JPH03297211A - Surface acoustic wave filter - Google Patents

Abstract

PURPOSE:To make the impedance of a filter changeable by providing a transmission line for impedance adjustment which is connected between an input terminal and an interdigital electrode and composed of strip lines having prescribed width, length and thickness, onto a piezoelectric substrate. CONSTITUTION:When an impulse voltage is applied to a circuit between an input terminal 25 and an output terminal 26, the distortion of a mutually reversed phase is generated between adjacent interdigital electrodes 21 and 22 by a piezoelectric effect. As a result, surface waves are excited and a frequency selection function is generated to respond to a specified frequency. Since a transmission line 30 for impedance control is formed on a piezoelectric substrate 20, the impedance of this filter can be changed by suitably selecting the width, length and thickness without increasing the length of the transmission line and further without exerting any influence upon the insertion loss of the filter. Therefore, when a shared equipment is constituted of using the surface acoustic wave filter, the transmission line for impedance adjustment in this filter can be used in place of a branching filter circuit, this filter can be miniaturized and the cost can be reduced.

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Application Field) The present invention relates to a surface acoustic wave filter for use in a duplexer, etc., which is compact and provides good frequency characteristics.

(Prior Art) Generally, a duplexer is composed of a transmission filter, a reception filter, and a branching circuit, and has a function of transmitting and receiving a transmission signal and a reception signal through a common antenna terminal or the like. If surface acoustic wave filters are used as the transmission filter and the reception filter, it becomes a surface acoustic wave filter duplexer. Surface acoustic wave filters are small and stable against temperature and aging, and have the characteristics that amplitude characteristics and phase characteristics can be designed almost independently and arbitrarily.

Conventionally, in order to obtain a high-performance surface acoustic wave filter duplexer, various proposals have been made, such as improving the loss of the surface acoustic wave filter and reducing the resistance loss and branching loss of the branching circuit. Furthermore, with the miniaturization of communication devices, it has become essential to realize a compact and high-performance duplexer. An example of a conventional common duplexer is shown in FIG.

FIG. 2 is a refined diagram of a conventional common duplexer.

This duplexer has a substrate 1 made of glass epoxy or the like, and on the substrate 1, an antenna terminal 2, an input terminal 3, and an output terminal 4 are provided. One end of a branching circuit pattern 5 is connected to the antenna terminal 2, and the other end of the branching circuit pattern 5 is connected to an input terminal 3 and an output terminal 4 via a transmission filter 6 and a reception filter 7, respectively. ing. The branching circuit pattern 5 includes a transmitting side transmission line 5a with a transmission line length Lt and a receiving side transmission line 5b with a transmission line length Lr.
It is made up of.

Transmission path length Lt from transmission filter 6 to antenna terminal 2
is designed so that the impedance of the transmission filter 6 from the antenna terminal 2 is maximized at the reception wave number due to the impedance conversion effect. Similarly, the transmission path length Lr from the reception filter 7 to the antenna terminal 2 is also determined so that the impedance of the reception filter from the antenna terminal 2 is maximized at the transmission frequency.

In this type of duplexer, for example, when a received signal is input from the antenna to the antenna terminal 2, the received signal passes through the receiving side transmission path 5b and is converted into a P wave by the receiving filter 7, and is converted into a P wave at the output terminal 4.
The signal is output from the receiver and sent to the receiver n, etc. Furthermore, when a transmission signal from a transmission circuit or the like is input to the input terminal 3, the transmission signal is R-wave-formed by the transmission filter 6, then outputted from the antenna terminal 2 through the transmission side transmission line 5a, and sent to the antenna. It will be done.

When constructing a surface acoustic wave filter duplexer using a general duplexer as described above, a surface acoustic wave filter may be used in place of the transmission filter 6 and the reception filter. FIG. 3 shows a general configuration example of the surface acoustic wave filter.

FIG. 3 is a plan view of a conventional general surface acoustic wave filter.

This surface acoustic wave filter has a piezoelectric substrate 10 for a surface acoustic wave element. On the piezoelectric substrate 10, an input comb-shaped electrode (also referred to as a blind electrode) 11 and an output comb-shaped electrode 12 are formed, and these electrodes 11.
12, an input terminal 15 and an output terminal 16 are formed, which are connected to each other via thin film transmission path patterns 13 and 14, respectively. Further, a ground pattern 17 is formed on the outer periphery of the comb-shaped electrodes 11.12, and the ground pattern 17 is connected to the ground side of each electrode 11.12 via a bonding wire 18.

In this type of surface acoustic wave filter, when an impulse voltage is applied between the input terminal 15 and the output terminal 16, a piezoelectric effect causes distortion in mutually opposite phases between adjacent electrode fingers, and a surface wave is excited. The surface pumping cams excited between the electrode fingers of the comb-shaped electrodes 11 and 12 produce the maximum output at matching frequencies, and conversely, the output becomes minimum when they do not match, functioning as a filter.

(Problems to be Solved by the Invention) However, the surface acoustic wave filter having the above configuration has the following problems.

As shown in Figure 2, the duplexer basically consists of a branching circuit (5
), a transmission filter 6 and a reception filter 7. In particular, the branching circuit (5) works so that the impedance of each transmission filter 6 and reception filter becomes maximum at the center frequency of the other. Therefore, even when a surface acoustic wave filter duplexer is configured using the surface acoustic wave filter shown in FIG. The demultiplexing loss is large, making it impractical. Therefore, in order to separate the transmitted wave and the received wave, the demultiplexing circuit 8 (5) is essential.

In this way, when a conventional surface acoustic wave filter is used to configure, for example, a surface acoustic wave filter duplexer, a branching circuit 8 (5) must be provided outside the surface acoustic wave filter. There is an rj3M in which the shared device becomes larger and the cost increases, and it has been difficult to solve this problem.

The present invention solves the problem that the conventional technology had, in that when a duplexer is constructed using a surface acoustic wave filter, the duplexer becomes large and expensive due to the provision of an external branching circuit. The present invention provides a surface acoustic wave filter.

(Means for Solving the Problems) In order to solve the above problems, the present invention provides a surface acoustic wave filter in which a plurality of comb-shaped electrodes connected to an input terminal and an output terminal are formed on a piezoelectric substrate. An impedance 9 connected between the input terminal and the comb-shaped electrode and consisting of a strip line having a predetermined width, length, and thickness.
A transmission path is provided on the piezoelectric substrate.

(Function) According to the present invention, since the surface acoustic wave filter is configured as described above, when an impulse voltage is applied between the input terminal and the output terminal, the piezoelectric effect causes the adjacent comb-shaped electrode fingers to have opposite phases to each other. Distortion is created, surface waves are excited, and a frequency-selective function that responds to specific frequencies occurs. and,
Since the transmission line for impedance adjustment is formed on a piezoelectric substrate, by appropriately selecting the width, length, and thickness of the transmission line, it is possible to insert a filter without increasing the length of the transmission line. without affecting losses.
It has the function of changing the impedance of the filter. Therefore, when this surface acoustic wave filter is not used to configure, for example, a duplexer, the impedance adjustment transmission line in the filter can be replaced with a conventional branching circuit. Therefore, the above problem can be solved.

(Example) FIG. 1 is a plan view of a surface acoustic wave filter showing an example of the present invention.

This surface acoustic wave filter is for transmission and has a piezoelectric substrate 20. This piezoelectric substrate 20 is made of, for example, a substrate material L i T a O3, a thickness of 0.3 mm, and a dielectric constant of 44. On this piezoelectric substrate 20, a plurality of input comb-shaped electrodes 21 having a plurality of electrode fingers are provided.
and comb-shaped tgi for output! 22 are formed, and their input comb-shaped electrodes 21 are commonly connected by a thin film transmission line pattern 23, and each output comb type &22 is connected to a thin film transmission line pattern 24. ! i is connected.

The transmission line pattern 23 on the input side is connected to the input terminal 25 via the impedance adjustment transmission Nr 30 formed on the piezoelectric substrate 20, and the transmission line pattern 24 on the output side is connected to the output terminal 26. It is connected to the. The impedance adjustment transmission #30 is formed of a strip line having a predetermined width, length, and thickness, and is made of a film-like material with good conductivity such as gold.

Further, a ground pattern 27 is formed on the piezoelectric substrate 20 on the outer periphery of the comb-shaped electrodes 21.22, and the ground pattern 27 is connected to the ground side of each comb-shaped electrode 21.22 by a bonding wire 28. ing.

In this surface acoustic wave filter, when an impulse voltage is applied between the input terminal 25 and the output terminal 26, a piezoelectric effect causes distortion in opposite phases between adjacent electrode fingers, and the surface acoustic wave is excited. be done. Comb-shaped electrode 21.2
The maximum output is obtained at a frequency that matches the surface wave output excited between the two electrode fingers, and the output is minimum when they do not match. Using the shoulder wave number selection characteristic of this surface wave output, the r wave of the input signal is performed.

In this way, the truth is 1t! , S surface acoustic wave filter is
It has almost the same functions as the conventional one. The filter of this embodiment differs from the conventional filter in that the input terminal 25 is connected to the input side transmission line pattern 23 via an impedance adjustment transmission line 30.

The impedance adjustment transmission line 3o is created on the same piezoelectric substrate with a high dielectric constant as the surface acoustic wave filter body, so it does not need to be very long.

The reason for this is that the transmission 130 is composed of a strip line, the length of which is inversely proportional to the square root of the dielectric constant of the piezoelectric substrate 2o.

The surface acoustic wave filter of this embodiment is for transmission, and has a center frequency of 835.0 MHz, for example.

The piezoelectric substrate 2o is made of substrate material LiTaO3 and has a thickness of 0.3
mm, and has a dielectric constant of 44. Transmission frequency 83
5.0 MHz and a reception frequency of 880.0 MHz, when the conventional surface acoustic wave filter shown in FIG. 3 is constructed under the same conditions except for the impedance adjustment transmission line 3o of this embodiment, the surface acoustic wave filter shown in FIG. The measured values of impedance Zl and Z2 in the filter are shown in the following equations.

835.0 MHz -21=60.71+j 3.2
7 (Ω) (1) 8B0.0 MHz-422=8.93-j 8.80
(Ω) (2) In order to maximize the absolute value of the impedance z2 of the filter at a reception frequency of 880.0 MHz, the impedance adjustment transmission N30 of this embodiment is configured as follows. For example, the line width 50 μm (characteristic impedance 50Ω, y
It is formed of a gold film transmission line (strip line) with i, m length l, 43 cm, and M thickness 3.0 μm or more. Then, the impedances Z1a and Z2a of the surface acoustic wave filter of this example are
changes as follows.

835, 0 MHz-”Z 1 a =40.85-j
0.76 (Ω) (LAN 8B0.0 MHz -22a =371.9+j 0
．． 48 (Ω)...(2a) As is clear from comparing equations (2) and (2a), at a receiving frequency of 880.0 MHz, the absolute impedance Z2a of the filter of this example is The value is larger than the absolute value of the impedance z2 of the conventional filter and is at its maximum value. Furthermore, from equations (1) and (1a), it is understood that in the passband of the transmission frequency of 835° 0 MHz, the absolute values of the impedance Zla of the filter of this embodiment and the impedance Z1 of the conventional filter do not differ, respectively. can. On the other hand, even if the impedance adjustment transmission N30 is provided as in this embodiment, it only affects the phase, but does not affect the insertion loss of the filter.

The impedances Zl, Z2 given by equations (1), (2), (1a), and (2a) are Zla.

The characteristic diagram of Z2a is shown in FIG. 4 (a>, (b)).

FIG. 4(a) shows the impedance characteristics of the conventional surface acoustic wave filter before introducing the impedance adjustment transmission line 30, and FIG. 4(b) shows the impedance characteristic of the filter of this embodiment after introducing the transmission line 30. is the impedance characteristic of

As is clear from this figure, transmission 1!
When t30 is provided, although the absolute value of the impedance of the filter in the pass band of 835.0 MHz is almost the same as that of the conventional filter, the absolute value of the impedance of the filter of this example at the reception frequency of 880.0 MHz is the same as that of the conventional filter. It is larger than that of , and has the maximum value.

Therefore, the impedance adjustment transmission line 30 provided in this example functions as a branching circuit in a duplexer, for example. Therefore, this embodiment has the following advantages.

Since the impedance adjustment transmission line 30 is created on the same piezoelectric substrate 20 as the surface acoustic wave filter main body, when the surface acoustic wave filter of this embodiment is used to configure a surface acoustic wave filter duplexer, for example, There is no need for the conventional branching circuit pattern 5 as shown in FIG. Therefore, by using the transmitting surface acoustic wave filter and the receiving surface acoustic wave filter manufactured based on this example, it is possible to easily configure a surface acoustic wave filter duplexer.

That is, the output terminal (26) of the transmitting surface acoustic wave filter and the input terminal (25) of the receiving surface acoustic wave filter,
If it is directly connected to the antenna terminal 2 shown in FIG. 2, a surface acoustic wave filter duplexer can be obtained.

In the duplexer as shown in Figure 2, energizing and branching circuit pattern 5
requires an area of approximately 2.5 cm x 4.0 cm or more. On the other hand, in this embodiment, since the transmission line 30 is provided in the surface acoustic wave filter, the substrate size of the surface acoustic wave filter becomes slightly larger, but the branching circuit pattern 5 unlike the conventional one is not required. When looking at the surface acoustic wave filter duplexer as a whole, it is possible to significantly downsize the surface acoustic wave filter as a whole compared to the conventional one while maintaining good frequency characteristics, and it is also expected to reduce costs.

Note that the present invention is not limited to the illustrated embodiment, and various modifications are possible. Examples of such modifications include the following.

(a) In the above embodiment, a surface acoustic wave filter for transmission has been described, but a filter for reception can be easily constructed by changing the electrode finger gap shown in FIG. 1, for example.

(b) The transmission line patterns 23, 24 and the ground pattern 27 can be modified to other shapes and arrangements depending on the number and arrangement of the comb-shaped electrodes 21, 22 in FIG. 1, or in accordance therewith. Furthermore, the arrangement positions of the input terminal 25 and the output terminal 26, or the planar shape of the transmission line 30 connected to the input terminal 25, etc. can be changed to a shape other than that shown in the drawings.

(C) In the above embodiment, a case where a surface acoustic wave filter duplexer is constructed using a surface acoustic wave filter has been explained. It is also possible to use the filter alone.

(Effects of the Invention) As explained in detail above, according to the present invention, the transmission line for impedance adjustment consisting of a strip line is formed on the piezoelectric substrate. The impedance of the filter can be changed while maintaining its characteristics. Therefore, when the surface acoustic wave filter of the present invention is used to configure, for example, a duplexer, the conventional demultiplexing circuit can be omitted, which makes it possible to reduce the overall size of the duplexer and also to reduce costs. . Further, even if the surface acoustic wave filter of the present invention is used alone or incorporated into another device, effects such as simplification of the circuit configuration can be expected.

[Brief explanation of drawings]

Fig. 1 is a plan view of a surface acoustic wave filter showing an embodiment of the present invention, Fig. 2 is a configuration diagram of a conventional common duplexer, Fig. 3 is a plan view of a conventional surface acoustic wave filter, and Fig. 4 is a plan view of a conventional surface acoustic wave filter. Figure (a>,
(b) is an impedance characteristic diagram of the conventional example and the present example. 20... Piezoelectric substrate, 21... Comb-shaped electrode for input, 22... Comb-shaped electrode for output, 23.2
4...Transmission line pattern, 25...Input terminal, 26...Output terminal, 30...Transmission line for impedance adjustment. 30; Transmission line for interference adjustment Fig. 2 Surface acoustic wave filter according to an embodiment of the present invention Fig. 1 Fig. 3 of a conventional surface acoustic wave filter

Claims (1)

[Scope of Claims] In a surface acoustic wave filter formed on a piezoelectric substrate, a plurality of comb-shaped electrodes connected to an input terminal and an output terminal are connected between the input terminal and the comb-shaped electrodes, and a plurality of comb-shaped electrodes are connected to each other. A surface acoustic wave filter, characterized in that an impedance adjustment transmission path made of a strip line having a width, length, and thickness is provided on the piezoelectric substrate.