The present invention relates to a microstrip line filter and particularly, although not exclusively, to a magnetic coupling mechanism arranged to couple resonators in a microstrip line filter.
The finite electromagnetic spectrum for modern wireless communications is becoming more and more crowded. Band pass filters with high spectral selectivity are highly demanded to make sufficient use of the electromagnetic spectrum. Microstrip line emerges as a good candidate for band pass filter designs due to its advantages of low cost, planar structure and easy fabrication. Among various microstrip line band pass filters, the traditional end-coupled band pass filters using gap-couplings are simple both in structure and in design procedure. However, the applications of these kinds of filters are not so wide because the performance is too sensitive to the sizes of the feeding and coupling gaps.
On the other hand, according to the coupled resonator theory, resonator and coupling are the two key factors in microwave band-pass filter design. Past research on microwave band pass filters, especially microstrip line band pass filters, had focused on proposing various new kinds of resonators to improve filter performance or achieve special functions. For coupling mechanism, end- and edge-couplings, both of which belong to gap-coupling, dominate the coupling mechanism in microstrip line band pass filters.
Therefore, there is a need for a coupling mechanism that can at least make use of the advantages of the end-coupled structure and yet avoid the disadvantages of the gap-coupling.
It is an object of the present invention to overcome or substantially ameliorate the above disadvantages or more generally to provide an improved coupling mechanism for microstrip line filter.
In accordance with a first aspect of the present invention, there is provided a microstrip line filter comprising: a coupling mechanism arranged to couple a first resonator and a second resonator, wherein the coupling mechanism includes a shared metallic coupling member arranged to have a predetermined dimension associated with an operation characteristics of the first and second resonators.
Preferably, the operation characteristic comprises a coupling coefficient of the first and second resonators.
In one embodiment of the first aspect, the first and second resonators are end-coupled or edge coupled with each other through the coupling mechanism.
In one embodiment of the first aspect, the microstrip line filter is a band pass filter.
Preferably, the coupling mechanism is substantially gapless between the first and second resonators.
In one embodiment of the first aspect, the shared metallic coupling member has a substantially circular cross section.
In a preferred embodiment of the first aspect, the predetermined dimension of the shared metallic coupling member associated with the coupling coefficient includes a diameter of the circular cross section of the shared metallic coupling member.
In one embodiment of the first aspect, the coupling coefficient of the first and second resonators is further dependent on the widths of the first and second resonators.
Preferably, the coupling mechanism is a magnetic coupling mechanism substantially independent of substrate permittivity ε.
In one embodiment of the first aspect, resonant frequencies of the first and second resonators are dependent on the lengths of the first and second resonators.
In one embodiment of the first aspect, the first and second resonators may be uniform-impedance resonance resonators, step-impedance resonators, stub-loaded resonators or other types of resonators.
In one embodiment of the first aspect, the resonators may be λ/2 or λ/4 resonators. Alternatively, the resonators may have different lengths (wavelengths).
In accordance with a second aspect of the present invention, there is provided a microstrip line filter comprising a plurality of resonators, each resonator being end-coupled with an adjacent resonator through a via-coupling mechanism having a shared metallic coupling member disposed between the resonators, or a gap-coupling mechanism having a gap disposed between the resonators.
Preferably, the microstrip line filter in accordance with the second aspect of the present invention comprises both the via-coupling mechanism and the gap-coupling mechanism.
In one embodiment of the second aspect, the via-coupling mechanism is a magnetic coupling mechanism and the gap-coupling mechanism is an electric coupling mechanism.
Preferably, the via-coupling mechanism is substantially gapless between the resonators.
In one embodiment of the second aspect, the shared metallic coupling member has a substantially circular cross section.
Preferably, a predetermined dimension of the shared metallic coupling member is associated with an operation characteristic of the resonators connected together through the via-coupling mechanism.
In one embodiment of the second aspect, the operation characteristic comprises a coupling coefficient of the resonators connected together through the via-coupling mechanism.
In one embodiment of the second aspect, the predetermined dimension of the shared metallic coupling member associated with the coupling coefficient is a diameter of the shared metallic coupling member.
In one embodiment of the second aspect, a width of the gap of the gap-coupling mechanism is associated with a coupling coefficient between the resonators connected together through the gap-coupling mechanism.
In a preferred embodiment of the second aspect, the plurality of resonators are arranged in a split ring structure.
In one embodiment of the second aspect, the microstrip line filter includes: a first resonator connected with a microstrip line input; a second resonator coupled with the first resonator; a third resonator coupled with the second resonator; and a fourth resonator coupled with the third resonator and connected with a microstrip line output; wherein the fourth resonator is further coupled with the first resonator such that the resonators are arranged in a split ring structure.
In one embodiment of the second aspect, the resonators are λ/2 or λ/4 resonators. Alternatively, the resonators may have different lengths (wavelengths).
In one embodiment of the second aspect, the first and the fourth resonators are λ/4 resonators; and the second and third resonators are λ/2 resonators.
In one embodiment of the second aspect, the gap-coupling mechanism is arranged between the first and fourth resonators; and the via-coupling mechanism is arranged between the first and the second resonators, between the second and the third resonators, and between the third and the fourth resonators.
In one embodiment of the second aspect, the split ring structure includes a radius; and a center frequency of the pass band of the band pass filter is dependent on the radius of the split ring structure.
Embodiments of the present invention will now be described, by way of example, with reference to the accompanying drawings in which:
Referring to
Based on the complementary concept of electromagnetics, the inventor of the present invention has devised that a via-coupling mechanism can be realized by sharing one metallic coupling member, a metallic via, between two resonators R1, R2 (made of substrate, with height h and width w) in a microstrip line filter.
As shown in
The circuit models 106, 108 show the complementariness between the gap-coupling and via-coupling mechanisms, with parallel capacitors C11, C22 corresponding to series inductors L11, L22 and series capacitor C12 corresponding to parallel inductor L12. In addition, the circuit models 106, 108 show that the gap-coupling mechanism is an electric coupling mechanism whereas the via-coupling mechanism is a magnetic coupling mechanism.
In coupled resonator theory, the coupling between resonators is characterized mainly by one parameter/operation characteristic, a coupling coefficient, which is much simpler than a three-parameter circuit model. Therefore, the inventor of the present invention has devised that the via-coupling mechanism can be characterized and studied using the coupled resonator theory. As resonator and coupling are the two essential factors of a microwave band pass filter, the study of coupling mechanisms in one embodiment of the present invention is based on a certain kind of resonator.
In this embodiment, without loss of generality, the inventor has chosen to utilize a short-ended λ/2 uniform-impedance resonator (UIR) 202 as shown in
According to coupled resonator theory, the coupling coefficient between two coupled resonators can be extracted by the following equation:
where fp1 and fp2 denotes the two split resonant frequencies of the coupled structure; the upper sign is for magnetic coupling and the lower sign is for electric coupling. By using Equation (1), the coupling coefficients of the via-coupling mechanism versus normalized widths w/h and normalized diameters d/h are plotted in
As shown in
As discussed above, the inventor of the present invention has devised through experiments and trials that the gap-coupling and via-coupling mechanisms are complementary and therefore there is a need to compare the performances of these coupling mechanisms.
By comparing
Firstly, for fixed w/h, the coupling coefficient of the via-coupling mechanism in the present embodiment decreases moderately and smoothly as d/h increases. However, the coupling coefficient of the gap-coupling mechanism decreases rapidly in the strong coupling region (especially when g/h is below 0.3), yet slowly in weak coupling region. This means that in strong coupling region, the fabrication tolerance of the via-coupling mechanism is much better than that of the gap-coupling mechanism. However, the situation is reversed in the weak coupling region, with the gap-coupling mechanism having a much better fabrication tolerance than that of the via-coupling mechanism.
Secondly, for fixed d/h, the coupling coefficient of the via-coupling mechanism of the present embodiment increases almost linearly and significantly when w/h increases. However, the coupling coefficient of the gap-coupling mechanism changes very little when w/h changes. This shows that the coupling coefficient of the via-coupling mechanism can be controlled by the width w of the microstrip line resonators and this provides via-coupling mechanism with an additional design variable that may be manipulated.
where E and H represent the electric and magnetic field vectors on the resonators (the subscripts indicate the notations of the resonators); ε and μ are the absolute permittivity and permeability respectively.
In Equation (2), the first part of the equation is for electric coupling and the second part of the equation is for magnetic coupling. Due to the existence of air in the microstrip line structure, ε is inhomogeneous so that it cannot be extracted from the integrals in the electric-coupling part of (2). Since gap-coupling mechanism belongs to an electric coupling, it should be dependent on ε (or εr). Via-coupling mechanism, on the other hand, belongs to magnetic coupling which is substantially independent of ε (or εr).
The inventor of the present invention has devised that traditional end-coupled band pass filters using gap-coupling mechanisms are simple in structure and in design procedure. However, the inventor has devised that the applications of these kinds of filters are not so wide for at least the following reasons.
First, the performance of theses filters (using gap-coupling) is too sensitive to the sizes of the coupling gap widths g realized by PCB fabrication. Fortunately, the via-coupling mechanism proposed in the present invention is substantially free of this kind of problem.
Secondly, traditional end-coupled band pass filters are often fed by the gaps between input/output of the microstrip line filters and the first/last resonators. The inventor has devised that, in this case, the filter performance is more sensitive to the feeding gaps because the feeding gaps are usually even narrower than the coupling gaps. Accordingly, in one embodiment of the present invention, both end-coupled band pass filters are fed by narrow microstrip lines, which are directly connected to the resonators. This feeding method allows the input/output external quality factor (QE) to be easily controlled.
The following steps are the design procedures for a band pass filter with specifications including a center frequency fc and a fractional bandwidth FBW in accordance with one embodiment of the present invention.
1. Generating the coupling matrix together with QE based on the given filter specifications. In one embodiment, the coupling matrix for a fourth-order Chebyshev response band pass filter is as follows:
It should be noted that, this method is not limited to the above coupling matrix. In some other embodiments, different mathematical models and formulas related to the coupling coefficients may be used.
2. Obtaining the parameters that control the couplings, d1/g1 and d2/g2, by comparing
3. Tuning the length of the resonators, l1 and l2, to guarantee that their resonant frequencies are around fc.
4. Tuning the feeding point, pf, to reach the required QE.
5. Processing a fine tuning to get optimized frequency responses.
As shown in
The inventor of the present invention has devised that, in most wireless communication systems, band pass filters with high selectivity are more desirable. To realize high-selectivity band pass filters, transmission zeros (TZs) may be generated close to the pass-bands by introducing cross-couplings between non-adjacent resonators. For a fourth-order BPF with cross-coupling between the first and fourth resonators, two TZs can be easily generated to obtain a quasi-elliptic frequency response.
In this case, the coupling matrix is:
where M14 is the cross-coupling and M12, M23, M34 are the main couplings. The condition is that the cross-coupling should have an opposite sign to the main couplings so that signals from the two paths will eliminate each other and this signal elimination generates TZs. Based on this concept, a fourth order end-coupled BPF with quasi-elliptic response in accordance with an embodiment of the present invention is provided by combining the gap-coupling and via-coupling mechanisms in accordance with one embodiment of the present invention.
Referring to
The present embodiment of the microstrip line filter has high flexibility of tuning not only for its center frequency, but also for its bandwidth. By just changing the radius of the ring R1 in
For the purpose of verification, a quasi-elliptic response band pass filter is fabricated in accordance with
Although the present invention has been described in detail with reference to the above embodiments and Figures, there are several important aspects of the present invention that should be highlighted.
First, the via-coupling mechanism of the present invention is substantially independent of the substrate permittivity ε. Therefore,
Also, although the study and design in the embodiments of the present invention are based on the uniform-impedance resonators (UIRs), the via-coupling mechanism is applicable and suitable for any types of resonators. Examples of these resonators include step-impedance resonators (SIRs) and stub-loaded resonators (SLRs). The via-coupling mechanism of the present invention is also suitable for other types of resonators. Furthermore, the via-coupling mechanism of the present invention can be used in resonators that are end-coupled or edge-coupled with each other.
In the present invention, the metallic via in the via-coupling mechanism will slightly affect the resonant frequencies of resonators. However, this influence can be adjusted by tuning the lengths of the resonators. The resonators of the quasi-elliptic response BPF in the present invention may be meandered to reduce the circuit size. Also, the via-coupling mechanism of the present invention is not limited to the design of end-coupled band pass filter. Lastly, the present invention is not limited to the design of microstrip line band pass filter, but can also be used in the design of other types of band pass filters such as but not limited to low temperature co-fired ceramic (LTCC) band pass filters.
The present invention is particularly advantageous in that: a new coupling mechanism, namely via-coupling mechanism, is provided and applied to implement microstrip line filters, in particular, microstrip line end-coupled band pass filters.
Experimental results above show that the via-coupling mechanism provides more flexibility and owns better tolerance to fabrication errors than the gap-coupling mechanism. As fabrication tolerance is a practical issue in filter application and design, the via-coupling mechanism which has enhanced fabrication tolerance may be a good candidate for microstrip line band pass filter designs.
The embodiment of the quasi-elliptic response end-coupled band pass filter of the present invention utilizes via-coupling mechanism in the main couplings and gap-coupling mechanism in the cross couplings. The utilization of the via-coupling mechanism in the main couplings results in a simpler design procedure, more design flexibility and better tolerance to fabrication errors than band pass filters utilizing the traditional gap-couplings mechanism. Also, the utilization of gap-coupling mechanism in the cross coupling guarantees a quasi-elliptic response with high selectivity. More importantly, the present invention can be applied in most planar wireless communication systems.
It will be appreciated by persons skilled in the art that numerous variations and/or modifications may be made to the invention as shown in the specific embodiments without departing from the spirit or scope of the invention as broadly described. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive.
Any reference to prior art contained herein is not to be taken as an admission that the information is common general knowledge, unless otherwise indicated.
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20150022284 A1 | Jan 2015 | US |
Number | Date | Country | |
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61856917 | Jul 2013 | US |