KR102437842B1 - Advanced block-up converter capable of miniaturization and weighting lightening - Google Patents

Abstract

Disclosed is a block-up converter of a novel structure capable of miniaturization and weight lightening. The block-up converter (BUC) comprises: a structure body formed of a metal material in which an inner space is prepared; a structure cover fixed to an upper part of the structure body with pieces and formed of a metal material; a printed circuit board positioned in the inner space of the structure body and mounted with elements required for converting an intermediate frequency signal (IF) to a high frequency signal (RF); and a common filter positioned in a lower portion of the printed circuit board, which is the inner space of the structure body, to eliminate unwanted waves.

Description

A block-up converter with a new structure capable of miniaturization and light weight

The present invention relates to a block-up converter (BUC), and specifically to a block-up converter (BUC) capable of miniaturization and weight reduction.

In general, a block-up converter (BUC) corresponds to a transmitter of a terrestrial terminal for satellite communication of a Ku-band of 12 GHz to 18 GHz, and such a block-up converter (BUC) is generally a parabolic shape directed toward a specific satellite. It is connected to an orthogonal-mode transducer facing the reflective plate of Since the size and characteristics of the block-up converter (BUC) are the most important factors in determining the performance of satellite communication, the block-up converter (BUC) is considered to be the most important module in the Ku-band satellite communication.

A conventional block-up converter (BUC) of a conventional conventional method as shown in FIG. 1a up-converts a low frequency signal of a 1 GHz to 2 GHz band into a signal of a 14 GHz band so as to be directly connected to a satellite to enable communication. It is a device that does As shown in FIG. 1A , the conventional block-up converter (BUC) includes a frequency up-converter, a local oscillator (path indicated in green), and a 14GHz band signal amplification unit (path indicated in red). The block-up converter (BUC) necessarily requires a bandpass filter (BPF) to remove the local oscillator signal and various unwanted waves, and in particular, a conventional block-up converter (BUC) as shown in FIGS. 1A and 1B . In this case, two stages of bandpass filters (BPF, F1 and F2) are used. The characteristics of each of the bandpass filters F1 and F2 are not very good, so even if two or more bandpass filters are used in multiple stages, the performance is not excellent, and these multistage bandpass filters F1 , F2) and other devices (IF AMP, LPF, Thermal Pad, SSPA Block, PLL, Power Divider, Multiplex), including amplifiers (IF AMP, DRA), when mounted on a printed circuit board weight and volume will get bigger

The conventional block-up converter (BUC) makes it difficult to reduce the size and weight of the transmitter by using the bandpass filter (BPF) in multiple stages. Therefore, a method for solving this problem is required in this technical field.

Republic of Korea Patent No. 10-1829121 (registered on Feb. 7, 2018)

December 2005, Journal of the Society of Electronic Engineering, Vol. 42 TE, No. 4 (Thesis 2005-42TE-4-11), "Ku-Band Cavity BPF Design"

The problem to be solved by the present invention is to reduce the size of the block-up converter (BUC) and to improve the performance of the transmitter by applying a conventional band pass filter to the transmitter in a new form, An object of the present invention is to provide a block-up converter of a new structure capable of miniaturization and light weight.

Block-UP converter according to an aspect of the present invention for solving the above problems, the structure body 110 formed of a metal material having an internal space, and the pieces on the upper portion of the structure body A structure cover 190 fixed to and formed of a metal material, and a printed circuit board 150 located in the inner space of the structure body and on which elements required for conversion from an intermediate frequency signal (IF) to a high frequency signal (RF) are mounted. , 160), and an internal space of the structure body, which is located under the printed circuit board and characterized in that it includes a cavity filter 120 for removing unwanted waves.

According to an embodiment, the structure body and the structure cover are formed of an aluminum material.

According to an embodiment, the block-up converter includes a mixer in which a local oscillation signal LO and the intermediate frequency signal IF are mixed, and the high frequency signal ( The cavity filter is located at the rear end of the mixer on the path to RF).

The present invention provides a block-up converter of a new structure in which a conventional band pass filter is applied to a transmitter in a new form, thereby enabling downsizing and weight reduction in configuring the block-up converter (BUC). has

1A and 1B are block diagrams of a conventional block-up converter (BUC) in a conventional manner;
2 is a block diagram of a block-up converter (BUC) according to the present invention;
3 is a block diagram illustrating an example of a cavity filter applied to a block-up converter (BUC) according to the present invention;
Figure 4 shows the characteristics of the bandpass filter used in the conventional block-up converter (BUC) of the conventional conventional method shown in Figure 1a,
5 is a block-up converter (BUC) according to the present invention showing the characteristics of the bandpass filter of the common filter applied to the filter,
6 is a diagram for explaining the structural features of a block-up converter (BUC) according to the present invention,
7 is a graph showing the spurious characteristic result in the block-up converter (BUC) of the conventional conventional method shown in FIG. 1A;
8 is a graph showing the spurious characteristic result in the block-up converter (BUC) according to the present invention;
9 is a table comparing characteristics of the conventional block-up converter (BUC) according to the present invention and the block-up converter (BUC) according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. It should be noted that the accompanying drawings and embodiments are simplified and illustrated for the purpose of helping those of ordinary skill in the art to understand the present invention.

2 is a block diagram of a block-up converter (BUC) according to the present invention, and FIG. 3 is a diagram showing an example of a cavity filter applied to the block-up converter (BUC) according to the present invention, Figure 4 shows the characteristics of the bandpass filter used in the conventional block-up converter (BUC) of the conventional conventional method shown in Figure 1a, Figure 5 is a block-up converter (BUC) according to the present invention applied to the cavity It shows the characteristics of the bandpass filter of the filter, Figure 6 is a block-up converter (BUC) according to the present invention is a diagram for explaining the structural features, Figure 7 is a block of the conventional conventional method shown in Figure 1a - It is a graph showing the spurious characteristic result in the up-converter (BUC), and FIG. 8 is a graph showing the spurious characteristic result in the block-up converter (BUC) according to the present invention, and FIG. 9 is a table comparing the characteristics of the conventional block-up converter (BUC) according to the present invention and the block-up converter (BUC) according to the present invention.

First, referring to FIG. 2 , the block-up converter (BUC) according to the present invention includes a frequency up-converter, a local oscillator (path indicated in green, LO Path), and a 14GHz band signal amplification unit (path indicated in red). , IF to RF Path). As mentioned above, a bandpass filter (BPF) is required to remove the local oscillator signal (LO) and various unwanted waves, and in the block-up converter (BUC) according to the present invention, in the 14GHz band signal amplification unit In this case, only one bandpass filter (BPF, F10) is used in the stage after the mixer (Mixer) where the local oscillation signal (LO) and the intermediate frequency signal (IF) are mixed. In particular, as one such bandpass filter, a cavity filter or a cavity bandpass filter is used.

Next, referring to FIG. 3, (a) is a top view of a cavity filter applied to a block-up converter (BUC) according to the present invention, (b) is a bottom view, (c) is (a) ) is a side cross-sectional view taken along line I-I. In the block-up converter (BUC) according to the present invention, by using this cavity type bandpass filter, it is possible to reduce the module size of the block-up converter (BUC) while maintaining the performance of the block-up converter (BUC). Specifically, as shown in FIG. 3 , the cavity filter includes a longitudinal groove 121 , a width direction groove 122 , and openings 123 . The longitudinal grooves 121 are formed to be elongated in the longitudinal direction at the top of the cavity filter, and the widthwise grooves 122 are formed in the width direction, which is a direction orthogonal to the longitudinal direction, and have the same depth as the longitudinal grooves 121 . is formed In addition, the openings 123 are vertically formed in communication with the longitudinal groove 121 to form a lower side. The openings 123 are formed so that both ends 121a and 121b of the longitudinal groove 121 are visible through the openings 123 , respectively. That is, as indicated by the line L1 and the line L2, both ends 121a and 121b of the longitudinal groove 121 are respectively positioned in the middle at the directly upper portion of each of the openings 123 .

4 and 5 together, the bandpass characteristics of the conventional block-up converter (BUC) in the band of 24 GHz to 34 GHz and the block-up converter (BUC) of the present invention can be compared. As shown in FIG. 5 , it can be seen that the block-up converter (BUC) of the present invention generally has excellent rejection performance of a local oscillation signal LO of 29 GHz or less.

Referring to Figure 6, the block-up converter (BUC) of the present invention, the structure body 110 in which an internal space is provided, the structure body 110, the structure cover 190 fixed to the upper portion of the body, the inside of the structure body The printed circuit boards 150 and 160 located in the space, and the internal space of the structure body 110 and a cavity filter 120 located below the printed circuit boards (150, 160). Reference numeral 130 is also a printed circuit board, on which elements required for the operation of the block-up converter (BUC) are mounted. A printed circuit board denoted by reference numeral 130 is disposed on the side of the cavity filter 120 . And, reference numerals 140, 170, and 180 are internal structures made of an aluminum material.

The structure body 110 is formed of a metal material, and accommodates the printed circuit boards 150 , 160 , 130 , the internal structures made of an aluminum material, and the cavity filter 120 therein.

The structure cover 190 is fixed with pieces on the upper portion of the structure body 110 and is formed of a metal material.

The printed circuit boards 150 and 160 are located in the inner space of the structure body 110 and elements required for conversion from the intermediate frequency signal IF to the high frequency signal RF are mounted. For example, amplifiers, mixers, etc. indicated by blocks in FIG. 2 may be mounted on the printed circuit boards 150 and 160 .

The cavity filter 120 is located in the inner space of the structure body 110 and is located below the printed circuit boards 150 and 160 to remove unnecessary waves.

The structure body 110 and the structure cover 190 from above are preferably formed of an aluminum material.

2 and 6 together, the block-up converter (BUC) of the present invention is a rear end of the mixer (Mixer) in which the local oscillation signal (LO) and the intermediate frequency signal (IF) are mixed, that is, the intermediate frequency signal (IF). ) to the high frequency signal RF, one cavity filter 120 is positioned at the rear end of the mixer.

Referring to FIGS. 7 and 8 together, in FIG. 7 showing the spurious characteristics in the conventional block-up converter (BUC), the spurious wave (indicated by a red oval) is -56.83 dB. , it can be seen that the spurious wave (indicated by a red oval) is -73.00 dB in FIG. 8 showing the result of the spurious characteristic in the block-up converter (BUC) according to the present invention. As such, it can be seen that the block-up converter (BUC) of the present invention has superior spurious wave characteristics compared to the conventional block-up converter (BUC).

Finally, referring to FIG. 9 , the antenna gain (Gain) and the saturation power (Psat) are substantially similar to the conventional block-up converter (BUC) and the block-up converter (BUC) of the present invention. In the case of the spurious wave characteristics, the characteristics of the block-up converter (BUC) of the present invention are improved by about 10% as 50 dBc and 55 dBc. In addition, in terms of size and weight, it can be seen that the block-up converter (BUC) of the present invention has a size of about 60% and a weight of about 57%, which is much smaller and lighter than in the prior art.

F1, F2: Conventional alumina bandpass filter
F10: Cavity Filter of the present invention

Claims (3)

A block-up converter comprising:
Structure body 110 formed of a metal material having an internal space;
a structure cover 190 fixed to the upper portion of the structure body with pieces and formed of a metal material;
a printed circuit board (150, 160) located in the inner space of the structure body and on which elements required for conversion from an intermediate frequency signal (IF) to a high frequency signal (RF) are mounted; and
It includes a; cavity filter 120 for removing unwanted waves located under the printed circuit board as well as the internal space of the structure body;
The cavity filter 120 is
A longitudinal groove elongated in the longitudinal direction on the upper portion, and a width direction groove formed in a width direction perpendicular to the longitudinal direction, wherein the width direction groove is connected to the longitudinal groove and formed to the same depth, and the length The block-up converter, characterized in that it includes openings formed vertically in communication with the directional groove and opened to the lower side, the openings being formed so that both ends of the longitudinal groove are visible through the openings.
The method according to claim 1,
The structure body and the structure cover are characterized in that formed of an aluminum material, block-up converter.
The method according to claim 1, The block-up converter,
A local oscillation signal (LO) and the intermediate frequency signal (IF) comprising a mixer (Mixer) is mixed,
The block-up converter, characterized in that the cavity filter is located at the rear end of the mixer on a path from the intermediate frequency signal (IF) to the high frequency signal (RF).

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