This application claims the benefit, under 35 U.S.C. §119 of French Patent Application No. 1452718, filed Mar. 28, 2014.
The present invention relates to a filtering circuit with slot line resonators, more specifically a compact filtering circuit specially adapted to make selective filters on conventional single-layer or multi-layer substrates. The present invention also relates to band-pass filters including such circuits, these filters being adapted notably but not exclusively to wireless or mobile communication devices.
With the growing demand for new services, devices used for mobile communications and in home networks must be able to operate at different frequencies and according to several standards. In this case, it is necessary, in order to maintain the integrity of the signals corresponding to these different standards, to use very narrow-band filters constituted of high quality factor resonators.
In general, the implementation of such filters requires a compromise between on one hand the electrical performance of the filter and on the other hand its cost and size. The performance of a filter depends typically on the quality factor Q of the resonator used. The higher the quality factor, the better the performances of the filter. However, a high quality factor Q involves the use of technologies whose cost is high and the filters realised, for example SMD (surface mounted device) technology, are most often bulky, which is hardly compatible with the necessities of mobile devices.
Whereas, in the technology of printed circuits, resonators with microstrip lines are typically used, new slot line resonators have recently appeared for the manufacture of filters. The main advantage of these resonators is that it is very easy to integrate electronic components into them such as capacitors, resistors or varactors to control their quality factor Q or their resonant frequency. However, particular attention must be paid to radiation losses in slot structures. Moreover, their excitation from standard transmission lines on printed circuits such as microstrip or coplanar lines is not so simple.
Several of these spiral slot line resonators can be coupled for the design of low-cost and highly compact filters. But, the adjustment of the coupling of the resonators is not very simple and a high coupling of the resonators can be difficult to attain as the resonators suffer from physical (related to the geometry of the structure of the resonator) and technical (limited to manufacturing tolerances) limitations.
The present invention has been devised with the foregoing in mind.
A first aspect of the invention provides a filtering circuit comprising at least two slot line resonators arranged side by side on a dielectric substrate having a first surface provided with a conductive layer and a second parallel surface, each of said at least two resonators comprising
The two slot line resonators have adjacent edges for electromagnetic coupling each slot line comprising a coupled portion at the respective adjacent edge and at least one uncoupled portion, opposite the adjacent edge. An uncoupled portion is parallel to and spaced apart from the adjacent edge. The said at least one discontinuity of the turn of the spiral pattern may be provided in said uncoupled portion of the slot line.
According to embodiments of the invention, coupling between two resonators may be increased by creating discontinuities in the spiral pattern of the resonators.
The increase in the level of electromagnetic coupling between the resonators can reduce the transmission losses of the filter.
According to a particular embodiment, the filtering circuit comprises two slot line resonators and the spiral patterns of said two slot line resonators are noticeably identical, one of said spiral patterns being pivoted by 180° in relation to the other of said spiral patterns.
This configuration of spiral patterns can provide a strong level of electrical field in the adjacent parts of the two spiral patterns.
According to a particular embodiment, the spiral patterns of said two slot line resonators have adjacent edges by which the electromagnetic coupling is realised and each spiral pattern comprises a portion, called coupled, contiguous to the adjacent edge and at least one other portion, called uncoupled, contiguous to the edge opposite the adjacent edge, said at least one discontinuity of the turn of the spiral pattern is present in said uncoupled portion of the spiral pattern.
According to a particular embodiment, the spiral patterns of said at least two slot line resonators are arranged such that, when the slot line resonators are excited, the highest electrical field values are present in said coupled portions and in that the electrical fields in said coupled portions are in phase (have the same direction).
According to a particular embodiment, each turn of the spiral patterns comprises a discontinuity.
According to a particular embodiment, the discontinuities of the spiral patterns are aligned on an axis linking the centres of the spiral patterns.
According to a particular embodiment, the spiral patterns have a general rectangular or square shape.
According to a particular embodiment, the spiral patterns comprise at least three turns.
According to a particular embodiment at least one supply structure is realised on the substrate to supply the slot line of the input and output resonators. For example, the at least one supply structure can be realised on the second face of the substrate.
According to a particular embodiment, the supply structure is realised on the second face of the substrate and comprises a patch located under the spiral pattern, said patch is linked to the slot line by a via through the dielectric substrate.
According to a particular embodiment, the via of each slot line resonator is positioned noticeably in the centre of the spiral pattern of the resonator.
Embodiments of the invention propose a filtering circuit comprising at least two slot line resonators coupled and arranged so as to reduce the transmission losses during the filtering.
Embodiments of the invention propose an arrangement of slot line resonators enabling a strong coupling of the resonators to be obtained while arranging them side by side without bringing them too close so as to be able to realise the filter on standard mass production lines and with the low-cost substrate.
Another aspect of the invention relates to a band-pass filter comprising at least one filtering device according to any embodiment of the first aspect of the invention.
A further aspect of the invention relates to an electronic device comprising at least one filtering device according to any embodiment of the first aspect of the invention.
Other advantages may also occur to those skilled in the art upon reading the examples below, illustrated by the annexed figures, given by way of illustration.
The resonator is realised on a dielectric substrate featuring on each of its faces a conductive layer.
More specifically, a dielectric substrate 1 is equipped on one of its faces with a conductive layer 2 wherein a slot line has been etched in a spiral pattern 3. This slot line has a width Ws and a length L which is a function of the operating frequency of the resonator.
On the face of the substrate opposite the conductive layer 2, a patch 4 made of a conductive layer has been implemented. This patch 4 is non-resonant and participates in feeding the slot line. It has a width Wp and a length Dp and covers the spiral pattern as shown by the dotted line in
Table 1 below gives the values used for the lengths and widths of the different elements of the resonator to obtain a resonance at a frequency close to 5 GHz.
In this embodiment, the slot line is folded into a spiral noticeably according to a square shaped pattern and is excited in its centre by the via 7 to the metal patch 4, said patch is supplied by the feed line 5. For the dimensions indicated, the resonator resonates at a frequency of 5.11 GHz.
For the filtering circuit shown in
The response in S of the filter of
It may be noted that more complex coupling structures such as resonators stacked on each other in a multilayer structure, as shown diagrammatically in
According to embodiments of the invention, instead of trying to bring as close together as possible the adjacent edges of the two slot line resonators (with the limitations mentioned in the preamble of this patent application), it is proposed to increase the electromagnetic coupling between the two resonators by creating discontinuities 10 in the spiral pattern of the slot line 3 as shown in
These discontinuities in the slot line are referenced 10 in
In the remainder of the description, embodiments of the invention will be described in a more detailed manner through different embodiments and the phenomena used in the invention will be explained. In all the embodiments described below, the filter comprises two slot line resonators R1 and R2 separated by a distance g equal to 0.2 mm as shown in
The operation of the pass-band filter of
A second configuration of the spiral patterns is proposed in
As can be seen, it is relatively difficult to realise the electromagnetic coupling between the two spiral slot line resonators. The transmission losses created make them practically unusable in the real world.
To resolve this problem, it was observed that the introduction of discontinuities in the turns of the spiral pattern portion in the uncoupled portion of the two spiral patterns associated with a particular configuration of the spiral patterns was able to significantly increase the coupling between the two slot line resonators, as shown in the
The low transmission losses observed are obtained thanks to the two simultaneous conditions mentioned above that are reached thanks to the presence of discontinuities and the configuration of the spiral patterns:
Note that the presence of discontinuities lowers the resonant frequency, which contributes to the miniaturization of the circuit. A possible explanation of this phenomenon is that the discontinuities act as capacitive/inductive elements to lower the effective resonant frequency of the resonator.
If the resonators are resized to obtain a band-pass filter at 5 GHz, the filter response illustrated by the diagram of
The transmission losses (S(2,1)) are in the order of −0.8 dB with embodiments of the invention. Also, an excellent impedance matching of the filter can be observed with S(1.1)<−20 dB on a band of 300 MHz around the central frequency of 5.15 GHz.
In the embodiment illustrated by
According to another embodiment illustrated by
In the embodiments described previously, the general shape of the turns of the spiral pattern is noticeably square. According to a particular embodiment, it is proposed to modify this shape factor.
According to other embodiments, the turns of the spiral pattern comprise more than one discontinuity per turn as illustrated by
The embodiments described above have been provided as examples. It is evident to those skilled in the art that they can be modified, notably regarding the shape of the spiral patterns, their dimensions, their number of turns, the number of discontinuities per turn and the position of the discontinuities.
With regard to what has preceded, it can be considered that the embodiments of the invention procure the following advantages:
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Number | Date | Country | |
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20150280301 A1 | Oct 2015 | US |