JP3497702B2 - Balun and push-pull amplifiers - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a balun for use in microwave circuits such as satellite communication, terrestrial microwave communication, mobile communication, mixers, oscillators and the like, and a push-pull amplifier using the balun. Is.

[0002]

2. Description of the Related Art FIG. 12 shows, for example, "Microwave Mixers sec.
ond edition ”(Stephen A. Maas, P257). In FIG. 12, 1 is a dielectric substrate, 2 is a backside metal film, 3 is a first microstrip line, 4 is a second microstrip line, and 5 is a first microstrip line.
, 6 is a second terminal, 7 is a third terminal, and 8 is a fourth terminal. The lengths of the first microstrip line 3 and the second microstrip line 4 are about a signal frequency. It is a quarter wavelength. In addition, the second terminal 6
Are grounded by through holes, side metallization, gold ribbon bonding and other means.

Next, the operation will be described. In the configuration example of the conventional balun, when a microwave signal is input from the first terminal 5, the signal is output to each of the third terminal 7 and the fourth terminal 8 due to inter-line coupling. If the lengths of the first microstrip line 3 and the second microstrip line 4 are set to about a quarter of the signal frequency, the third terminal 7
And the phase difference between the signals output to the fourth terminal 8 can be 180 degrees. The amplitudes of the signals output to the third terminal 7 and the fourth terminal 8 are determined by selecting the line widths and the line intervals of the first microstrip line 3 and the second microstrip line 4 to appropriate values. You can control.

FIG. 13 shows another configuration example of the conventional balun. 13, the same parts as those shown in FIG. 12 are designated by the same reference numerals and the description thereof will be omitted. As a new reference numeral, 9 is the center conductor of the coaxial line, 10 is the outer conductor of the coaxial line, and 11 is the outer peripheral cylindrical conductor.
The length of the coaxial line formed by the outer conductor 10 and the outer conductor 10 is about a quarter wavelength at the signal frequency. One end of the outer peripheral cylindrical conductor 11 on the first terminal 5 side and the second terminal 6 of the outer conductor 10 of the coaxial line are grounded. Also in the configuration example of the conventional balun shown in FIG. 13, the first microstrip line 3 of the configuration example shown in FIG. 12 is the center conductor 9 of the coaxial line, and the second microstrip line 4 is the outer conductor 10 of the coaxial line. When replaced with, the operation is similar to the configuration example of the conventional balun shown in FIG.

[0005]

In the configuration example of the conventional balun shown in FIG. 12 described above, the line spacing between the first microstrip line 3 and the second microstrip line 4 is reduced to the limit that can be physically realized. Even if the signals output to the third terminal 7 and the fourth terminal 8 cannot be made equal in amplitude, the problem that the third terminal 7 and the fourth terminal 8 cannot be isolated, There was a problem that the above-mentioned multiple distribution was not possible. Further, the conventional balun configuration example shown in FIG. 13 has the same problem.

The present invention has been made in order to solve the above problems, and an object thereof is to obtain a balun capable of extracting two signals of equal amplitude but different in phase by 180 degrees. Moreover, it aims at obtaining the balun which can improve an isolation characteristic. Moreover, it aims at obtaining the balun which can enable multiple distribution. Furthermore, it is also an object to obtain a push-pull amplifier having a highly efficient characteristic by using these baluns.

[0007]

In the balun according to the present invention, a first microstrip line and a second microstrip line having a length of about a quarter wavelength at a signal frequency are arranged adjacent to each other in parallel. Then, the input side terminal of the second microstrip line is electrically grounded, a signal is input from the input side terminal of the first microstrip line, and the output side terminal of the first microstrip line and the second microstrip line are input. In a microstrip coupling line type balun for extracting a signal from the output side terminal of the stripline, the first microstripline and the second microstripline are electrically connected via a capacitor. .

Further, the first center conductor and the second center conductor having a length of about a quarter wavelength at the signal frequency are arranged adjacent to each other in parallel, and the input side terminal of the second center conductor is electrically connected. In a rectangular coaxial coupling line type balun, which is grounded electrically, inputs a signal from the input side terminal of the first center conductor, and takes out a signal from the output side terminal of the first center conductor and the output side terminal of the second center conductor. A dielectric sheet is provided between the first central conductor and the second central conductor.

Further, the first center conductor and the second center conductor having a length of about a quarter wavelength at the signal frequency are arranged adjacent to each other in parallel, and the input side terminal of the second center conductor is electrically connected. In a rectangular coaxial coupling line type balun, which is grounded electrically, inputs a signal from the input side terminal of the first center conductor, and takes out a signal from the output side terminal of the first center conductor and the output side terminal of the second center conductor. The first central conductor and the second central conductor are surrounded by a floating shield.

Further, the first coplanar line and the second coplanar line having a length of about a quarter wavelength at the signal frequency are arranged adjacent to each other in parallel, and the input side terminal of the second coplanar line is electrically connected. In the coplanar coupling line type balun, the signal is inputted from the input side terminal of the first coplanar line and the signal is taken out from the output side terminal of the first coplanar line and the output side terminal of the second coplanar line. It is characterized in that a third coplanar line is further provided in parallel with and adjacent to the first coplanar line.

Further, the first microstrip line and the second microstrip line having a length of about a quarter wavelength at the signal frequency are arranged adjacent to each other in parallel, and the input side of the second microstrip line is arranged. The terminal is electrically grounded, the signal is input from the input side terminal of the first microstrip line, and the signal is output from the output side terminal of the first microstrip line and the output side terminal of the second microstrip line. In the strip coupled line type balun,
A slit is provided in the metal film on the back surface of the dielectric substrate that constitutes the microstrip line, the length of this slit is set to one quarter wavelength at the signal frequency on one side, and an isolation resistor is mounted on the slit part. It is characterized by.

Further, an outer peripheral cylindrical conductor is further provided on the outer periphery of the coaxial line having a length of about a quarter wavelength at the signal frequency, and an input side terminal of the outer peripheral cylindrical conductor and an input side terminal of the outer conductor of the coaxial line are electrically connected. In the coaxial line type balun, the signal is input from the input side terminal of the center conductor of the coaxial line, and the signal is extracted from the output side terminal of the center conductor of the coaxial line and the output side terminal of the outer conductor of the coaxial line. A slit is provided in the cylindrical conductor, and an isolation resistor is mounted on the slit portion.

Further, the outer conductor of the coaxial line length of about a quarter wavelength at the signal frequency, configured by providing the metal film on the inner wall of the hollow insulator, provided on the inner wall of the hollow insulator The input side terminal of the metal film is electrically grounded, a signal is input from the input side terminal of the center conductor of the coaxial line, and the output side terminal of the center conductor of the coaxial line and the metal film provided on the inner wall of the hollow insulator A coaxial line type balun for extracting a signal from an output side terminal is characterized in that a slit is provided in a metal film provided on an outer wall of a hollow insulator, and an isolation resistor is mounted on the slit portion.

Further, in the grounding metal film of the coplanar line,
Provide a slit with a length of about a quarter wavelength at the signal frequency,
This slit is equipped with an isolation resistor.

Further, the first to seventh microstrip lines each having a length of about a quarter wavelength at the signal frequency are arranged adjacent to each other in parallel, and the first, third, fifth and seventh microstrip lines are arranged. The input side terminal of the line is electrically grounded, and the 1st and 3rd
And the output side terminals of the fifth and seventh microstrip lines are electrically connected, respectively, and the output side terminals of the second and sixth and third and fifth microstrip lines are respectively connected via isolation resistors. The signal is input from a terminal that is connected and the input side terminals of the second, fourth, and sixth microstrip lines are bundled, and is output from the output side terminals of the first, second, sixth, and seventh microstrip lines. It is characterized by taking out two output signals.

Also, the first to fourth coplanar lines having a length of about a quarter wavelength at the signal frequency are arranged adjacent to each other in parallel, and the input side terminals of the first and fourth coplanar lines are electrically connected. From the terminal that is connected to the output side terminals of the first and fourth and second and third coplanar lines through an isolation resistor, and the input side terminals of the second and third coplanar lines are bundled together. It is characterized in that signals are inputted and four output signals are taken out from the output side terminals of the first to fourth coplanar lines.

Further, the push-pull amplifier according to the present invention is provided with any one of the above-mentioned baluns on the input side and the output side, and the number of output terminals of the input-side balun is between the input-side balun and the output-side balun. It is characterized in that a plurality of amplifiers corresponding to the above are arranged in parallel.

[0018]

DETAILED DESCRIPTION OF THE INVENTION

Embodiment 1. 1 is a configuration diagram of a balun according to Embodiment 1 of the present invention. In FIG. 1, the same parts as those in the conventional example shown in FIG.
As a new code, 12 is a capacitor. The two terminals of the capacitor 12 are connected to the first microstrip line 3 and the second microstrip line 4, respectively. The lengths of the first microstrip line 3 and the second microstrip line 4 are about a quarter wavelength at the signal frequency, and the second terminal is grounded. A plurality of capacitors 12 may be mounted.

Next, the operation will be described. According to the conventional theory, when the even mode impedance of the coupled line is extremely large compared with the odd mode impedance (for example, 10 times or more), the third terminal 7 and the fourth terminal 8 have approximately equal amplitudes. The signal is said to be retrieved. However, as a practical matter, as long as a substrate having a relative dielectric constant of about 2 to 90 is used, even if the line spacing is reduced to the limit within a workable range, the ratio between the even mode impedance and the odd mode impedance is 10 times or more. It is impossible to do. Therefore, in the configuration example of the conventional balun shown in FIG. 12, the equal-amplitude distribution characteristic cannot be realized, and for this reason, it is rarely used.

In the first embodiment of the present invention, the first microstrip line 3 and the second microstrip line 4 each having a length of about a quarter wavelength at the signal frequency are arranged adjacent to each other and in parallel. The second terminal 6 which is the input side terminal of the second microstrip line 4 is electrically grounded, and the signal is input from the first terminal 5 which is the input side terminal of the first microstrip line 3, In the microstrip coupling line type balun for extracting a signal from the third terminal 7 which is the output side terminal of the microstrip line 3 and the fourth terminal 8 which is the output side terminal of the second microstrip line 4, By mounting the capacitor 12 between the microstrip line 3 and the second microstrip line 4, the degree of coupling is increased, and the first microstrip line 3 and the first microstrip line 3 are connected. Of the microstrip line 4 greatly increased the even mode impedance of the formed bond line with, it can be realized characteristics very close to equal amplitude distribution. Therefore, when a microwave signal is input from the first terminal 5,
The third terminal 7 and the fourth terminal 8 have the same amplitude and
Signals having a 0 ° phase difference are output.

Embodiment 2. 2 is a configuration diagram of a balun according to a second embodiment of the present invention. In FIG. 2, FIG.
The same parts as those of the first embodiment shown in are attached with the same notations and an explanation thereof will be omitted. As new symbols, 13 is a housing provided with a groove, 14 is a center conductor of the first rectangular coaxial line, 15 is a center conductor of the second rectangular coaxial line, 16 is a dielectric sheet, and a dielectric sheet 16 Is provided between the center conductor 14 of the first rectangular coaxial line and the center conductor 15 of the second rectangular coaxial line. Also, the center conductor 1 of the first rectangular coaxial line
The lengths of the center conductors 15 of the fourth and second rectangular coaxial lines are about a quarter wavelength at the signal frequency, and the second terminal 6 is grounded.

Next, the operation will be described. In the second embodiment, the center conductor 14 of the first rectangular coaxial line and the center conductor 15 of the second rectangular coaxial line having a length of about a quarter wavelength at the signal frequency are arranged adjacent to each other in parallel. , The second terminal 6 which is the input side terminal of the center conductor 15 of the second rectangular coaxial line is electrically grounded, and the first terminal 5 which is the input side terminal of the center conductor 14 of the first rectangular coaxial line Input the signal from the first
Which is the output side terminal of the center conductor 14 of the rectangular coaxial line
In the rectangular coaxial coupling line type balun for extracting a signal from the terminal 7 and the fourth terminal 8 which is the output side terminal of the central conductor 15 of the second rectangular coaxial line, the central conductor 14 and the second rectangular coaxial line By mounting the dielectric sheet 16 between the center conductor 15 of the rectangular coaxial line and the center conductor 15 of the first rectangular coaxial line, the degree of coupling is increased. The even mode impedance of the coupled line constituted by 15 is remarkably increased, and the characteristics which are extremely close to equal amplitude distribution can be realized. Therefore, the first terminal 5
When a microwave signal is input from the third terminal 7 and the fourth terminal
Signals of approximately equal amplitude and different in phase by 180 degrees are output to the terminal 8 of.

Embodiment 3. FIG. 3 is a configuration diagram of a balun according to a third embodiment of the present invention. In FIG. 3, FIG.
The same parts as those of the second embodiment shown in FIG. As a new reference numeral, 17 indicates a floating shield.
Is provided so as to surround the center conductor 14 of the first rectangular coaxial line and the center conductor 15 of the second rectangular coaxial line.
The lengths of the center conductor 14 of the first rectangular coaxial line and the center conductor 15 of the second rectangular coaxial line are about a quarter wavelength at the signal frequency, and the second terminal 6 is grounded.

Next, the operation will be described. In the third embodiment, the center conductor 14 of the first rectangular coaxial line and the center conductor 15 of the second rectangular coaxial line having a length of about a quarter wavelength at the signal frequency are arranged adjacent to each other in parallel. , The second terminal 6 which is the input side terminal of the center conductor 15 of the second rectangular coaxial line is electrically grounded, and the first terminal 5 which is the input side terminal of the center conductor 14 of the first rectangular coaxial line Input the signal from the first
Which is the output side terminal of the center conductor 14 of the rectangular coaxial line
In the rectangular coaxial coupling line type balun for extracting a signal from the terminal 7 and the fourth terminal 8 which is the output side terminal of the central conductor 15 of the second rectangular coaxial line, the central conductor 14 and the second rectangular coaxial line By mounting the central conductor 15 of the rectangular coaxial line and the central conductor 15 of the second rectangular coaxial line by surrounding them with the floating shield 17, the degree of coupling is increased, and the central conductor 14 of the first rectangular coaxial line and the central conductor 15 of the second rectangular coaxial line are connected. The even-mode impedance of the coupled line composed of is significantly increased, and the characteristics that are extremely close to equal amplitude distribution can be realized. Therefore, when a microwave signal is input from the first terminal 5, the third terminal 7 and the fourth terminal 8 have the same amplitude and a 180
Signals with different phase are output.

Fourth Embodiment 4 is a configuration diagram of a balun according to Embodiment 4 of the present invention. In FIG. 4, FIG.
The same parts as those of the first embodiment shown in are attached with the same notations and an explanation thereof will be omitted. As new symbols, 18 is a first grounding metal film, 19 is a second grounding metal film, 20 is a first coplanar line, 21 is a second coplanar line, 22 is a third coplanar line, and 23 is a new coplanar line. Indicates a gold wire, the lengths of the first to third coplanar lines 20 to 22 are about a quarter wavelength at the signal frequency, and the second terminal 6 is grounded. Further, the gold wire 23 has one end on the second terminal 6 side of the second coplanar line 21 and the third coplanar line 22 and a fourth terminal of the second coplanar line 21 and the third coplanar line 22. It is assumed that one ends on the eight side are electrically connected. Furthermore, as a result, the third
One end of the coplanar line 22 on the second terminal 6 side is also grounded.

Next, the operation will be described. In the fourth embodiment, the first coplanar line 20 and the second coplanar line 21 each having a length of about a quarter wavelength at the signal frequency are arranged adjacent to each other in parallel, and the second coplanar line 21 is The second terminal 6, which is an input side terminal, is electrically grounded, a signal is input from the first terminal 5, which is an input side terminal of the first coplanar line 20, and the output side terminal of the first coplanar line 20. In the coplanar coupling line type balun that takes out the signal from the third terminal 7 which is the fourth terminal and the fourth terminal which is the output side terminal of the second coplanar line 21, the first coplanar line 2
By arranging yet another third coplanar line 22 adjacent to 0 in parallel, the first coplanar line 2
The coupling between 0 and the second coplanar line 21 is strengthened. This is equivalent to an increase in the even mode impedance of the coupling line composed of the first coplanar line 20 and the second coplanar line 21, and a characteristic very close to equal amplitude distribution can be realized. Therefore, when a microwave signal is input from the first terminal 5, signals having substantially the same amplitude and different phases by 180 degrees are output to the third terminal 7 and the fourth terminal 8.

Embodiment 5. 5 is a block diagram of a balun according to a fifth embodiment of the present invention. In FIG. 5, FIG.
The same parts as those of the first embodiment shown in are attached with the same notations and an explanation thereof will be omitted. As a new reference numeral, 24 is a slit provided on the back surface metal film 2 of the dielectric substrate 1 forming the microstrip line so as not to be metallized, and 25 is a thin film mounted on the corresponding position of the slit 24 portion on the substrate surface. The length of the slit 24 is about a quarter wavelength at the signal frequency on one side, which is a half wavelength in total, and the first microstrip line 3 and The length of the second microstrip line 4 is about a quarter wavelength at the signal frequency, and the second terminal 6 is grounded.

Next, the operation will be described. In the fifth embodiment, the first microstrip line 3 and the second microstrip line 4 each having a length of about a quarter wavelength at the signal frequency are arranged adjacent to each other in parallel, and the second microstrip line is formed. The second terminal 6 that is the input side terminal of the line 4 is electrically grounded, and the signal is input from the first terminal 5 that is the input side terminal of the first microstrip line 3 In the microstrip coupled line type balun for extracting a signal from the third terminal 7 which is the output side terminal of 3 and the fourth terminal 8 which is the output side terminal of the second microstrip line 4, the dielectric which constitutes the microstrip line A slit 24 is provided in the back surface metal film 2 of the body substrate 1, the length of the slit 24 is set to one quarter wavelength at one side of the signal frequency, and the isolation resistor 2 is provided in the slit portion. Having mounted the third terminal 7 and a fourth terminal 8
When there is an imbalance in the loads connected to the terminals, the unbalanced mode signals reflected by these loads are reversely input to the third terminal 7 and the fourth terminal 8, but the isolation resistance 25 Reduces the current flowing through the backside metal film 2 caused by the unbalanced mode signal, so that the isolation characteristics of the third terminal 7 and the fourth terminal 8 can be improved.

Sixth Embodiment 6 is a configuration diagram of a balun according to a sixth embodiment of the present invention. In FIG. 6, FIG.
The same parts as those of the conventional example shown in FIG. 3 and the fifth embodiment shown in FIG. 5 are designated by the same reference numerals, and the description thereof will be omitted. As a new code, 26 is a slit formed by hollowing out a part of the outer peripheral cylindrical conductor 11, and the isolation resistor 25 is attached to this slit 26. Further, the length of the coaxial line constituted by the central conductor 9 of the coaxial line and the outer conductor 10 of the coaxial line is about a quarter wavelength at the signal frequency, and one end of the outer peripheral cylindrical conductor 11 on the second terminal 6 side is It shall be grounded.

Next, the operation will be described. In the sixth embodiment, an outer peripheral cylindrical conductor 11 is further provided on the outer periphery of a coaxial line having a length of about one-quarter wavelength at a signal frequency, and a second input terminal is provided on the outer conductor 10 of the coaxial line. The terminal 6 and one end of the outer peripheral cylindrical conductor 11 on the side of the first terminal 5 are electrically grounded, and a signal is input from the first terminal 5 which is an input side terminal provided on the center conductor 9 of the coaxial line, A coaxial line type balun for extracting a signal from a third terminal 7 which is an output side terminal provided on the center conductor 9 of the line and a fourth terminal 8 which is an output side terminal provided on the outer conductor 10 of the coaxial line By providing a slit 26 in the conductor 11 and mounting an isolation resistor 25 on the slit 26,
When there is an imbalance in the loads connected to the terminals 7 and the fourth terminal 8, the signals in the unbalanced mode reflected by these loads are the third terminal 7 and the fourth terminal 8.
However, since the isolation resistor 25 attenuates the current flowing through the outer peripheral cylindrical conductor 11 caused by the unbalanced mode signal, the isolation resistor 25 isolates the third terminal 7 from the fourth terminal 8. The properties are improved.

Embodiment 7. 7 is a configuration diagram of a balun according to a seventh embodiment of the present invention. In FIG. 7, FIG.
The same parts as those of the sixth embodiment shown in FIG. As new symbols, 27 to 29 are an inner wall metal film, an outer wall metal film, and a hollow columnar insulator that form the outer conductor of the coaxial line. Reference numeral 30 is a slit configured to remove a part of the outer wall metal film 28,
An isolation resistor 25 is provided so as to straddle the slit 30. Further, the length of the coaxial line formed by the center conductor 5 of the coaxial line and the inner wall metal film 27 is about a quarter wavelength at the signal frequency, and one end of the outer wall metal film 28 on the second terminal 6 side is grounded. I shall.

Next, the operation will be described. In the seventh embodiment, the outer conductor of the coaxial line having a length of about a quarter wavelength at the signal frequency is formed by providing the metal film 27 on the inner wall of the hollow columnar insulator 29. The second input terminal of the metal film 27 provided on the inner wall of the insulator 29
Electrically grounded terminal 6 of the inputs a signal from the first terminal 5 is an input-side terminal of the central conductor 9 of the coaxial line, a third terminal 7 which is an output side terminal of the central conductor 9 of the coaxial line And a coaxial line type balun for extracting a signal from the fourth terminal 8 which is an output side terminal of the metal film 27 provided on the inner wall of the hollow columnar insulator 29, the metal film 28 provided on the outer wall of the hollow columnar insulator 29. When the slits 30 are provided on the slits 30 and the isolation resistors 25 are mounted on the slits 30, the loads connected to the third terminal 7 and the fourth terminal 8 are unbalanced. The unbalanced mode signal reflected by the third terminal 7 and the fourth terminal 8
However, the isolation resistor 25 is connected to the outer wall metal film 2 generated by the unbalanced mode signal.
Since it attenuates the current flowing through the third terminal 7 and the fourth terminal 7,
The isolation characteristic of the terminal 8 is improved.

Embodiment 8. FIG. 8 is a configuration diagram of a balun according to Embodiment 8 of the present invention. In FIG.
The same parts as those in the fourth embodiment shown in are attached with the same notations and an explanation thereof will be omitted. As new symbols, 31 and 32 are slits formed by removing parts of the first and second grounding metal films 18 and 19, respectively.
Isolation resistors 25 are mounted on the terminals 32 and 32, respectively. Further, the lengths of the slits 31 and 32 and the lengths of the first to third coplanar lines 20 to 22 are each about one quarter wavelength at the signal frequency. Further, the gold wire 23 has one end on the second terminal 6 side of the second coplanar line 21 and the third coplanar line 22 and the fourth terminal 8 side of the second coplanar line 21 and the third coplanar line 22. The first terminals 6 are electrically connected to each other, and the second terminal 6 is grounded.

Next, the operation will be described. In the eighth embodiment, the second and third coplanar lines 21 and 22 are provided.
Since the grounding metal films 19 and 18 are provided with slits 32 and 31 having a length of about a quarter wavelength at the signal frequency and the isolation resistors 25 are mounted on the slits 32 and 31, respectively, When there is an imbalance in the loads connected to the terminals 7 and the fourth terminal 8, the signals in the unbalanced mode reflected by these loads are reversed to the third terminal 7 and the fourth terminal 8. Although input, the isolation resistor 25 attenuates the current flowing through the first ground metal film 18 and the second ground metal film 19 caused by the unbalanced mode signal, so that the third terminal The isolation characteristics of 7 and the fourth terminal 8 are improved.

Ninth Embodiment 9 is a block diagram of a balun according to Embodiment 9 of the present invention. In FIG. 9, as new symbols, 33 to 39 are first to seventh microstrip conductors, 40 is an input terminal, and 41 to 44.
Are first to fourth output terminals, and are second, fourth and sixth output terminals.
One end of each of the microstrip lines 34, 36, and 38 is bundled and connected to the input terminal 40, and the first, third, fifth, and seventh microstrip conductors 33, 35, 37,
One end of 39 on the input terminal 40 side is grounded and is connected to each other by the gold wire 23. Also, one ends of the first and third microstrip conductors 33 and 35 on the output terminal side and the fifth and seventh microstrip conductors 37 and 3 are connected.
One end on the output terminal side of 9 is also interconnected by the gold wire 23, and the second and sixth microstrip conductors 34 and 38 are connected.
Isolation resistors 25 are mounted between the output terminals of the above and between the output terminals of the third and fifth microstrip conductors 35 and 37, respectively. Further, the lengths of the first to seventh microstrip conductors 33 to 39 are set to about a quarter wavelength at the signal frequency.

Next, the operation will be described. In the ninth embodiment, when a microwave signal is input from the input terminal 40, the first or fourth output terminal 4 is generated due to inter-line coupling.
A signal is output to 1 to 44. If the line width and line spacing of each microstrip line are set to appropriate values, 4
A signal of equal amplitude can be output to one output terminal.
The signals at the first output terminal 41 and the fourth output terminal 44 are in phase, and the signals at the second output terminal 42 and the third output terminal 43 are also in phase. Further, a phase difference of 180 degrees occurs between the former and latter signals. When the loads on the second output terminal 42 and the third output terminal 43 are unbalanced, the signals in the unbalanced mode reflected by these loads are the second output terminal 42 and the third output terminal. Although it is reversely input to 43, the impedance that allows the balun is open for this unbalanced mode signal.
The signal in the unbalanced mode is absorbed by the isolation resistor 25, and the isolation characteristics of the second output terminal 42 and the third output terminal 43 are improved. By the same operation, the isolation characteristics of the first output terminal 41 and the fourth output terminal 44 are also improved.

Embodiment 10. FIG. 10 is a configuration diagram of a balun according to Embodiment 10 of the present invention. In FIG. 10, as new reference numerals 45 to 48 are first to fourth coplanar conductors, which are bundled at one end of the second and third coplanar conductors 46 and 47 and connected to the input terminal 40. And one ends of the fourth coplanar conductors 45 and 48 on the input terminal 40 side are grounded and connected to each other by the gold wire 23. In addition, the first and fourth coplanar conductors 4
An isolation resistor 25 is mounted on one end of the output terminals 5 and 48 and on the output terminal of the second and third coplanar conductors 46 and 47, respectively. Furthermore, the length of the first to fourth coplanar conductors 45 to 48 is about a quarter wavelength at the signal frequency.

Next, the operation will be described. In the tenth embodiment, when a microwave signal is input from the input terminal 40, the first to fourth output terminals 4 are connected by line coupling.
A signal is output to 1 to 44. Each coplanar line 4
If the line width and line spacing of 5 to 48 are set to appropriate values, signals of equal amplitude can be output to the four output terminals 41 to 44. The signals at the first output terminal 41 and the fourth output terminal 44 are in phase, and the signals at the second output terminal 42 and the third output terminal 43 are also in phase. Further, a phase difference of 180 degrees occurs between the former and latter signals.
When the loads on the second output terminal 42 and the third output terminal 43 are unbalanced, the signals in the unbalanced mode reflected by these loads are output to the second output terminal 41 and the third output terminal 43.
However, the impedance of the unbalanced mode signal is absorbed by the isolation resistor 25, and the second unbalanced mode signal is absorbed by the isolation resistor 25. The isolation characteristics of the output terminal 42 and the third output terminal 43 are improved. By the same operation, the isolation characteristics of the first output terminal 41 and the fourth output terminal 44 are also improved.

Eleventh Embodiment 11 is a block diagram of a push-pull amplifier according to Embodiment 11 of the present invention.
In FIG. 11, 49 is a first amplifier, 50 is a second amplifier, 51 is an input side balun, 52 is an output side balun, and 53.
Is an input terminal of the push-pull amplifier, and 54 is an output terminal of the push-pull amplifier.

Here, as the input-side balun 51 and the output-side balun 52, the balun of any of the above-described first to tenth embodiments is used. The first amplifier 49 and the second amplifier 50 are operated in class B or class AB. The signal input from the input terminal 53 of the push-pull amplifier is distributed by the input-side balun 51 into two signals having the same amplitude but different phases by 180 degrees. These two signals are amplified by the first amplifier 49 and the second amplifier 50, respectively, and then combined by the output side balun 52, and the output terminal 54 of the push-pull amplifier.
Is output from. From input terminal to input side balun 51, first
Of the amplifier 49 and the output side balun 52 to the output terminal and the signal path from the input terminal to the input side balun 51, the second amplifier 50 and the output side balun 52 to the output terminal are in phase. In addition, the terminal arrangement of the input side balun 51 and the output side balun 52 is targeted.

Next, the operation will be described. Embodiment 1
Since the baluns Nos. 10 to 10 have the distribution characteristics of equal amplitude and different phases by 180 degrees, the first amplifier 49 and the second amplifier 49 have the same distribution characteristics as the conventional baluns having unbalanced distribution characteristics. The output of the amplifier 50 is efficiently combined, and the output and efficiency of the amplifier as a whole are improved. In addition,
In the eleventh embodiment, the case where the output terminal of the input-side balun 51 (the input terminal of the output-side balun 52) is two terminals is described. However, in addition to four terminals as in the ninth or tenth embodiment, 2n terminals are provided. Similarly, in the case of (n is a natural number), it can be implemented by providing an amplifier according to the number of terminals.

[0042]

As described above, according to the balun according to the present invention, since the coupling degree of the coupling line constituted by the two microstrip lines is increased by the capacitor, the amplitudes are extremely close to each other and the phases are different by 180 degrees. Two signals can be picked up.

Further, since the degree of coupling of the rectangular coaxial coupling line is increased by the dielectric sheet provided between the center conductors of the two rectangular coaxial lines, two signals having extremely close amplitudes and phases different by 180 degrees are taken out. be able to.

Further, since the coupling degree of the rectangular coaxial coupling line is enhanced by the floating shield that surrounds the center conductors of the two rectangular coaxial lines, the amplitude is very close to the equal amplitude and the phase is 18 degrees.
It is possible to extract two signals that differ by 0 degrees.

Further, since the degree of coupling of the coplanar coupling line is increased by the third coplanar line, it is possible to extract two signals having extremely close amplitudes and phases different by 180 degrees.

Further, since the isolation resistance provided in the slit of the back surface metal film attenuates the current flowing through the back surface metal film due to the imbalance of the load, the isolation characteristic between the two output terminals is improved.

Further, the isolation resistance provided in the slit of the outer peripheral cylindrical conductor attenuates the current flowing through the outer peripheral cylindrical conductor due to the imbalance of the load, so that the isolation characteristic between the two output terminals is improved.

Further, since the isolation resistance provided in the slit of the outer wall metal film of the hollow cylindrical conductor attenuates the current flowing through the outer peripheral metal film of the hollow cylindrical conductor caused by the imbalance of the load, the output resistance between the two output terminals is reduced. The isolation characteristics are improved.

Further, since the isolation resistance provided in the slit of the grounding metal film of the coplanar line attenuates the current flowing through the grounding metal film due to the imbalance of the load, the isolation characteristic between the two output terminals is reduced. Is improved.

Further, by providing a plurality of microstrip conductors, four divisions can be realized, and the isolation characteristic provided between the predetermined terminals improves the isolation characteristic between the output terminals.

Further, by providing a plurality of coplanar conductors, four divisions can be realized, and the isolation resistance provided between the predetermined terminals improves the isolation characteristic between the output terminals.

Further, according to the push-pull amplifier of the present invention, since the balun having the distribution characteristic of equal amplitude and different phase by 180 degrees is used, the output and efficiency are improved.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a balun according to a first embodiment of the present invention.

FIG. 2 is a configuration diagram of a balun according to a second embodiment of the present invention.

FIG. 3 is a configuration diagram of a balun according to a third embodiment of the present invention.

FIG. 4 is a configuration diagram of a balun according to a fourth embodiment of the present invention.

FIG. 5 is a configuration diagram of a balun according to a fifth embodiment of the present invention.

FIG. 6 is a configuration diagram of a balun according to a sixth embodiment of the present invention.

FIG. 7 is a configuration diagram of a balun according to a seventh embodiment of the present invention.

FIG. 8 is a configuration diagram of a balun according to an eighth embodiment of the present invention.

FIG. 9 is a configuration diagram of a balun according to a ninth embodiment of the present invention.

FIG. 10 is a configuration diagram of a balun according to Embodiment 10 of the present invention.

FIG. 11 is a configuration diagram of a push-pull amplifier according to a tenth embodiment of the present invention.

FIG. 12 is a configuration diagram of a balun according to a conventional example.

FIG. 13 is a configuration diagram of a balun according to another conventional example.

[Explanation of symbols]

2 back metal film, 3 first microstrip line,
4 first microstrip line, 5 first terminal,
6 2nd terminal, 7 3rd terminal, 8 4th terminal, 9
Coaxial line center conductor, 10 Coaxial line outer conductor, 11
Peripheral cylindrical conductor, 12 Capacitor, 14 First center conductor of rectangular coaxial line, 15 Second center conductor of rectangular coaxial line, 16 Dielectric sheet, 17 Floating shield, 18 First metal film for grounding, 19 Second Ground metal film, 20 first coplanar line, 21 second coplanar line, 22 third coplanar line, 23 gold wire, 24, 26, 30 to 32 slit, 25 isolation resistance, 27 inner wall metal film, 28 outer wall metal film, 29 hollow cylindrical insulator, 33-39 first to seventh
Microstrip conductor, 40 input terminals, 41-4
4 1st-4th output terminals, 45-48 1st-4th
Coplanar conductor, 49 First amplifier, 50 Second amplifier, 51 Input side balun, 52 Output side balun, 5
3 Push-pull amplifier input terminal, 54 Push-pull amplifier output terminal.

─────────────────────────────────────────────────── ─── Continuation of the front page (56) Reference JP-A-5-251939 (JP, A) JP-A-63-209201 (JP, A) JP-A-59-36402 (JP, A) JP-A-57- 180202 (JP, A) JP-A-5-67904 (JP, A) JP-B-51-7388 (JP, B1) US patent 5304959 (US, A) US patent 5121090 (US, A) US patent 4739289 (US, A) (58) Fields surveyed (Int.Cl. ⁷ , DB name) H01P 5/10

Claims (11)

(57) [Claims] 1. A first microstrip line having a length of about a quarter wavelength at a signal frequency and a second microstrip line are arranged adjacent to each other in parallel, and an input side of the second microstrip line is provided. The terminal is electrically grounded, the signal is input from the input side terminal of the first microstrip line, and the signal is output from the output side terminal of the first microstrip line and the output side terminal of the second microstrip line. A strip-coupled line balun, wherein the first microstrip line and the second microstrip line are electrically connected via a capacitor. 2. A first central conductor and a second central conductor each having a length of about a quarter wavelength at a signal frequency are arranged adjacent to each other in parallel, and an input side terminal of the second central conductor is electrically connected. In a rectangular coaxial coupling line type balun, which is grounded electrically, inputs a signal from the input side terminal of the first center conductor, and takes out a signal from the output side terminal of the first center conductor and the output side terminal of the second center conductor. ,
A balun, wherein a dielectric sheet is provided between the first central conductor and the second central conductor. 3. A first central conductor and a second central conductor having a length of about a quarter wavelength at a signal frequency are arranged adjacent to each other in parallel, and an input side terminal of the second central conductor is electrically connected. In a rectangular coaxial coupling line type balun, which is grounded electrically, inputs a signal from the input side terminal of the first center conductor, and takes out a signal from the output side terminal of the first center conductor and the output side terminal of the second center conductor. ,
A balun, characterized in that the first central conductor and the second central conductor are surrounded by a floating shield. 4. A first coplanar line and a second coplanar line having a length of about a quarter wavelength at a signal frequency are arranged adjacent to each other in parallel, and an input side terminal of the second coplanar line is electrically connected. In the coplanar coupling line type balun, the signal is inputted from the input side terminal of the first coplanar line and the signal is taken out from the output side terminal of the first coplanar line and the output side terminal of the second coplanar line. A balun, further comprising a third coplanar line provided in parallel with and adjacent to the first coplanar line. 5. A first microstrip line and a second microstrip line having a length of about a quarter wavelength at a signal frequency are arranged adjacent to each other in parallel, and an input side of the second microstrip line is provided. The terminal is electrically grounded, the signal is input from the input side terminal of the first microstrip line, and the signal is output from the output side terminal of the first microstrip line and the output side terminal of the second microstrip line. In the strip-coupled line type balun, a slit is provided in the metal film on the back surface of the dielectric substrate that constitutes the microstrip line, and the length of this slit is set to one quarter wavelength at the signal frequency on one side and the slit part is isolated. A balun that is equipped with a ration resistance. 6. An outer peripheral cylindrical conductor is further provided on the outer periphery of a coaxial line having a length of about a quarter wavelength at a signal frequency, and an input side terminal of the outer peripheral cylindrical conductor and an input side terminal of the outer conductor of the coaxial line are electrically connected. In the coaxial line type balun, the signal is input from the input side terminal of the center conductor of the coaxial line, and the signal is extracted from the output side terminal of the center conductor of the coaxial line and the output side terminal of the outer conductor of the coaxial line. Provide a slit in the cylindrical conductor,
A balun characterized by mounting an isolation resistor in this slit part. The outer conductor of 7. signal frequency of about quarter wave length coaxial line of the inner wall of the hollow insulator constituted by providing the metal film, provided on the inner wall of the hollow insulator The input side terminal of the metal film is electrically grounded, a signal is input from the input side terminal of the center conductor of the coaxial line, and the output side terminal of the center conductor of the coaxial line and the metal film provided on the inner wall of the hollow insulator In the coaxial line type balun that takes out the signal from the output side terminal,
A balun characterized in that a slit is provided in a metal film provided on an outer wall of a hollow insulator, and an isolation resistance is mounted on the slit portion. 8. The balun according to claim 4, wherein the metal film for grounding the coplanar line is provided with a slit having a length of about a quarter wavelength at a signal frequency, and an isolation resistor is mounted on the slit portion. Balun characterized by that. 9. The first to seventh microstrip lines each having a length of about a quarter wavelength at a signal frequency are arranged adjacent to each other in parallel, and the first, third, fifth and seventh microstrip lines are arranged. The input side terminal of the line is electrically grounded, and the output side terminals of the first and third and fifth and seventh microstrip lines are electrically connected, respectively, and the second, sixth, third and third The output side terminals of the microstrip line 5 are respectively connected through isolation resistors, and signals are input from the terminals obtained by bundling the input side terminals of the second, fourth, and sixth microstrip lines. A balun, wherein four output signals are taken out from the output side terminals of the second, sixth, and seventh microstrip lines. 10. The first to fourth coplanar lines having a length of about a quarter wavelength at a signal frequency are arranged adjacent to each other in parallel, and the input side terminals of the first and fourth coplanar lines are electrically connected. From the terminal that is connected to the output side terminals of the first and fourth and second and third coplanar lines through an isolation resistor, and the input side terminals of the second and third coplanar lines are bundled together. A balun, wherein signals are input and four output signals are taken out from the output side terminals of the first to fourth coplanar lines. 11. The balun according to any one of claims 1 to 10 is provided on an input side and an output side, and the number of output terminals of the input side balun is set between the input side balun and the output side balun. A push-pull amplifier having a plurality of amplifiers arranged in parallel.