Surface wave filter comprising reactance elements

Abstract

Proposed is a SAW HF filter with reactance elements, which is particularly suitable for mobile radio. The filter is balanced on both sides, is electrically symmetric, and comprises a four-pole reactance series element, which can be formed from two two-pole reactance elements or from a four-pole reactance element, and a resonator. One bar of the respective reactance elements is connected to the input side of the filter, while the other bar is connected to the output side of the filter.

Description

[0001] Surface acoustic wave (SAW) filters are used predominantly in GSM mobile telephones. SAW filters are operated single-ended on an input side and balanced on an output side. Single-ended means that a signal is applied to only one of two connectors, while the other connector is grounded. This method of connection is also referred to as asymmetric. An input or output of a SAW filter that is operated in a balanced mode, on the other hand, has two connectors whose signals are ideally phase-shifted by 180° relative to one another. This means that a signal that is equal in magnitude can be obtained at both connectors, and that the signal differs merely in its prefix. Such symmetric/asymmetric operation is also referred to as a BALUN function.

[0002] For more modem mobile radio systems, such as EDGE, UMTS and CDMA, the market is increasingly demanding SAW filters that can be operated in balanced mode on both sides. Such filters are already being installed in numerous established mobile radio systems under AMPS, PCS, and PDC 1.5.

[0003] Another critical factor for the mode of operation of a SAW filter is the filter's impedance. Until recently, a filter impedance of 50 ohm on the input side and the output side was consistently being demanded and offered, while now, higher impedance values in the range of 100 to 400 ohm are increasingly required for balanced-balanced filters.

[0004] A SAW HF (high frequency) filter must also satisfy stringent requirements with regard to selection and insertion attenuation, particularly in the realm of mobile communication. These requirements can only be met with special, novel filter structures.

[0005] Known filters that can be operated in balanced mode on both sides are known, for example, from EP-A-0 605 884. These filters are implemented using longitudinal mode resonator filters (=dual mode SAW=DMS filters) on lithium niobate or lithium tantalate. In these filters, an odd number of interdigital transformers is disposed between two reflectors for each track. A balanced-balanced filter is structured, for example, as a two-track filter, in which two tracks with three transformers are respectively switched in cascade via the center transformer. The two outer transformers of a track are respectively connected to the input or output, and demonstrate a phase inversion, which permits symmetric operation at each input or output. Such a filter possesses the same impedance on the input and the output sides.

[0006] It is the object of the present invention to provide filters that can be operated in balanced mode on both sides, and that demonstrate a high level of selection and a low insertion attenuation.

[0007] According to the invention, this object is accomplished by a surface acoustic wave filter according to claim 1. Advantageous further developments of the invention ensue from the dependent claims.

[0008] The invention proposes, for the first time, to structure an HF filter that can be operated in balanced mode on both sides with reactance elements on a SAW basis. A reactance element on a SAW basis can be embodied as a SAW resonator. However, the general definition of a reactance element is that it does not act as a filter in and of itself, but rather only by way of its impedance, which can therefore also be replaced by any desired impedance element. The filter according to the invention is embodied to be completely electrically symmetric. It has at least one four-pole reactance series element, with two poles (=connectors) forming the symmetric input and output, respectively. A four-pole reactance series element can be formed by two individual, geometrically identical two-pole reactance elements, or by a single (four-pole) reactance element with four connectors (poles). The term reactance series element is understood to mean a SAW reactance element that has at least one interdigital transformer, one of whose current bars is connected to the input side, while its other current bar is connected to the output side, thereby producing a serial connection (=path) between the input side and the output side, in which the reactance series element is embedded.

[0009] A four-pole reactance series element according to the invention represents a basic structure for a rudimentary SAW HF filter that accomplishes the stated object in a simple manner. Previous reactance filters have an asymmetric structure and possess only one signal-conducting connector on both sides, in other words, a single-ended connector, while the other connector is grounded. This type of known reactance filter therefore possesses only a serial path that connects the two signal-conducting connectors with one another on the input and output sides. The connection to ground is made via resonators, i.e., reactance elements switched in parallel to this. The entire arrangement of known reactance filters is therefore both electrically and geometrically asymmetric.

[0010] In the simplest embodiment, two resonators are provided, which together form a reactance series element. One connector of each of the resonators is connected to the input side; the other is connected to the output side via the other current bar. The resonators are not coupled acoustically.

[0011] In a further embodiment of the invention, the two serial paths that each have a reactance element, i.e., a resonator, can be symmetricly connected to one another via at least one parallel branch, thereby producing a high-quality HF filter. In the simplest case, this can be a SAW resonator switched in parallel.

[0012] It is also possible, however, to connect the inputs or outputs of the four-pole reactance series element to the symmetric input of a DMS filter that is symmetric on both sides. The outputs of the DMS filter then represent the output and input, respectively, of a high-quality filter in accordance with the invention.

[0013] In a further embodiment of the invention, a parallel branch is also provided between the two serial paths, in which branch two reactance elements, i.e., resonators, switched in series are disposed, the elements not being acoustically coupled. A resonator having a current bar that has been divided into two axially symmetric parts can also be provided as the parallel reactance element; the two parts are each connected to the two connectors of the interdigital transformer. The opposite current bar of the interdigital transformer divided in this way represents a virtual ground point that can also be connected to a ground connector, if necessary.

[0014] A single four-pole reactance series element is also obtained if the interdigital transformer of a surface acoustic wave resonator is symmetricly divided into two partial transformers having two connectors each. On both sides of the acoustic track of the resonator, symmetric inputs and outputs are then formed, which represent the inputs and outputs of a basic structure of an HF filter that is fully functional with further symmetric SAW components.

[0015] In a further embodiment of the invention, the four-pole reactance series element can be switched symmetricly with other reactance elements or also in cascade with other DMS filters. Thus, a DMS filter switched in cascade with the reactance series element can be arranged in cascade with another symmetric DMS filter. It is also possible to connect two symmetric DMS filters to one another via the four-pole reactance series element that is switched between them. Each of the DMS filters can again be cascaded; in other words, it can have several acoustic tracks switched in cascade.

[0016] In another embodiment of the invention, two four-pole reactance elements are connected to one another crosswise, in the form of a bridge circuit. The two connectors of the symmetric input of the first four-pole reactance element are connected to one connector of the input and the output of the second four-pole reactance element, respectively. The two connectors of the output of the first reactance element are respectively connected to the other connector of the input and the output of the second reactance element. This is a variation of the invention that does not have a geometrically symmetric arrangement, but merely an electrically symmetric arrangement.

[0017] A reactance filter according to the invention can also include a DMS track or a resonator in which two surface acoustic wave structures that are disposed adjacent to one another and are selected independently of one another from an interdigital transformer and a reflector are phase-shifted relative to one another. The transition between the two phase-shifted surface acoustic wave structures is formed by a continuously varied finger period and continuously varied finger distances, or only by a continuously varied finger period. The finger period exhibits a minimum in the region of the transition and continuously decreasing from both sides. This avoids leakage losses in the HF filter.

[0018] In a further embodiment of the invention, individual or groups of interdigital transformers of reactance elements, or DMS filters or DMS tracks switched with them, can be weighted in order to adapt various parameters of the entire filter. For example, the bandwidth of the filter can be varied in this way, the impedance of the filter can be changed, or the selection can be increased. Such weighting can be performed as omission weighting or overlap weighting. Other examples of weighted interdigital transformers that can all be used in filters according to the invention can be found, for example, in DE-A-1-9724259 (=97P1705), which is hereby incorporated by reference in its entirety.

[0019] It is also possible, however, to implement cascade weighting in an interdigital transformer. For this purpose, part of the interdigital transformer is replaced by two or more partial transformers switched in series, each having a reduced track width. Serial switching of the partial transformers can be achieved by incorporating an additional current bar into a conventional interdigital transformer. It is also possible that an internal current bar does not extend over the entire length of the interdigital transformer. The result is an interdigital transformer that is divided into several partial transformers switched in parallel, with one of these partial transformers being divided in turn into two or more partial transformers switched in series. In this way, the impedance of the interdigital transformer, and therefore that of the input or output or the reactance element or the filter, can be increased in a simple manner.

[0020] Preferably, a filter according to the invention is constructed on a single substrate, with lithium tantalate and lithium niobate being the preferred materials.

[0021] Electrode structures comprising aluminum, an aluminum/copper alloy, aluminum and copper layers, an aluminum/magnesium alloy, or aluminum and magnesium layers are suitable for the use as metal on these substrate materials. These materials are distinguished by good adhesion to the substrate material, for example. A SAW HF filter according to the invention is also highly geometrically symmetric, with the exception of the bridge circuit, when implemented on the piezoelectric substrate. Consequently, the electrical connectors (poles) are also arranged symmetricly on the substrate. If the filter according to the invention is mounted to a base plate using flip-chip technology, in which the substrate is connected to metal that faces the base plate by way of solder beads or bumps, this produces filters that have particularly compact external dimensions.

[0022] The invention will be explained in greater detail below by way of exemplary embodiments and the associated 14 figures.

[0023] FIG. 1 shows a four-pole reactance element comprising two reactance elements;

[0024] FIG. 2 shows a reactance series element configured as a four-pole reactance element;

[0025] FIG. 3 shows two symmetric resonators switched in series in the parallel branch;

[0026] FIG. 4 shows a symmetric parallel branch with a reactance element;

[0027] FIG. 5 shows a symmetric DMS filter structure;

[0028] FIG. 6 shows a reactance element in the symmetric parallel branch;

[0029] FIG. 7 shows a symmetric reactance series element in cascade with a symmetric DMS filter;

[0030] FIG. 8 shows a symmetric DMS filter in cascade with a symmetric reactance series element;

[0031] FIG. 9 shows a symmetric reactance element switched between two symmetric DMS filters;

[0032] FIG. 10 shows two serial reactance elements with a reactance element switched in parallel, so that the elements form a symmetric reactance filter;

[0033] FIG. 11 shows a four-pole symmetric reactance series element, with a two-pole reactance element being switched in parallel thereto, forming a symmetric reactance filter;

[0034] FIG. 12 shows a bridge circuit comprising two four-pole reactance series elements;

[0035] FIG. 13 shows a transmission curve of a filter according to the invention; and

[0036] FIG. 14 shows an interdigital transformer, partly divided into half-tracks, for a reactance element having increased impedance.

[0037] FIG. 1 illustrates a simple embodiment of the invention, in which the four-pole reactance series element is formed by two geometrically identical reactance elements RS configured as resonators. Two two-pole reactance elements RS1, RS2 each have a connector (pole), which connectors together form the input IN, while the two other connectors form the output OUT. Each reactance element comprises an interdigital transformer IDT, which is disposed between two reflectors RF. The first reactance element RS1 forms the first serial path SP1 and the second reactance element RS2 forms the second serial path SP2, as shown in simplified form in the right part of FIG. 1. The two reactance elements RS are not acoustically coupled to each other, as illustrated in the left part of the drawing by the double wave line. FIG. 2 shows a four-pole reactance series element that is embodied as a reactance element (resonator) having four connectors. In this resonator, the central interdigital transformer is symmetricly divided in the center into a first partial transformer T1 and a second partial transformer T2, each of which has two connectors. In this case, two connectors located on one side are combined to form the input IN or the output OUT, respectively. Such a four-pole reactance element represents a rudimentary SAW filter. Because of the reciprocity of SAW components, it is clear for this and all other filters according to the invention that they can also be operated in the opposite direction, that is, in a mode of operation in which the inputs and outputs IN, OUT are reversed. This also holds true for the arrangement of the partial structures described below, which can be switched in cascade with such a reactance series element.

[0038] FIG. 3 shows a parallel branch PA, which can be switched between the IN and OUT connectors on the input or output side of the reactance series element. Two reactance elements RP are switched in series in the parallel branch. A virtual ground point G exists between the two reactance elements RP, which demonstrates a constant electrical potential because of its symmetric central position between the serial paths, and can optionally also be connected to ground.

[0039] FIG. 4 shows a reactance element with a different structure, which is likewise arranged in a parallel branch and can be switched between the two connectors of the input or the output of a reactance series element. This reactance element has an interdigital transformer that is disposed between two reflectors and has a current bar that is symmetricly divided into two partial bars TS1, TS2 (shown on the right in the figure). As a result, the interdigital transformer is divided into two partial transformers that are switched in series and together represent a reactance element for the parallel branch, and can be connected to one of the reactance series elements shown in FIG. 1 or 2.

[0040] FIG. 5 shows a known DMS filter, which can function on its own, and has symmetric connectors on the input and output sides. The center interdigital transformer of the three interdigital transformers is provided with two IN connectors on one side of the acoustic track through the symmetric division of one current bar. These connectors form the symmetric input IN. The two outer interdigital transformers are connected to the output OUT. Such a symmetric DMS filter can now be connected to the input or the output of a reactance series element, similar to a reactance element in the parallel branch, as an additional partial structure (see FIG. 1 or 2), or, to state it differently, it can be switched in cascade with this element. It is also possible to switch a DMS filter in cascade with a reactance series element that has a reactance element in the parallel branch.

[0041] FIG. 6 shows another possible partial structure that can be connected to a reactance series element according to the invention. Here, a simple SAW resonator is disposed in a parallel branch as a parallel reactance element RP.

[0042] FIG. 7 shows a further embodiment of the invention, in which a four-pole reactance series element VS is switched in cascade with a symmetric DMS filter DMS (see FIG. 5, for example). The output formed via the outer interdigital transformers of the DMS filter DMS is connected to the two connectors of the input of the reactance series element.

[0043] FIG. 8 shows a switching layout similar to that in FIG. 7, but here, the symmetric DMS filter DMS is connected to the reactance series element VS via the two connectors of the center interdigital transformer. FIG. 9 shows a reactance series element VS that is switched in cascade with a respective symmetric DMS filter DMS1, DMS2 on both sides. In the illustrated embodiment, the DMS filters are each connected to the reactance series elements via the outer interdigital transformers. It is also possible, however, to create the connection between the DMS filter and the reactance series element via the two connectors of the center interdigital transformer of the DMS filters.

[0044] FIG. 10 shows a filter according to the invention, in which two serial paths are provided, with a two-pole reactance element RS1, RS2 (resonator) being disposed in each path. The two serial paths are bridged with a further two-pole reactance series element, i.e., with a two-pole resonator, which is disposed in the parallel branch. In this instance, the resonator (RP) in the parallel branch is unbalanced in frequency relative to the resonators (RS1, RS2) in the serial paths, so the resonance frequencies of the resonators (RS1, RS2) in the serial paths are greater than or equal to the anti-resonance frequency of the resonator (RP) in the parallel branch (PA).

[0045] FIG. 11 shows a reactance series element VS in which the two connectors of the output OUT are switched in parallel with a two-pole reactance element RP. This reactance element of the parallel branch corresponds to the reactance element shown in FIG. 4; namely, it has a divided current bar at the interdigital transformer. In an advantageous embodiment of this filter, the electrical connectors for the output OUT are connected to the reflectors of the reactance element in the parallel branch, and these are connected to the outputs of the reactance series element VS. In this manner, the electrically inactive reflectors, which likewise comprise metallic structures, can be used as tracks. This eliminates the need for additional tracks on the surface of the chip on which the filter is constructed.

[0046] FIG. 12 shows a further filter according to the invention, in which two four-pole reactance series elements VS1, VS2 are switched crosswise to form a bridge. The resonators A and B of the two reactance series elements are unbalanced relative to each other in terms of frequency, which can be adjusted by means of a different finger period or a different distance between the interdigital transformer and the reflectors of the resonators, for example.

[0047] FIG. 13 shows a transmission curve of a filter according to the invention, which was determined using a filter embodied according to FIG. 7, for example. The filter demonstrates a high level of selection of more than 20 dB, and a low insertion attenuation of a maximum of 3 dB over the entire transmission range. Therefore, this filter is particularly well suited for use in mobile radio systems, since it meets the strict specifications required for this purpose. This also holds true for all of the other filters of the invention that are described in the exemplary embodiments.

[0048] FIG. 14 shows a cascade-weighted interdigital transformer that is known per se, and can be used in the reactance elements of filters according to the invention, or in DMS filter switched in cascade to form reactance series elements; the transformer increases the impedance of the corresponding filter or reactance element. It has an additional center current bar ZS, at least in part, which divides the transformer into two partial transformers switched in series. The figure shows an interdigital transformer of this type, which can be divided into three partial transformers TW1, TW2, and TW3 switched in parallel with one another, with the center partial transformer TW3 in turn comprising two partial transformers switched in series via the additional current bar ZS. This interdigital transformer has an increased impedance as compared with a normal interdigital transformer.

[0049] The variations of the invention described in the exemplary embodiments represent only a few of the solutions that are possible by combining the individual elements described above, and which can be realized. This invention is therefore not limited to the structures shown, and ensues in a general form from claim 1.

Claims

1. An HF filter with reactance elements on a SAW basis, the filter being structured on a piezoelectric substrate, and configured to be balanced/balanced and therefore having a symmetric input (IN) and a symmetric output (OUT) with two connectors each, the filter being structured to be electrically symmetric, and having a four-pole reactance element (VS) that includes a single symmetric reactance element (VS) having four poles or two geometrically identical reactance elements (RS) having two poles each, with each reactance element (VS, RS) having interdigital transformers (IDT), one current bar of which is connected to the input side (IN), while the other current bar is connected to the output side (OUT).

2. The filter according to claim 1, wherein the reactance series element (VS) comprises two geometrically identical reactance elements (RS) having two poles each, which elements are disposed in a first or in a second serial path (SP1, SP2), respectively, wherein at least one parallel branch (PA) is provided, in which a resonator (RP) is disposed, the resonator being switched between the first and the second serial path (SP1, SP2), with one pole of the first and the second serial path, respectively, forming the symmetric input (IN), and the respective other pole of the first and second serial path forming the symmetric output (OUT) of the filter.

3. The filter according to claim 1, wherein the four-pole reactance series element (VS) is a resonator with an interdigital transformer (IDT) that is disposed between two reflectors (RF), and has been divided into two axially symmetric partial transformers, with a connector being provided for each partial transformer on each side of the acoustic track, and with two connectors with opposite phases being disposed on each side of the acoustic track.

4. The filter according to claim 3, wherein at least one parallel branch (PA) is provided, in which a resonator (RP) is disposed, the resonator being switched between the first and the second serial path (SP1, SP2), and wherein one pole of each of the first and second path forms the symmetric input (IN), and the respective other pole of the first and the second path forms the symmetric output (OUT) of the filter.

5. The filter according to claim 2, wherein the resonator (RP) in the parallel branch (PA) is unbalanced in frequency relative to the resonators (RS1, RS2) of the reactance series element (VS) in such a way that the resonance frequencies of the resonators (RS1, RS2) of the reactance series element (VS) are greater than or equal to the anti-resonance frequency of the resonator (RP) in the parallel branch (PA).

6. The filter according to one of claims 1 through 5, wherein the two connectors (IN; OUT) of the reactance series element (RS) on the input and output side are switched in cascade with a symmetric input or output of a symmetric DMS filter (DMS).

7. The filter according to claim 6, the filter being switched in cascade with at least one further DMS filter (DMS2).

8. The filter according to one of claims 1 through 7, wherein at least one reactance element (RP) is switched in parallel to two connectors of the filter or the reactance series element (VS) on the input or output side.

9. The filter according to claim 8, wherein the reactance element (RP) switched in parallel comprises the series circuit of two resonators (RP1, RP2).

10. The filter according to claim 8 or 9, wherein the reactance element (RP) switched in parallel has an interdigital transformer (IDT) that is disposed between two reflectors (RF), the current bar of which is divided into two axially symmetric partial bars (TS1, TS2), which are each connected to one of the two connectors of the resonator (FIG. 4).

11. The filter according to claim 3, wherein two reactance series elements (VS1, VS2) that are frequency-shifted relative to one another are connected crosswise to form a bridge circuit.

12. The filter according to one of claims 1 through 11, wherein an interdigital transformer is cascade-weighted and therefore at least partially comprises partial transformers switched in series in the transverse direction.

13. The filter according to one of claims 1 through 11, wherein an interdigital transformer is omission-weighted or overlap-weighted.

14. The filter according to one of claims 1 through 13, wherein one of the reactance elements or a DMS filter has two adjacent surface acoustic wave structures, selected from an interdigital transformer and a reflector, which are phase-shifted relative to one another, with the finger period having a minimum in the region of the transition and decreasing continuously from both sides.

15. The filter according to one of claims 1 through 14, which is constructed on a substrate that is selected from lithium tantalate and lithium niobate.

16. The filter according to one of claims 1 through 15, wherein the filters and the reactance elements have a metallization that contains aluminum, aluminum and copper, or aluminum and magnesium.

17. The filter according to one of claims 1 through 16, wherein the inputs and outputs (IN; OUT) of the filter are connected to connector pads on the substrate, which in turn are contacted on a base plate by way of bumps, using flip-chip technology.