The present Application for Patent claims priority to German Patent Application No. 102016110139.7, filed Jun. 1, 2016, which is hereby expressly incorporated by reference herein in its entirety.
In order to reduce the temperature response of SAW filters, they are provided with a compensation layer, usually including SiO2. A side effect of this measure, however, is that the coupling is reduced. Broadband filters having such compensation layers can therefore be produced only on highly coupled substrates such as lithium niobate LN.
Bandpass filters made of SAW resonators having a compensation layer can, for example, be made on lithium niobate crystals having a red-128 cut angle. The resonance frequency of the acoustic Rayleigh mode is used on this substrate material.
Many filters having specific material combinations for electrodes and the layers deposited thereupon, and/or for specific layer thickness combinations are capable of propagating parasitic modes, in particular a disk mode. The resonance frequency of the disk mode is above the resonance frequency of the Rayleigh mode. For the serial resonators of a filter, the resonances of the disk mode are above the passband of the filter and cause sharp drops in the transmission function of the filter. Even if the geometry of this filter is optimized for maximum suppression of the interference mode, it can be enhanced as a result of geometric deviations caused by tolerances and under temperature and power loads. This can cause an increased temperature and power load on the resonators that could result in premature wear and, ultimately, failures of the filter. In other cases, the frequency of an interference mode is at another usage frequency that is also shared by the device having the filter arrangement and operation at this frequency is disturbed.
In the case of other material combinations, other interference modes can also occur that unacceptably interfere with the filter characteristics in the range of the passband or in other important frequency ranges.
An extensive suppression of the interfering SH mode is successful if the electrical coupling of this mode is reduced. This can be achieved by a carefully optimized geometry in which the layer heights of dielectric layers as well as the width and the height of the transducer fingers are controlled within narrow limits. This sets narrow tolerances for the manufacturing process, however.
The object of the present invention is thus to reliably and continuously suppress interference modes and, in particular, interference modes of a SAW filter.
This object is achieved by a SAW filter according to claim 1. Advantageous embodiments of the invention are provided in additional claims.
The proposed SAW filter has an interdigital transducer whose transducer fingers are arranged in succession in the longitudinal direction in relation to their finger centers in a first periodicity. The periodicity determines the resonance frequency of the transducer, which corresponds to the resonance of the main mode. Hereinafter, the resonance of the transducer is always understood to include the resonance of the main mode unless another resonance is specifically indicated.
The transducer fingers of the transducer form a first and a second group or are assigned to either a first or a second group of transducer fingers. In the first group, a first increment changes a geometric parameter that determines the resonance in the transverse direction. In the second group of transducer fingers, a second increment changes a geometric parameter that determines the resonance in the transverse direction and is opposed to the first increment or produces an effect opposed to the first increment.
In the present case, the variation of the geometric parameter in the transducer fingers of the second group, when considered by itself in isolation, causes a frequency change which is opposed to the one caused by the corresponding variation in the transducer fingers of the first group.
The transverse variations in the first and second groups of transducer fingers thus compensate for each other with respect to their effects on the resonance of the main mode. Thus, a consistent resonance of the main mode is present in any transverse subsection of the transducer.
At the same time, the resonance frequency of an interfering secondary mode is affected by the transverse variation of the geometric parameters. In contrast to the corresponding effect on the main mode, however, the effects of the transverse changes in the first and second groups of transducer fingers do not compensate for each other with respect to the secondary mode. This results in a variation of the secondary mode resonance frequency in the transverse direction, whereby the interfering resonance peak spreads in the spectrum. The excitation of the secondary mode is thus reduced overall and the secondary mode is suppressed.
For virtually all interdigital transducers, a geometric parameter can be found that, when changed, can affect the resonance frequency of the transducer's main mode. Typically, such a geometric change shifts also the resonance frequency of the secondary mode. In most cases, the dependency of the resonance frequencies on the change of the geometric parameters is different for the two modes. This means that the resonance frequencies of the main and secondary modes can be shifted to varying degrees by a given geometric parameter change.
For each change of the geometric parameters or for each shift of the resonance frequency caused by the change of the geometric parameter in a group of transducer fingers, there is at least one geometric setting in the second group of transducer fingers that precisely compensates for this shift in the main mode. Because of the different dependencies with which the resonance frequency of the main mode and the secondary mode react to a change in the geometric parameters, compensation cannot be achieved for the secondary mode. As a result, the resonance of the secondary mode shifts and varies over the transverse direction in transverse subsections. This results in a lower excitation of the secondary mode, to a reduced or damped noise signal through the secondary mode in the case of an unmodified main mode.
In an advantageous embodiment of the invention, the number of transducer fingers is equal in both groups. This means that a transducer finger of a first group can be assigned to exactly one transducer finger of a second group. Preferably the transducer fingers of the two groups are arranged alternately in the longitudinal direction. By using the alternating arrangement, a higher homogeneity is achieved in the transducer and the transmission properties are influenced positively.
The geometric parameter, whose change affects the resonance frequency of the transducer, can be chosen from among: finger width, mass allocation of the transducer fingers and metalization thickness η. For the metalization thickness η, it is important that it is not only dependent upon the fingers of the finger group and, therefore, also cannot be set independently of the electrode fingers of the second finger group.
If the finger width of a first group of transducer fingers is increased in the transverse direction, then it must usually be decreased in the second group of transducer fingers in the transverse direction. The change in the geometric parameter of the second group must usually take place with a different amount, thus having the consequence that in the transverse direction not only the finger width of the transducer fingers of the two finger groups changes, but also the metalization thickness η.
It is generally not possible to fully compensate for the effects of geometric parameter changes in the first and the second finger groups by mutually symmetrical geometric parameter changes.
In the case of constant periodicity of the transducer fingers, the finger width cannot be changed independently of the finger spacing or of the spacing of the finger centers. A change of the finger spacing alone when the remaining parameters remain otherwise constant would result in a change in the periodicity. This is only permissible, however, if the change in periodicity for fingers of the first group has an effect on the resonance frequency that can be equalized again by a corresponding change in the second group.
In an advantageous embodiment, the transverse variation of the geometric parameter takes place continuously, for example, and conforms to a continuous function. Continuous changes are possible that follow a linear or a non-linear function.
It is also possible to change the geometric parameter in the transverse direction stepwise, so that the geometric parameter in a transverse section of the transducer is constant, whereas the adjacent one varies stepwise. Such a stepped geometric change includes at least two adjacent transverse sections. Even with just two sections, the effect according to the invention of suppressing the secondary mode is achieved if the geometric changes in the two transverse sections have different effects on the resonance of the main and secondary modes.
However, the transducer can be divided into any number of transverse sections, so that an infinite, yet continuous change can be achieved.
A SAW filter according to the invention may have a layer stack with a piezoelectric substrate overlain by a metalization layer in which the transducer fingers are formed and, over that, a dielectric layer or a dielectric layer sequence. In one embodiment of the invention, materials and/or layer thicknesses of the layer stack can now be varied in such a way that the extent of mode influence on the main mode and the secondary mode is maximally different. In this manner, a maximum suppression of the interfering secondary mode can be achieved by corresponding geometric variations.
In the aforementioned layer stack, the desired effect for changing the geometric parameter of the transducer fingers can also be increased by a regularly structured layer, which is arranged over or under the transducer fingers and is applied over the dielectric layer, for example.
The structured layer can have a periodicity in the longitudinal direction that corresponds to the periodicity of the metalization layer or of the transducer fingers.
Additionally or alternately, the structured layer can have a transverse variation of a geometric parameter.
It is also possible to double the periodicity of the structures in the structured layer, which, by alternately arranging the transducer fingers of the first and second groups, results in the periodicity of the structured layer corresponding to the periodicity of a group of transducer fingers, and this, therefore, affects only this group of transducer fingers.
In the case of a different sequence of transducer fingers of the first and second finger groups, a different periodicity corresponding to the respective finger group can also be set in the structured layer.
Transducer fingers of this group and the structured layer can then interact in such a way that the two transverse geometric variations together influence the resonance frequency of the transducer.
The invention will be explained in greater detail below with reference to exemplary embodiments and the accompanying figures. The figures are, in part, only shown schematically and only serve for better understanding and are, therefore, not to scale. Individual parts can be depicted enlarged, reduced, simplified or distorted.
The basic idea of the invention is to allow the frequency of an interference mode—the origin of which is not directly relevant to the invention—to vary by changing one or a plurality of geometric parameters across the width of the transducer, meaning in the transverse direction, wherein the frequency conditions or the resonance conditions for the main mode are kept constant across the entire aperture.
In a first step, the main and secondary mode dependencies are determined by this geometric parameter.
In the next step, a transverse frequency variation caused by a change in the geometric parameters is again compensated by geometric measures. In accordance with the invention, this succeeds if the transducer fingers EF of the interdigital transducer are divided into two groups that are preferably alternately arranged in succession in the longitudinal direction LR. While a variation of the geometric parameter in transducer fingers in the first finger group FG1 results in a frequency shift according to curve M1 from
The invention makes it possible to hold the frequency of main mode M1 constant by appropriate geometric variations in first and second finger groups FG1, FG2. Because the frequency of the secondary mode M2 is otherwise a function of the variation in the geometric parameter, the frequency deviation of the secondary mode is not compensated by the geometric parameter variations implemented through first and second finger groups FG1, FG2.
The embodiments according to
Insofar as a division of the interdigital transducer into two transverse subsections TA does not sufficiently damp the secondary mode or does not sufficiently “smear” its resonance, the transducer must be divided into a higher number of subsections, each having different geometric parameters.
In the embodiment according to
The invention could be explained in reference to just a few exemplary embodiments and is, therefore, not limited to these. All possible geometric parameters, which have an influence on the resonance of a mode can be changed, wherein the variations can also be carried out in forms other than those depicted. Because the geometric variations are applied depending upon the mode, different interfering secondary modes can be compensated in this manner. Each variation is then oriented or optimized to precisely one interference mode.
DL dielectric layer
EF converter finger
f Frequency
FG1 first group of transducer fingers
FG2 second group of transducer fingers
LR longitudinal direction
M1 main mode
M2 secondary mode
ME metalization layer
p periodicity of the transducer fingers
ST regularly structured layer
SU piezoelectric substrate
TA transverse section
TR transverse direction
η metalization thickness
Number | Date | Country | Kind |
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102016110139.7 | Jun 2016 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/US2017/034977 | 5/30/2017 | WO | 00 |