KR102325640B1 - Multi-mode communication apparatus - Google Patents

Abstract

The present invention provides a satellite RF transceiver for transmitting and receiving signals through a satellite communication network using a satellite antenna, a terrestrial RF transceiver for transmitting and receiving signals through a terrestrial communication network using a terrestrial antenna, and an audio signal by processing an input audio signal An audio processing unit that outputs through the input/output unit and signal-processes the audio input from the audio input/output unit, processes the signal input from the audio processing unit and transmits it to any one of the satellite RF transceiver and the terrestrial RF transceiver, and the satellite RF transceiver and A signal processing unit that processes a signal received from any one of the terrestrial RF transceivers and transmits it to an audio processing unit, a GNSS unit that receives a satellite signal and provides location information and time information, and location information and time information input from the GNSS unit to manage call processing by controlling timing with It characterized in that it comprises a control unit for performing communication through the terrestrial communication network or the satellite communication network.

Description

Multimode communication terminal {MULTI-MODE COMMUNICATION APPARATUS}

The present invention relates to a multi-mode communication terminal, and more particularly, to a multi-mode communication terminal that supports a terrestrial communication network and a satellite communication network with a single chip to perform voice and data communication through the terrestrial communication network and the satellite communication network, respectively. .

Satellite communication refers to a communication method that allows satellites launched into the sky outside the atmosphere to relay communication. This is possible and at the same time, it has the advantage of not being restricted by communication even in the event of a disaster.

A satellite communication system is largely composed of a satellite and a communication terminal, and the satellite located outside the atmosphere plays a role of connecting the satellite communication terminals located on the ground.

When transmitting a signal, the satellite communication terminal transmits a specific signal to the satellite, and when receiving a signal, serves to receive a specific signal transmitted from the satellite.

Meanwhile, a mobile communication terminal such as a smart phone using a general commercial network (2G, 3G, 4G) is widely distributed to the public and is used for personal use or corporate work.

However, in public institutions, for example, the Fire and Disaster Prevention Administration, the National Police Agency, the Railroad Administration, the Airport Corporation, and companies that require various communication services for business, the user needs both a satellite communication terminal and a mobile communication terminal according to the nature of the business. This can happen.

Accordingly, the user is equipped with both a satellite communication terminal and a mobile communication terminal as necessary, and uses a satellite communication terminal and a mobile communication terminal according to circumstances.

The background technology of the present invention is disclosed in 'Mobile terminal system for satellite communication' of Korean Patent Laid-Open Publication No. 10-2007-0000261 (January 02, 2007).

The present invention has been devised to solve the above problems, and an object of the present invention is to support a terrestrial communication network and a satellite communication network with a single chip to enable communication through any one of the terrestrial communication network and the satellite communication network. to provide a terminal.

Another object of the present invention is to perform communication using the terrestrial communication network within the coverage area of the terrestrial communication network and connect to the satellite communication network to perform communication when out of the coverage area of the terrestrial communication network, thereby continuously communicating regardless of whether the terrestrial communication network is available. It is to provide a multi-mode communication terminal capable of performing the

A multi-mode communication terminal according to an aspect of the present invention includes: a satellite RF transceiver for transmitting and receiving a signal through a satellite communication network using a satellite antenna; a terrestrial RF transceiver for transmitting and receiving signals through a terrestrial communication network using a terrestrial antenna; an audio processing unit for signal processing an input audio signal, outputting the signal through an audio input/output unit, and signal processing the audio inputted from the audio input/output unit; The signal input from the audio processing unit is signal-processed and transmitted to one of the satellite RF transceiver and the terrestrial RF transceiver, and the signal received from any one of the satellite RF transceiver and the terrestrial RF transceiver is processed a signal processing unit for transmitting the signal to the audio processing unit; a GNSS unit for receiving a satellite signal and providing location information and time information; and controlling the timing with the location information and time information input from the GNSS unit to manage call processing, and control the signal processing unit according to whether the signal processing unit processes a signal to perform satellite communication and whether a terrestrial communication network is available. It is characterized in that it comprises a control unit for performing communication through a terrestrial communication network or a satellite communication network through any one of the satellite RF transceiver and the terrestrial RF transceiver.

In the present invention, the control unit is characterized in that it determines whether or not the terrestrial communication network is available based on whether the terrestrial communication network is included in the area.

In the present invention, the controller determines whether the terrestrial communication network is usable based on whether the terrestrial communication network operates normally.

In the present invention, when the terrestrial communication network is not available, the control unit performs communication through the satellite communication network using the signal processing unit and the satellite RF transceiver.

In the present invention, the RF transceiver for the satellite converts the high frequency satellite signal received through the satellite antenna into a signal of an intermediate frequency by signal processing, and then converts it into an I/Q (In phase/Quadrature phase) signal which is a baseband digital signal, , a satellite RF receiver for inputting the converted I/Q signal to the signal processing unit; and a satellite RF transmitter that converts the I/Q signal input from the signal processor into an intermediate frequency, converts it into a high-frequency satellite signal, and transmits the converted I/Q signal to the satellite through the satellite antenna.

In the present invention, the terrestrial RF transceiver includes: a terrestrial RF transmitter that up-converts and amplifies the frequency of the signal received from the signal processing unit and transmits it through the terrestrial antenna; and a terrestrial RF receiver for low-noise amplification of a signal received through the terrestrial antenna, down-converting the frequency, and inputting the signal to the signal processing unit.

In the present invention, the signal processing unit for demodulating the signal input from the RF transceiver for the satellite and for modulating the signal input from the audio processing unit for the satellite signal processing unit; a terrestrial signal processor for demodulating a signal input from the terrestrial RF transceiver and modulating a signal input from the audio processor; a signal output unit for inputting a signal input from any one of the satellite signal processing unit and the terrestrial signal processing unit to the audio processing unit; and a signal input unit for inputting the signal input from the audio processing unit to one of the satellite signal processing unit and the terrestrial signal processing unit.

The present invention supports the terrestrial communication network and the satellite communication network with a single chip to perform voice and data communication through the terrestrial communication network and the satellite communication network, respectively.

In the present invention, communication is performed using the terrestrial communication network within the coverage of the terrestrial communication network, and communication is performed by accessing the satellite communication network when out of the coverage area of the terrestrial communication network. make it possible

1 is a block diagram of a multimode communication terminal according to an embodiment of the present invention.
2 is a block diagram of an RF transceiver for satellite according to an embodiment of the present invention.
3 is a block diagram of a terrestrial RF transceiver according to an embodiment of the present invention.
4 is a block diagram of a signal processing unit according to an embodiment of the present invention.

Hereinafter, a multi-mode communication terminal according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users and operators. Therefore, definitions of these terms should be made based on the content throughout this specification.

1 is a block diagram of a multimode communication terminal according to an embodiment of the present invention, FIG. 2 is a block diagram of a satellite RF transceiver according to an embodiment of the present invention, and FIG. 3 is an embodiment of the present invention is a block diagram of a terrestrial RF transceiver according to FIG. 4 is a block diagram of a signal processing unit according to an embodiment of the present invention.

1, the multimode communication terminal according to an embodiment of the present invention includes a satellite antenna 10, a satellite RF (Radio Frequency) transceiver 20, a terrestrial antenna 30, a terrestrial RF transceiver ( 40 ), a signal processing unit 50 , an audio processing unit 60 , an audio input/output unit 70 , a control unit 80 , a user interface unit 100 , and an application module unit 110 .

The satellite RF transceiver 20 transmits and receives a high-frequency satellite signal using the satellite antenna 10 . The satellite RF transceiver 20 includes a satellite RF transmitter 21 and a satellite RF receiver 22 as shown in FIG. 2 .

Here, the high-frequency satellite signal is a signal such as an L (L) band, S (S) band, Ku band, and Ka band transmitted from a geostationary orbit satellite, a medium orbit satellite, or a low orbit satellite, and is a voice signal. (Voice) It means a signal such as data, fax, and packet. In addition, the satellite antenna 10 is an antenna that can directly transmit and receive from a geostationary orbit satellite, a medium orbit satellite, and a low orbit satellite.

The satellite RF transmitter 21 converts the high-frequency satellite signal received from the satellite through the satellite antenna 10 into an intermediate frequency signal and then converts it into an I/Q (In phase/Quadrature phase) signal, which is a baseband digital signal, The converted I/Q signal is input to the signal processing unit 50 . That is, the RF transmitter 21 for the satellite converts the digital signal I signal and the Q signal into an intermediate frequency signal in the form of an analog signal, converts the intermediate frequency signal into a high frequency satellite signal, and then a power amplifier (PA) It amplifies the high-frequency satellite signal through Here, the frequency of the signal transmitted to the satellite by the RF transmitter 21 for the satellite is 1626.5 MHz to 1660.5 MHz.

The satellite RF receiver 22 converts an I/Q signal, which is a baseband digital signal, into an intermediate frequency, converts it into a high-frequency satellite signal, and transmits it to the satellite through the satellite antenna 10 . That is, the satellite RF receiver 22 amplifies the high-frequency satellite signal of a low power level received through the antenna using a Low Noise Amplifier (LNA) while minimizing noise, and uses an RF/IF converter (Radio Frequency/Intermediate Frequency Converter). (not shown) converts a high-frequency satellite signal into a signal of an intermediate frequency, and then converts the signal of the intermediate frequency into digital signals, I and Q signals. Here, the frequency of the high-frequency satellite signal received by the satellite RF receiver 22 from the satellite is 1525 MHz to 1559 MHz.

For reference, in the present embodiment, the RF transceiver 20 for satellites may use the L band as described above, but the technical scope of the present invention is not limited thereto, and other than the L band, such as S band, Ka band, or Ku band, etc. Band frequency signals can also be used.

As the satellite communication network, a satellite communication network conforming to communication standards such as GMR-1, GMR-2, and GMR-1 3G may be employed.

The terrestrial RF transceiver 40 communicates with other terminals through the terrestrial communication network using the terrestrial antenna 30 . In this case, the terrestrial communication network includes communication methods such as LTE (Long Term Evolution), CDMA (Code Division Multiple Access), GSM (Global System for Mobile communications), WiMAX (World Interoperability for Microwave Access), TDMA (Time Division Multiple Access), etc. includes all terrestrial networks consisting of

The terrestrial RF transceiver 40 includes a terrestrial RF transmitter 41 and a terrestrial RF receiver 42 as shown in FIG. 3 .

The terrestrial RF transmitter 41 up-converts and amplifies the frequency of the signal received from the signal processor 50 , and transmits it through the terrestrial antenna 30 .

The terrestrial RF receiver 42 low-noise amplifies the signal received through the terrestrial antenna, down-converts the frequency, and inputs it to the signal processor 50 .

The signal processing unit 50 processes a signal input from the audio processing unit 60 according to the control signal of the control unit 80 and transmits the signal to the satellite RF transceiver 20 or the terrestrial RF transceiver 40, and RF transceiver The signal received from the radio or ground RF transceiver 40 is signal-processed and transmitted to the audio processing unit 60 .

The signal processing unit 50 includes a satellite signal processing unit 51 , a terrestrial signal processing unit 52 , a signal input unit 53 , and a signal output unit 54 as shown in FIG. 4 .

The satellite signal processing unit 51 performs matched filtering on the I/Q signal input from the satellite RF receiver 22, and transmits data (voice data, text data, fax data, and multimedia data) to satisfy satellite communication standards. etc.) through modulation of I/Q signal, system reference timing and communication channel frequency maintenance, power control, interfacing with SIM (Subscriber Identity Module) card, and PCM (Pulse Code Modulation) data of compressed voice data perform processing.

In more detail, the satellite signal processing unit 51 performs matched filtering on the I/Q signal input from the satellite RF receiving unit 22 , while performing a modulation process to output the I/Q signal to the RF transmitting unit. In this case, as the modulation method, various digital modulation methods such as Quadrature Phase Shift Keying (QPSK), Compatible Phase Shift Keying (CQPSK), and Binary Phase Shift Keying (BPSK) may be employed. In addition, the satellite signal processing unit 51 performs a PLL (Phase Locked Loop) operation for maintaining a reference frequency required for system reference timing, high frequency conversion, and intermediate frequency conversion. Furthermore, the signal processing unit 51 for satellite interfaces information of the subscriber, such as a unique number stored in the SIM card, an account number, and a registered phone number.

The terrestrial signal processing unit 52 encodes and modulates a signal to be transmitted, and demodulates and decodes a received signal. The terrestrial signal processing unit 52 may include a modem (MODEM) and a codec (CODEC).

The signal output unit 54 inputs a signal input from any one of the satellite signal processing unit 51 and the terrestrial signal processing unit 52 to the audio processing unit 60 according to the control signal of the control unit 80 .

The signal input unit 53 inputs a signal input from the audio processing unit 60 according to the control signal of the control unit 80 to either the satellite signal processing unit 51 or the terrestrial signal processing unit 52 .

The audio processing unit 60 outputs an audio signal input from the signal processing unit 50 through the audio output unit 72 or processes the audio signal from the audio input unit 71 and inputs it to the signal processing unit 50 . That is, the audio processing unit 60 forms PCM data by sampling, quantizing, and coding the audio analog signal input through the audio input unit 71 , and decoding the PCM data input from the signal processing unit 50 to obtain an analog signal. After restoration to , output through the audio output unit 72 .

The audio input unit 71 converts the user's voice into an electrical signal and inputs it to the audio processing unit 60 . A microphone or the like may be employed as the audio input unit 71 .

The audio output unit 72 outputs an audio signal input from the audio processing unit 60 . A speaker or the like may be employed as the audio output unit 72 .

The GNSS (Global Positioning System) unit 90 receives a satellite signal from a satellite and inputs location information and time information to the control unit 80 . In this case, the location information and the time information serve as time synchronization.

Here, the GNSS unit 90 includes navigation satellites such as a Global Positioning System (GPS), a Global Navigation Satellite System (GLONASS) of Russia, a BaiDou Navigation Satellite System (BDS) of China, and Galileo of Europe. For reference, in this embodiment, GPS will be described as an example.

The user interface unit 100 provides a user interface such as receiving various control commands from the user and outputting various information. The user interface unit 100 includes an input unit 101 and a display unit 102 .

The input unit 101 receives various information including numbers and characters from the user, and receives commands for inputting various menus and functions.

The display unit 102 outputs not only information input through the input unit 101, but also various information according to operation performance. have.

Here, in the user interface unit 100, the input unit 101 and the display unit 102 may be provided separately, but may be implemented as a touch pad or the like.

The application module unit 110 is a module that provides additional functions in addition to calls using a terrestrial communication network or a satellite communication network. 112), etc. may be included and may be further changed in various other ways.

The control unit 80 controls the data transmitted and received through the satellite communication network and the terrestrial communication network to control the application module unit 110 , and includes a central processing unit 81 and an external interface unit 82 .

The external interface unit 82 interfaces with an external memory such as an external interface such as a universal serial bus, FireWire, Ethernet, universal asynchronous transmission/reception, and serial peripheral interface bus, an input/output device, an auxiliary storage device, a multimedia device, and the like.

The central processing unit 81 is capable of high-speed operation and data processing capable of supporting terrestrial and satellite communication to correspond to various communication standards. The central processing unit 81 demodulates the I/Q signal from the satellite signal processing unit 51 to perform channel decoding and message decoding, and a data format according to a protocol related to satellite communication. is formed and is output to the satellite signal processing unit 51 after channel coding. In addition, the central processing unit 81 receives a satellite signal from the satellite, provides position and time information to the signal processing unit 50, and divides the data into timeslots and transmits the GNSS for time division multiplexing (TDM). Timing is controlled with the precise location information and time information input from the unit 90 and call processing is managed. In addition, the central processing unit 81 controls the operation of various application module units 110 and external devices.

In addition, the central processing unit 81 performs data communication using a terrestrial communication network centering on the terrestrial signal processing unit 52 and the terrestrial RF transceiver 40, and the satellite signal processing unit 51 and the satellite RF transceiver unit Centering on (20), data communication using a satellite communication network is performed.

In particular, the central processing unit 81 controls the signal processing unit 50 according to whether the terrestrial communication network is available, for example, whether it is located within the terrestrial communication network area or whether the terrestrial communication network is operating normally, to control the satellite RF transceiver 20 ) and the terrestrial RF transceiver 40 through any one of the terrestrial communication network or the satellite communication network to perform data communication.

That is, the central processing unit 81 processes voice data communication using the terrestrial communication network within the area of the terrestrial communication network, and connects to the satellite communication network when out of the terrestrial communication network so that the voice data communication can be continued. In addition, the central processing unit 81 provides a user interface through the user interface unit 100 and provides various functions by controlling the application module unit 110 .

In more detail, the central processing unit 81 processes the audio signal input through the audio input unit 71 through the audio processing unit 60 in the area of the terrestrial communication network and then inputs it to the terrestrial signal processing unit 52 . Then, the central processing unit 81 controls the terrestrial signal processing unit 52 to perform the signal processing as described above, and transmits the signal through the terrestrial RF transceiver 40 . In addition, when the central processing unit 81 receives a signal received through the terrestrial antenna 30 through the terrestrial RF transceiver 40, the central processing unit 81 controls the terrestrial signal processing unit 52 to perform a signal processing process, and an audio processing unit ( 60), and then outputs the audio through the audio output unit 72.

In this process, when the terrestrial communication network is out of the area or the terrestrial communication network operates abnormally, the central processing unit 81 performs data communication using the satellite communication network. That is, the central processing unit 81 processes the audio signal input through the audio input unit 71 through the audio processing unit 60 and then inputs it to the satellite signal processing unit 51 . Then, the central processing unit 81 controls the satellite signal processing unit 51 to perform the signal processing process as described above, and transmits the signal through the satellite RF transceiver 20 . In addition, when the central processing unit 81 receives a signal received through the satellite antenna 10 through the satellite RF transceiver 20, it controls the satellite signal processing unit 51 to perform a signal processing process, and the audio processing unit 60 After performing an audio processing process, the audio is output through the audio output unit 72 .

Here, the signal processing unit 50, the audio processing unit 60, and the control unit 80 are manufactured as a single chip in the form of a SYSTEM ON CHIP (SOC). As described above, since the signal processing unit 50, the audio processing unit 60, and the control unit 80 are manufactured as a single chip, it is possible to provide both the terrestrial communication network and the satellite communication network in multi-mode in a single chip, thereby reducing the size of the product and development cost can be reduced.

As described above, the present embodiment supports the terrestrial communication network and the satellite communication network with a single chip to perform voice and data communication through the terrestrial communication network and the satellite communication network, respectively.

In addition, the present embodiment processes communication using the terrestrial communication network within the coverage area of the terrestrial communication network, and accesses the satellite communication network to process the communication when out of the coverage area of the terrestrial communication network, so that communication can be continuously performed.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary and those of ordinary skill in the art to which the art pertains are aware that various modifications and equivalent other embodiments are possible therefrom. will understand Accordingly, the true technical protection scope of the present invention should be defined by the following claims.

10: satellite antenna
20: RF transceiver for satellite
21: RF transmitter for satellite
22: RF receiver for satellite
30: terrestrial antenna
40: terrestrial RF transceiver
41: terrestrial RF transmitter
42: terrestrial RF receiver
50: signal processing unit
51: signal processing unit for satellite
52: terrestrial signal processing unit
53: signal input unit
54: signal output unit
60: audio processing unit
70: audio input/output unit
71: audio input unit
72: audio output unit
80: control unit
81: central processing unit
82: external interface unit
90: GNSS unit
100: user interface unit
101: input unit
102: display unit
110: application module unit
111: camera module
112: bluetooth module

Claims (7)

a satellite RF transceiver for transmitting and receiving signals through a satellite communication network using a satellite antenna;
a terrestrial RF transceiver for transmitting and receiving signals through a terrestrial communication network using a terrestrial antenna;
an audio processing unit for signal processing an input audio signal, outputting the signal through the audio input/output unit, and signal processing the audio inputted from the audio input/output unit;
Signals inputted from the audio processing unit are processed and transmitted to one of the satellite RF transceiver and the terrestrial RF transceiver, and the signal received from any one of the satellite RF transceiver and the terrestrial RF transceiver is processed a signal processing unit for transmitting the signal to the audio processing unit;
a GNSS unit for receiving satellite signals and providing location information and time information; and
The call processing is managed by controlling the timing with the location information and time information input from the GNSS unit, and the signal processing unit processes the signal to perform satellite communication and controls the signal processing unit according to whether a terrestrial communication network is available. A control unit for performing communication through a terrestrial communication network or a satellite communication network through any one of the satellite RF transceiver and the terrestrial RF transceiver;
wherein the control unit determines whether the terrestrial communication network is usable based on whether the terrestrial communication network is included within the area of the terrestrial communication network or whether the terrestrial communication network operates normally.
delete delete The multi-mode communication terminal of claim 1, wherein the control unit performs communication through the satellite communication network using the signal processing unit and the satellite RF transceiver if the terrestrial communication network is not available.
According to claim 1, wherein the RF transceiver for satellite
The high-frequency satellite signal received through the satellite antenna is signal-processed and converted into an intermediate frequency signal, then converted into a baseband digital signal I/Q (In phase/Quadrature phase) signal, and the converted I/Q signal is converted to the above-mentioned signal. RF transmitter for satellite input to the signal processing unit; and
and a satellite RF transmitter that converts the I/Q signal input from the signal processor into an intermediate frequency, converts it into a high-frequency satellite signal, and transmits the converted I/Q signal to the satellite through the satellite antenna.
The method of claim 1, wherein the terrestrial RF transceiver unit
a terrestrial RF transmitter that up-converts and amplifies the frequency of the signal input from the signal processor and transmits it through a terrestrial antenna; and
and a terrestrial RF receiver for low-noise amplification and frequency down-conversion of a signal received through the terrestrial antenna and input to the signal processing unit.
According to claim 1, wherein the signal processing unit
a satellite signal processing unit for demodulating a signal inputted from the satellite RF transceiver and modulating a signal inputted from the audio processing unit;
a terrestrial signal processor for demodulating a signal input from the terrestrial RF transceiver and modulating a signal input from the audio processor;
a signal output unit for inputting a signal input from one of the satellite signal processing unit and the terrestrial signal processing unit to the audio processing unit; and
and a signal input unit for inputting the signal input from the audio processing unit to either one of the satellite signal processing unit and the terrestrial signal processing unit.

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