DUAL-FREQUENCY MATCHING CIRCUIT
The connection topology of input terminals 2, elements 4a, 4b, 4c and 4d and load 5 is designed similarly to a so-called “seven-segment display”, which is often used to display numerals on an electronic calculator or a digital watch. More specifically, suppose in the three horizontally running segments, the top and bottom segments are associated with the input terminals 2 and the load 5 is allocated to one of the four vertically running segments. Then, the three other vertical segments and the other horizontal segment are associated with the elements 4a, 4b, 4c and 4d, which are a capacitor with a capacitance of 0.403 pF, an inductor with an inductance of 8.981 nH, a capacitor with a capacitance of 0.597 pF, and an inductor with an inductance of 8.216 nH, respectively. By adopting this circuit configuration, the total number of elements can be reduced to four and the loss can be reduced significantly. In addition, since the resonant circuits can be eliminated and the size of the ladder circuit can be reduced, impedance matching is achieved with a high degree of stability.
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This is a continuation of International Application No. PCT/JP2008/002348, with an international filing date of Aug. 28, 2008, which claims priority of Japanese Patent Application No. 2007-222393, filed on Aug. 29, 2007, the contents of which are hereby incorporated by reference.
BACKGROUND OF THE INVENTION1. Field of the Invention
The present invention relates to a dual-frequency impedance matching circuit to be inserted between an antenna and an RF circuit in a mobile terminal in order to carry out impedance matching between the antenna and the RF circuit in two arbitrary frequency bands.
2. Description of the Related Art
As cellphone services have become amazingly popular nowadays, there are increasing demands for an even higher degree of mobility and even more versatile telecommunications services. To meet such demands, it is now one of the major technological objects to develop a mobile terminal that has an even smaller size and yet can use multiple telecommunications systems that are currently operating on mutually different frequency bands (such a device is called a “multi-band device”). Quite the same object is shared by an antenna that is an important device operating as a radio wave input/output interface. That is to say, development of an even smaller antenna operating on multiple different frequency bands (which is called a “multi-band antenna”) is awaited.
In actually developing a mobile terminal, however, it is extremely difficult to realize good antenna properties on multiple desired frequency bands just by optimizing the configuration of the antenna. That is why the final frequency adjustment and good impedance matching with an RF circuit often get done by inserting an appropriate matching circuit between the antenna and the RF circuit. Currently, the frequency bands utilized by various cellphone services are in 800-900 MHz range and 1.5-2 GHz range. To realize a multi-band mobile terminal, its antenna should operate on both of these two frequency bands. However, these two frequency bands are so far apart from each other that it is difficult for a normal single-frequency matching circuit to carry out flexible matching and adjustment on both of these two frequency bands. That is why to achieve the object described above, it is preferable to apply a dual-frequency matching circuit that can carry out independent matching on those two frequency bands.
In such a background, some conventional dual-frequency matching circuits that have been adopted so far include a ladder circuit consisting of multiple single-frequency matching circuits and multiple resonant circuits (see Japanese Patent Application Laid-Open Publication No. 2004-242269 (page 18 and
In
The conventional dual-frequency matching circuit 108 shown in
Consider each of these three matching circuits 103, 104 and 105 as a single circuit block. In that case, the conventional dual-frequency matching circuit 108 shown in FIG. 11 is composed of the two fundamental types of single-frequency matching circuits 121a and 121b shown in
The function of the conventional dual-frequency matching circuit 108 is equivalent to transmitting an RF signal from the input terminal 106 to the load 101 on two desired frequency bands without causing any reflection attenuation. That is why by adopting the ladder circuit 131 shown in
However, the conventional configuration has the following two drawbacks.
Firstly, it is difficult to reduce the loss caused by the dual-frequency matching circuit. To improve the quality of cellphone services, the transmission and receiving properties of mobile terminals must be improved. The transmission and receiving properties are improved mainly by reducing the transmission loss between the antenna and the RF circuit. That is why the loss to be caused by the dual-frequency matching circuit inserted there is preferably as little as possible. The conventional configuration, however, needs too many elements (including inductors and capacitors) and must use a number of resonant circuits, and therefore, is a problem as far as loss reduction is concerned.
Another problem is that it is difficult to stabilize the matching property with respect to the variation in the impedance of the load 101. Normally, when a mobile terminal is used, the user's hand or head comes close to the antenna. That is why the frequency dependency of the impedance for the antenna is affected by how the device is used. For that reason, to ensure stabilized transmission and receiving quality, the matching property must be stabilized with respect to the variation in the impedance of the antenna. However, since the conventional circuit described above includes a lot of resonant circuits, of which the electrical properties (represented by a two-terminal S parameter) vary steeply with the frequency, the matching property is easily affected by the variation in the impedance of the load 101. Furthermore, in the ladder circuit 131, the impedance is transformed in each single-frequency matching circuit 121a, 121b (see
In order to overcome the problems described above, the present invention has an object of providing a dual-frequency matching circuit that causes little loss and that achieves high stability with respect to a variation in the impedance of a load.
SUMMARY OF THE INVENTIONA dual-frequency matching circuit according to the present invention includes: first and second input terminals that receive a first RF signal with a frequency of 0.85 GHz and a second RF signal with a frequency of 1.55 GHz, respectively, from an RF circuit with an impedance of 50 Ω; first and second output terminals that are connected to an antenna; and a group of circuit elements that are connected between the input terminals and the output terminals. The group of circuit elements includes first, second, third and fourth elements. The first and fourth elements are connected in series between the first and second input terminals and the second input terminal is short-circuited with the second output terminal. The second element is connected between the first input terminal and the first output terminal. The third element is connected between a connection node of the first and fourth elements and the first output terminal. The first element is a capacitor with a capacitance of 0.403 pF. The second element is an inductor with an inductance of 8.981 nH. The third element is a capacitor with a capacitance of 0.597 pF. And the fourth element is an inductor with an inductance of 8.216 nH.
In one preferred embodiment, the impedance of the antenna is 66.7-31.9i Ω (where i is an imaginary unit) at a frequency of 0.85 GHz and 43.5-19.2i Ω (where i is an imaginary unit) at a frequency of 1.55 GHz, respectively.
In a specific preferred embodiment, the antenna is an inverted F antenna to be built in a cellphone.
The dual-frequency matching circuit of the present invention can resolve the two major technological issues (i.e., loss reduction and stabilization of matching property).
Other features, elements, processes, steps, characteristics and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments of the present invention with reference to the attached drawings.
Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.
EmbodimentThe dual-frequency matching circuit 1 of this preferred embodiment includes four elements 4a, 4b, 4c and 4d, which are lumped constant elements and each of which is either an inductor or a capacitor. The types of these elements 4a, 4b, 4c and 4d, which should be either inductors or capacitors, and the specific values of their respective element constants are determined unequivocally by the impedance value of the load 5 that has been defined in advance on the two frequency bands, where matching should be achieved, and by the impedance value of the RF circuit connected to the input terminals 2. As for specifically how to determine them, it will be described in detail later.
The connection topology of the input terminals 2, the elements 4a, 4b, 4c and 4d and the load 5 is similar to that of a so-called “seven-segment display”, which is often used to display numerals on an electronic calculator or a digital watch. More specifically, suppose in the three horizontally running segments of the seven-segment display, the top and bottom segments are associated with the input terminals 2 and the load 5 is allocated to one of the four vertically running segments. Then, the three other vertical segments and the other horizontal segment (i.e., four segments in total) are associated with the elements 4a, 4b, 4c and 4d.
Next, it will be described specifically how to determine the element constant values of the elements 4a, 4b, 4c and 4d. Since each of these elements 4a, 4b, 4c and 4d is either an inductor or a capacitor, the impedance of each element is a pure imaginary number. Thus, in the following description, the impedances of the respective elements are supposed to have the signs shown in
As described above, the impedance of each element is represented by a real number quantity αj(f) (where j=1, 2, 3 or 4). Also, depending on whether each element is an inductor or a capacitor, αj(f) (where j=1, 2, 3 or 4) is defined by the following Equation (1):
In Equation (1), Lj and Cj are element constants (i.e., the inductance and capacitance, respectively) of the jth element. At this point in time, those specific values have not been determined yet and are still unknown numbers. That is why the specific Lj and Cj values are obtained by solving the following four simultaneous equations (which will be collectively referred to herein as Equations (2)) at the two frequencies f1 and f2 at which the impedance matching should be achieved.
Equations (2) may be solved in the following manner. First, each of the elements 4a, 4b, 4c and 4d is provisionally supposed to be a capacitor or an inductor. Then, αj (f) (where j=1, 2, 3 or 4) becomes a function relative to the frequency f, including four undetermined element constants (Lj or Cj), according to Equation (1).
Then, the impedance Zr(f) and Zi(f) of the load 5 and the impedance value z0 of the RF circuit connected to the input terminals 2, of which the frequency characteristics are already known, and a j(f) (where j=1, 2, 3 or 4), of which the specific function form has been determined by Equation (1), are substituted into the right sides of the third through sixth ones (as counted from the top) of Equations (2), thereby constituting A(f), B(f), C(f) and D(f).
Then, A(f), B(f), C(f) and D(f), of which the specific function forms relative to the frequency f are now known, are substituted into the two-condition equation on the first and second rows of Equations (2) and two desired frequencies fk (where k=1 and 2) are given, thereby obtaining four mutually independent equations with respect to the four undetermined element constants (Lj or Cj). Then, those four equations are solved simultaneously to derive the four undetermined element constants. It should be noted that since the number of undetermined constants agrees with that of independent equations, Equations (2) always have solutions. However, the element constants must be positive real numbers. That is why only if positive real numbers are obtained as solutions Lj or Cj, the dual-frequency matching circuit of this preferred embodiment can be actually implemented as the circuit shown in
Sixteen (2̂4=16) different combinations of capacitors and inductors can be allocated to the elements 4a, 4b, 4c and 4d. That is why by solving Equations (2) just as described above for each and every one of those sixteen combinations, all possible circuit configurations that could be implemented as real circuits can be extracted. And if one of those possible circuit configurations that satisfies most perfectly the requirements imposed on the antenna as needed is selected according to the situation, the design process of the dual-frequency matching circuit of this preferred embodiment is completed.
Examples of those requirements to be imposed as needed include whether the bandwidth that would achieve good matching is sufficiently broad or not, whether the dual-frequency matching circuit is made up of elements with small element constants or not (i.e., whether or not there is any inductor with a large element constant), and whether or not the matching property is affected easily by a variation in the impedance of the antenna. If the dual-frequency matching circuit of the present invention is designed as a matching circuit for an antenna in a mobile terminal as described above, the last requirement is particularly important.
According to such a configuration, a dual-frequency matching circuit is made up of four lumped elements, each of which is either a capacitor or an inductor, thereby reducing the minimum required number of elements to four. And as those elements are coupled together with a circuit configuration other than a ladder circuit consisting of resonant circuits, a dual-frequency matching circuit, which would cause little loss and would operate with good stability without having its impedance matching easily affected by a variation in the impedance of the load 5, can be provided.
In the preferred embodiment described above, each of the elements 4a, 4b, 4c and 4d is supposed to be either a single inductor or a single capacitor. However, if any of those elements is implemented as an inductor, the inductor could be replaced with two or more inductors that are connected in series together as shown in
Likewise, if any of those elements is implemented as a capacitor, the capacitor could be replaced with two or more capacitors that are connected in parallel with each other as shown in
Hereinafter, a specific example of a dual-frequency matching circuit according to the present invention will be described. The basic configuration of this specific example is the same as the configuration of the preferred embodiment shown in
As shown in
Also, supposing this analytical model was put in a free space (i.e., an infinite vacuum), the model was subjected to a radio frequency analysis using an electromagnetic field simulator IE3D version 11.23, thereby extracting the frequency behaviors of the impedance of the antenna 6, including the influence of the mobile terminal's housing 7 at the output terminals 3. In this specific example, the antenna had an impedance of 32.9-13.3i Ω (where i is an imaginary unit) at a frequency of 0.88 GHz and an impedance of 90.9+21.0i Ω (where i is an imaginary unit) at a frequency of 1.86 GHz, respectively.
Hereinafter, it will be described how to design the dual-frequency matching circuit of this specific example, which will be connected to the output terminals 3 of the mobile terminal shown in
First, the single-terminal S parameters, which were calculated at the output terminals 3 of the mobile terminal shown in
In this specific example, the two frequencies f1 and f2, at which the impedance matching should be achieved, are supposed to be 0.88 GHz and 1.86 GHz, respectively, and the impedance value of the RF circuit to be matched is supposed to be 50 Ω (i.e., Z0=50).
As can be seen from
The element constants that were calculated by the design process described above are shown in
As described above, the dual-frequency matching circuit of this specific example includes: first and second input terminals 2a, 2b that receive a first RF signal with a frequency of 0.88 GHz and a second RF signal with a frequency of 1.86 GHz, respectively, from an RF circuit with an impedance of 50 106 ; first and second output terminals 3a, 3b that are connected to an antenna (load 5); and a group of circuit elements that are connected between the input terminals 2a, 2b and the output terminals 3a, 3b.
The group of circuit elements includes first, second, third and fourth elements 4a, 4b, 4c and 4d. The first and fourth elements 4a and 4d are connected in series between the first and second input terminals 2a and 2b and the second input terminal 2b is short-circuited with the second output terminal 3b. The second element 4b is connected between the first input terminal 2a and the first output terminal 3a. The third element 4c is connected between a connection node of the first and fourth elements 4a, 4d and the first output terminal 3a.
And the group of circuit elements is one of the following four sets:
The first set includes an inductor with an inductance of 5.168 nH, an inductor with an inductance of 3.633 nH, a capacitor with a capacitance of 1.779 pF, and a capacitor with a capacitance of 1.207 pF as the first, second, third and fourth elements, respectively.
The second set includes an inductor with an inductance of 1.951 nH, a capacitor with a capacitance of 7.335 pF, a capacitor with a capacitance of 14.190 pF, and an inductor with an inductance of 15.834 nH as the first, second, third and fourth elements, respectively.
The third set includes an inductor with an inductance of 15.059 nH, a capacitor with a capacitance of 1.286 pF, an inductor with an inductance of 12.071 nH, and a capacitor with a capacitance of 5.602 pF as the first, second, third and fourth elements, respectively.
And the fourth set includes an inductor with an inductance of 4.355 nH, a capacitor with a capacitance of 1.005 pF, an inductor with an inductance of 6.195 nH, and a capacitor with a capacitance of 5.308 pF as the first, second, third and fourth elements, respectively.
When used, every mobile terminal always comes close to the user's hand or head. And the degrees of the closeness change according to how he or she uses it or who uses it. That is why to provide good telecommunication quality, it is important to stabilize the matching property with respect to a variation in the impedance of the antenna that will be caused when the user's hand or head comes close to the terminal. Thus the present inventors calculated how much the characteristic of the analytical model shown in
As used herein, the “band” is defined to be a frequency band with a voltage standing wave ratio of 2 or less. It can be seen from
Even within the scope of the conventional technology described above, a dual-frequency matching circuit can also be made up of the same number of elements (i.e., four elements) as the dual-frequency matching circuit of the present invention. Such a circuit has a circuit configuration in which the single-frequency matching circuits with the configuration shown in
Hereinafter, another specific example of a dual-frequency matching circuit according to the present invention will be described.
The frequency bands that are already utilized currently and the ones that will be exploited in the near future can be roughly classified into the three frequency bands, namely, a low frequency band in a 0.45 GHz range, an intermediate frequency band in 0.8 GHz, 0.85 GHz and 0.9 GHz ranges, and a radio frequency band in 1.5 GHz, 1.7 GHz, 1.8 GHz, 1.9 GHz and 2.0 GHz ranges. Among other things, the intermediate and radio frequency bands are in particularly high demand for common use. For that reason, in this specific example, a representative frequency of 0.85 GHz is selected from the intermediate frequency band and three representative frequencies of 1.55 GHz, 1.7 GHz and 2.05 GHz are selected from the radio frequency band to design an antenna first.
These frequencies are selected because all the other frequency bands are asymptotic to one of the four selectable frequencies including 1.86 GHz and because as far as the frequency dependency of the antenna's impedance is concerned, there should be no significant deviation from the designed value at the selected frequency.
The configuration of this specific example is basically the same as, but is slightly different from, that of the preferred embodiment shown in
The antennas that can be connected to the dual-frequency matching circuit of this specific example are shown in
The frequency dependencies of the radio frequency properties at the output terminal 3 that is connected to the antenna shown in
As can be seen easily from
The element configurations and element constants of the dual-frequency matching circuits of this specific example to be connected to the antennas shown in
The dual-frequency matching circuits defined by
This dual-frequency matching circuit includes: first and second input terminals 2a, 2b that receive a first RF signal with a frequency of 0.85 GHz and a second RF signal with a frequency of 1.55 GHz, respectively, from an RF circuit with an impedance of 50 Ω; first and second output terminals 3a, 3b that are connected to an antenna (load 5); and a group of circuit elements that are connected between the input terminals 2a, 2b and the output terminals 3a, 3b.
The group of circuit elements includes first, second, third and fourth elements 4a, 4b, 4c and 4d. The first and fourth elements 4a and 4d are connected in series between the first and second input terminals 2a and 2b and the second input terminal 2b is short-circuited with the second output terminal 3b. The second element 4b is connected between the first input terminal 2a and the first output terminal 3a. The third element 4c is connected between a connection node of the first and fourth elements 4a, 4d and the first output terminal 3a.
The first element 4a is a capacitor with a capacitance of 0.403 pF. The second element 4b is an inductor with an inductance of 8.981 nH. The third element 4c is a capacitor with a capacitance of 0.597 pF. And the fourth element 4d is an inductor with an inductance of 8.216 nH.
Configuration Shown in FIG. 21This dual-frequency matching circuit includes: first and second input terminals 2a, 2b that receive a first RF signal with a frequency of 0.85 GHz and a second RF signal with a frequency of 1.7 GHz, respectively, from an RF circuit with an impedance of 50 Ω; first and second output terminals 3a, 3b that are connected to an antenna (load 5); and a group of circuit elements that are connected between the input terminals 2a, 2b and the output terminals 3a, 3b.
The group of circuit elements includes first, second, third and fourth elements 4a, 4b, 4c and 4d. The first and fourth elements 4a and 4d are connected in series between the first and second input terminals 2a and 2b and the second input terminal 2b is short-circuited with the second output terminal 3b. The second element 4b is connected between the first input terminal 2a and the first output terminal 3a. The third element 4c is connected between a connection node of the first and fourth elements 4a, 4d and the first output terminal 3a.
The first element 4a is an inductor with an inductance of 5.119 nH. The second element 4b is a capacitor with a capacitance of 1.370 pF. The third element 4c is an inductor with an inductance of 8.360 nH. And the fourth element 4d is a capacitor with a capacitance of 5.942 pF.
Configuration Shown in FIG. 22This dual-frequency matching circuit includes: first and second input terminals 2a, 2b that receive a first RF signal with a frequency of 0.85 GHz and a second RF signal with a frequency of 2.05 GHz, respectively, from an RF circuit with an impedance of 50 Ω; first and second output terminals 3a, 3b that are connected to an antenna (load 5); and a group of circuit elements that are connected between the input terminals 2a, 2b and the output terminals 3a, 3b.
The group of circuit elements includes first, second, third and fourth elements 4a, 4b, 4c and 4d. The first and fourth elements 4a and 4d are connected in series between the first and second input terminals 2a and 2b and the second input terminal 2b is short-circuited with the second output terminal 3b. The second element 4b is connected between the first input terminal 2a and the first output terminal 3a. The third element 4c is connected between a connection node of the first and fourth elements 4a, 4d and the first output terminal 3a.
The first element 4a is a capacitor with a capacitance of 0.573 pF. The second element 4b is an inductor with an inductance of 5.013 nH. The third element 4c is a capacitor with a capacitance of 0.692 pF. And the fourth element 4d is an inductor with an inductance of 2.543 nH.
When the circuit is designed, a number of element configurations other than the ones shown in
From these viewpoints, the circuit configurations shown in
It should be noted that if the impedance of an antenna for use in the present invention varied at each frequency due to the change of the structures or dimensions of the antenna, the element constant values shown in
Even if an antenna that has a different structure or different dimensions from the one shown in
Stated otherwise, in a situation where the impedance of the antenna is equal to the value of the specific example described above, even if the respective values of element constants do not exactly match the ones shown in
A dual-frequency matching circuit according to the present invention is made up of as small as four elements, and therefore, causes little loss and achieves high stability with respect to a variation in the impedance of a load. That is why the dual-frequency matching circuit of the present invention can be used effectively in an amplifier or a mixer, for example. The present invention is also applicable to a tuned circuit for use in a plasma generation source for a thin-film deposition system that deposits a thin film on a substrate by a physical or chemical process and to a tuned circuit for a magnetron for use in a microwave oven for heating with microwaves.
While the present invention has been described with respect to preferred embodiments thereof, it will be apparent to those skilled in the art that the disclosed invention may be modified in numerous ways and may assume many embodiments other than those specifically described above. Accordingly, it is intended by the appended claims to cover all modifications of the invention that fall within the true spirit and scope of the invention.
Claims
1. A dual-frequency matching circuit comprising:
- first and second input terminals that receive a first RF signal with a frequency of 0.85 GHz and a second RF signal with a frequency of 1.55 GHz, respectively, from an RF circuit with an impedance of 50 Ω;
- first and second output terminals that are connected to an antenna; and
- a group of circuit elements that are connected between the input terminals and the output terminals,
- wherein the group of circuit elements includes first, second, third and fourth elements, and
- wherein the first and fourth elements are connected in series between the first and second input terminals and the second input terminal is short-circuited with the second output terminal, and
- wherein the second element is connected between the first input terminal and the first output terminal, and
- wherein the third element is connected between a connection node of the first and fourth elements and the first output terminal, and
- wherein the first element is a capacitor with a capacitance of 0.403 pF, and
- wherein the second element is an inductor with an inductance of 8.981 nH, and
- wherein the third element is a capacitor with a capacitance of 0.597 pF, and
- wherein the fourth element is an inductor with an inductance of 8.216 nH.
2. The dual-frequency matching circuit of claim 1, wherein the impedance of the antenna is 66.7-31.9i Ω (where i is an imaginary unit) at a frequency of 0.85 GHz and 43.5-19.2i Ω (where i is an imaginary unit) at a frequency of 1.55 GHz, respectively.
3. The dual-frequency matching circuit of claim 2, wherein the antenna is an inverted F antenna to be built in a cellphone.
Type: Application
Filed: Jan 12, 2009
Publication Date: Aug 6, 2009
Applicant: PANASONIC CORPORATION (Osaka)
Inventor: Ushio SANGAWA (Nara)
Application Number: 12/352,122
International Classification: H03H 7/38 (20060101);