JPH0786803A - Low-pass filter - Google Patents

Abstract

PURPOSE:To obtain a low-pass filter provided with improved electrical perfor mance capable of making a pattern shape small by interposing an input/output separation pattern set to ground potential between the mutually parallelly ar ranged parts of respective micro strip lines and forming a capacitor between them. CONSTITUTION:This filter is constituted of the micro strip lines(MSL) 103 and 104 of high impedance in a crank shape formed in the shape of rectangular waves by being connected for plural numbers, the input/output separation pattern 108 installed in the ground potential and interposed between the mutually parallelly arranged parts of the MSLs 103 and 104 and the capacitor 106 formed between the connection points of the respective MSLs 103 and 104 and the input/output separation pattern 108. Then, by integrally forming the input/output separation pattern 108 and a ground pattern 11 and setting the input/output separation pattern 108 to the ground potential, spatial coupling between the MSL 103 and the MSL 104 is interrupted by the input/output separation pattern 108 of the ground potential.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a low-pass filter used in equipment using microwaves such as radio communication equipment.

[0002]

2. Description of the Related Art In a device using microwaves such as a wireless communication device, a harmonic having a frequency component twice or three times the fundamental frequency is generated in an active circuit such as an amplifier or an oscillator, which causes transmission. It is known to cause distortion, where it is used as a means of removing these harmonics.
A pass filter is used.

Such a low-pass filter can be easily realized by a microstrip line as a lumped constant combination of inductance and capacitance. FIG. 4 shows an example of a conventional microwave low-pass filter. 403 and 404 are high-impedance microstrip lines (hereinafter abbreviated as MSL). Input / output ports 401, 402, MSL403, MSL40
4. The input / output ports 402 are arranged in a line in a straight line.

Input / output port 401 and MSL 403
Connection point, MSL403 and MSL404 connection point, MS
Capacitors 405, 406, and 4 are provided between the ground pattern 41 and the connection point of L404 and the input / output port 402, respectively.
07 are formed.

[0005]

However, the input / output port 401, the MSL 403, and the MS in the above-mentioned configuration are as follows.
Since the L404 and the input / output port 402 are linearly arranged in a line, the area occupied on the printed circuit board becomes large, which makes it difficult to downsize a device using the same.

Therefore, in order to reduce the occupied area on the printed circuit board, as shown in FIG. 5, the MSL 503 and MSL 504 are bent in a crank shape so that the input / output port 5
01 and the MSL 503, and the connection point between the MSL 504 and the input / output port 502, capacitors 505 and 507 are formed between the ground pattern 51 and M.
It is considered that a capacitor 506 is formed between the SL 503 and the MSL 504 at a connection point with another ground pattern 52.

With this arrangement, the area occupied on the printed circuit board can be reduced and the device can be made compact. However, with such a configuration, the portions of the MSL 503 and MSL 504 on the printed circuit board, which are arranged in parallel with each other, are spatially coupled via a predetermined distance as shown in FIG. That is MSL
Since 503 and the MSL 504 are formed of high impedance lines, the electric field component E of the microwave radiated into space facilitates the coupling. Therefore, there is a problem that unnecessary signals and the like that are to be removed by this filter are bypassed at this spatially coupled portion and pass to the output side, which significantly deteriorates the electrical performance as a filter.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a low-pass filter having a small pattern shape and having good electrical performance.

[0009]

SUMMARY OF THE INVENTION According to the present invention, a high-impedance microstrip line is formed in a rectangular wave shape by forming a crank shape and connecting a plurality of cranks, and these microstrip lines are arranged in parallel with each other. Input / output separation pattern placed at the ground potential interposed between the parts and a capacitor formed between the connection point of each microstrip line and the input / output separation pattern. There is.

[0010]

As a result, according to the present invention, crank-shaped MSLs having a high impedance are connected in series to form a rectangular wave, and a ground potential is provided between the portions of each MSL arranged in parallel with each other. Since a set input / output separation pattern is interposed and a capacitor is formed between this input / output separation pattern and the connection point of each MSL, each MS is connected.
The spatial coupling between the L's can be blocked by the input / output separation pattern, and the unwanted signal which the filter intends to block can be prevented from being bypassed by the spatial coupling section and passing to the output side. The size can be reduced by making the pattern shape rectangular.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows a schematic configuration of the same embodiment. In the figure, 103 and 104 are high impedance MSLs, 1
Reference numerals 01 and 102 denote signal input / output ports. These input / output ports 101, MSL103, MSL104, and input / output ports.
The switch 102 is connected in series.

In this case, the MSL 103 and the MSL 104 are crank-shaped ones and are formed in a rectangular wave shape as a whole. At the connection point between the input / output port 101 and the MSL 104 and at the connection point between the MSL 104 and the input / output port 102, a capacitor 105 is provided between the input / output port 101 and the ground pattern 11.
107 is formed, and a capacitor 106 is formed between the MSL 103 and the MSL 104 and an input / output separation pattern 108.

Here, the input / output separation pattern 108 is formed integrally with the ground pattern 11, and is arranged in parallel on the printed circuit board 21 as shown in FIG.
It is arranged so as to be interposed between 103 and the MSL 104.

The ground pattern 11 and the input / output separation pattern 108 are connected to the ground pattern 22 on the back surface of the printed board 21 via the through hole 109, and the ground pattern 11 and the ground pattern 11 are connected. Input / output separation pattern 1
08 is set to the ground potential.

According to this structure, since the input / output separation pattern 108 set to the ground potential is interposed between the MSL 103 and the MSL 104, the MSL 103 and the MSL 103 are connected.
The spatial coupling between the SLs 104 is the input / output separation pattern 1
It will be blocked by 08. Therefore, as shown in FIG. 2, the electric field component E of the microwave radiated from the MSL 103 into the space is the input / output separation pattern 1 of the ground potential.
Since the MSLs 104 are affected by the MSLs 08, the MSLs 10 which have been conventionally coupled to each other by a strong electric field.
3 and the MSL 104 can be effectively cut off.

Therefore, according to such an embodiment, the MSL 10 in the configuration in which the input / output port 101, the MSL 103, the MSL 104, and the input / output port 102 are connected in series.
3 and MSL104 are used in a crank shape, and the connection point between the input / output port 101 and MSL103, MSL104
And the connection point between the I / O port 102 and the ground pattern 1
Capacitors 105 and 107 are formed between the
A capacitor 106 is provided at the connection point between 103 and MSL 104.
And the input / output separation pattern 108 is formed integrally with the ground pattern 11 and is set to the ground potential so that the spatial coupling between the MSL 103 and the MSL 104 is blocked by the ground potential 108. As a result, unnecessary signals, etc., which the filter tries to remove are not bypassed by the spatial coupling part and can be prevented from passing to the output side, and good electrical performance can be maintained. Since the filter pattern can be made smaller by making it rectangular, it can greatly contribute to downsizing of the device.

Next, FIG. 3 shows many MSLs to which FIG. 1 is applied.
FIG. 3 is a configuration diagram in the case of a pattern design using a capacitor and a capacitor. In the figure, five capacitors 304, four MSL 303, and a total of nine elements are used, and the MS in FIG.
The configuration of L is arranged continuously. By doing so, the occupied area can be remarkably reduced as compared with the conventional configuration in which elements are linearly arranged.
The present invention is not limited to the above-mentioned embodiments, and can be modified and implemented as appropriate without departing from the scope of the invention.

[0018]

According to the present invention, crank-shaped MSLs having a high impedance are connected in series to form a rectangular wave, and a ground potential is provided between the portions of each MSL arranged in parallel with each other. Since a set input / output separation pattern is interposed and a capacitor is formed between this input / output separation pattern and the connection point of each MSL, each MSL is connected.
Spatial coupling between each other can be blocked by the input / output separation pattern, and unwanted signals that the filter is trying to block can be prevented from being bypassed by the spatial coupling section and passing to the output side, thus achieving good electrical characteristics. Can be maintained. Also,
Since the pattern shape of the MSL has a rectangular wave shape, the effect of reducing the area occupied on the printed circuit board can be exerted as the number of elements increases, which can contribute to further downsizing of the device.

[Brief description of drawings]

FIG. 1 is a diagram showing a schematic configuration of an embodiment of the present invention.

FIG. 2 is a sectional view of a printed circuit board according to an embodiment.

FIG. 3 is an application diagram of an embodiment.

FIG. 4 is a diagram showing a schematic configuration of a conventional example.

FIG. 5 is a diagram showing a schematic configuration of a conventional example.

FIG. 6 is a sectional view of a conventional printed circuit board.

[Explanation of symbols]

11 ... Grand pattern, 101 ... Input / output port, 10
2 ... Input / output port, 103 ... Microstrip line (MSL), 104 ... Microstrip line (MS
L), 105 ... Capacitor, 106 ... Capacitor, 10
7 ... Capacitor, 108 ... Input / output separation pattern, 109
... through-hole, 21 ... substrate, 22 ... ground pattern
Input / output port, 302 ... Input / output port, 3
03 ... Microstrip line (MSL), 304 ...
Capacitor, 305 ... Input / output separation pattern, 306 ... Through hole.

Claims (1)

[Claims] 1. A high-impedance microstrip line formed in a rectangular wave shape by forming a crank shape and connecting a plurality of cranks, and interposed between these microstrip lines arranged in parallel with each other. A low-pass filter comprising an input / output separation pattern installed at a ground potential and a capacitor formed between the connection point of each microstrip line and the input / output separation pattern. filter.