JP3239612B2 - Power distributor - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power distributor mainly used for microwaves.

[0002]

2. Description of the Related Art There is a fan-shaped planar circuit power multi-distributor as a power distributor for branching a microwave signal wave on a transmission line as required. FIG. 8 shows that a microwave signal wave is
It is the perspective view which deleted and showed a part of composition of the fan-shaped plane circuit power distributor which distributes. In the figure, 1 is a flat ground conductor, 1a is a ground conductor below the power distributor, 1b is a ground conductor above the power distributor, 2 is a dielectric substrate adhered on the ground conductor 1, and 2a Is a dielectric substrate adhered to the upper surface of the ground conductor 1a, 2b is a dielectric substrate adhered to the lower surface of the ground conductor 1b, 3 is a thin film resistor provided on the dielectric substrate 2a,
4 is a strip conductor provided on the thin film resistor 3, 5 is a ground conductor 1, a dielectric substrate 2, a thin film resistor 3, and a strip conductor 4
It is a triplate type strip line composed of
5a is an input line, 5b is a branch, and 5c is an output line. Reference numeral 6 denotes a ground conductor 1, a dielectric substrate 2, and a thin film resistor 3.
Is a linear flat plate type isolation resistor consisting of 7
Is a slot provided in the branch portion 5b. here,
Reference numeral 6a denotes an isolation resistor having a high resistance value, and 6b denotes an isolation resistor having a low resistance value, each of which is formed in a shape that linearly connects the output lines 5c. Also, 6
c is a low resistance linear flat plate type isolation resistor formed in the middle of the slot 7. By the way, on the dielectric substrate used in the actual pattern production of the input line 5a, the branch portion 5b, the output line 5c and the isolation resistor 6, only one surface has a copper foil attached thereto, and the other surface has a dielectric material. And a thin film resistor is added between the copper foil. Therefore, the input line 5a, the branching portion 5b, the output line 5c, and the isolation resistors 6a, 6b, 6c are formed of a copper foil and a thin film in an outer region with respect to a certain surface of the thin film resistor according to its outer shape. It is formed by performing pattern etching so as to remove the resistor, and then performing etching to remove only the copper foil so that the thin film resistor is exposed only in the pattern portion of the isolation resistor.

Next, the operation will be described. The microwave signal input from the input line 5a is equally distributed in the branching unit 5b, and is output from the output line 5c at the same power ratio. At this time, the reflected wave of the microwave from each output line 5c is absorbed by the isolation resistors 6a and 6b provided between the output lines 5c and the slot 7 provided with the isolation resistor 6c, so that good power distribution characteristics are obtained. Is obtained. Here, each isolation resistor 6
Is determined mainly by the number of distributions of the power distributor, and the arrangement position is substantially determined by the operating frequency.
For example, FIG. 9 is a view of the vicinity of the isolation resistors 6a and 6b of the power distributor of FIG. 8 as viewed from above. Assuming that the length of one wavelength of the output line at the operating frequency of this power divider is λ, the isolation resistor 6a having a high resistance value is located at λ / 4 from the boundary between the branch portion 5b and the output line 5c. The isolation resistor 6b having a resistance value is connected to the branch portion 5b.
And λ / 4 from the boundary of the output line 5c. The resistance value R of the isolation resistor 6 is related to the width w, the height h, the length L, and the resistance value ρ per unit volume of the thin film resistor 3 as shown in the following equation (1).

[0004]

(Equation 1)

Here, the length L of the isolation resistor 6
Is determined by the interval between the output lines at the place where the isolation resistor is arranged, and finally, a desired resistance value R is realized by changing the width w of the isolation resistor 6.

[0006]

With the above configuration, in the conventional power distributor, the strip conductor and the isolation resistor are formed on the same dielectric substrate by pattern etching as shown in FIG. The resistance value of the isolation resistor can be set to any value by changing the area exposed by etching without causing contact failure with the isolation resistor.However, in actual strip line and isolation resistor pattern fabrication, As shown in FIG. 10, when the etching region 8 is slightly displaced in the vertical direction, the copper foil portion 9 for conducting between the output lines remains in the isolation, and there is a problem that the electric characteristics of the power distributor are largely deteriorated. Further, if an etching method is used in which the copper foil portion is shaved on the inside of the wide etching region 10 as shown in FIG. As shown in FIG. 12, there is a problem that a large discontinuous portion 11 is formed in the output line, and the electrical characteristics of the power distributor are largely deteriorated. Furthermore, since the resistance of the isolation resistor itself is adjusted only by its width, the width becomes very narrow as the desired resistance becomes higher, so that the wire is disconnected by a small external pressure or the time required for the etching process is reduced. There was a problem that the resulting resistance value was greatly changed by a slight difference.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the first embodiment to suppress the deterioration of the electrical characteristics of a power distributor due to a small deviation at the time of pattern etching. Further, the second and third embodiments aim at obtaining a power distributor which can realize a high resistance value without reducing the width of the isolation resistor. Further, the fourth, fifth and sixth embodiments have the object of obtaining the power divider. In addition, in the seventh embodiment, a power divider capable of suppressing the deterioration of the electrical characteristics of the power divider due to a small deviation at the time of etching and realizing a high resistance value without reducing the width of the isolation resistor is obtained. It is intended to be.

[0008]

According to a first aspect of the present invention, there is provided a power distributor including a first ground conductor, a first dielectric substrate, and a thin film resistor formed on the first dielectric substrate. Stacking a strip conductor formed on a thin film resistor, a second dielectric substrate, and a second ground conductor in the above order, and forming an input line, a branch portion, a plurality of output lines, And a connecting line connecting between the linear plate type isolation resistor and the output line.

Further, in a power distributor according to a second embodiment of the present invention, a first ground conductor, a first dielectric substrate, a thin film resistor formed on the first dielectric substrate, and a thin film resistor The strip conductor formed above, the second dielectric substrate, and the second ground conductor are stacked in the above order, and the input line, the branch portion, the plurality of output lines, and the plurality of arc-shaped flat plates are formed. And a mold isolation resistor.

In the power distributor according to a third embodiment of the present invention, the first ground conductor, the first dielectric substrate, the thin film resistor formed on the first dielectric substrate, and the thin film resistor An input line, a branch, a plurality of output lines, and a plurality of linear concave mirrors are formed by superposing the strip conductor, the second dielectric substrate, and the second ground conductor formed on the above in the above order. And a mold isolation resistor.

Further, in the power distributor according to the fourth embodiment of the present invention, the first ground conductor, the first dielectric substrate, the thin film resistor formed on the first dielectric substrate, and the thin film resistor The strip conductor formed above, the second dielectric substrate, and the second ground conductor are stacked in the above order, and the input line, the branch portion, the plurality of output lines, and the plurality of arc-shaped flat plates are formed. And a plurality of connecting lines connecting between the arc-shaped flat plate type isolation resistor and the output line.

Further, in a power distributor according to a fifth embodiment of the present invention, a first ground conductor, a first dielectric substrate, a thin film resistor formed on the first dielectric substrate, and a thin film resistor An input line, a branch, a plurality of output lines, and a plurality of linear concave mirrors are formed by superposing the strip conductor, the second dielectric substrate, and the second ground conductor formed on the above in the above order. And a plurality of connecting lines connecting between the linear concave mirror type isolation resistor and the output line.

In the power distributor according to a sixth embodiment of the present invention, a first ground conductor, a first dielectric substrate, a thin film resistor formed on the first dielectric substrate, and a thin film resistor An input line, a branch portion, a plurality of output lines, and a plurality of elliptical flat plates are formed by stacking the strip conductor, the second dielectric substrate, and the second ground conductor formed on the above in the above order. And a plurality of connection lines connecting between the elliptical flat isolation resistor and the output line.

In the power distributor according to a seventh embodiment of the present invention, the first ground conductor, the first dielectric substrate, the thin-film resistor formed on the first dielectric substrate, and the thin-film resistor The strip conductor formed above, the second dielectric substrate, and the second ground conductor are stacked in the above order, and the input line, the branch portion, the plurality of output lines, and the plurality of notches are provided. A flat isolation resistor and a plurality of connection lines connecting between the notched flat isolation resistor and the output line are formed.

[0015]

In the first embodiment of the present invention, a connection line for connecting an output line formed on a first dielectric substrate and a linear flat type isolation resistor between the output lines is formed. As a result, it is possible to suppress the deterioration of the electrical characteristics of the power distributor due to a small deviation when patterning the isolation resistor by etching.
Further, by forming the connection line on the first dielectric substrate by etching in the same manner as the strip conductor, it is possible to easily configure the connection line without impairing mass productivity.

In the second embodiment of the present invention, an arc-shaped flat plate type isolation resistor is formed so as to connect each output line formed on the first dielectric substrate. The resistance value can be increased without reducing the width of the
It is possible to reduce the possibility of disconnection of the isolation resistor due to external pressure or the like, and to improve the yield rate in pattern production of the power divider without impairing mass productivity.

In the third embodiment of the present invention, the isolation resistor itself is formed by forming a linear concave mirror type isolation resistor so as to connect each output line formed on the first dielectric substrate. The resistance value can be increased without reducing the width of the power divider, the possibility of disconnection of the isolation resistor due to external pressure, etc. is reduced, and the yield rate in pattern production of the power divider is impaired in mass production. It can be improved without.

Further, in the fourth embodiment of the present invention, an arc-shaped flat plate type isolation resistor is formed between each output line formed on the first dielectric substrate, and the output line and the arc-shaped flat plate are further formed. By forming a connection line that connects the isolation resistor to the mold, it is possible to suppress the deterioration of the electrical characteristics of the power distributor due to a small deviation when the isolation resistor is patterned by etching.
In addition, the resistance value of the isolation resistor can be increased without reducing the width of the isolation resistor itself, the possibility of disconnection of the isolation resistor due to external pressure, etc. is reduced, and the yield rate in pattern production of the power divider is reduced. It can be improved without impairing mass productivity.

In a fifth embodiment of the present invention, a linear concave mirror type isolation resistor is formed between each output line formed on the first dielectric substrate, and the output line and the linear concave mirror are further formed. By forming a connection line that connects to the isolation resistor, it is possible to suppress the deterioration of the electrical characteristics of the power divider due to a small deviation when the isolation resistor is patterned by etching. The resistance value can be increased without reducing the width of the resistor itself, reducing the possibility of disconnection of the isolation resistor due to external pressure, etc., and impairing the yield rate in pattern production of the power divider and impairing mass productivity. Can be improved without the

In the sixth embodiment of the present invention, an elliptical flat isolation resistor is formed between the output lines formed on the first dielectric substrate, and furthermore, the elliptical flat isolation resistor is formed between the output lines. By forming a connection line connecting the isolation resistor with a flat plate, deterioration of the electrical characteristics of the power distributor due to a small deviation when the isolation resistor is patterned by etching can be suppressed. Reduction of the width of the isolation resistor itself can be kept small, the possibility of disconnection of the isolation resistor due to external pressure etc. is reduced, and the yield rate in pattern production of power dividers is improved without impairing mass productivity Can be done.

In the seventh embodiment of the present invention, a notched plate-type isolation resistor is formed between the output lines formed on the first dielectric substrate, and is further separated from the output lines. By forming a connection line that connects to the notched flat isolation resistor, it is possible to minimize the deterioration of the electrical characteristics of the power divider due to a small deviation when patterning the isolation resistor by etching. In addition, the reduction of the width of the isolation resistor itself can be suppressed, the possibility of disconnection of the isolation resistor due to external pressure, etc. is reduced, and the yield rate in pattern production of the power distributor is impaired in mass production. It can be improved without.

[0022]

【Example】

Embodiment 1 FIG. FIG. 1 is a configuration diagram of a power distributor according to Embodiment 1 of the present invention. In the figure, reference numeral 12 denotes a connecting line connecting the output line 5c and the linear flat plate type isolation 6. FIG. 13 shows an example of a configuration near the isolation resistors 6a and 6b. The length of one wavelength of the output line at the operating frequency of this power divider is λ
Then, the connection line 12a connecting the high-resistance isolation resistor 6a and the output line 5c is located at λ / 4 from the boundary between the branching portion 5b and the output line 5c, and the low-resistance isolation resistor 6b and the output line 5c are connected. Connecting line 12 connecting 5c
b is provided at a position of λ / 8 from the boundary between the branch portion and the output line. Here, the input line 5a, the branch portion 5b, and the output line 5
c, the connection lines 12a, 12b and the isolation resistors 6a, 6b, 6c are removed by etching the outer copper foil and the thin film resistor according to the outer shape, and then the etching region 10 as shown in FIG. It is formed by performing etching so as to remove the copper foil on the thin film resistor only at the end.

Next, the operation of the first embodiment will be described. The microwave signal input from the input line 5a is equally distributed in the branching unit 5b, and is output from the output line 5c at the same power ratio. At this time, the reflected wave of the microwave signal from each output line 5c is absorbed by the isolation resistors 6a and 6b provided between the connection lines 12 and the slot 7 provided with the isolation resistor 6c, so that good power distribution is achieved. Characteristics will be obtained. Here, even if the vertical and horizontal deviations occur in the actual pattern etching of the linear isolation resistors 6a and 6b, FIG.
As described above, since a large discontinuous portion does not occur in the output line 5c, deterioration of the electrical characteristics due to manufacturing errors is suppressed. The length L of the isolations 6a and 6b is reduced by providing the connection line 12, but the original resistance value R can be realized by reducing the width w.

In the first embodiment, the case of four distributors has been described. However, three, five, or six or more distributors may be provided, and the same effects as in the first embodiment can be obtained.

Embodiment 2 FIG. FIG. 2 is a configuration diagram of a power distributor according to Embodiment 2 of the present invention. In the figure, reference numeral 13 denotes an arc-shaped flat plate type isolation resistor. FIG. 16 shows an example of a configuration near the isolation resistor 13. Assuming that the length of one wavelength of the output line at the operating frequency of the power divider is λ, the isolation resistor 13a having a high resistance value is located at λ / 4 from the boundary between the branch portion 5b and the output line 5c. The isolation resistor 13b having a resistance value is provided at a position of λ / 8 from the boundary between the branch portion and the output line. Here, the input line 5a, the branch portion 5b, the output line 5c, the arc-shaped flat plate type isolation resistor 13a, 1
3b and the linear flat plate type isolation resistor 6c are removed by etching the copper foil and the thin film resistor outside thereof according to the outer shape, and then the region 1 as shown in FIG.
Only 4 is formed by etching so as to remove the copper foil on the thin film resistor.

Next, the operation of the second embodiment will be described. The microwave signal input from the input line 5a is equally distributed in the branching unit 5b, and is output from the output line 5c at the same power ratio. At this time, the reflected wave of the microwave signal from each output line 5c is transmitted by the slots 7 provided with the arc-shaped plate-type isolation resistors 13a and 13b and the linear plate-type isolation resistor 6c provided between the output lines 5c. It is absorbed and good power distribution characteristics can be obtained. Here, the arc-shaped plate-type isolation resistor 13 can adjust the length t of the arc by changing the radius r and the angle φ as shown in FIG. 18, and can change the resistance value by changing the length t of the arc. R can be adjusted. Thus, even if the desired isolation resistance value is high, the width w can be realized by increasing the length t of the arc without reducing the width w. Therefore, when the width of the isolation resistor is reduced, the external pressure that frequently occurs is reduced. Thus, problems such as disconnection due to disconnection and a change in resistance value due to a minute difference in etching time are eliminated.

In the second embodiment, the case where the arc-shaped flat plate type isolation resistor is used has been described.
The same effect can be obtained by using a broken-line plate-shaped isolation resistor instead of using the arc-shaped plate-shaped isolation resistors 13a and 13b.

In the above-described second embodiment, the case of a four-way distributor has been described. However, the number of distributions may be three, five, or six or more, and the same effects as in the second embodiment can be obtained.

Embodiment 3 FIG. FIG. 3 is a configuration diagram of a power distributor according to Embodiment 3 of the present invention. In the figure, reference numeral 15 denotes a linear concave mirror type isolation resistor. FIG.
3 shows an example of a configuration near the isolation resistor 15. Assuming that the length of one wavelength of the output line at the operating frequency of the power divider is λ, the isolation resistor 12a having a high resistance value is located at λ / 4 from the boundary between the branch portion 5b and the output line 5c. The isolation resistor 12b having a resistance value is provided at a position of λ / 8 from the boundary between the branch portion and the output line. Here, the input line 5a, the branch portion 5b, the output line 5c, the linear concave mirror type isolation resistor 15
a, 15b and linear plate type isolation resistor 6c
Is etched to remove the copper foil and the thin film resistor outside thereof according to the external shape, and then to remove the copper foil on the thin film resistor only in the etching region 16 as shown in FIG. And then
It is formed by shaving the portion of the thin film resistor appearing on the surface into a concave shape with a laser.

Next, the operation of the third embodiment will be described. The microwave signal input from the input line 5a is equally distributed in the branching unit 5b, and is output from the output line 5c at the same power ratio. At this time, the reflected wave of the microwave signal from each output line 5c is transmitted by the slot 7 provided with the linear concave mirror type isolation resistors 15a and 15b provided between the output lines 5c and the linear flat plate type isolation resistor 6c. It is absorbed and good power distribution characteristics can be obtained. Here, the resistance value R of the linear concave mirror type isolation resistor 15 can be adjusted by changing the depth d of the depression as shown in FIG. Thereby, even when the desired isolation resistance value is high,
This can be realized by increasing the depth d of the depression without reducing the width w, so that when the width of the isolation resistor is reduced, the disconnection due to external pressure that frequently occurs and the change in the resistance value due to a minute difference in etching time are caused. And the like will be solved.

In the third embodiment, the description has been given of the case of the four distributors. However, the number of distributions may be three, five, six or more, and the same effects as in the third embodiment can be obtained.

Embodiment 4 FIG. FIG. 4 is a configuration diagram of a power distributor according to Embodiment 4 of the present invention. FIG. 22 shows an example of a configuration in the vicinity of the arc-shaped flat plate type isolation resistor 13. Assuming that the length of one wavelength of the output line at the operating frequency of the power divider is λ, the connection line 12a connecting the high-resistance isolation resistor 13a and the output line 5c is located at the boundary between the branching portion 5b and the output line 5c. λ / 4
, And the low-resistance isolation resistor 13b
A connecting line 12b connecting the output line 5c and the output line 5c is provided at a position of λ / 8 from the boundary between the branch portion and the output line. Here, the input line 5a, the branching portion 5b, the output line 5c, the connection line 12
a, 12b, arc-shaped plate type isolation resistor 13
a, 13b and linear plate type isolation resistor 6c
23, the copper foil and the thin film resistor on the outer side thereof are removed by etching according to the external shape, and then the etching is performed so that only the etching region 17 as shown in FIG. Is formed.

Next, the operation of the fourth embodiment will be described. The microwave signal input from the input line 5a is equally distributed in the branching unit 5b, and is output from the output line 5c at the same power ratio. At this time, the reflected wave of the microwave signal from each output line 5c is absorbed by the isolation resistances 13a and 13b provided between the connection lines 12 and the slot 7 provided with the isolation resistance 6c, thereby providing good power distribution. Characteristics will be obtained. Here, the arc-shaped plate type isolation resistor 13 can adjust the length t of the arc by changing the radius r and the angle φ as shown in FIG. 23, and can change the resistance value by changing the length t of the arc. R
Can be adjusted. Thus, even if the desired isolation resistance value is high, the width w can be realized by increasing the length t of the arc without reducing the width w. Therefore, when the width of the isolation resistor is reduced, the external pressure that frequently occurs is reduced. Thus, problems such as disconnection due to disconnection and a change in resistance value due to a minute difference in etching time are eliminated. Further, even if the vertical and horizontal deviations occur in the actual pattern etching, a large discontinuous portion cannot be formed in the output line 5c as shown in FIG. 24, so that the deterioration of the electrical characteristics due to a manufacturing error is suppressed.

In the fourth embodiment, the case where the arc-shaped flat plate type isolation resistor is used has been described.
The same effect can be obtained by using a broken-line plate-shaped isolation resistor instead of using the arc-shaped plate-shaped isolation resistors 13a and 13b.

Although the fourth embodiment has been described in connection with the four distributors, the number of distributions may be three, five, six or more, and the same effects as in the fourth embodiment can be obtained.

Embodiment 5 FIG. FIG. 5 is a configuration diagram of a power distributor according to Embodiment 5 of the present invention. FIG. 25 shows an example of a configuration near the linear concave mirror type isolation resistor 15. Assuming that the wavelength of the output line at the operating frequency of the power divider is λ, the connection line 12a connecting the high-resistance isolation resistor 15a to the output line 5c.
Is located at λ / 4 from the boundary between the branching portion 5b and the output line 5c, and the connecting line 12b connecting the low-resistance isolation resistor 15b and the output line 5c is located at λ / 8 from the boundary between the branching portion and the output line. Is provided. Here, input line 5
a, branching section 5b, output line 5c, connecting lines 12a, 12
b, the isolation resistors 15a and 15b and the isolation resistor 6c are formed by removing the copper foil and the thin film resistor outside thereof by etching according to the external shape, and then thinning only the etching region 18 as shown in FIG. Etching is performed so as to remove the copper foil on the resistor, and furthermore, a portion of the thin film resistor appearing on the surface is cut into a concave mirror shape by laser.

Next, the operation of the fifth embodiment will be described. The microwave signal input from the input line 5a is equally distributed in the branching unit 5b, and is output from the output line 5c at the same power ratio. At this time, the reflected wave of the microwave signal from each output line 5c is absorbed by the isolation resistors 15a and 15b provided between the connection lines 12 and the slot 7 provided with the isolation resistor 6c, so that good power distribution is achieved. Characteristics will be obtained. Here, the resistance value R of the linear concave mirror type isolation resistor 15 can be adjusted by changing the depth d of the depression as shown in FIG. Thus, even when the desired isolation resistance value is high, the isolation resistance can be realized by increasing the depth d of the depression without reducing the width w, and therefore, when the width of the isolation resistance is reduced, it is frequently performed. Problems such as disconnection due to the generated external pressure and a change in resistance value due to a minute difference in etching time are eliminated. Further, even if the vertical and horizontal deviations occur in the actual pattern etching, as shown in FIG.
Since a large discontinuous portion cannot be formed in the inside, deterioration of electrical characteristics due to a manufacturing error is also suppressed.

Although the fifth embodiment has been described in connection with the four distributors, the number of distributions may be three, five, six or more, and the same effects as in the fifth embodiment can be obtained.

Embodiment 6 FIG. FIG. 6 is a configuration diagram of a power distributor according to Embodiment 6 of the present invention. In the figure, reference numeral 19 denotes an elliptical flat isolation resistor. FIG. 29 shows an example of a configuration near the isolation resistor 19. One of the output lines at the operating frequency of this power divider
Assuming that the length corresponding to the wavelength is λ, the connecting line 12a connecting the elliptical flat isolation resistor 19a having a high resistance value and the output line 5c is λ / 4 from the boundary between the branch portion 5b and the output line 5c.
And the connecting line 12b connecting the low resistance elliptical flat isolation resistor 19b and the output line 5c is provided at a position of λ / 8 from the boundary between the branch portion and the output line.
Here, the input line 5a, the branch portion 5b, the output line 5c, the connection lines 12a and 12b, the isolation resistor 19a,
19b and the isolation resistor 6c are formed by removing the copper foil and the thin-film resistor on the outside according to the outer shape by etching, and then removing the etching region 2 as shown in FIG.
It is formed by performing etching so as to remove the copper foil on the thin film resistor only for 0.

Next, the operation of the sixth embodiment will be described. The microwave signal input from the input line 5a is equally distributed in the branching unit 5b, and is output from the output line 5c at the same power ratio. At this time, the reflected wave of the microwave signal from each output line 5c is absorbed by the isolation resistances 19a and 19b provided between the connection lines 12 and the slot 7 provided with the isolation resistance 6c, thereby providing good power distribution. Characteristics will be obtained. Here, the elliptical flat isolation resistors 19a and 19b are shown in FIG.
It can be adjusted by changing the horizontal axis diameter a and the vertical axis diameter b as shown in FIG. Accordingly, even when a desired isolation resistance value is high, the pattern width can be realized by increasing the horizontal axis diameter a without reducing the pattern width. Therefore, when the isolation resistance width is reduced, disconnection or etching due to external pressure frequently occurs. Problems such as a change in the resistance value due to a minute difference in time are eliminated. Further, even when the vertical and horizontal deviations occur in the actual pattern etching or when the horizontal axis diameter a is increased to some extent, the discontinuous portion 21 is smoothly formed in the output line 5c as shown in FIG. Therefore, deterioration of the electric characteristics due to this is suppressed to a relatively small amount.

In the sixth embodiment, the case where the elliptical flat isolation resistor is used has been described.
Similar effects can be obtained by using tapered plate-type isolation resistors 22a and 22b as shown in FIG. 32 instead of using the elliptical plate-type isolation resistors 19a and 19b.

In the sixth embodiment, the case where the elliptical flat isolation resistor is used has been described.
Similar effects can be obtained by using flat-plate isolation resistors 23a and 23b with corner cuts as shown in FIG. 33 instead of using the elliptical flat-plate isolation resistors 19a and 19b.

Although the sixth embodiment has been described with reference to the case of a four-way distributor, the number of distributions may be three, five, six or more, and the same effects as in the sixth embodiment can be obtained.

Embodiment 7 FIG. FIG. 7 is a configuration diagram of a power distributor according to Embodiment 7 of the present invention. In the figure, reference numeral 24 denotes a notched flat plate type isolation resistor. FIG.
Shows an example of the configuration near the isolation resistor 24. Assuming that the length of one wavelength of the output line at the operating frequency of the power divider is λ, the connection line 12 connecting the high-resistance isolation resistor 24a and the output line 5c is formed.
a is at a position of λ / 4 from the boundary between the branch portion 5b and the output line 5c, and the connecting line 12b connecting the low-resistance isolation resistor 24b and the output line 5c is at λ / 8 from the boundary between the branch portion and the output line. Position. Here, input line 5
a, branching section 5b, output line 5c, connecting lines 12a, 12
b, the isolation resistors 24a and 24b and the isolation resistor 6c are formed by removing the copper foil and the thin film resistor outside thereof by etching according to the external shape, and then thinning only the etching region 25 as shown in FIG. It is formed by performing etching so as to remove the copper foil on the resistor.

Next, the operation of the seventh embodiment will be described. The microwave signal input from the input line 5a is equally distributed in the branching unit 5b, and is output from the output line 5c at the same power ratio. At this time, the reflected wave of the microwave signal from each output line 5c is absorbed by the isolation resistors 24a and 24b provided between the connection lines 12 and the slot 7 provided with the isolation resistor 6c.
Good power distribution characteristics can be obtained. Here, the notched plate type isolation resistor 24 corresponds to FIG.
It can be adjusted by changing each width w and a length L ₁ and L ₂ as shown in. Thereby, even when the desired isolation resistance value is high, the width w is not reduced,
Can be realized by increasing the length L ₁ or L _2, problems such as changes in the resistance value is eliminated by the minute difference of disconnection and etching time by frequently occurring external pressure when the width of the isolation resistance is thinner Will be. Further, even if the actual case where the shift in the vertical and horizontal directions occurs in the pattern etching and length L ₁ becomes large to some extent, since the area of the discontinuous portion 26 projecting output line within 5c as shown in FIG. 36 are small Thus, the deterioration of the electric characteristics due to this is suppressed to a relatively small value.

Although the seventh embodiment has been described in connection with the four distributors, the number of distributions may be three, five, six or more, and the same effects as in the seventh embodiment can be obtained.

[0047]

According to the present invention, mass productivity is impaired.
To provide a power distributor that can improve and stabilize quality
be able to.

[0048]

[0049]

[0050]

[0051]

[0052]

[0053]

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a power distributor showing a first embodiment of the present invention.

FIG. 2 is a configuration diagram of a power distributor showing a second embodiment of the present invention.

FIG. 3 is a configuration diagram of a power distributor showing a third embodiment of the present invention.

FIG. 4 is a configuration diagram of a power distributor showing a fourth embodiment of the present invention.

FIG. 5 is a configuration diagram of a power distributor showing a fifth embodiment of the present invention.

FIG. 6 is a configuration diagram of a power distributor showing a sixth embodiment of the present invention.

FIG. 7 is a configuration diagram of a power distributor showing a seventh embodiment of the present invention.

FIG. 8 is a configuration diagram showing a conventional power distributor.

FIG. 9 is a configuration diagram of an isolation resistor of a conventional power distributor.

FIG. 10 is a configuration diagram of an isolation resistor portion when a pattern etching shift occurs in a conventional power distributor.

FIG. 11 is a pattern etching region of an isolation resistor of a conventional power distributor.

FIG. 12 is a configuration diagram of an isolation resistor when a pattern etching shift occurs in a conventional power divider.

FIG. 13 is a configuration diagram of an isolation resistor unit of the power distributor according to the first embodiment of the present invention.

FIG. 14 is a pattern etching region of an isolation resistor in the power distributor according to the first embodiment of the present invention.

FIG. 15 is a configuration diagram of an isolation resistor part when a pattern etching shift occurs in the power distributor according to the first embodiment of the present invention.

FIG. 16 is a configuration diagram of an isolation resistor of a power divider according to a second embodiment of the present invention.

FIG. 17 is a pattern etching region of an isolation resistor in the power distributor according to the second embodiment of the present invention.

FIG. 18 is a configuration diagram of an isolation resistor of a power distributor according to a second embodiment of the present invention.

FIG. 19 is a configuration diagram of an isolation resistance part of a power divider according to a third embodiment of the present invention.

FIG. 20 is a pattern etching region of an isolation resistor in a power distributor according to a third embodiment of the present invention.

FIG. 21 is a configuration diagram of an isolation resistor in a power distributor according to a third embodiment of the present invention.

FIG. 22 is a configuration diagram of an isolation resistor of a power divider according to a fourth embodiment of the present invention.

FIG. 23 is a pattern etching region of an isolation resistor in a power distributor according to a fourth embodiment of the present invention.

FIG. 24 is a configuration diagram of an isolation resistor portion when a shift in pattern etching occurs in a power divider according to a fourth embodiment of the present invention.

FIG. 25 is a configuration diagram of an isolation resistance part of a power distributor according to a fifth embodiment of the present invention.

FIG. 26 is a pattern etching region of an isolation resistor in a power distributor according to a fifth embodiment of the present invention.

FIG. 27 is a configuration diagram of an isolation resistor in a power distributor according to a fifth embodiment of the present invention.

FIG. 28 is a configuration diagram of an isolation resistor portion when a shift in pattern etching occurs in a power divider according to a fifth embodiment of the present invention.

FIG. 29 is a configuration diagram of an isolation resistor part of a power divider showing a sixth embodiment of the present invention.

FIG. 30 is a pattern etching region of an isolation resistor in a power distributor according to a sixth embodiment of the present invention.

FIG. 31 is a configuration diagram of an isolation resistor portion when a shift in pattern etching occurs in a power distributor according to a sixth embodiment of the present invention.

FIG. 32 is a configuration diagram of an isolation resistor part of a power distributor according to a sixth embodiment of the present invention.

FIG. 33 is a configuration diagram of an isolation resistance part of a power distributor according to a sixth embodiment of the present invention.

FIG. 34 is a configuration diagram of an isolation resistor part of a power distributor showing a seventh embodiment of the present invention.

FIG. 35 is a pattern etching region of an isolation resistor in a power distributor according to a seventh embodiment of the present invention.

FIG. 36 is a configuration diagram of an isolation resistor when a pattern etching shift occurs in the power distributor according to the seventh embodiment of the present invention.

[Explanation of symbols]

1a First ground conductor 1b Second ground conductor 2a First dielectric substrate 2b Second dielectric substrate 3 Thin film resistor 4 Strip conductor 5a Input line 5b Branch 5c Output line 6a High resistance linear plate Type isolation resistor 6b Linear flat type isolation resistor 6c with low resistance value 6c Linear flat type isolation resistor in slot 7 Slot 8 Etching area of isolation resistance 9 Copper foil part to conduct between output lines 10 Isolation Etching region for preventing conduction of resistance 11 Discontinuous portion formed on output line 12 Connection line 12a Connection line for isolation resistance with high resistance value 12b Connection line for isolation resistance with low resistance value 13 Arc-shaped plate-type isolation resistance 13a High resistance arc flat plate isolation resistor 13b Low resistance Value arc-shaped flat plate isolation resistor 14 arc-shaped flat plate isolation resistor etching area 15 linear concave mirror type isolation resistor 15a high resistance linear concave mirror type isolation resistor 15b low resistance value linear concave mirror type isolator 16 is an etching area of an arc-shaped flat-plate isolation resistor. 18 is an etching area of a linear-concave mirror isolation resistance. 19 is an elliptical flat-plate isolation resistor. 19a is an elliptical shape having a high resistance value. Plate-type isolation resistor 19b Elliptical plate-type isolation resistor with low resistance value 17 Etching region of elliptical plate-type isolation resistor 21 Discontinuous part occurring in output line 22a Tapered plate-type isolation with high resistance value Resistor 22b Low-resistance flat-plate isolation resistor with taper 23a High-resistance flat-plate isolation resistor with corner cut 23b Low-resistance flat-plate isolation resistor with corner cut 24 Notched flat-plate isolation resistor 24a High Flat-plate isolation resistor with cut-out of resistance value 24b Flat-plate isolation resistor with cut-out of low resistance value 25 Etching region of flat-plate isolation resistor with cut-out 26 Discontinuous part generated in output line

Continuation of the front page (56) References JP-A-60-229502 (JP, A) JP-A-62-292007 (JP, A) JP-A-5-199022 (JP, A) JP-A-2-217002 (JP) JP-A-64-29002 (JP, A) JP-A-2-192301 (JP, A) JP-A-4-50901 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB (Name) H01P 5/19

Claims (7)

(57) [Claims] 1. A first ground conductor, a first dielectric substrate having the same shape as the first ground conductor, a thin film resistor provided on the first dielectric substrate, and a thin film resistor A strip conductor provided thereon, a second ground conductor, a second dielectric substrate having the same shape as the second ground conductor, a first ground conductor, a first dielectric substrate, a thin film resistor, It is composed of a triplate strip line formed by stacking a strip conductor, a second dielectric substrate, and a second ground conductor in this order, and includes an input line, a branch portion for branching a signal from the input line, and a branch portion. Each divided signal is output independently and spreads radially from the branch.
And a plurality of output lines, wherein both ends formed between the output lines are parallel on the first dielectric substrate in order to obtain isolation between the output lines.
A linear flat plate isolation resistor having a simple shape ,
Forming the linear plate type isolation resistor between the output line
And a linear flat plate whose both ends are parallel to the output line that spreads radially
And a connection line having a shape that compensates for a difference in shape of the type isolation resistor . 2. A first ground conductor, a first dielectric substrate having the same shape as the first ground conductor, a thin-film resistor provided on the first dielectric substrate, and a thin-film resistor A strip conductor, a second ground conductor, and a second dielectric substrate having the same shape as the second ground conductor are provided on the first ground conductor, the first dielectric substrate, and the thin film resistor. , A strip conductor, a second dielectric substrate, and a second ground conductor, which are formed in this order, a triplate-type strip line, an input line, a branch portion for dividing a signal from the input line, and a branch portion. And a plurality of output lines for independently outputting each of the signals divided by the above, wherein the arc-shaped flat plate for obtaining isolation between the respective output lines is provided on the first dielectric substrate. A power distributor comprising an isolation resistor. 3. A first ground conductor, a first dielectric substrate having the same shape as the first ground conductor, a thin-film resistor provided on the first dielectric substrate, and a thin-film resistor A strip conductor, a second ground conductor, and a second dielectric substrate having the same shape as the second ground conductor are provided on the first ground conductor, the first dielectric substrate, and the thin film resistor. , A strip conductor, a second dielectric substrate, and a second ground conductor, which are formed in this order, a triplate-type strip line, an input line, a branch portion for dividing a signal from the input line, and a branch portion. And a plurality of output lines for independently outputting each of the signals divided by the above, wherein a linear concave mirror type for obtaining isolation between the respective output lines is provided on the first dielectric substrate. A power distributor comprising an isolation resistor. 4. A first ground conductor, a first dielectric substrate having the same shape as the first ground conductor, a thin-film resistor provided on the first dielectric substrate, and a thin-film resistor A strip conductor, a second ground conductor, and a second dielectric substrate having the same shape as the second ground conductor are provided on the first ground conductor, the first dielectric substrate, and the thin film resistor. , A strip conductor, a second dielectric substrate, and a second ground conductor, which are formed in this order, a triplate-type strip line, an input line, a branch portion for dividing a signal from the input line, and a branch portion. And a plurality of output lines for independently outputting each of the signals divided by the above, wherein the arc-shaped flat plate for obtaining isolation between the respective output lines is provided on the first dielectric substrate. Isolation resistor and this arc-shaped flat plate isolation resistor and output A power distributor, comprising: a connection line connecting the lines. 5. A first ground conductor, a first dielectric substrate having the same shape as the first ground conductor, a thin-film resistor provided on the first dielectric substrate, and a thin-film resistor A strip conductor, a second ground conductor, and a second dielectric substrate having the same shape as the second ground conductor are provided on the first ground conductor, the first dielectric substrate, and the thin film resistor. , A strip conductor, a second dielectric substrate, and a second ground conductor, which are formed in this order, a triplate-type strip line, an input line, a branch portion for dividing a signal from the input line, and a branch portion. And a plurality of output lines for independently outputting each of the signals divided by the above, wherein a linear concave mirror type for obtaining isolation between the respective output lines is provided on the first dielectric substrate. Isolation resistance and this linear concave mirror type isolation resistance A power distributor, comprising: a connection line connecting an output line. 6. A first ground conductor, a first dielectric substrate having the same shape as the first ground conductor, a thin-film resistor provided on the first dielectric substrate, and a thin-film resistor A strip conductor, a second ground conductor, and a second dielectric substrate having the same shape as the second ground conductor are provided on the first ground conductor, the first dielectric substrate, and the thin film resistor. , A strip conductor, a second dielectric substrate, and a second ground conductor, which are formed in this order, a triplate-type strip line, an input line, a branch portion for dividing a signal from the input line, and a branch portion. And a plurality of output lines for independently outputting each of the signals divided by the above, wherein the elliptical flat plate type for obtaining isolation between the respective output lines is provided on the first dielectric substrate. Isolation resistor and this elliptical plate type isolation resistor and output A power distributor, comprising: a connecting line connecting the lines. 7. A first ground conductor, a first dielectric substrate having the same shape as the first ground conductor, a thin-film resistor provided on the first dielectric substrate, and a thin-film resistor A strip conductor, a second ground conductor, and a second dielectric substrate having the same shape as the second ground conductor are provided on the first ground conductor, the first dielectric substrate, and the thin film resistor. , A strip conductor, a second dielectric substrate, and a second ground conductor, which are formed in this order, a triplate-type strip line, an input line, a branch portion for dividing a signal from the input line, and a branch portion. And a plurality of output lines for independently outputting each of the signals divided by a notch on the first dielectric substrate for obtaining isolation between the output lines.
A plate-type isolation resistor, power divider, characterized in that a connecting line connecting the notched plate-type isolation resistor and the output line.