KR101834074B1 - Method and system for satellite communication based on repeater - Google Patents

Abstract

The present invention relates to a repeater-based satellite communication method and system.
A repeater-based satellite communication method according to the present invention includes the steps of: a first repeater transmitting a first satellite communication band signal received from a satellite to a user equipment through a downlink; a second satellite communication band signal Wherein the repeater includes a low noise block down converter (LNB) and a remote unit (RU), and each of the LNB and the RU individually transmits a first satellite communication band signal and the second satellite communication band signal, 2 satellite communication band signals, respectively.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a repeater-based satellite communication method and system,

The present invention relates to a communication method and system, and more particularly, to a repeater-based satellite communication method and system.

The practical use of satellite communication has been introduced in international communication. The launch of the first communication satellite of INTELSAT was in April 1965, and this opened the era of satellite communication of the communication put on the stationary orbit. From that time, the satellites that replaced the role of wireless communication brokerage station or submarine telegraph were replaced by satellites, and clear sound quality and clear images were relayed throughout the globe, and the space age of communication was opened.

A mobile satellite system (MSS) can be the ultimate mobile cellular phone that can make instant calls with anyone anywhere on earth anywhere using low earth orbit (LEO). Communication in a satellite communication system can be utilized variously in a situation where an emergency or a cellular network does not operate in the area of mobile communication.

In other words, a satellite phone can be used as an emergency communication means in the event of a disaster of a major disaster (typhoon, earthquake, fire, etc.), and the collapse of the communication network of the wired / wireless. In the event of an emergency, a satellite mobile phone is also operating as a gas-producing production base as a major national facility that should prevent social, economic, and material losses. The necessity of satellite phone for disasters in neighboring countries is being reconsidered due to the existing 2011 earthquake in Japan and Fukushima nuclear power plant accident.

Demand for satellite communications is increasing in military, aviation, maritime and disaster relief companies. However, since there are many shaded areas where communication is impossible due to satellite communication, it is difficult to utilize them practically. Therefore, it is necessary to develop a satellite communication repeater capable of making calls anywhere in the service area where the antenna is installed, whether inside or outside the building.

Table 1 below shows domestic satellite phone service currently in use.

division Inmarsat Iridium Global Star Turaya Satellite orbit Geostationary track Low orbit Low orbit Geostationary track Satellite altitude 35,786 km 780 km 1,414 km 38,600 km Service start 82 years 98 94 years 97 Domestic service provider KT Arion Cyber Free Co., Ltd. AP satellite communication Indoor availability Impossible Impossible Impossible Impossible Initial investment cost
And maintenance costs Low plenty Low Low

In the current satellite communication system, communication can not be performed when the line of sight (LOS) is not secured. For example, in an indoor environment such as an in-building, there is an area where satellite communication is impossible and communication is impossible even in an outdoor area. In addition, propagation loss may occur depending on weather conditions (rain, fog, snow, etc.). In addition, implementation for high gain antennas may be difficult.

1 is a conceptual diagram showing a conventional satellite communication system. Referring to FIG. 1, it may be difficult to communicate between user terminals capable of satellite communication using only satellites. When the orbit of the satellite is about 36,000 km, a propagation loss of 190 dB may occur in the transmission of the satellite signal. Specifically, the intensity of the received electric field is insufficient (for example, -130 dBm) in the room, so that the signal transmitted to the user equipment is weak, so that the user equipment may not be able to communicate with the satellite. Also, even in the case of outdoor, the received electric field intensity is lower than -1000 dBm at some points, and satellite communication in the user equipment may not be possible.

KR 10-2005-7015008

An object of the present invention is to provide a repeater-based satellite communication method.

It is another object of the present invention to provide a system for performing a repeater-based satellite communication method.

It is still another object of the present invention to provide a method and apparatus for transmitting a first satellite communication band signal received from a satellite to a user equipment through a downlink, Wherein the repeater comprises a low noise block down converter (LNB) and a remote unit (RU), each of the LNBs and RUs individually receiving the first satellite communication band signal And performing a frequency conversion and amplification procedure on each of the second satellite communication band signals and the second satellite communication band signals.

According to an aspect of the present invention, the step of transferring the first satellite communication band signal received from the satellite to the user equipment through the downlink may include receiving the LNB from the satellite in the first satellite communication band Signal, the LNB down-converting and amplifying the first satellite communication band signal to a first intermediate frequency band signal and transmitting the amplified signal to the RU, and the RU amplifying the first intermediate frequency band signal And upconverting the first intermediate frequency band signal to the first satellite communication band signal; and transmitting the first satellite communication band signal to the user equipment.

According to another aspect of the present invention, the step of transmitting, by the relay device, the second satellite communication band signal received from the user equipment to the satellite via the uplink may include receiving, by the RU, Band signal; down-converting and amplifying the second satellite communication band signal to a second intermediate frequency band signal and transmitting the signal to the LNB; and transmitting the second intermediate frequency band signal to the LNB Amplifying and upconverting the second intermediate frequency band signal to the second satellite communication band signal; and transmitting the second satellite communication band signal to the satellite by the LNB.

According to another aspect of the present invention, the repeater limits signal transmission based on switching when the first satellite communication band signal and the second satellite communication band signal are oscillated, and the repeater transmits the signal through the uplink And may perform processing on the second satellite communication band signal received through the uplink based on the switching only when the power of the second satellite communication band signal transmitted is equal to or greater than a threshold value.

According to another aspect of the present invention, the repeater may further include a gain control unit that receives a gain of the second satellite communication band signal transmitted on the uplink by a value smaller by -5 dB than a gain of the first satellite communication band signal transmitted through the downlink .

It is another object of the present invention to provide a wireless communication system including a repeater, wherein the repeater transmits a first satellite communication band signal received from a satellite to a user equipment through a downlink, Wherein the repeater comprises a low noise block down converter (LNB) and a remote unit (RU), each of the LNBs and RUs individually receiving the first satellite communication band signal And performing a frequency conversion and amplification procedure on each of the first satellite communication band signals and the second satellite communication band signals.

According to one aspect of the present invention, the LNB receives the first satellite communication band signal from the satellite, downconverts the first satellite communication band signal to a first intermediate frequency band signal, amplifies and transmits the first satellite communication band signal to the RU Wherein the RU is configured to amplify the first intermediate frequency band signal, upconvert the first intermediate frequency band signal to the first satellite communication band signal, and transmit the first satellite communication band signal to the user equipment Can be implemented.

According to another aspect of the present invention, the RU receives the second satellite communication band signal from the user equipment, downconverts the second satellite communication band signal to a second intermediate frequency band signal, amplifies and transmits the second satellite communication band signal to the LNB Wherein the LNB is configured to amplify the second intermediate frequency band signal and upconvert the second intermediate frequency band signal to the second satellite communication band signal and to transmit the second satellite communication band signal to the satellite Can be implemented.

According to another aspect of the present invention, the repeater limits signal transmission based on switching when the first satellite communication band signal and the second satellite communication band signal are oscillated, and the repeater transmits the signal through the uplink And to perform processing for the second satellite communication band signal received on the uplink based on the switching only when the power of the second satellite communication band signal transmitted is equal to or greater than a threshold value.

According to another aspect of the present invention, the repeater sets a gain of the second satellite communication signal transmitted on the uplink to a value smaller by -5 dB than a gain of the first satellite communication signal transmitted on the downlink As shown in FIG.

The repeater-based satellite communication method and system according to the present invention ensures satellite communication coverage indoors and outdoors and prevents oscillation of the repeater included in the satellite communication system and also prevents reverse power from being automatically adjusted, Consumption can be reduced.

1 is a conceptual diagram showing a conventional satellite communication system.
2 and 3 are conceptual diagrams illustrating a satellite communication system according to an embodiment of the present invention.
4 to 6 are conceptual diagrams illustrating a repeater according to an embodiment of the present invention.
7 is a conceptual diagram illustrating a method for communicating with a user device based on satellite communication when a dangerous situation occurs according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood, however, that the embodiments described below are only for explanation of the embodiments of the present invention so that those skilled in the art can easily carry out the invention, It does not mean anything. In describing various embodiments of the present invention, the same reference numerals are used for components having the same technical characteristics.

A satellite-based communication method and system according to an embodiment of the present invention relates to a method for overcoming conventional limitations using a satellite repeater. In the case where a repeater for shading the indoor / outdoor satellite phone according to the exemplary embodiment of the present invention is used, it is possible to prevent the occurrence of an emergency call in the indoor / outdoor coverage based on the satellite communication repeater, A possible emergency communication system can be established.

2 and 3 are conceptual diagrams illustrating a satellite communication system according to an embodiment of the present invention.

2 and 3 illustrate a method for enabling satellite communication of a user equipment located indoors and outdoors by relaying a satellite signal through a repeater.

The repeater can be composed of a satellite antenna, a low noise block down converter (LNB), and a remote unit (RU). At this time, the RU (indoor / outdoor type) can incorporate a 20 dBm class amplifier. The LNB and the RU may be implemented in a separate form, and the RU may be implemented in the service target location to communicate with the user device.

For example, in the case of downlink (link from satellite to user equipment), the LNB may transmit a satellite communication frequency band signal (e.g., a signal of 1.5 GHz to 1.6 GHz band) received from a satellite via a receiving antenna to a first intermediate frequency band Signal to an RU after conversion to IF (Intermediate Frequency signal) (for example, a frequency band of 100 MHz or less). The LNB can be implemented in a stratosphere and atmospheric layer at a long distance from a geostationary orbit, approximately 36,000 Km away from the ground, The LNB can remove the noise of the received satellite signal propagation.

In addition, the LNB receives a second intermediate frequency band signal (for example, a frequency band of 100 MHz or more) converted and amplified by the RU in the case of an uplink (link from a user apparatus to a satellite) The signal can be amplified and converted to a satellite communication frequency band signal and transmitted to the satellite.

In case of the downlink, the RU may receive the first intermediate frequency band signal received from the LNB, amplify it, convert it into a satellite communication frequency band, and transmit it to the user equipment.

In case of the uplink, the RU may change the satellite communication frequency band signal received from the user equipment to a second intermediate frequency band signal, amplify it, and transmit the amplified signal to the LNB.

2, a method for providing an indoor-area telephone service based on a repeater 200 is disclosed in detail. Referring to FIG. 2, the repeater 200 receives the satellite communication band signal and can transmit the satellite signal to a user equipment located indoors through a final signal transmission terminal located in the room. The final signal transmission stage may be an RU. Specifically, the repeater 200 downconverts the satellite communication band signal in which the propagation loss occurs to a first intermediate frequency band signal based on the LNB, low-noise amplifies the signal, and transmits the signal to the RU. Conversion of these frequency bands reduces signal loss, and thick and expensive cables may not be used for signal transmission.

RU may be transmitted to the user equipment by upconverting the first intermediate frequency band signal back to the satellite communication frequency band signal. As described above, the RU may be separate from the LNB and located adjacent to the user equipment. In this way, the user equipment located within 30 m of the final signal propagation end in the room can receive the satellite signal and perform communication based on the satellite signal.

In the uplink, the user equipment may transmit the satellite communication band signal to the RU, and the RU may down-convert the satellite communication band signal to the second intermediate frequency band signal, amplify it, and transmit the amplified signal to the LNB. The LNB may amplify the second intermediate frequency band signal and upconvert it to a satellite communication band signal and transmit it to the satellite.

FIG. 3 illustrates a method of providing an outdoor satellite telephone service based on a repeater. Referring to FIG. 3, the repeater 250 may be installed in a building that is not a service target, and may receive a satellite signal and transmit the satellite signal to a user device located outside the room. The LNB and RU implemented in the repeater 250 may operate in the same manner as that described in FIG. 2

The repeater-based satellite communication method according to an embodiment of the present invention includes the steps of transmitting a first satellite communication band signal received from a satellite to a repeater 200 or 250 through a downlink, And transmitting the second satellite communication band signal received from the user equipment to the satellite via the uplink. In this case, the repeaters 200 and 250 include a low noise block down converter (LNB) and a remote unit (RU), and each of the LNB and the RU may separately receive the first satellite communication band signal and the second satellite communication band signal Frequency conversion and amplification procedures can be performed.

The step of transferring the first satellite communication band signal received from the satellites 200 and 250 to the user equipment via the downlink includes receiving the first satellite communication band signal from the satellite LNB, Converting the first intermediate frequency band signal to a first intermediate frequency band signal and transmitting the amplified first intermediate frequency band signal to a first intermediate frequency band signal and transmitting the amplified first intermediate frequency band signal to a first intermediate frequency band signal, Signal, and the RU may transmit the first satellite communication band signal to the user equipment.

The step of transmitting the second satellite communication band signal received by the repeater 200, 250 from the user equipment to the satellite via the uplink comprises the steps of the RU receiving the second satellite communication band signal from the user equipment, Converting the second satellite communication band signal to a second intermediate frequency band signal and transmitting the amplified second intermediate frequency band signal to the LNB; and amplifying the second intermediate frequency band signal to a second intermediate frequency band signal, , And the LNB may transmit the second satellite communication band signal to the satellite.

The repeaters 200 and 250 according to the embodiment of the present invention may restrict the transmission of signals based on switching when the first satellite communication band signal and the second satellite communication band signal are oscillated. The repeaters 200 and 250 perform processing on the second satellite communication band signal received on the uplink based on the switching only when the power of the second satellite communication band signal transmitted through the uplink is equal to or greater than the threshold value can do. In addition, the repeaters 200 and 250 can set the gain of the second satellite communication signal transmitted through the uplink to a value smaller by -5 dB than the gain of the first satellite communication signal transmitted through the downlink. A detailed description thereof will be described later.

4 to 6 are conceptual diagrams illustrating a repeater according to an embodiment of the present invention.

First, a repeater in which oscillation is prevented is disclosed in Fig.

Referring to FIG. 4, a satellite signal received through a satellite antenna may be transmitted to a final signal propagation end through a downlink (or forward) based on LNA and RU. At this time, the satellite signal may be oscillated. The repeater according to the embodiment of the present invention can prevent damage to the circuit due to the oscillated signal by keeping the first switch 310 in the OFF state when the set maximum output is exceeded. Conversely, when the set maximum output is not exceeded, the first switch 310 can be kept in the ON state.

Specifically, when the first switch 310 is turned off to prevent the oscillation, if there is a power on the DET (device execute trigger), the first switch 310 is turned on again . On the contrary, if there is no power in the DET, the first switch 310 can be switched to the OFF state since it is in the oscillating state.

In a similar manner, the second satellite communication band signal propagated through the user equipment to the final signal propagation path may be transmitted to the satellite antenna through the uplink (or reverse) based on the LNB and RU. At this time, the second satellite communication band signal may be oscillated. The repeater according to the embodiment of the present invention can prevent damage to the circuit due to the oscillated signal by keeping the second switch 320 in the OFF state when the set maximum output is exceeded. Conversely, when the set maximum output is not exceeded, the second switch 320 can be kept in the ON state.

Similarly, in order to prevent the oscillation, when the second switch 320 is switched to the off state and there is power to the DET, the second switch 320 can be switched to the ON state since it is not an oscillation. On the contrary, if there is no power in the DET, the second switch 320 can be switched to the OFF state since it is in the oscillating state.

In Fig. 5, a method for saving power of a repeater is disclosed.

Referring to FIG. 5, the repeater can restrict the operation in the reverse direction (uplink) considering the magnitude of the power received from the user equipment.

For example, when the size of the reverse received power of the repeater is equal to or less than a first threshold level (e.g., kTB + a) for a predetermined time (x time), the repeater maintains the second switch in the OFF state and is consumed for the reverse operation The power can be reduced.

In addition, when the size of the reverse received power of the repeater is equal to or greater than the second threshold level during the set time (y time), the repeater maintains the ON state of the second switch 420 and transmits the second satellite communication band signal It can be transmitted to the satellite via the antenna. In addition, in the repeater according to the embodiment of the present invention, the gain of the reverse (uplink) can be automatically adjusted to be 5 dB smaller than the gain of the forward (downlink).

Referring to FIG. 6, the repeater includes an LNB 500 and an RU 520.

The LNB 500 downconverts the satellite communication band signal received in the downlink to the first intermediate frequency band signal for transmission to the RU and transmits the second intermediate frequency band signal received in the uplink to the satellite through satellite communication And a frequency converter for up-converting the frequency band signal into a band signal. In addition, the LNB 500 may include an amplification unit for performing amplification on the frequency signal.

The MUX of the LNB 500 may multiplex global positioning system (GPS) information and received information to the RU 520. Conversely, the MUX of the LNB 500 may demultiplex the signal received from the RU and transmit the demultiplexed signal to the amplifying unit and the frequency converting unit.

The maximum gain of the LNB 500 may be 60 dB and the noise figure may be less than 6 dB. As described above, the LNB 500 can compensate for the propagation loss according to the distance between the satellite and the terminal.

Similarly, the RU 520 may also be configured to uplink the first intermediate frequency band signal received from the LNB to the user equipment in the downlink to a satellite communication frequency band, Band signal to a second intermediate frequency band signal. In addition, an amplification section for performing amplification on the frequency signal may be included. As described above, the RU may be implemented separately from the LNB and located closer to the user equipment.

The MUX of the RU 520 may demultiplex the GPS information and the received information to the RU 520. Conversely, the MUX of the RU 520 may multiplex the signal received from the RU and forward it to the LNB 500.

The indoor RU 520 and the outdoor RU 520 may have a maximum of 20 dBm in the downlink and a maximum of 20 dBm in the uplink.

7 is a conceptual diagram illustrating a method for communicating with a user device based on satellite communication when a dangerous situation occurs according to an embodiment of the present invention. In FIG. 7, a method of propagating a dangerous situation through a repeater is disclosed when communication is broken due to the inoperative cellular network.

Referring to FIG. 7, an alarm system can transmit a warning message to a user via a satellite, and the satellite can transmit a warning message to a user device via satellite communication.

The header of the message, such as a warning message, may include an indicator that directs transmission to the peripheral user device for a critical condition. Based on this indicator, the user device can deliver a warning message to the neighboring user device.

For example, the first user device 600 may receive a warning message through a relay according to an embodiment of the present invention. The first user device 600 may send a warning message to the neighboring user device. The first user equipment 600 may establish a network with the neighboring user equipment for the transmission of such a warning message.

The first user equipment 600 may determine whether the peripheral user equipment is a user equipment operable only on a cellular network or a user equipment operable on the basis of a satellite communication network. For example, a user equipment (hereinafter, a cellular user equipment 620) operable only on a cellular network is a user equipment that is capable of communicating based on a first data format in a first frequency band and a user equipment Hereinafter, the satellite communication user equipment 640) may be a user equipment capable of communicating on the second frequency band based on the second data format.

The first user device 600 may transmit the first scan message of the first format and the second scan message of the second format on a broadcast basis to search for peripheral user devices located nearby. The scan message of the first format may be transmitted to the cellular user device and the scan message of the second format may be transmitted to the satellite communications user device.

Upon receiving the first scan message, the cellular user equipment 620 may transmit the first scan response message to the first user device 600 in response to the first scan message. Similarly, the satellite communication user device 640 receiving the second scan message may transmit a second scan response message to the first user device 600 in response to the second scan message.

The first scan response message may include identification information and location information of the cellular user equipment 620 and identification and location information of the neighboring cellular device 630. Upon receiving the first scan message, the cellular user equipment 620 can acquire information about the neighboring cellular user equipment 630 through the search for the neighbor cellular user equipment 630, and then transmit the first scan response message.

The second scan response message may include identification and location information of the satellite communication user equipment 640 and identification and location information of the peripheral satellite communication device 650. Upon receiving the second scan message, the satellite communication user device 640 obtains information about the peripheral satellite communication user device 650 through the search for the peripheral satellite communication user device 650 and transmits a second scan response message .

The first user equipment 600 having received the first scan response message and the second scan response message can transmit a warning message based on the first scan response message and the second scan response message.

For example, when the first user equipment 600 receives both the first scan response message and the second scan response message, it can be known that both the cellular user equipment and the satellite communication user equipment exist in the vicinity. In this case, the first user device 600 may send a first alert message of a first format that can be received over the cellular network to the cellular user device 620 based on the broadcast transmission. The first user device 600 may also transmit a second alert message in a second format that is receivable over the satellite communications network to the satellite communications user device 640 based on the broadcast transmissions.

The transmission strength of the first alert message may be determined in consideration of the location of the cellular user equipment 620 included in the first scan response message and the location information of the neighboring cellular user equipment 630. [ The transmission strength of the second alert message may be determined in consideration of the location of the satellite communication user equipment 640 included in the second scan response message and the location information of the neighboring satellite communication user equipment 650. Through the determination of the transmission strength, the warning message can be transmitted to the surrounding cellular user equipment and the satellite communication user equipment while minimizing the power consumption of the first user equipment.

The first warning message may include the location information of the first user device 600 and may include a message requesting movement to a location adjacent to the first user device 600. [ The cellular user device 620 and the neighboring cellular user device 630 may receive the first warning message and be moved to the periphery of the first user device 600. [ The first user device 600 may be configured to receive a first user device 600 and a second user device 600 that have been received via subsequent satellite communications at a relatively low transmit power when the cellular user device 620 and the neighboring cellular user device have moved to the periphery of the first user device 600 at 630 Alert message to the cellular user device 620 and the neighboring cellular user device 630.

Likewise, the second alert message includes the location information of the first user device 600 and may include a message requesting movement to a location adjacent to the first user device 600. The satellite communication user device 640 and the peripheral satellite communication user device 650 may receive a second alert message and may be moved to the periphery of the first user device 600. [ The satellite communication user equipments 640 and 650, which have moved to the periphery of the first user equipment 600, may then receive the warning message directly through the repeater. Thus, the unnecessary power consumption required to transmit the warning message to the satellite communication user device can be reduced.

Such satellite-based communication methods may be implemented in an application or may be implemented in the form of program instructions that may be executed through various computer components and recorded in a computer-readable recording medium. The computer-readable recording medium may include program commands, data files, data structures, and the like, alone or in combination. The program instructions recorded on the computer-readable recording medium may be those specially designed and configured for the present invention and may be those known and used by those skilled in the computer software arts. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape, optical recording media such as CD-ROMs and DVDs, magneto-optical media such as floptical disks, media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those generated by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware device may be configured to operate as one or more software modules for performing the processing according to the present invention, and vice versa.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

200,250: repeater
310: first switch
320, 420: second switch
500: LNB
520: RU
600: first user device
620: cellular user device
630: neighboring cellular user device
640: Satellite communication user device
650: peripheral satellite communication user device

Claims (10)

And a repeater for transmitting the first satellite communication band signal received from the satellite to the user equipment through the downlink and transmitting the second satellite communication band signal received from the user equipment to the satellite through the uplink,
The repeater comprising:
A low noise block down converter (LNB) and a remote unit (RU), which are physically separated from each other, and which convert the intermediate frequency band signal into an intermediate frequency band signal, convert the intermediate frequency band signal into the satellite communication band signal, ≪ / RTI &
When the LNB receives the first satellite communication band signal from the satellite, the LNB down-converts the first satellite communication band signal to the first intermediate frequency band signal through the downlink and transmits the first satellite communication band signal to the RU, RU upconverts the first intermediate frequency band signal to the first satellite communication band signal and transmits it to the user equipment,
When the RU receives a second satellite communication band signal from the user equipment, the RU down-converts the second satellite communication band signal to a second intermediate frequency band signal on the uplink and transmits the second satellite communication band signal to the LNB, And the LNB up-converts the second intermediate frequency band signal to the second satellite communication band signal and transmits it to the satellite. The method according to claim 1,
Wherein the LNB and the RU are connected to each other through a wired or wireless connection. delete The method according to claim 1,
Wherein the gain of the second satellite communication band signal is smaller than the gain of the first satellite communication band signal. The method according to claim 1,
Wherein the first intermediate frequency band signal and the second intermediate frequency band signal are signals of different frequency bands. A user apparatus for performing satellite communication using a satellite communication band signal provided from a satellite; And
And a repeater for relaying the satellite communication band signal between the satellite and the user equipment,
The repeater comprising:
An LNB and an RU for down-converting the satellite communication band signal to an intermediate frequency band signal or up-converting the intermediate frequency band signal to the satellite communication band signal,
The RU is physically separated from the LNB and is disposed at a plurality of locations inside the building,
When the LNB receives a first satellite communication band signal from the satellite, the LNB down-converts the first satellite communication band signal to a first intermediate frequency band signal through a downlink and transmits the first satellite communication band signal to the RU, Converts the first intermediate frequency band signal to the first satellite communication band signal and transmits it to the user equipment,
When the RU receives a second satellite communication band signal from the user equipment, the RU down-converts the second satellite communication band signal to a second intermediate frequency band signal on the uplink and transmits the second satellite communication band signal to the LNB, And the LNB up-converts the second intermediate frequency band signal to the second satellite communication band signal to transmit to the satellite. delete delete delete delete

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