A resonance pattern (21) made of conductive material and having a circular plan shape is formed over the principal surface of a dielectric substrate. first and second virtual straight lines mutually crossing at a right angle are defined. A first input port (22) and a first output port (23) are electromagnetically coupled to the resonance pattern at two cross points between the first virtual straight line and an outer circumference line of the resonance pattern. A second input port (24) and a second output port (25) are electromagnetically coupled to the resonance pattern at two cross points between the second virtual straight line and the outer circumference line of the resonance pattern. A first inter-port waveguide (26) propagates a high frequency signal output to the first output port to the second input port.
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3. A high frequency filter comprising:
a substrate comprised of dielectric material;
a first resonance pattern comprised of conductive material, disposed over a principal surface of the substrate and having a circular plan shape, that is substantially solid;
a first input port electromagnetically coupled with the first resonance pattern at one cross point between a first virtual straight line passing through a center of the first resonance pattern and an outer circumference line of the first resonance pattern;
a first output port electromagnetically coupled with the first resonance pattern at the other cross point between the first virtual straight line and the outer circumference line of the first resonance pattern;
a second input port electromagnetically coupled with the first resonance pattern at one cross point between a second virtual straight line and the outer circumference line of the first resonance pattern, the second virtual straight line passing through the center of the first resonance pattern and crossing the first virtual straight line at a right angle;
a second output port electromagnetically coupled with the first resonance pattern at the other cross point between the second virtual straight line and the outer circumference line of the first resonance pattern; and
a first inter-port waveguide for propagating a high frequency signal from the first output port to the second input port,
wherein a transmission line length of the first inter-port waveguide is in a range between 90% and 110% of a transmission line wavelength corresponding to a fundamental resonance frequency of the first resonance pattern.
1. A high frequency filter comprising:
a substrate comprised of dielectric material;
a first resonance pattern comprised of conductive material, disposed over a principal surface of the substrate and having a circular plan shape, that is substantially solid;
a first input port electromagnetically coupled with the first resonance pattern at one cross point between a first virtual straight line passing through a center of the first resonance pattern and an outer circumference line of the first resonance pattern;
a first output port electromagnetically coupled with the first resonance pattern at the other cross point between the first virtual straight line and the outer circumference line of the first resonance pattern;
a second input port electromagnetically coupled with the first resonance pattern at one cross point between a second virtual straight line and the outer circumference line of the first resonance pattern, the second virtual straight line passing through the center of the first resonance pattern and crossing the first virtual straight line at a right angle;
a second output port electromagnetically coupled with the first resonance pattern at the other cross point between the second virtual straight line and the outer circumference line of the first resonance pattern;
a first inter-port waveguide for propagating a high frequency signal from the first output port to the second input port;
a second resonance pattern comprised of conductive material, disposed over the principal surface of the substrate and having a same plan shape as the first resonance pattern;
a third input port electromagnetically coupled with the second resonance pattern at one cross point between a third virtual straight line passing through a center of the second resonance pattern and an outer circumference line of the second resonance pattern;
a third output port electromagnetically coupled with the second resonance pattern at the other cross point between the third virtual straight line and the outer circumference line of the second resonance pattern;
a fourth input port electromagnetically coupled with the second resonance pattern at one cross point between a fourth virtual straight line and the outer circumference line of the second resonance pattern, the fourth virtual straight line passing through the center of the second resonance pattern and crossing the third virtual straight line at a right angle;
a fourth output port electromagnetically coupled with the second resonance pattern at the other cross point between the fourth virtual straight line and the outer circumference line of the second resonance pattern;
a second inter-port waveguide for propagating a high frequency signal from the third output port to the fourth input port; and
an inter-stage waveguide for propagating a high frequency signal from the second output port to the third input port,
wherein a transmission line length of the inter-stage waveguide is ⅜times a transmission line wavelength corresponding to a fundamental resonance frequency of the first resonance pattern.
2. A high frequency filter comprising:
a substrate comprised of dielectric material;
a first resonance pattern comprised of conductive material, disposed over a principal surface of the substrate and having a circular plan shape, that is substantially solid;
a first input port electromagnetically coupled with the first resonance pattern at one cross point between a first virtual straight line passing through a center of the first resonance pattern and an outer circumference line of the first resonance pattern;
a first output port electromagnetically coupled with the first resonance pattern at the other cross point between the first virtual straight line and the outer circumference line of the first resonance pattern;
a second input port electromagnetically coupled with the first resonance pattern at one cross point between a second virtual straight line and the outer circumference line of the first resonance pattern, the second virtual straight line passing through the center of the first resonance pattern and crossing the first virtual straight line at a right angle;
a second output port electromagnetically coupled with the first resonance pattern at the other cross point between the second virtual straight line and the outer circumference line of the first resonance pattern;
a first inter-port waveguide for propagating a high frequency signal from the first output Dort to the second input Dort;
a second resonance pattern comprised of conductive material, disposed over the principal surface of the substrate and having a same plan shape as the first resonance pattern;
a third input port electromagnetically coupled with the second resonance pattern at one cross point between a third virtual straight line passing through a center of the second resonance pattern and an outer circumference line of the second resonance pattern;
a third output port electromagnetically coupled with the second resonance pattern at the other cross point between the third virtual straight line and the outer circumference line of the second resonance pattern;
a fourth input port electromagnetically coupled with the second resonance pattern at one cross point between a fourth virtual straight line and the outer circumference line of the second resonance pattern, the fourth virtual straight line passing through the center of the second resonance pattern and crossing the third virtual straight line at a right angle;
a fourth output port electromagnetically coupled with the second resonance pattern at the other cross point between the fourth virtual straight line and the outer circumference line of the second resonance pattern;
a second inter-port waveguide for propagating a high frequency signal from the third output port to the fourth input port; and
an inter-stage waveguide for propagating a high frequency signal from the second output port to the third input port,
wherein as viewed toward the principal surface of the substrate, a direction of rotation from the first output port toward the second input port around the center of the first resonance pattern, is opposite to a direction of rotation from the third output port toward the fourth input port around the center of the second resonance pattern.
4. The high frequency filter according to
5. The high frequency filter according to
6. The high frequency filter according to
7. The high frequency filter according to
8. The high frequency filter according to
a dielectric member disposed in a region to be influenced by a generated electromagnetic field, at least at one of a coupling portion between the first resonance pattern and the first output port and a coupling portion between the first resonance pattern and the second input port; and
a support member for supporting the dielectric member so as to be capable of changing a gap between the substrate and the dielectric member.
9. The high frequency filter according to
10. The high frequency filter according to
a package for accommodating and electrically shielding the substrate;
an input coaxial connector mounted on the package and connected to the first input port; and
an output coaxial connector mounted on the package and connected to the second output port.
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This application is based on and claims priority of Japanese Patent Application Nos. 2007-115538 filed on Apr. 25, 2007 and 2008-069914 filed on Mar. 18, 2008, the entire contents of which are incorporated herein by reference.
A) Field of the Invention
The present invention relates to a high frequency filter having a resonance pattern of a microstrip line or a strip line structure.
B) Description of the Related Art
On a principal surface of a dielectric substrate 101 (
Another dielectric substrate 110 is placed on the resonance pattern 102 as illustrated in
Degeneration of two electromagnetic field modes of the resonance pattern 102 mutually crossing at a right angle is resolved and the resonance frequency is separated because the conductive pattern 111 and resonance pattern 102 are electromagnetically coupled with each other. In this state, the high frequency device shown in
As compared with a hair pin type resonance pattern and a straight line type resonance pattern, in the disc type resonance pattern shown in
The characteristics of the high frequency filter shown in
One possible object is to provide a high frequency filter capable of inhibiting current concentration upon a specific area of a resonance pattern and deviation of the filter characteristics from design values.
The present invention is directed to an embodiment of a high frequency filter including:
a substrate made of dielectric material;
a first resonance pattern made of conductive material, formed over a principal surface of the substrate and having a circular plan shape;
a first input port electromagnetically coupled with the first resonance pattern at one cross point between a first virtual straight line passing through a center of the first resonance pattern and an outer circumference line of the first resonance pattern;
a first output port electromagnetically coupled with the first resonance pattern at the other cross point between the first virtual straight line and the outer circumference line of the first resonance pattern;
a second input port electromagnetically coupled with the first resonance pattern at one cross point between a second virtual straight line and the outer circumference line of the first resonance pattern, the second virtual straight line passing through the center of the first resonance pattern and crossing the first virtual straight line at a right angle;
a second output port electromagnetically coupled with the first resonance pattern at the other cross point between the second virtual straight line and the outer circumference line of the first resonance pattern; and
a first inter-port waveguide for propagating a high frequency signal from the first output port to the second input port.
It must be noted that like features depicted in the different drawing or figures are designated by the same reference numbers and may not be described in detail for all drawing or figures in which they appear.
A dielectric substrate 20 (
The package main body 15A is a container of a rectangular parallelepiped shape with an upper opening, and this opening is closed with a ceiling plate 15B as illustrated in
The dielectric substrate 20 is made of magnesium oxide (MgO) exposing a (100) crystal plane on its principal surface, and has a thickness of 0.5 mm. Material of the dielectric substrate 20 may be dielectric material having a high dielectric constant and a low loss such as LaAlO3 and sapphire.
As shown in
d=(n/2)λr (n is a natural number) (1)
where λr is a wavelength of a high frequency signal resonating in the resonance pattern 21 and d is a diameter of the resonance pattern 21. A frequency corresponding to a wavelength λr at n=1 is called a “fundamental resonance frequency”. Namely, a signal at the fundamental resonance frequency of the resonance pattern 21 has a wavelength of twice as long as the diameter, i.e., 22 mm. An actual resonance frequency can be obtained from an effective dielectric constant of the microstrip line and a resonance frequency measured electrically. Practically, the wavelength of a resonating high frequency signal shifts slightly from the resonance wavelength λr calculated by the formula (1) because of leakage radiation of an electromagnetic wave from an edge of the resonance pattern 21.
A first virtual straight line 40 and a second virtual straight line 41 are defined which are crossing at a right angle and pass through the center of the resonance pattern 21. At one cross point between the circumference of the resonance pattern 21 and the first virtual straight line 40, the first input port 22 is electromagnetically coupled with the resonance pattern 21, and at the other cross point, the first output port 23 is electromagnetically coupled with the resonance pattern 21. A plan shape of each of the first input port 22 and first output port 23 is a crescent shape having a radius of curvature in conformity with the circumference of the resonance pattern 21, and is line-symmetric with respect to the first virtual straight line 40.
At one cross point between the circumference of the resonance pattern 21 and the second virtual straight line 41, the second input port 24 is electromagnetically coupled with the resonance pattern 21, and at the other cross point, the second output port 25 is electromagnetically coupled with the resonance pattern 21. A plan shape of each of the second input port 24 and second output port 25 is a falcate shape having a radius of curvature in conformity with the circumference of the resonance pattern 21, and is line-symmetric with respect to the second virtual straight line 41. Each of these input and output ports 22 to 25 is disposed spaced by a gap of 25 to 100 μm from the edge of the resonance pattern 21.
An input waveguide 31 is connected to the first input port 22. The input waveguide 31 is disposed along the first virtual straight line 40. An output waveguide 32 is connected to the second output port 25. The output waveguide 32 is disposed along the second virtual straight line 41. The inter-port waveguide 26 connects the first output port 23 to the second input port 24 and transmits a high frequency signal from the first output port 23 to the second input port 24.
The resonance pattern 21, input and output ports 22 to 25, waveguides 31 and 32, inter-port waveguide 26 and ground film 27 are made of YBa2Cu3O6+x (hereinafter called “YBCO”), and have a thickness of 100 to 500 nm. Instead of YBCO, these conductive patterns may be made of superconductive oxide material presenting a superconductivity state at a liquid nitrogen temperature. Examples of the superconductive oxide material include R—Ba—Cu—O based material (R is Nb, Ym, Sm or Ho), Bi—Sr—Ca—Cu—O based material, Pb—Bi—Sr—Ca—Cu—O based material, CuBapCaqCurOx based material (1.5<p<2.5, 2.5<q<3.5, 3.5<r<4.5) and the like.
A width of each of the input waveguide 31, output waveguide 32 and inter-port waveguide 26 is 0.5 mm when these waveguides are formed on the dielectric substrate 20, and the characteristic impedance of each waveguide is 50Ω. An electrode is formed on the surface of each of the input waveguide 31 and output waveguide 32 near the end thereof farther away from the resonance pattern 21, the electrode being a lamination of a Cr film, a Pd film and an Au film stacked in this order.
The YBCO film can be formed, for example, by pulse laser vapor deposition. Each YBCO pattern on the principal surface of the dielectric substrate 20 can be formed by using typical photolithography techniques. The electrode including the Cr film, Pd film and Au film can be formed by vapor deposition and lift-off.
A coaxial input connector 35 and a coaxial output connector 36 are mounted on side walls of the package main body 15A. A central conductor of the input connector 35 is connected to the electrode at the end of the input waveguide 31 by an Au wire having a diameter of 25 μm, and a central conductor of the output connector 36 is connected to the electrode at the end of the output waveguide 32 by an Au wire having a diameter of 25 μm. Instead of the Au wire, an Au ribbon or an Al wire may be used.
Referring to
The abscissa of
As different from the conventional high frequency filter shown in
A waveguide having a width of 0.5 mm formed on an MgO substrate having a thickness of 0.5 mm has an effective dielectric constant of 6.50. Therefore, a wavelength of a high frequency signal at 5 GHz propagating along the waveguide is 23.5 mm. Transmission line lengths of the inter-port waveguides 26 having lengths of 11.3 mm, 12.0 mm and 12.5 mm are therefore 0.48 times, 0.51 times and 0.53 times the transmission line wavelength of a high frequency signal, respectively. A transmission line length of a waveguide normalized by a transmission line wavelength of a signal having a specific frequency and propagating along the waveguide is called an “electrical transmission line length”.
Every high frequency filter takes a maximum value of S21 near at a frequency of 5 GHz, and has an attenuation pole on both sides of this frequency. S11 parameter shows two sharp minimum values near at a frequency of 5 GHz. This indicates that a dual mode resonance occurs in the resonance pattern 21. An interval between these two minimum values broadens as the electrical transmission line length of the inter-port waveguide 26 is made longer. The passband width of S21 broadens as the electrical transmission line length of the inter-port waveguide 26 elongates. This means that as the electrical transmission line length of the inter-port waveguide 26 is made longer, coupling of the dual mode increases.
A change in the pass band with the electrical transmission line length of the inter-port waveguide 26 can be explained by an inter-resonance coupling coefficient k. The inter-resonance coupling coefficient k is given by the following formula:
k=(fh2−fl2)/(fh2+fl2) (2)
where fl and fh (fl<fh) represent two different resonance frequencies while dual mode resonances occur.
The inter-resonance coupling coefficient k becomes 0 as a transmission line length of the inter-port waveguide 26 is set to 11.3 mm (the electrical transmission line length normalized by the transmission line wavelength of a high frequency signal at a frequency of 5 GHz is about 0.48), and the passband width becomes narrowest. As the inter-port waveguide 26 is elongated, the inter-resonance coupling coefficient k increases. It can be understood from the graph shown in
The electrical transmission line length of the inter-port waveguide 26 depends on its geometrical length and width, a gap between the first output port 23 and resonance pattern 21, a gap between the second input port 24 and resonance pattern 21, a dielectric constant of ambient space of the inter-port waveguide 26, and the like. By changing these parameters, the electrical line length of the inter-port waveguide 26 can therefore be changed.
In the range between 20.5 mm and 24.5 mm of the transmission line length of the inter-port waveguide 26, as the transmission line length becomes longer, the transmission band shifts toward the low frequency side. The transmission characteristics show a similar tendency if the transmission line length of the inter-port waveguide 26 is in the range between 0.9 times and 1.1 times the transmission line wavelength corresponding to the fundamental resonance frequency. It is therefore possible to shift the transmission band, by changing the transmission line length of the inter-port waveguide 26 in the range between 0.9 times and 1.1 times the transmission line wavelength corresponding to the fundamental resonance frequency.
As described above, the second stage conductive pattern is equal to a mirror image of the first stage conductive pattern. Therefore, as viewed toward the principal surface of the dielectric substrate 20 (
An inter-stage waveguide 50 interconnects the second output port 25 of the first stage and the third input port 22A of the second stage. A transmission line length of the inter-stage waveguide 50 is ⅜ times the transmission line wavelength corresponding to the fundamental resonance.
The second stage conductive pattern is coincident with a conductive pattern obtained by rotating the first stage conductive pattern itself. Therefore, as viewed toward the principal surface of the dielectric substrate 20, a direction (clockwise direction in
An inter-stage waveguide 50 interconnects the second output port 25 of the first stage and the third input port 22B of the second stage. A transmission line length of the inter-stage waveguide 50 is ⅜ times the transmission line wavelength corresponding to the fundamental resonance.
In the second embodiment, two attenuation poles appear on both sides of the passband. In contract, in the comparative example, no attenuation pole appears. As in the second embodiment, by giving a mirror image relation between the first stage conductive pattern and second stage conductive pattern, the cutoff frequency characteristics can be made sharper. It can be considered that different behaviors of the transmission characteristics between the high frequency filter of the second embodiment and the high frequency filter of the comparative example may be ascribed to that electromagnetic waves radiated upward from the resonance patterns of the first and second stages are mutually influenced.
When the electrical transmission line length of the inter-stage waveguide 50 is set equal to the transmission line wavelength, a resonance peak pL appears on the low frequency side of the passband. When the electrical transmission line length of the inter-stage waveguide 50 is set ½ times the transmission line wavelength, a resonance peak pH appears on the high frequency side of the passband. In contrast, when the electrical transmission line length of the inter-stage waveguide 50 is set ⅜ times the transmission line wavelength, good band pass filter characteristics are obtained.
As seen from the evaluation results, it is preferable that the electrical transmission line length of the inter-stage waveguide 50 is set ⅜ times the transmission line wavelength corresponding to the fundamental resonance frequency.
Although the high frequency filter of the second embodiment is constituted of two stages, a structure constituted of a plurality of three or more stages may be adopted. In this case, in order to make sharp the frequency cutoff characteristics, it is preferable that the conductive pattern at an odd number stage and the conductive pattern at an even number stage have mutually a mirror image relation.
In the first and second embodiments, although the plan shapes of the input and output ports are a crescent shape, other shapes may also be used so long as they provide electromagnetic coupling to the resonance pattern.
The structure of a dielectric substrate 20, conductive patterns 21, 22 and 23 and the like on the principal surface of the substrate and a ground film 27 on the bottom surface is the same as that of the high frequency filter of the first embodiment. A dielectric film 60 is disposed on the principal surface of the dielectric substrate 20, covering the conductive patterns 21, 22 and 23 and the like. On the surface of the dielectric film 60, an upper ground film 61 is formed.
Even with this strip line structure, it is possible to obtain advantages as in the case of the high frequency filter of the microstrip line structure. The inner conductive patterns 21, 22 and 23 and the like may have a multiple stage structure like the high frequency filter of the second embodiment.
In the first to third embodiments, since the resonance pattern and the like are formed on one side of the substrate, a manufacture efficiency is high, and more distinctive advantages are expected particularly when the resonator is made of multiple stages. Further, since a circular resonance pattern is used, electric power tolerance is high, and nonlinearity upon input of large electric power can be suppressed.
A first dielectric member 70 and a second dielectric member 71 are disposed above a dielectric substrate 20 (
The first dielectric member 70 is supported via a first support member 72 to a package 15 (
As the first support member 72, for example, a screw threaded with a through hole formed through the wall of a ceiling plate 15B of the package 15 may be used. By rotating the screw, the first dielectric member 70 can be raised and lowered. As the first support member 72, a linear actuator may be used which makes an object translate in response to a drive signal from an external.
Similar to the first dielectric member 70, the second dielectric member 71 is supported via a second support member 73 to the package 15 to be able to rise and fall.
As the first dielectric member 70 and second dielectric member 71 are raised and lowered, an electrostatic capacitance between the resonance pattern 21 and first output port 23 and an electrostatic capacitance between the resonance pattern 21 and second input port 24 change. The transmission characteristics and reflection characteristics of the high frequency filter change correspondingly.
It can be understood that the passband width becomes broad as the first dielectric member 70 and second dielectric member 71 are disposed. In this case, the center frequency hardly changes. As a gap is generated between the first dielectric member 70 and substrate 20 and between the second dielectric member 71 and substrate 20, the passband width has an intermediate width between when the dielectric members are disposed and when the dielectric members are not disposed, as shown in
In order to enhance controllability of the passband width, it is preferable to dispose the first dielectric member 70 and second dielectric member 71 in the region where an electromagnetic field is strong. For example, it is preferable to dispose the first dielectric member 70 so as to overlap with the gap between the resonance pattern 21 and first output port 23 as viewed in plane-view as illustrated in
It is preferable to use a structure that the first dielectric member 70 and second dielectric member 71 can be disposed in such a manner that a gap between the first dielectric member 70 and substrate 20 and a gap between the second dielectric member 71 and substrate 20 are equal to or narrower than 10 nm.
In the fourth embodiment, although the first dielectric member 70 and second dielectric member 71 have a disc shape, other geometrical shapes such as a cylinder shape, a cube shape and a rectangular parallelepiped shape may be used.
Also in the fourth embodiment, although MgO is used as the material of the first dielectric member 70 and second dielectric member 71, other dielectric materials may also be used. In order to enhance controllability and reduce a loss, it is preferable to use material having a high dielectric constant and a small dielectric loss. Such material is, for example, SrTiO3, TiO2, Al2O3 or the like other than MgO. The first dielectric member 70 and first support member 72 may be cast from one body made of dielectric material. Similarly, the second dielectric member 71 and second support member 73 may be casted from one body made of dielectric material.
If dielectric members are disposed near the coupling portion between the resonance pattern 21 and first input port 22 and near the coupling portion between the resonance pattern 21 and second output port 25, sharpness of the transmission characteristics changes, while the passband width hardly changes. Therefore, in order to control the passband width, it is preferable to dispose a dielectric member near at least one of coupling portions between the resonance pattern 21 and first output port 23 and between the resonance pattern 21 and second input port 24.
Although the present invention has been described in connection with the embodiments, the present invention is not limited thereto. For example, it is apparent to those skilled in the art that various modifications, improvements, combinations and the like are possible.
Yamanaka, Kazunori, Ishii, Masatoshi, Nakanishi, Teru, Akasegawa, Akihiko, Baniecki, John D.
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