputs a pulsed high-frequency signal from the second terminal 86b, and then connects the first terminal 86a and the third terminal 86c, A signal is output from the third terminal 86c. A first end 82a of the second transmission line 82 in the transmission direction of the high-frequency signal is connected to the second terminal 86b. A first end 84a of the fourth transmission line 84 in the transmission direction of the high frequency signal is connected to the third terminal 86c.

  The duplexer 87 has fourth, fifth and sixth terminals 87a, 87b and 87c, outputs a high frequency signal applied to the fourth terminal 87a to the fifth terminal 87b, and provides a high frequency signal applied to the fifth terminal 87b. The signal is output to the sixth terminal 87c. A second end 82b of the second transmission line 82 in the transmission direction of the high frequency signal is connected to the fourth terminal 87a. A first end 83a of the third transmission line 83 in the transmission direction of the high frequency signal is connected to the fifth terminal 87b. The second end 83 b of the third transmission line 83 in the transmission direction of the high frequency signal is connected to the transmission / reception antenna 88.

  A first end 85a of the fifth transmission line 85 in the transmission direction of the high frequency signal is connected to the sixth terminal 87c. The second end portion 84 b of the fourth transmission line 84 in the high-frequency signal transmission direction and the second end portion 85 b of the fifth transmission line 85 in the high-frequency signal transmission direction are connected to the mixer 89. The duplexer 87 is realized by a hybrid circuit. The hybrid circuit is a directional coupler and is realized by a magic T, a hybrid ring, or a rat race.

The high-frequency signal generated by the high-frequency oscillator 61 passes through the first transmission line 81 and the dielectric line 5 of the phase shifter 1, and passes through the branching device 86, the second transmission line 82, the duplexer 87 , and the third transmission line. The signal is given to the transmission / reception antenna 88 via 82 and radiated as a radio wave from the transmission / reception antenna 88. Further, the high-frequency signal generated by the high-frequency oscillator 61 passes through the first transmission line 81 and the dielectric line 5 of the phase shifter 1 and is supplied as a local signal to the mixer 89 via the branching device 86 and the fourth transmission line 84. Given.

  When a radio wave coming from the outside is received by the transmission / reception antenna 88, the transmission / reception antenna 88 gives a high-frequency signal based on the radio wave to the third transmission line 83, and gives it to the mixer 89 via the duplexer 87 and the fifth transmission line 85. It is done.

  The mixer 89 mixes the high frequency signals given from the fourth and fifth transmission lines 84 and 85 and outputs an intermediate frequency signal. The intermediate frequency signal output from the mixer 89 is given to the distance detector 91.

  The distance detector 91 includes the high frequency detector 71 described above, and is based on the intermediate frequency signal obtained by receiving the radio wave (echo) radiated from the high frequency transmitter / receiver 80 and reflected by the measurement object. The distance to the measurement object is calculated. The distance detector 91 is realized by a microcomputer, for example.

  In the high frequency transmitter / receiver 80, the phase shifter 1 is inserted into the first transmission line 81 so that a high frequency signal passes through the dielectric line 5. By adjusting the phase of the high-frequency signal that changes undesirably due to the high-frequency transmitter / receiver, for example, it is possible to realize a high-frequency transmitter / receiver 80 having stable oscillation characteristics and high transmission output because the insertion loss is suppressed to a small level In addition, for example, a high-frequency transmitter / receiver 80 having a stable detection characteristic and a high detection output because the insertion loss is suppressed to a low level can be realized, and the reliability of the intermediate frequency signal generated by, for example, the mixer 89 can be realized. Can be improved. Since the phase shifter 1 is small and can be operated at a low voltage as described above, the high-frequency transmitter / receiver 80 can be formed small even if the phase shifter 1 is provided. It is possible to prevent the configuration for applying a voltage from becoming complicated.

  In the radar device 90, based on the intermediate frequency signal from the high frequency transmitter / receiver 80, the distance detector detects the distance from the high frequency transmitter / receiver 80 to the detection target, for example, the distance between the transmission / reception antenna 88 and the detection target. Therefore, the distance to the detection target can be accurately detected.

  The branching device 86 may be realized by a directional coupler. In this case, the high-frequency signal supplied to the first terminal 86a is branched and output to the second terminal 86b and the third terminal 86c. In this case, the power of the radio wave output from the transmission / reception antenna 88 is lower than that of the above-described configuration, but the control of the apparatus is simplified because it is not necessary to control the branching device 86.

  In the present embodiment, the phase shifter 1 is inserted into the first transmission line 81, but in still another embodiment of the present invention, the phase shifter 1 is at least one of the first to fifth transmission lines 81 to 85. Alternatively, a high-frequency signal may be inserted so as to pass through the dielectric line 5. Even if it is such a structure, the same effect can be achieved.

  Moreover, although the phase shifter 1 is used in the high frequency transmitter / receiver 80, any one of the phase shifters of the respective embodiments described above may be used. Even if comprised in this way, the same effect can be achieved.

  In still another embodiment of the present invention, the duplexer 87 may be realized by a circulator, and the same effect can be achieved even with such a configuration.

  FIG. 7 is a schematic diagram showing a configuration of the radar apparatus 100 including the array antenna apparatus 99 including the phase shifter 1 according to the embodiment of the present invention. In the embodiment of the present invention, the same components as those of the above-described embodiment are denoted by the same reference numerals, and the description thereof is omitted. The radar device 100 includes an array antenna device 99, a high frequency transmitter / receiver 109, and a distance detector 91.

  The array antenna device 99 includes an antenna array body 102 provided with an antenna element 105 with a phase shifter configured by an antenna element 101 and a phase shifter 1 added to the antenna element 101, and each phase shifter. And a transmission line 107 connected to the attached antenna element 105. In the embodiment of the present invention, the plurality of antenna elements 101 are arranged in a line with their radiation directions aligned. The antenna elements 101 are provided at equal intervals along the arrangement direction R.

  The antenna element 101 is realized by, for example, a slot antenna, a microstrip antenna, a horn antenna, a lot antenna, or a reflector antenna. In the embodiment of the present invention, the array antenna device 99 includes eight antenna elements 101 and eight phase shifters 1.

  The transmission line 107 is configured to include a branching device 103, and a high-frequency signal input from the input unit 104 is branched into a plurality by the branching device 103, and is given to each antenna element 105 with phase shifter. The transmission line 107 is realized by a microstrip line, a strip line, a coplanar line, a coplanar line with a ground, a slot line, a waveguide, a dielectric waveguide, or the like.

  The high frequency transmitter / receiver 109 may be configured by the high frequency transmitter / receiver 80 of each of the above-described embodiments, or the high frequency transmitter / receiver 80 may not include a phase shifter. And a conventional high-frequency transceiver that receives a high-frequency signal captured by the array antenna device 99 may be used.

  The phase shifter 1 is provided between the transmission line 107 and the antenna element 101 of each phase shifter-equipped antenna element 105. A high-frequency signal propagating through the transmission line 107 passes through the dielectric line 5 of the phase shifter 1 and is given to the antenna element 101. Each phase shifter 1 adjusts the phase of the radio wave radiated from each antenna element by shifting the phase of the high-frequency signal, so that the equiphase surface is moved from the first direction R1 of the arrangement direction R as shown in FIG. The direction of the radiation beam 106 is changed from the front by the first direction R1 or the first direction R1 of the arrangement direction R of the antenna elements 101 by shifting the phase of the radio wave radiated from the adjacent antenna elements 101 by Δφ toward the second direction R2. It can be tilted in the two directions R2 by an angle θ.

Phase shifter 1, it is possible to operate with a small type and low voltage, never array antenna system 99 is increased in size. By providing the phase shifter 1, the array antenna device 99 can change the direction of the radiation beam, thereby changing the direction of the radiation beam without mechanically operating the antenna element 101. , Can improve convenience.

  Further, since the radar apparatus 100 can be easily changed without increasing the size of the radar apparatus 100, a highly convenient radar apparatus can be realized.

  Although the phase shifter 1 is used in the radar apparatus 100, any one of the phase shifters of the above-described embodiments may be used instead of the phase shifter 1. Even if comprised in this way, the same effect can be achieved.

  In the radar apparatus 100, the phase shifter 1 may be configured by changing to any one of the phase shifters of the above-described embodiments.

  The high-frequency switch according to the embodiment of the present invention has the same configuration as any of the phase shifters of the above-described embodiments. Hereinafter, the “high frequency switch” is simply referred to as “switch”. In such a switch, the cutoff frequency in the non-radiative dielectric line 2 can be changed by applying a voltage to the first and second electrodes 23a and 23b.

  The voltage applying means 23 applies an AC voltage or a DC voltage having a frequency lower than the frequency of the propagating electromagnetic wave to the first and second electrodes 3a and 3b. The voltage applying means 23 applies a voltage to the first and second electrodes 3a and 3b, so that the dielectric constant of the dielectric line 5 is reduced, thereby increasing the cutoff frequency of the switch. When the voltage applying unit 23 does not apply a voltage to the first and second electrodes 3a and 3b, the switch is configured such that the cut-off frequency of the switch is lower than the frequency of the electromagnetic wave to be propagated (use frequency). The voltage applying unit 23 can apply a voltage to the first and second electrodes 3a and 3b so that the cut-off frequency of the switch is equal to or higher than the use frequency. Accordingly, in the switch, the voltage application means 23 causes the propagation state where the cutoff frequency is lower than the frequency of the electromagnetic wave propagating through the dielectric line 5 and the cutoff frequency becomes higher than the frequency of the electromagnetic wave propagating through the dielectric line 5. The cut-off state can be switched. In the embodiment of the present invention, the operating frequency is constant, and therefore ON / OFF operation is possible by the switching described above.

  In the switch having the above configuration, a propagation state in which the cutoff frequency in the non-radiative dielectric line 2 is lower than the frequency of the electromagnetic wave propagating through the dielectric line 5 according to the electric field applied to the dielectric line 5, and the electromagnetic wave Since it is possible to switch between a cutoff state higher than the frequency of the first and second electrodes 23a and 23b, the propagation state and the cutoff state can be easily switched by changing the voltage applied to the first and second electrodes 23a and 23b. it can. When the switching mode is in the OFF state, the cut-off state is entered, so that an essentially high ON / OFF ratio can be obtained. In addition, since there is no mechanical drive part, it is possible to realize a highly reliable high-frequency switch having excellent durability. Moreover, the said structure can implement | achieve the switch which can change a cutoff frequency with a low voltage. In addition, since the high-frequency signal in the LSE mode can be satisfactorily taken out to the planar line by the connection structure, it is possible to realize a high-frequency switch that has good mountability on the planar circuit board.

  Even if the voltage applied to the first and second electrodes 23a and 23b is reduced in order to apply an electric field to the dielectric line 5, an electric field having a large electric field strength is applied to the changed portion, and the line length of the dielectric line 5 is increased. Even if is short, an electric field having a large electric field strength is applied to the changing portion, so that a switch that is small and can be operated at a low voltage can be realized. In addition, since there is no mechanical drive part, it is possible to realize a highly reliable high-frequency switch having excellent durability.

  The attenuator according to one embodiment of the present invention has the same configuration as any of the phase shifters according to the respective embodiments described above. In such an attenuator, by applying a voltage to the first and second electrodes 3a and 3b, the cutoff frequency in the non-radiative dielectric line 2 can be changed to change the propagation characteristics. The high frequency signal can be attenuated by changing the propagation characteristics in the non-radiative dielectric line 2 according to the electric field applied to the dielectric line 5, and the high frequency signal in the LSE mode can be reduced by the connection structure. Since it can be satisfactorily taken out to a planar line, an attenuator with good mountability on a planar circuit board can be realized. As in the phase shifter described above, the attenuator preferably has a frequency of 1.03 <f / fc <1.5 when the cutoff frequency is fc and the frequency used is f. It is formed so that 03 <f / fc <1.2. Further, even if the voltage applied to the first and second electrodes 3a and 3b is reduced, an electric field having a large electric field strength is applied to the changed portion, and the attenuation characteristic near the cutoff frequency is used. Even if the length of the transmission line is short, the electromagnetic wave can be sufficiently attenuated even if the transmission line length is short, so that an electric field having a large electric field strength is given to the changing portion, so that it can be operated with a small size and a low voltage. An attenuator can be realized. Moreover, since there is no mechanical drive part, a highly reliable attenuator with excellent durability can be realized.

  FIG. 8 is a schematic diagram showing a configuration of a high-frequency transmitter 160 according to another embodiment of the present invention. The high-frequency transmitter 160 has a configuration in which the high-frequency switch 161 is provided in place of the phase shifter 1 of the high-frequency transmitter 60 in FIG. 4 described above and the stub 64 is omitted. The description is omitted. The switch 161 has the same configuration as any of the phase shifters of the above-described embodiments.

  The switch 161 is inserted into the transmission line 62 and transmits a high-frequency signal transmitted to the transmission line 62 by setting the propagation state, and blocks the high-frequency signal transmitted to the transmission line 62 by setting the cutoff state.

  When the switch 161 is in a propagation state, the high-frequency signal generated by the high-frequency oscillator 61 is transmitted to the transmission line 62, passes through the dielectric line 5 of the switch 161, is given to the transmitting antenna 63, and is radiated as a radio wave. . When the switch 161 is in the cut-off state, the high frequency signal generated by the high frequency oscillator 61 is not transmitted to the transmitting antenna 63 because it does not pass through the switch 161. By switching the propagation state and cut-off state of the switch 161, a pulse signal wave can be radiated from the transmitting antenna 63. A high-frequency transmitter 160 with high reliability can be realized by using a high-reliability high-frequency switch with excellent durability and high ON / OFF ratio. The voltage applying means 23 applies a voltage to the switch 161 on the basis of the predetermined information, and turns on / off the switch 161, whereby a radio wave corresponding to the predetermined information can be radiated from the transmitting antenna 63. .

  In the high-frequency transmitter 160, the transmission line 62 may be realized by a coplanar line, a grounded coplanar line, a slot line, a waveguide, a dielectric waveguide, or the like in addition to the microstrip line and the strip line.

  FIG. 9 is a schematic diagram showing a configuration of a radar apparatus 190 including a high-frequency transceiver 180 according to another embodiment of the present invention. The high frequency transmitter / receiver 180 has a configuration in which a high frequency switch 161 is provided in place of the phase shifter 1 of the high frequency transmitter / receiver 80 of FIG. 6 described above. Description is omitted.

  By setting the switch 161 inserted in the first transmission line 81 in a propagation state, the high frequency signal generated by the high frequency oscillator 61 is transmitted to the first transmission line 81 and given to the first terminal 86a of the branching device 86, The signal is supplied from the second terminal 86 b of the branching device 86 to the second transmission line 82, supplied to the fourth terminal 87 a of the branching filter 87, and supplied from the fifth terminal 87 b of the branching device 87 to the third transmission line 83. And radiated from the transmitting / receiving antenna 88. When the switch 161 inserted into the first transmission line 81 is cut off, the high-frequency signal generated by the high-frequency oscillator 61 is not transmitted through the switch 161 and thus is cut off and is not radiated from the transmission / reception antenna 88. By switching the propagation state and cut-off state of the switch 161, a pulse signal wave can be radiated from the transmission / reception antenna 88. A high-reliability high-frequency transmitter / receiver can be realized by using a highly reliable switch 161 that can obtain a large ON / OFF ratio and has excellent durability. In the present embodiment, the switch 161 is inserted into the first transmission line 81. However, in still another embodiment of the present invention, the switch 161 is connected to at least one of the first to third transmission lines 81 to 83. , May be inserted. Even in such a configuration, all the switches 161 inserted in at least one of the first to third transmission lines 81 to 83 are set in a propagation state, and at least the first to third transmission lines 81 to 83 are set. By setting any one of the switches 161 inserted in any one of the cut-off states to a cut-off state, it is possible to radiate a pulse signal wave from the transmission / reception antenna 88 and achieve the same effect as the above-described radar device. Can do.

  In a radar apparatus according to still another embodiment of the present invention, the branching device 86 constituting the high frequency transmitter / receiver 80 may be configured by two switches 161 in the radar apparatus according to each of the above embodiments.

FIG. 10 is a schematic diagram illustrating a configuration of the branching device 86 configured by the switch 161. The two switches 161 are referred to as a first switch 161A and a second switch 161B. The first switch 161A transmits the high-frequency signal between the first terminal 86a and the second terminal 86b by setting the propagation state, and the high-frequency signal between the first terminal 86a and the second terminal 86b by setting the cutoff state. Shut off. The second switch 161B transmits the high-frequency signal between the first terminal 86a and the third terminal 86c by setting the propagation state, and the high-frequency signal between the first terminal 86a and the third terminal 86c by setting the cutoff state. Shut off. The first ends of the first and second switches 161A and 161B in the electromagnetic wave propagation direction are connected to serve as the first terminal 86a. The second end portion in the guiding direction X of the electromagnetic wave of the first switch 161A and the second terminal 86 b. The second end portion in the guiding direction X of the electromagnetic wave of the second switch 161B and the third terminal 86 c.

  A control signal is given to the first and second switches 161A and 161B from a control unit (not shown), and when the first switch 161A is in a propagation state based on the control signal, the second switch 161B is cut off, When the first switch 161A is in the cut-off state, the high frequency signal input from the first terminal 86a is selectively output from the second and third terminals 86b and 86c by setting the second switch 161B to the propagation state. be able to. The radar apparatus is realized by a pulse radar. The control unit controls the first and second switches 161A and 161B, connects the first terminal 86a and the second terminal 86b, and outputs a pulsed high-frequency signal from the second terminal 86b. The first and second switches 161A and 161B are controlled to connect the first terminal 86a and the third terminal 86c, so that a high frequency signal is output from the third terminal 86c. A high-reliability high-frequency transmitter / receiver can be realized by forming the branching device 86 using the highly reliable switch 161 having excellent durability while being able to obtain a large ON / OFF ratio.

  In the radar apparatus according to still another embodiment of the present invention, the duplexer 87 constituting the high frequency transmitter / receiver 80 may be configured by two switches 161 in the radar apparatus according to each of the above embodiments.

  FIG. 11 is a schematic diagram showing the configuration of the duplexer 87 configured by the switch 161. The duplexer 87 includes two switches 161. The two switches 161 are referred to as a third switch 161C and a fourth switch 161D. The third switch 161C transmits a high-frequency signal between the fourth terminal 87a and the fifth terminal 87b by being in a propagation state, and is a high-frequency signal between the fourth terminal 87a and the fifth terminal 87b by being in a cutoff state. Shut off. The fourth switch 161D transmits the high-frequency signal between the fifth terminal 87b and the sixth terminal 87c by setting the propagation state, and the high-frequency signal between the fifth terminal 87b and the sixth terminal 87c by setting the cutoff state. Shut off. The first end of the third switch 161C in the propagation direction of the electromagnetic wave is referred to as a fourth terminal 87a. In addition, the second ends of the third and fourth switches 161C and 161D in the propagation direction of the electromagnetic wave are connected in common to form a fifth terminal 87b. The first end of the fourth switch 161D in the propagation direction of the electromagnetic wave is referred to as a sixth terminal 87c.

  The third and fourth switches 161C and 161D receive a control signal from a control unit (not shown), and when the third switch 161C is in the propagation state based on the control signal, the fourth switch 161D is cut off, When the third switch 161C is in the cutoff state, the high frequency signal input from the fourth terminal 87a is output from the fifth terminal 87b and input from the fifth terminal 87b by setting the fourth switch 161D to the propagation state. A high frequency signal can be output from the sixth terminal 87c. The control unit controls the third and fourth switches 161C and 161D, connects the fourth terminal 87a and the fifth terminal 87b, transmits a pulsed high-frequency signal to the transmitting and receiving antenna, By controlling the fourth switches 161C and 161D, the fifth terminal 87b and the sixth terminal 87c are connected, and the high-frequency signal captured by the transmission / reception antenna is output from the sixth terminal 87c. The control unit sets the first and third switches 161A and 161C to be in a propagation state and the second and fourth switches 161B and 161D to be in a cutoff state, or the first and third switches 161A and 161C are cut. The first to fourth switches 161A to 161D are controlled so that the second and fourth switches 161B and 161D are in the propagation state. A high-frequency transmitter / receiver with high reliability can be realized by configuring the duplexer 87 using the highly reliable switch 161 having excellent durability while being able to obtain a large ON / OFF ratio.

In each of the embodiments described above, the changing portion may be a piezoelectric element whose size changes according to the applied electric field. Depending on the applied voltage, the phase of the electromagnetic wave propagating through the dielectric part including the changing part is changed by changing the dimension of the piezoelectric element in the electromagnetic wave direction, that is, by changing the thickness of the piezoelectric element in the propagation direction. It is possible to achieve the same effects as those of the above-described embodiment. The piezoelectric element is made of, for example, quartz, zinc oxide, aluminum nitride, Pb (Zr, Ti) O ₃ , BaTiO ₃ , LiNbO _3, or SbSI. The phase shifter, switch, and attenuator of each of the above embodiments are dielectric waveguide devices.

  Note that the present invention is not limited to the above-described embodiments and examples, and various modifications may be made without departing from the scope of the present invention.

It is sectional drawing which shows typically the structure of the phase shifter 1 of one Embodiment of this invention. 3 is a plan view of the phase shifter 1. FIG. It is sectional drawing seen from the cut surface line III-III of FIG. It is a schematic diagram which shows the structure of the high frequency transmitter 60 of one Embodiment of this invention. It is a schematic diagram which shows the structure of the high frequency receiver 70 of one Embodiment of this invention. It is a schematic diagram which shows the structure of the radar apparatus 90 provided with the high frequency transmitter-receiver 80 of one Embodiment of this invention. It is a schematic diagram which shows the structure of the radar apparatus 100 containing the array antenna apparatus 99 provided with the phase shifter 1 of embodiment of this invention. It is a schematic diagram which shows the structure of the high frequency transmitter 160 of other embodiment of this invention. It is a schematic diagram which shows the structure of the radar apparatus 190 provided with the high frequency transmitter-receiver 180 of other embodiment of this invention. 3 is a schematic diagram showing a configuration of a branching device 86 constituted by a switch 161. FIG. 4 is a schematic diagram showing a configuration of a duplexer 87 configured by a switch 161. FIG.

DESCRIPTION OF SYMBOLS 1 Phase shifter 2 Non-radiative dielectric line 3a 1st electrode 3b 2nd electrode 4 Mounting part 5 Dielectric line 6a, 6b Flat plate conductor part 9 Interplate dielectric part 11 Mounting dielectric part 12 Strip conductor part 19 Through-hole 60, 160 High-frequency transmitter 61 High-frequency oscillator 62, 81, 82, 83, 84, 85 Transmission line 63 Transmitting antenna 64 Stub 70 High-frequency receiver 71 High-frequency detector 73 Receiving antenna 80, 180 High-frequency transmitter / receiver 86 Branch device 87 Demultiplexer 88 Transmitting / receiving antenna 89 Mixer 86a First terminal 86b Second terminal 86c Third terminal 87a Fourth terminal 87b Fifth terminal 87c Sixth terminal 90, 190 Radar device 91 Distance detector 100 Array antenna device 101 Antenna element 161 switch

Claims (18)

A dielectric line including a change part whose dielectric constant changes according to an applied electric field and electromagnetic waves propagate, and a non-radiative dielectric line including a pair of flat conductor parts sandwiching the dielectric line;
Provided along the dielectric line, and in a state perpendicular to the direction in which the dielectric line and the pair of flat plate conductors overlap, with a gap narrower than the gap between the pair of flat plate conductors. A pair of electrodes for sandwiching the dielectric line and applying an electric field to the changing portion;
A dielectric part provided on a surface part opposite to the dielectric line of either one of the pair of flat conductor parts;
A strip conductor portion provided on the surface portion of the dielectric portion opposite to the flat conductor portion, and a part of which is overlapped with the dielectric line;
The flat plate conductor portion is formed with a through hole at a position where a part of the dielectric line and a part of the strip conductor portion overlap each other.   2. The dielectric waveguide device according to claim 1, wherein the pair of electrodes are formed to be thinner than a skin thickness with respect to an electromagnetic wave propagating through the dielectric line, and sandwich the dielectric line.   The dielectric waveguide device according to claim 2, wherein the pair of electrodes are connected to the different flat plate conductor portions.   2. A second dielectric part provided between the pair of flat conductor parts, sandwiching the dielectric line and the electrode and having a dielectric constant lower than a dielectric constant of the dielectric line. Item 4. The dielectric waveguide device according to Item 2 or 3. A dielectric waveguide device according to any one of claims 1 to 4, comprising:
By changes before Symbol change part of the dielectric constant depending on the electric field applied to the varying portion, the phase shifter, characterized in that varying the phase of an electromagnetic wave propagating through the transmission line. A dielectric waveguide device according to any one of claims 1 to 4, comprising:
By pre-Symbol changing part of the dielectric constant varies according to an electric field applied to the varying portion, the cut-off frequency in the transmission line, the low made propagation conditions than the frequency of the electromagnetic wave propagating through the transmission line, high A high-frequency switch characterized in that it can be switched between a cut-off state. A dielectric waveguide device according to any one of claims 1 to 4, comprising:
Attenuator, wherein the change unit to change the dielectric constant of the front Symbol changing portion according to an electric field applied to it, attenuate electromagnetic waves propagating through the transmission line. A high-frequency oscillator that generates a high-frequency signal;
A transmission line connected to the high-frequency oscillator and transmitting a high-frequency signal from the high-frequency oscillator;
An antenna connected to the transmission line and emitting a high-frequency signal;
The phase shifter according to claim 5, wherein the phase shifter is inserted into the transmission line so that a high-frequency signal passes through the dielectric line.
A high frequency transmitter comprising: a stub provided on at least one of the upstream side and the downstream side of the phase shifter in a transmission direction of a high frequency signal. An antenna that captures high-frequency signals;
A transmission line connected to the antenna and transmitting a high-frequency signal captured by the antenna;
A high-frequency detector connected to the transmission line and detecting a high-frequency signal transmitted to the transmission line;
The phase shifter according to claim 5, wherein the phase shifter is inserted into the transmission line so that a high-frequency signal passes through the dielectric line.
A high frequency receiver comprising: a stub provided on at least one of the upstream side and the downstream side of the phase shifter in the transmission direction of the high frequency signal. A high-frequency oscillator that generates a high-frequency signal;
A first transmission line that is connected to the high-frequency oscillator and transmits a high-frequency signal; and first, second, and third terminals; the first terminal is connected to the first transmission line and applied to the first terminal A branching device that selectively outputs a high-frequency signal to be output to the second terminal or the third terminal;
A second transmission line connected to the second terminal and transmitting a high-frequency signal applied from the second terminal;
A fourth, fifth, and sixth terminal that outputs a high-frequency signal applied to the fourth terminal via the second transmission line to the fifth terminal, and a high-frequency signal applied to the fifth terminal; A duplexer that outputs to the sixth terminal;
A third transmission line connected to the fifth terminal for transmitting a high-frequency signal output from the fifth terminal and transmitting the high-frequency signal to the fifth terminal;
An antenna connected to the third transmission line for radiating and capturing high-frequency signals;
A fourth transmission line connected to the third terminal and transmitting a high-frequency signal output from the third terminal;
A fifth transmission line connected to the sixth terminal for transmitting a high-frequency signal output from the sixth terminal;
A mixer that is connected to the fourth and fifth transmission lines, mixes high-frequency signals given from the fourth and fifth transmission lines, and outputs an intermediate frequency signal;
And a phase shifter inserted in at least one of the first to fifth transmission lines such that a high-frequency signal passes through the dielectric line. Transceiver. A high-frequency oscillator that generates a high-frequency signal;
A high-frequency transmission line connected to the high-frequency oscillator and transmitting a high-frequency signal from the high-frequency oscillator;
An antenna connected to the high-frequency transmission line and emitting a high-frequency signal;
The high-frequency signal inserted into the high-frequency transmission line is transmitted through the high-frequency transmission line by setting the propagation state, and the high-frequency signal transmitted to the high-frequency transmission line is blocked by setting the cutoff state. A high-frequency transmitter comprising the high-frequency switch according to claim 6. A high-frequency oscillator that generates a high-frequency signal;
A first high-frequency transmission line that is connected to the high-frequency oscillator and transmits a high-frequency signal; and first, second, and third terminals; the first terminal is connected to the first high-frequency transmission line; A branching device that selectively outputs a high-frequency signal given to the second terminal or the third terminal;
A second high frequency transmission line connected to the second terminal and transmitting a high frequency signal applied from the second terminal;
A high-frequency signal having fourth, fifth, and sixth terminals, outputting a high-frequency signal supplied to the fourth terminal via the second high-frequency transmission line to the fifth terminal, and supplied to the fifth terminal A duplexer that outputs to the sixth terminal;
A third high-frequency transmission line that is connected to the fifth terminal, transmits a high-frequency signal output from the fifth terminal, and transmits a high-frequency signal to the fifth terminal;
An antenna connected to the third high-frequency transmission line for radiating and capturing high-frequency signals;
A fourth high-frequency transmission line connected to the third terminal and transmitting a high-frequency signal output from the third terminal;
A fifth high-frequency transmission line connected to the sixth terminal and transmitting a high-frequency signal output from the sixth terminal;
A mixer that is connected to the fourth and fifth high-frequency transmission lines, mixes high-frequency signals given from the fourth and fifth high-frequency transmission lines, and outputs an intermediate frequency signal;
The branching device includes two high-frequency switches according to claim 6, wherein the first high-frequency switch transmits the high-frequency signal between the first terminal and the second terminal by being in the propagation state, and the cut The high-frequency signal is cut off between the first terminal and the second terminal by turning off, and the high-frequency signal is cut off between the first terminal and the third terminal by turning on the propagation state. A high-frequency transmitter / receiver that cuts off a high-frequency signal between the first terminal and the third terminal by being transmitted and in the cut-off state. A high-frequency oscillator that generates a high-frequency signal;
A first high-frequency transmission line that is connected to the high-frequency oscillator and transmits a high-frequency signal; and first, second, and third terminals; the first terminal is connected to the first high-frequency transmission line; A branching device that selectively outputs a high-frequency signal given to the second terminal or the third terminal;
A second high frequency transmission line connected to the second terminal and transmitting a high frequency signal applied from the second terminal;
A high-frequency signal having fourth, fifth, and sixth terminals, outputting a high-frequency signal supplied to the fourth terminal via the second high-frequency transmission line to the fifth terminal, and supplied to the fifth terminal A duplexer that outputs to the sixth terminal;
A third high-frequency transmission line that is connected to the fifth terminal, transmits a high-frequency signal output from the fifth terminal, and transmits a high-frequency signal to the fifth terminal;
An antenna connected to the third high-frequency transmission line for radiating and capturing high-frequency signals;
A fourth high-frequency transmission line connected to the third terminal and transmitting a high-frequency signal output from the third terminal;
A fifth high-frequency transmission line connected to the sixth terminal and transmitting a high-frequency signal output from the sixth terminal;
A mixer that is connected to the fourth and fifth high-frequency transmission lines, mixes high-frequency signals given from the fourth and fifth high-frequency transmission lines, and outputs an intermediate frequency signal;
The duplexer includes two high-frequency switches according to claim 6, wherein the third high-frequency switch transmits a high-frequency signal between the fourth terminal and the fifth terminal by being in the propagation state, and The high-frequency signal is cut off between the fourth terminal and the fifth terminal by setting the cut-off state, and the fourth high-frequency switch is set between the fifth terminal and the sixth terminal by setting the propagation state. And a high-frequency transmitter-receiver that cuts off a high-frequency signal between the fifth terminal and the sixth terminal by setting the cutoff state. A high-frequency oscillator that generates a high-frequency signal;
A first high-frequency transmission line that is connected to the high-frequency oscillator and transmits a high-frequency signal; and first, second, and third terminals; the first terminal is connected to the first high-frequency transmission line; A branching device that selectively outputs a high-frequency signal given to the second terminal or the third terminal;
A second high frequency transmission line connected to the second terminal and transmitting a high frequency signal applied from the second terminal;
A high-frequency signal having fourth, fifth, and sixth terminals, outputting a high-frequency signal supplied to the fourth terminal via the second high-frequency transmission line to the fifth terminal, and supplied to the fifth terminal A duplexer that outputs to the sixth terminal;
A third high-frequency transmission line that is connected to the fifth terminal, transmits a high-frequency signal output from the fifth terminal, and transmits a high-frequency signal to the fifth terminal;
An antenna connected to the third high-frequency transmission line for radiating and capturing high-frequency signals;
A fourth high-frequency transmission line connected to the third terminal and transmitting a high-frequency signal output from the third terminal;
A fifth high-frequency transmission line connected to the sixth terminal and transmitting a high-frequency signal output from the sixth terminal;
A mixer that is connected to the fourth and fifth high-frequency transmission lines, mixes high-frequency signals given from the fourth and fifth high-frequency transmission lines, and outputs an intermediate frequency signal;
The high-frequency switch according to claim 6, wherein the high-frequency switch is inserted into at least one of the first to third transmission lines so that a high-frequency signal passes through the dielectric line when in the propagation state. A high frequency transceiver characterized by.   15. The high-frequency transceiver according to claim 10, 12 or 14, wherein the duplexer is formed by a hybrid circuit or a circulator. A high-frequency transceiver according to any one of claims 10 and 12 to 15,
A radar apparatus comprising: a distance detector that detects a distance from the high frequency transmitter / receiver to an object to be detected based on an intermediate frequency signal from the high frequency transmitter / receiver.   An array antenna apparatus comprising a plurality of antennas with phase shifters each having an antenna element and the phase shifter according to claim 5. An array antenna device according to claim 17,
A radar apparatus comprising: a high-frequency transmitter / receiver connected to the array antenna apparatus, for applying a high-frequency signal to the array antenna apparatus, and for receiving a high-frequency signal captured by the array antenna apparatus.

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