DE4319248A1 - Surface wave filter using IIDT arrangement - Google Patents

Abstract

A new dimensioning rule for the respective input (E1, ...) and output (A1, ...) converters contained therein is given for filters of the IIDT type, which filters have respective finger numbers which are dimensioned in combined form with respect to one another region by region or section by section. <IMAGE>

Description

For applications in the send and receive branch of Mobilfunksy You need filters with a low insertion rate attenuation at the same time a low ripple in the through range and a relative bandwidth of up to Reach 5%.

A suitable and known filter technology is based on a special arrangement of surface wave transducers. See also M. Lewis, "SAW filters employing interdigitated interdigital transducers, IEED", IEEE Ultrasonics Symp. Proc. (1983), pp 59 to 61. This embodiment of a surface acoustic wave filter, known as the IIDT filter, has several in one and the same acoustic track on a piezoelectric substrate, such as, for. B. lithium niobate, arranged interdi gital converter. These converters are alternately connected to the filter input or to the filter output. Fig. 1 shows a schematic diagram of such an IIDT filter, where this schematic diagram also represents a filter according to the invention and the invention is embodied in the new design according to the invention of the individual input converters E1 to E8 and output converters A1 to A7.

It is known to build IIDT filters so that their interdi Gitalwandler E and A are dimensioned such that the ratio the number of fingers of two adjacent transducers, for example 0.7 or 1 / 0.7. For this, see also EP-0 448 357 A2 pointed out. So it applies

N _Ei / N _Ai approximated = 0.7 or 1 / 0.7 (1)

With this dimensioning, the blocking attenuation of the filter can be increase because the first zeros in the electroacoustic the transfer function of the converter with the larger type number of fingers with the first secondary maxima of the electroaku  tical transfer function of the converter with the smaller one Number of fingers collapse.

If all input converters are identical, each individual converter has an admittance Y _E , and all output converters also match the admittance Y _{A of} the individual converter, the ratio of the input admittance to the output admittance of the filter, which consists of a total of N _W converters

Due to the different number of fingers according to equation 1) in the input transducers on the one hand and the output transducers on the other hand, the admittances Y _E and Y _A are different from one another. Equation 2) thus means that the input admittance and the output admittance of the overall filter differ from one another. For practical use as a filter, however, it is advantageous if it has the same input and output admittance. You can then z. B. use the same adjustment elements for input and output. This means that the number of different construction elements to be used is reduced, and less warehousing. Ideally, you only need a matching element for a gate and in gün stigen cases such is even unnecessary.

The object of the present invention is therefore to implement measures or specify a design for an IIDT filter that is almost has the same input admittance and output admittance, low Insertion loss and low ripple in the pass band has a relative bandwidth of up to 5% makes available.

This task is accomplished with an IIDT surface wave filter 4 solved the features of claim 1 and 4 and more Design and further training are based on the subclaims Chen stands out.  

The present invention differs from the prior art Technology on a number of important points. Starting from the known technology with transducers, the ratio of the fingers number behaves approximately like 0.7, the invention sees however, before, these converters separated into several from each other summarize local areas to be considered. There are u. a. several areas each consisting of the same or featured at least nearly the same transducers in one track see, where the respective number of fingers of the transducers nes area from that of another area below can divorce. It can also (not directly neighboring) areas with a wall in these areas learn with the same number of fingers.

In the invention, the filter admittances are at the entrance and closer together at the exit than in known arrangements. In order to specify the transmission characteristics as precisely as possible meet, it is provided in the invention that neighboring areas in terms of the number of fingers of their Distinguish transducers from each other. Even with fiction filters that consist of only a few converters (e.g. nine wall with a filter bandwidth of 3%) that the number of fingers of neighboring transducers is often not that known ratio of 0.7 corresponds.

The invention also has the advantage that known measures weighting of the transducers (e.g. with overlap or Omission weighting) can be performed.

In some embodiments, this is even better be made visible.

A first example of a filter with e.g. B. 15 transducers has a sequence as shown in FIG. 1 E1, A1. . . A7, E8 of the individual input and output converters with 24-28-28-34-32-38-38-40-38-38-32-34-28-28-24 fingers per converter. This example clearly shows the area structure on which the invention is based. Two first areas each consist of two transducers with 38 transducer fingers each. Two second areas each consist of two transducers with 28 transducer fingers each. Transducers are provided between each of a first and a second area, which are assigned to third areas or are to be regarded as such. Firstly, there are the areas with the two transducers with 34 and 32 fingers. You are between a first area and a second area. There are also "degenerate" third areas, each consisting of only one transducer, namely a third area with a single transducer with 40 fingers and at the ends of the acoustic track a third area with a transducer with 24 fingers. It can be seen that in the invention the number of fingers of the transducers is the same in a first and in a second area. In one or more (here two) defined third areas (within the area) neighboring transducers have a finger count ratio different from 1. Other third (degenerate) areas (here three) with only one transducer have a difference in the number of fingers in relation to the neighboring one Transducer of the adjacent area.

Another example of a filter with 15 converters and unsung The number of fingers per converter is as follows:

25-29-29-35-33-39-39-41-39-39-33-35-29-29-25. This too Filter has (first) areas with converters matching with 39 transducer fingers, (second) areas with transducers with matching 29 transducer fingers and has (third) Areas of type with 35-33 transducer fingers per transducer and (degenerate third) areas with 41 or 25 fingers each because only one converter.

In summary, the principle of the invention can be said that an inventive filter a number of areas with inner same transducers (38 Fingers, 28 fingers, 39 fingers, 29 fingers), which is the first  and second areas are designated. In addition, the be written third areas between first areas, between first and second areas and, if necessary, between second areas (the latter not shown) provided. According to the variant of claim 4 (instead of according to Claim 1 defined areas) sections with these encompassed transducers, for which the ratio of each because of the number of fingers to each other at least essentially is approximately 1, d. H. especially various 1 and for the sections among themselves an average of the number of fingers of the transducers of the respective gen section is determined.

The above explanations indicate the principle on which the invention is based. This is different from the state of the art Technology provided local distribution of the different Number of input or output transducer fingers gear converter in the filter.

In practice, one uses for the filter design (semi) automatic process. Such a procedure will described below, however, are previously general specified principles.

There are still filter properties such as bandwidth, wavy speed, passband and blocking selection from the nearer end design of the geometry of the filter structure. Without one limitation of the general applicability of the invention a filter from z. B. a total of 15 transducers (as above games) created by design. It is assumed that at the same distance from the spatial ends of the surface same filter are arranged as this the examples show. For the filter there is a relative band width of about 5%. (With other requirements can be made).  

For the simulation calculations to be carried out, the Me height of the transducer fingers on the substrate surface surface with approximately 2% of the acoustic wavelength of the filter taken. The substrate must be specified, preferably a highly coupling material such as B. 36 ° red Y, X lithium tan talat.

All simulation calculations are carried out using the so-called P-matrix model carried out, which in principle be skilled in the art is known. This model is already up to parasitic Effects, the electromagnetic crosstalk from the filter going to the filter output and the excitation of unwanted volu men waves through fashion conversion effects, which also got can be taken into account, all essential phy contain physical phenomena.

The transducers are first divided into selected sections of the basic structure. A total of three sections have been adopted for the invoice model. First, a decision is made as to how the individual converters are to be distributed over these three sections. For this purpose, the sections at the ends (left end and right end in FIG. 1) of the filter should consist of N _external transducers with an identical structure. The section in the middle part of the filter (see FIG. 1) then automatically comprises N _inside = N _W - 2 × N _outside = 15 - 2 × N _outside transducers. These are also identical to one another. In view of the specified and achievable bandwidth of 5%, the respective number of transducer fingers of the two transducer types is selected to be 28 (outer sections) and 38 (inner sections). It should be noted that the finger count ratio is approximately 0.7 so that the above equation 1) is satisfied. Fig. 2 shows the most important filter properties (insertion loss, selection, ripple and bandwidth), plotted over the section size N _outside . The best lock selection is obtained e.g. B. visible for N _outside = 5, ie if all three sections consist of the same number of transducers. The above-described basic structure of the filter according to the invention with three sections from the same number of converters each, with all converters being identical within one section, serves as the starting point for the further filter design. Discontinuities occur in particular on the outer edge of the filter or where two sections meet. The invention also provides for a separate treatment of these transitions, since such discontinuities lead to poor selection and high ripple in the pass band of the filter transfer function.

Starting from this division into sections, one varies on Calculate the respective number of fingers of the converter until you look has optimally approximated the specifications. This then delivers Filter according to claims 1 to 3 or a filter according to the Claims 4 and 5 with the division of the optimized converter to the sections discussed above.

Figs. 3a to 3d show as an example the effects of varying the number of transducer fingers in the transducers El and E8 of FIG. 1. Variations in the number of transducer fingers in the other transducers A₁, E₂. . . E₇, A₇ result in analogous dependencies, on the basis of which the person skilled in the art makes the respective decision about the number of fingers of each of the transducers.

Claims (5)

1. IIDT surface acoustic wave filters with a number of input transducers and with a number of output transducers different from them, the input transducers and the output transducers relative to one another having a ratio of their number of fingers in a predetermined number range,
being in the main direction of propagation of the acoustic wave of the filter
In at least one local first area there are mutually adjacent input and output transducers, which have a ratio equal to one another to the number of their transducer fingers and the number of fingers of the individual transducer is predetermined, and
at least two local areas not directly adjacent to a local first area are provided with input transducers and with output transducers, the ratio of the number of fingers of the individual transducers to one another again being equal to 1 between the adjacent input and output transducers of these second areas, the number of fingers the individual transducers of the second regions are however different in size from the number of fingers of the individual transducers of a respective first region
wherein the ratio of the number of fingers of the individual transducers of the first areas to the number of fingers of the individual transducers of the second areas is between approximately 1.2: 1 and 1.6: 1 and wherein first and second and optionally also first areas and / or second areas each are separated from each other by third areas,
either from adjacent input and output transducers, these input transducers learning from the output wall have a close to 1, but different ratio of the respective number of their transducer fingers, or are formed from only one transducer. 2. IIDT surface acoustic wave filter according to claim 1,  such a single, forming a third area Converter to an adjacent converter of a first or two range is close to 1 but differs from 1 which has the ratio of the respective number of transducer fingers. 3. IIDT surface acoustic wave filter according to claim 1 or 2, that additionally in the main direction of propagation of the acousti wave another terminal input / Provided output converter. 4. IIDT surface acoustic wave filter with a number of input transducers and with a number of output transducers different from it, the input transducers and the output transducers relative to one another having a ratio of their number of fingers in a predetermined number range,
being in the main direction of propagation of the acoustic wave of the filter
in at least one local first section there are input converters and output converters whose ratio of the number of fingers of adjacent input and output converters is at least approximately equal to 1, and
at least two adjacent local second sections with input transducers and output transducers are provided, the ratio between the number of transducer fingers between adjacent input and output transducers being at least approximately equal to 1,
wherein the respective average number of fingers, averaged from all transducers of a first section to the average number of fingers, averaged from all transducers of a respective one of the further second sections, has a ratio between 1.2 and 1.6. 5. IIIDT surface converter according to claim 4, in which the at least a first section and the little at least two second sections different from each other Number of input and output converters.