KR20160077927A - Filter for harmonic rejection - Google Patents

Abstract

Provided is a filter for harmonic rejection. The filter includes: a band passing filter passing a frequency of a specific band; and a resonator for harmonic rejection prepared in the front end and the rear end of the band passing filter. The resonator for harmonic rejection is implemented by a stub.

Description

[0001] FILTER FOR HARMONIC REJECTION [0002]

The present invention relates to a filter used in the field of radio equipment, and more particularly to a filter having harmonic elimination characteristics.

A filter is a device for passing or removing frequencies of a specific band, and is an indispensable element for communication, signal generation, signal processing, and signal output. In the filtering process by the filter, a harmonic of a fundamental frequency is inevitably generated. The harmonic is called a high frequency, and is defined as a multiple frequency component of the fundamental frequency.

This harmonic affects the peak value of the fundamental frequency, which causes a lot of problems in signal processing. Therefore, the harmonic components must be removed.

If a band pass filter (Band Pass Filter, BPF) which passes only a specific frequency band to the output of the amplifier is designed, the second harmonic in nature, the frequency of the amplifier of the BPF (2 ^nd harmonic) and / or the third harmonic (3 since ^rd harmonic) of the removal is difficult, and both may be used the second harmonic (2 ^nd harmonic) and / or the third harmonic (3 ^rd harmonic) to remove the low pass filter (low pass filter, LPF).

That is, both the BPF and the LPF must be designed at the output stage of the amplifier. In this case, since two filters are designed, it is difficult to downsize the filter.

It is therefore an object of the present invention is the second harmonics (2 ^nd harmonic) and / or the third harmonic (3 ^rd harmonic) small by removal using a single BPF, and form the single BPF a three-dimensional structure in a substrate And a filter having a resonator for harmonic elimination.

According to another aspect of the present invention, there is provided a harmonic elimination filter including a band-pass filter for passing a frequency of a specific band and a harmonic removing resonator provided at a front end and a rear end of the band-pass filter, respectively. Here, the resonator for removing harmonics may be embodied as a stub.

According to another aspect of the present invention, there is provided a filter for removing harmonics, comprising: an input / output port; a filter for passing a signal of a specific frequency band within a frequency band of an input signal input through the input port, A first harmonic elimination resonator for connecting a transmission line connecting the input port and the band-pass filter to a ground, and a transmission line for connecting the band-pass filter and the output port to a ground And a second harmonic removing resonator. Each of the first and second harmonic elimination resonators includes a stub connected to the transmission line and a capacitor connected in series with the stub to ground the stub.

According to the invention, in addition to the cavity of the stub (stub) pattern the BPF, the second harmonics (2 ^nd harmonic) and / or the third harmonic (3 ^rd harmonic) the removal and, at the same time stub (stub) of a resonator of the pattern Dimensional structure in the substrate, it is possible to manufacture the BPF with a small size.

1 is an equivalent circuit diagram of a harmonic removal filter according to an embodiment of the present invention.
2 is an equivalent circuit diagram of a harmonic removal filter according to another embodiment of the present invention.
3 is an equivalent circuit diagram of a filter for removing harmonics according to another embodiment of the present invention.
FIG. 4 is a three-dimensional view of a three-dimensional structure of the harmonic elimination filter shown in FIG.
5A to 5E are layouts of respective layers for implementing the harmonic removal filter implemented with the three-dimensional structure shown in FIG.
FIG. 6 is a characteristic graph illustrating harmonic elimination characteristics between the conventional art and the present invention.

The harmonic filter for removing harmonics according to the present invention is applied to a laminate filter using LTCC (Low Temperature Co-Fired Ceramic) to be realized as a compact laminate filter.

In addition, the harmonic removal filter according to the present invention is to eliminate the second harmonic of the fundamental frequency (2 ^nd harmonic) and / or the third harmonic (3 ^rd harmonic) which is input from the front end, the cavity of the stub patterns are designed to add .

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an equivalent circuit diagram of a harmonic removal filter according to an embodiment of the present invention.

1, the filter 100 for removing harmonics according to an embodiment of the present invention passes a signal of a specific frequency band within a frequency band of an input signal input through an input port Pin, A band pass filter (BPF) 110 for outputting a signal of a frequency band through an output port Pout and a transmission line TL for connecting the input port Pin to the BPF 110 and a ground And a second harmonic elimination resonator 130 connected between the transmission line TL connecting the output port Pout and the BPF 110 and the ground.

The BPF 110 is implemented in a comb line structure and is configured to include an LC parallel resonator 112 and two resonators 114 and 116 connected by the LC parallel resonator 112 . The first resonator 114 includes an input node Nin electrically connected to the input port Pin and an open stub 114a and a short stub 114b connected in common to the input node Nin . Here, when the open stub 114a is opened to a length of 'x', the short stub 114b is configured to be grounded to a length of? / 4 - x '. The second resonator 116 includes an output node Nout electrically connected to the output port Pin and an open stub 116a and a short stub 116b commonly connected to the input node Nin . The open stub 116a and the short stub 116b are designed to have the same structure as the open stub 114a and the short stub 114b included in the first resonator 114, respectively.

The first and the second harmonic of the input signal input via the input port (Pin), each cavity (120, 130) for the second harmonic removal (2 ^nd harmonic) and / or the third harmonic (3 ^rd harmonic) to remove .

To this end, the first harmonic elimination resonator 120 is connected between the transmission line TL connecting the input port Pin and the BPF 110 and ground, and is grounded at a length of? / 4 And is implemented with a short stub 122. The second harmonic elimination resonator 130 is connected between the transmission line TL connecting the output port Pout and the BPF 110 and the ground and is connected to a short- Stub 132 as shown in FIG.

The first and second harmonic length 'λ' which is applied to each of the short stubs of removing the resonator (120, 130) is not the length that corresponds to the frequency used by the BPF (110) 2 ^nd harmonic or 3 ^rd It is the length corresponding to the harmonic. That is, when the 3 ^rd harmonic is removed and the filter passband of the BPF 110 is 5 GHz, '?' Applied to the first and second harmonic elimination resonators 120 and 130 is 15 GHz (5 GHz * 3 ).

If the 4 ^th harmonic and the 5 ^th harmonic are to be removed, 'λ' corresponding to 4 times and 5 times the filter pass band is applied to each of the shots 120 and 130 constituting the first and second harmonic elimination resonators 120 and 130 And is applied to the stubs 122 and 132.

2 is an equivalent circuit diagram of a harmonic removal filter according to another embodiment of the present invention.

2, the harmonic elimination filter 200 according to another embodiment of the present invention has the same configuration and function as the harmonic elimination filter 100 described with reference to FIG. 1, There is a difference between the first and second harmonic eliminating resonators 220 and 230 connected thereto. Therefore, redundant description will be omitted.

The first and second harmonic eliminating resonators 220 and 230 provided in the harmonic eliminating filter 200 according to another embodiment of the present invention are different from the harmonic eliminating resonators 120 and 130 of FIG. (222, 232), respectively. Here, each of the open stab (222, 232) is open to a length of, 'λ / 2' as shown in FIG. 2, the second harmonics (2 ^nd harmonic) and / or the third harmonic (3 ^rd harmonic) .

1, a length '?' Applied to each of the open stubs of the first and second harmonic elimination resonators 220 and 230 has a length corresponding to a frequency used in the BPF 110 Not 2 ^nd harmonic or 3 ^rd harmonic.

3 is an equivalent circuit diagram of a filter for removing harmonics according to another embodiment of the present invention.

3, the harmonic elimination filter 300 according to another embodiment of the present invention is constructed so that the length of the short stub constituting the harmonic elimination resonator described with reference to FIG. 1 is smaller than '? / 4' The first and second harmonic elimination resonators 320 and 330 coupled to the short stub and the capacitor are connected to both ends of the BPF 110.

More specifically, the first harmonic elimination resonator 320 is implemented with a stub 322 having one end connected to the transmission line TL and a capacitor 324 connecting the other end of the stub 322 and ground. When the open stubs 114a and 116a included in the resonators 114 and 116 in the BPF 110 are implemented with a length of 'x', the stub 322 has a length of '/ 4 - x' And is configured to be grounded via the capacitor 324.

The first harmonic elimination resonator 320 designed in the harmonic elimination filter 300 according to another embodiment of the present invention is similar to the first harmonic elimination resonator 320 shown in FIG. 1 except for the short stub 122 (? / 4 - x) shorter than the length (? / 4) of the short stub (? / 4).

The second harmonic elimination resonator 330 has the same configuration and function as the first harmonic elimination resonator 320 so that the second harmonic elimination resonator 330 also has the harmonic elimination resonator 120, (? / 4 - x) which is shorter than the length (? / 4) of the short stub constituting the short stub (b) and functions as a short stub grounded by the capacitor.

FIG. 4 is a three-dimensional diagram of the harmonic elimination filter shown in FIG. 3 in a three-dimensional structure. FIGS. 5A to 5E are diagrams for explaining the harmonic elimination filter implemented in the three- . For ease of understanding, FIG. 3 is also referenced.

Referring to FIG. 4, the harmonic elimination filter 300 shown in FIG. 3 can be miniaturized by being implemented as a laminated filter having a three-dimensional structure in the substrate 30 according to the LTCC process. Here, the substrate 30 has a multilayer structure, and the harmonic elimination filter 300 shown in FIG. 3 may be implemented with a plurality of patterns each patterned in five layers.

The first layer (31)

Referring to FIG. 5A, the first layer 31 is a top layer, and is provided with a ground plate formed entirely over the top layer.

The second layer (33)

Referring to FIG. 5B, the second layer 33 is a layer disposed under the top layer 31, and the second layer 31 is provided with a transmission layer 31 for connecting an input port Pin and an output port Pin, Line short-circuited by the short stubs 322 and 332 and the LC parallel resonator 112 constituting the first and second harmonic elimination resonators 320 and 330 formed on the transmission line TL, And the inductor 112a of the LC parallel resonator 112 are patterned. The two resonators 114 and 116 and the inductor 112a of the LC parallel resonator 112 are patterned.

Specifically, the transmission line TL has a first transmission line TL1, one end of which is connected to the input port Pin and extends in one direction, and a second transmission line TL1, which extends in the same line as the first transmission line TL1, And a second transmission line TL2 connected to the output port Pout.

The short stub 322 constituting the first harmonic elimination resonator 320 is implemented in the first pattern P1 so as to have a length of? / 4 - x in the vertical direction of the first transmission line pattern TL1, The short stub 332 constituting the second harmonic elimination resonator 330 is implemented in the second pattern P2 so as to have a length of? / 4 - x in the vertical direction of the second transmission line pattern TL2 .

The open stub 114a of the resonator 114 connected to the LC parallel resonator 112 is connected at one end to the other end of the first transmission line TL1 and in a direction perpendicular to the extending direction of the first transmission line TL1 And the short stub 114b of the resonator 114 is extended from the other end of the open stub 114a in the same direction as the extending direction of the open stub 114a, 4 pattern (P4).

The open stub 116a of the resonator 116 connected to the LC parallel resonator 112 is connected at one end to the other end of the second transmission line TL2 and is connected in the direction perpendicular to the extending direction of the first transmission line TL1 And the short stub 116b of the resonator 116 is formed to extend from the other end of the open stub 114a in the same direction as the extending direction of the open stub 116a, 6 pattern (P6).

The inductor 112a of the LC parallel resonator 112 is implemented by a seventh pattern P7 connecting the third pattern P3 and the fourth pattern P4. At this time, the length of the inductor 112a A length L2 of the seventh pattern P7 and a length L1 of a third pattern corresponding to a distance from the other end of the first transmission line TL1 to one end of the seventh pattern P7, And a sum (2 x L1 + L2) of a length L1 of a fifth pattern P5 corresponding to a distance from the other end of the second transmission line TL2 to one end of the seventh pattern P7, .

The third layer (35)

Referring to FIG. 5C, the eighth pattern P8 is patterned in the third layer 35 to form the capacitor 112b of the LC parallel resonator 112, and the eighth pattern P8 is patterned into the third pattern And extends in the horizontal direction between the third pattern P3 and the fifth pattern P5. The eighth pattern P8 serves as one electrode of the capacitor 112b.

The fourth layer (37)

5D, the fourth layer 37 overlaps with both ends of the eighth pattern P8 functioning as one electrode of the capacitor 112b, and the other electrode of the capacitor 112b is formed The ninth and tenth patterns P9 and P10 are patterned. The ninth pattern P9 is connected to the other end of the first transmission line TL1 by the third via V3 and the tenth pattern P10 is connected to the other end of the second transmission line TL2 by the fourth via V4. The first resonator 114 and the second resonator 116 may be connected by the LC parallel resonator 112 in connection with the other end of the second resonator TL2.

The fourth layer 37 is formed with a rectangular shape including a short stub 322 included in the first harmonic elimination resonator 320 and one electrode of the capacitor 324 connected by the fifth via V5, Which is formed by one electrode of the capacitor 334 connected by the sixth stub 322 and the sixth via V6 included in the eleventh pattern P11 of the second harmonic elimination resonator 330, The twelfth pattern P12 is formed.

The fifth layer (39)

5E, the fifth layer 39 is a bottom layer, and a ground plate is formed on the bottom layer 39. The ground plate formed on the bottom layer 39 is connected to the capacitor 324 and the capacitor 334, The other electrode is formed.

The ground plate formed on the bottom layer 39 is electrically connected to the end portions of the fourth pattern and the sixth patterns P4 and P6 by the first and second vias V1 and V2, The short stubs 114b and 116b of the resonators 114 and 116, which are configured in the resonator 114 and 116, are grounded.

3 can be realized in a three-dimensional structure by the first to twelfth patterns P1 to P12 patterned in five layers, thereby achieving miniaturization, in addition, it is possible to improve the release properties of the second harmonics (2 ^nd harmonic) and / or the third harmonic (3 ^rd harmonic) by the stub pattern harmonic resonator for removal of the designed to both ends of the BPF.

The harmonic elimination characteristics of the harmonic elimination filter implemented by the embodiment of FIGS. 1 to 5A to 5E are as follows. In the conventional filter, as shown in the characteristic graph of FIG. 6A, the 3 ^rd harmonic is removed at 15 GHz However, as can be seen from the characteristic graph of FIG. 6 (b) in all of the harmonic elimination filters implemented in the embodiments of FIGS. 1 to 3, it can be seen that the 3 ^rd harmonic removal characteristic is improved at 15 GHz.

Claims (6)

A band pass filter for passing a frequency in a specific band; And
And a harmonic removing resonator provided at the front end and the rear end of the band-pass filter, respectively,
Wherein the resonator for removing harmonics is a stub.
The stapler according to claim 1,
wherein the short stub is grounded at a length of? / 4.
The stapler according to claim 1,
wherein the open stub is opened at a length of? / 2.
Input and output ports;
A band pass filter for passing a signal of a specific frequency band within a frequency band of an input signal input through the input port and outputting the signal through a signal of a specific frequency band;
A first harmonic removing resonator for connecting a transmission line connecting the input port and the band-pass filter to a ground,
And a second harmonic elimination resonator for connecting a transmission line connecting the band-pass filter and the output port to a ground,
Wherein each of the first and second harmonic elimination resonators comprises:
A stub connected to the transmission line; And
And a capacitor connected in series with the stub for grounding the stub.
5. The apparatus of claim 4, wherein the band-
A first resonator including an open stub commonly connected to an input node connected to the input port and a short stub;
A second resonator including an open stub commonly connected to an output node connected to the output port and a short stub; And
And an LC parallel resonator connecting the first resonator and the second resonator.
The stamper according to claim 5, wherein the stub included in each of the first and second harmonic elimination resonators comprises:
Wherein when the open stub included in each of the first and second resonators is opened at a length of x, it functions as a short stub that is grounded at a length of? / 4 - x by the capacitor. filter.

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