KR950004803B1 - Diflexer - Google Patents

Abstract

The diplexer decreases weight and size, drops the price and increases the performance of diplexer using asymmetric diplexer. The diplexer consists of a corrugate hone(2), a square common waveguide(5), parallel receiving interfaces(7a, 7b), corrugate-type low-pass filters(8a, 8b), post-type low-pass filters(10a, 10b) and a high-pass filter(12).

Description

Circularly Polarized Diplexer Device for 4 / 6GHz Satellite Communication

1 is a perspective view of a 4/6 GHz diplexer of the present invention.

FIG. 2 is a front view of the rear AA ′ portion of FIG. 1.

* Explanation of symbols for main parts of the drawings

1: opening surface of horn 2: corrugated horn

3: matching waveguide 4: connecting part of matching part

5 forward common waveguide 6 stepped waveguide

7a, 7b: parallel receiving junction 8a, 8b: corrugated low pass filter

9a, 9b: Directional waveguide 10a, 10b: Post type low pass filter

11a, 11b: slope matching portion 12: high pass filter

13 orthogonal mode converter 14: receiver porous 3dB coupler

15: transmitting end porous 3dB coupler 16: transmitting left turning circular polarization terminal

17: Receive left turn circular polarization terminal 18: Transmit priority circular polarization terminal

19: reception priority circular polarization terminal

The present invention relates to an outline of a circular plate wave diplexer using a 3 dB porous coupler at a transmitting and receiving terminal.

Internationally, satellite communication of C-band frequency band consists of 4GHz band (3.7 ~ 4.2GHz) receiving frequency band and 6GHz band (5.925 ~ 6.425GHz) transmission frequency band. High capacity is required, and transmission and reception characteristics must be satisfied over a wide band. Moreover, in Korea, since the heavy rainfall is severe, 4/6 GHz communication is most used. On the other hand, the diplexer is a component used in a large caseegrain antenna related to a satellite communication earth station, and was initially only partially installed in a new caseegrain antenna feeder, but nowadays, most of antennas for satellite communication reuse frequency for efficient frequency operation. Since the method is used, it is applied to most feeding devices. Conventional C-band diplexers use symmetrical structures or symmetrical filter structures to minimize or possibly suppress higher-order effects. However, there are disadvantages of the conventional diplexer having such characteristics, which are large and heavy and expensive.

In order to solve the above disadvantages, in the present invention, an asymmetric diplexer method is used, and the corrugated low pass filter and the post type low pass filter part of the receiving end are in the form of a horizontal polarization terminal and a vertical polarization terminal. It is constructed similarly to the method, but the other parts constitute the diplexer system in a different structure.

Accordingly, the present invention was devised in view of the above characteristics, and developed an asymmetric diplexer using a porous 3dB coupler (transceiver terminal), thereby reducing the size and weight of the diplexer, lowering the manufacturing cost, and also improving performance. An object of the present invention is to invent an improved circularly polarized diplexer device.

The configuration of the present invention for achieving the above and the object is as follows.

The part connected to the corrogate horn 2 is a square common waveguide 5, and in the two parallel receiving junctions 7a and 7b coupled in parallel to the orthogonal planes of the waveguide, the signals of the reception band are horizontally and vertically directed. Separately, the corrugated low pass filter 8a, 8b has a waveguide of WR-229, a C-Band receiving waveguide comprising post type low pass filters 10a, 10b. An orthogonal mode converter 13 is connected in parallel to an end of the transmission high pass filter 12. The waveguide has a size of WR-137, which is a C-Band transmission waveguide. In the square waveguide, the size of the transmitter high pass filter 12 is configured in consideration of the cutoff frequency so that only the transmission band signal can pass, and the matching circuit of the stepped waveguide 6 has an insertion loss in the transmission / reception frequency band in consideration of impedance matching. Was minimized. Between the transmitting terminals 16 and 18 of the left turning circular polarization and the preferred turning circular polarization and the transmission band orthogonal mode converter 13, a transmitting end porous 3 dB coupler 15 is provided. A receiving end porous type 3dB coupler 14 is connected between the 17 and 19 and the slope matching portions 11a and 11b.

Features and functions of the present invention configured as described above are as follows.

The corrugated horn (2) with concentric grooves on the inside of the conical horn can suppress the generation of high order mode according to the excellent axial ratio and depth of groove processing due to the concentric accuracy, and can satisfy the characteristics of the frequency band used widely. The waveguide 3 achieves impedance matching of the horn and diplexer connection. The square common waveguide 5 in which transmission and reception frequencies exist together has superior polarization characteristics than a general circular waveguide, suppresses the generation of the higher-order mode TE ₂₀ , transmits the basic mode TE ₁₁ , TM ₁₁ , and has a stepped shape. The waveguide 6 reduces insertion loss in a small space. In addition, the post type low pass filters 10a and 10b at the receiving end improve the accuracy of the phases of the two reception band waveguides and increase the separation of reception for transmission.

When transmitted by an antenna, the linearly polarized transmission signal inputted through the transmission priority circular polarization terminal 18 and the transmission left linear member polarization terminal 16 is a horizontal waveguide with a ± 90 ° phase difference in the porous 3dB combiner 15. After being separated into horizontal and vertical polarization through the vertical waveguide and the vertical waveguide, it is met by the orthogonal mode converter 13. When the phase meets 0 ° and -90 °, it is a left-handed circular polarization. When the phase meets 0 ° and + 90 °, The signals are converted into polarized waves, which are radiated from the antenna via the horn 2 after passing through the high pass filter 12 and the square common waveguide 5. That is, the linearly polarized signal inputted through the transmission priority circular polarization terminal 18 is copied to the priority circular polarization from the antenna, and the linearly polarized signal input from the transmission left circular polarization terminal 16 is radiated to the left circular circular polarization. do.

On the other hand, the reception band signal of the left-circular circular polarization and the preferred-circular circular polarization introduced through the opening surface 1 of the horn passes through the square common waveguide 5 and includes two parallel reception junctions 7a and 7b configured in the vertical polarization and horizontal polarization directions. ), The circularly polarized signal is separated into vertical and horizontal linearly polarized signals. First, in the case of the reception left turning circular polarization, the vertically polarized signal at -90 ° phase is divided into parallel reception junction 7a, and the horizontal polarization at 0 ° phase is simultaneously divided into another parallel reception junction 7b. The polarization having a -90 ° phase passes through the parallel receiving junction 7a, the corrugated low pass filter 8a, the diverting waveguide 9a, the post type low pass filter 10a, and the gradient matching portion 11a. The polarized wave transmitted to the porous 3dB combiner 14 and having a 0 ° phase is transmitted to another parallel receiving junction 7b, a corrugated low pass filter 8b, a diverting waveguide 9b, and a post type low pass filter 10b. And then it is transmitted to the receiving end porous 3dB combiner 14 via the slope matching portion (11b). Here, the -90 ° polarized signal changes its phase by -90 ° again, and the phase becomes -180 ° and when it meets the 0 ° phase polarized signal, the signal disappears and the 0 ° phase polarized wave changes to -90 °. When it encounters the original -90 ° signal, it is output to the receiving left turn circular polarized terminal. In addition, a linear vertical polarization signal of + 90 ° in a first-order circular polarization signal having a phase difference of + 90 ° and 0 ° includes a parallel receiving junction 7a, a corrugated low pass filter 8a, and a switching waveguide 9a. , The post type low pass filter 10a and the gradient matching portion 11a are transmitted to the receiving end porous 3dB combiner 14, and the linear horizontal polarization signal of 0 ° is parallel received junction 7b, corrugated low pass. It is transmitted to the receiving end porous type 3dB combiner 14 via the pass filter 8b, the directional waveguide 9b, the post type low pass filter 10b and the gradient matching portion 11b. Here, when a signal with + 90 ° and two signals changed in phase from 0 ° to -90 ° meet, the signal disappears.When the signal with phase 0 ° meets with two signals changed in phase from 0 ° to 90 °, priority is received. It is output to the member type polarization terminal 19.

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

1 and 2 show the overall structure of the present invention, in which an antenna is attached to the opening face 1 of the corrugated horn 2, and the corrugated horn 2 is a circular waveguide. It is connected to the matching waveguide (3) to convert, which is connected to the common common waveguide (5) through the junction (4) of the matching portion, the forward common waveguide (5) is a 1.8 inch copper tube to the stepped waveguide (6) Continues 3.8 inches. The stepped waveguide 6 has a step of λg / 4 (λg: in-tube wavelength) to minimize the loss of the signal passing through it, which is divided into parallel receiving junctions 7a and 7b and the transmitter high pass filter 12. do. Two parallel receiving junctions 7a and 7b configured to be perpendicular to each other are divided into a horizontal linear polarization and a vertical linear polarization that are orthogonal to each other, and transmit the received circular polarizations, respectively. The receiver corrugated low pass filter 8a connected thereto is connected thereto. 8b) is asymmetrical to pass the low pass signal and to block the high pass signal. It is a form of 9 posts attached at intervals of λg / 4, and is connected to post type low pass filters 10a and 10b for improving the phase adjustment and separation as well as the band pass function. A 90 ° directional waveguide 9a, 9b is provided between the pass filter 8a, 8b and the post type low pass filter 10a, 10b to switch the magnetic field of the waveguide in the 90 ° direction, and the outer edge portion is 45 °. Cut to The post type low pass filter 10a, 10b is connected to the slope matching portions 11a, 11b, the slope matching portions 11a, 11b, the reception priority circular polarization terminal 19, and the reception left turn circular polarization terminal 17. Between the receiving end is composed of a porous 3dB coupler 14, which is designed by giving six holes and symmetrical staircase.

On the other hand, the transmitting end porous 3dB coupler 15 is configured between two terminals of the left-turning circular polarization multifunction 16 and the preferentially circularly polarized terminal 18 and two waveguides branched from the orthogonal mode converter 13, and the transmitting end The ball 3dB coupler 15 arranged the posts staircased on the top wall in left and right symmetry, and six holes were also made symmetrically between the stepped posts. The signals of the two terminals, which are phase-shifted and transmitted through the transmitter end porous 3dB combiner 15, are met by the orthogonal mode converter 13, converted into circular polarization, and transmitted to the high pass filter 12, which is a square waveguide.

As described above, according to the present invention, the device size and bandwidth are improved by using a symmetric porous coupler, and the structure of the entire diplexer can be simplified to reduce the number of devices as well as the size of the conventional structure. I also can reduce the weight much.

In addition, the present invention is not limited to the above embodiments, and various modifications may be made to the low pass filter and the porous 3dB coupler without departing from the gist of the present invention, for example, the receiver porous 3dB. The same effect can be obtained by using a phase shifter and a Magic-Tee instead of the coupler 14.

Claims (1)

A matching waveguide 3 is formed between the corrugated horn 2 and the connecting portion 4 of the matching portion, which is in turn connected to the connecting portion 4 of the matching portion, the common common waveguide 5 and the stepped waveguide 6, Here, it is divided into parallel receiving junctions 7a and 7b of the receiving end and the high pass filter 12 of the transmitting end, and in the case of the receiving end, two corrugated types in series to the two parallel receiving junctions 7a and 7b which are arranged in a vertical direction to each other. The low pass filters 8a and 8b are connected to each other and the post type low pass filters 10a and 10b are connected to the post type low pass filters 10a and 10b, respectively. After being connected to the receiving end porous 3dB combiner 14, respectively, it is formed in the form of being connected to the receiving priority first circular polarization terminal 19 and the receiving left turning circular polarization terminal 17, while in the case of the transmitting end, the stepped waveguide 6 In order the high pass filter (12) and orthogonal mode converter (13) And the orthogonal mode converter 13 is orthogonal to the vertical rectangular and horizontal rectangular waveguides WR-137 as branching points, and these are transmitted through the transmission end porous 3dB combiner 15 and the transmit priority circular polarization 18 and A circular polarized wave diplexer device for 4/6 GHz satellite communication, which is connected to a transmitting left circular circularly polarized terminal (16).