KR20150069957A - Heterogeneous radio voice interconnection system and method - Google Patents

Abstract

The present invention relates to a heterogeneous radio voice inter-operation system and a heterogeneous radio voice inter-operation method using the same, the invention comprising: N number of internal radios for performing radio communication with a plurality of commercial radios; and N number of IP communication management apparatuses connected corresponding to one internal radio among the N number of internal radios and assigned with respective IP addresses and performing a group information management function in association with a local server and for performing an IP-based call processing function and a real-time voice data transmission function with regard to members of a group to which the IP communication management apparatus belongs wherein the members are IP communication management apparatuses, and the group information managed by the group information management function includes an IP address of the member and other members.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio communication system,

The present invention relates to a heterogeneous transceiver voice interaction system and method enabling voice communication between disparate transceivers.

In the event of a disaster, a close coordination mechanism such as prompt dispatching and business cooperation through the sharing of information between field personnel dispatched to the disaster site and the field commander, very important. For this cooperation system, disaster communication is very important to exchange disaster situations.

Unlike a mobile phone or other communication terminal, a walkie-talkie does not have a troublesome operation before a call such as inputting a telephone number of the other party, and when a communication frequency channel is the same, a plurality of walkie-talkie can transmit a situation through voice to a walkie-talkie. For this reason, walkie talkies are being used as communication means to communicate and share information among individuals such as police, firefighting, emergency, forests, etc., and industrial sites.

However, for voice communication between radios, the same radio frequency and communication method should be used. However, a disaster management agency uses a dual radio having different radio frequency and communication method for various reasons such as purpose and purpose.

Currently used radios include analog and digital radios in the 100 MHz VHF band, analog and digital radios in the 400 MHz UHF band, and TRS (Trunked Radio System) radios in the 800 MHz band such as Terrestrial Trunked Radio (TETRA) and Integrated Digital Enhanced Network (IDEN) Very diverse as

Different types of radios are not capable of voice communication due to differences in the frequency band or / and communication method used. However, in the actual disaster scene, the police, the fire department, and the staffs dispatched from 119 are mixed, and each agency has different kinds of walkie-talkie.

For this reason, there is a demand for a technique for enabling voice communication in a heterogeneous radio transmission period.

SUMMARY OF THE INVENTION The present invention is directed to a system and method for heterogeneous transceiver voice communication that enables heterogeneous transceiver voice communications.

According to an aspect of the present invention, there is provided a heterogeneous transceiver voice interlocking system. The system comprises a plurality of disparate radios, N internal radios for performing radio communication, and an internal radio of one of the N internal radios, each having an independent IP address assigned thereto, And N IP communication managers that perform a group information management function in association with each other and perform an IP-based call processing function and a real-time voice data transmission function for the members of the group to which the terminal belongs, the member being an IP communication manager, The group information managed by the group information management function includes the IP address of itself and other members.

Each of the N IP communication managers includes a voice processing unit that converts an analog voice signal into a digital codec when it receives the analog voice signal and converts the analog voice signal into an analog voice signal upon receiving the digital voice codec, A group information management unit for performing the group information management function by accessing the local server when the power is turned on, a group information management unit for managing the IP-based call processing using the IP address of the group member to which the group member belongs, And an Ethernet voice communication unit performing the voice transmission function.

Each of the N internal radios being capable of radio-to-radio communication with at least one of the plurality of commercial radios; and a communication module connected to a signal input and a signal output of the communication module, Generates a COR (Carrier Operated Relay) signal of a common standard and provides the same to a connected IP communication manager, generates a Push To Talk (PTT) signal of a common standard and provides the same to the communication module, And an adapter for transmitting a voice signal during the IP communication management period.

The group information includes information indicating the IP address and the power on / off status of all the members of the group to which the user belongs, or a temporary group including IP address information on members that are in a power- Information.

According to another aspect of the present invention, there is provided a method for interworking with a radio transceiver. The method includes the steps of: (a) registering an IP address to a local server through an Internet network when the first IP communication manager is powered on, receiving and storing the group information of the first group to which the first IP communication manager belongs from the local server, ) Informing the first IP communication manager of the pressing of a PPT button when the first internal radio connected to the first IP communication manager grasps the pressing of the PPT button from the first commercial radio, (c) Performing IP-based call processing with a member of the group according to the group information of the first group to connect with the member; (d) when the first IP communication manager receives the first commercial radio from the first internal radio, (E) when the member receiving the voice transmits an internal radio to the connected member, the member transmits the voice to the connected member according to the Internet data transmission method. It comprises the step of transmitting the analog voice, the member is an IP communications manager, the group information includes an IP address of the own and the another member.

(B), the first internal radio watches the PPT button pressed to generate a COR (Carrier Operated Relay) signal of a common standard and notifies the first IP communication manager of the COR (Carrier Operated Relay) signal, and the step (e) An internal radio connected to the member transmits a PPT (Push To Talk) signal according to the COR signal received from the first IP communication manager, and then transmits the analog voice received from the first IP communication manager .

In the step (d), the first IP communication manager performs a call processing function based on a SIP (Session Initiation Protocol), and transmits voice based on the RTP (Real-Time Transport Protocol).

According to the embodiment of the present invention, it is possible to realize an organic disaster response collaboration system between related organizations by enabling voice communication of homogeneous and heterogeneous radio signals in a disaster scene. Further, according to the embodiment of the present invention, voice communication can be performed between homogeneous or heterogeneous radios outside the communication range of the radio.

1 is a block diagram and network diagram of a heterogeneous transceiver voice interworking system in accordance with an embodiment of the present invention.
2 is a block diagram of an internal radio according to an embodiment of the present invention.
3 is a block diagram of an IP communication manager according to an embodiment of the present invention.
4 is a block diagram of a local server according to an embodiment of the present invention.
5 is a network state diagram of radios to which a heterogeneous transceiver voice interworking method according to an embodiment of the present invention is applied.
6 is an overall flowchart of a heterogeneous transceiver voice interworking method according to an embodiment of the present invention.
7 is a diagram illustrating a group information sharing process according to an embodiment of the present invention.
FIG. 8 is a diagram illustrating a process of setting up a disparate IP-based call and a voice communication 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 so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Now, with reference to the drawings, a description will be given in detail of a heterogeneous transceiver voice interworking method according to an embodiment of the present invention.

FIG. 1 is a block diagram and network diagram of a heterogeneous transceiver voice interworking system according to an embodiment of the present invention, with four internal radio and IP communication managers. Of course, the internal radio and IP communication manager can be composed of two, but actually more than four will be used.

FIG. 1 is a block diagram and network diagram of a heterogeneous transceiver voice interworking system according to an embodiment of the present invention, with four internal radio and IP communication managers.

As shown in FIG. 1, a heterogeneous transceiver voice interlocking system 1000 according to an embodiment of the present invention includes four internal transceivers 100a to 100d and four IP communication managers 200a to 200d. The heterogeneous radio interlocking system 1000 configured as described above is connected to the local server 300 via the Internet and the local server 300 is managed by the user manager 400. [

The four internal radios 100a to 100d are configured to perform radio communication (e.g., VHF, UHF, IDEN, TETRA, etc.) with commercial radios 10 to 40 of different models (or models). Ideally, it will consist of N internal radios to allow radio communication with all types of radios. For example, if there are five types of commercial radios, N internal radios are composed of five internal radios capable of radio communication in correspondence with each of five different radios. That is, in correspondence with the commercial radios of the first to fifth models (or models), N internal radios are classified into five types such as a first internal radio corresponding to the first model and a second internal radio corresponding to the second model It consists of five corresponding internal radios.

Each of the four IP communication managers 200a to 200d is given an independent IP address. Hereinafter, the IP communication manager 200 having the reference numeral 200 is used when referring to one IP communication manager.

 Each of the IP communication managers 200a to 200d is connected to one of the internal radios 100a to 100d so that one of the internal radios 100a to 100d is connected to an Internet access device 300 ). Also, each of the IP communication managers 200a to 200d performs a group information management function, a call processing function, and an IP-based real-time voice data transmission function.

The group information management function manages the IP address to be connected, and the connection target is members in the group to which the group information belongs. The members are themselves and other IP communication managers, and IP communication devices located in the control room can be further added. The group information management function acquires and stores the temporary group information from the local server 300 when the power is on, and deletes the temporary group information stored when the power is off.

Here, the temporary group is a group of members that remain powered on in the group to which the temporary group belongs. Of course, the IP communication manager 200 can receive the group information, not the temporary group information. In this case, the IP communication manager 200 includes information on the current state (i.e., on / off state) of the members in addition to the IP address of the members in the group information do.

The call processing function grasps the IP addresses of the members included in the temporary group information, makes an internet call connection with other members through the Ethernet switch 300, and cancels the connected Internet call. At this time, call connection and termination are performed based on, for example, a session initiation protocol (SIP).

The real-time voice data transmission function converts the voice received from the internal radios 100a to 100d into data of the Internet data transmission protocol and transmits the voice to the connected object, or transmits the voice transmitted from the connected object to at least one of the internal radios 100a to 100d One).

Therefore, one radio can be used for voice communication with the same type or different type of radio by the plurality of the inner radios 100a to 100d and the IP communication managers 200a to 200d.

Meanwhile, the local server 300 stores a plurality of group information and temporary group information. The local server 300 performs IP address registration of the IP communication manager 200 and informs the IP communication manager 200, which has performed registration, Information or temporary group information. Here, the local server 300 generates temporary group information according to the IP address of the first member among the members of the group, and then adds a new member to the created temporary group information when the new member registers the IP address And performs temporary group information update. The updated temporary group information provides the IP address to the registered member.

The user manager 400 is a device that provides information (or commands) to the user to allow the user to make a group or change group information to the local server 300. The user manager 400 may be configured as a device independent of the local server 300, or may be integrated with the local server 300.

In the above-described embodiment, the configuration of the system 1000 for voice communication with the heterogeneous transceivers 10 to 40 is described based on IP, but the heterogeneous transceiver voice interworking system 1000 according to the embodiment of the present invention It can be applied to similar commercial radios. The IP-based voice communication for the same type commercial radio is a sub-technology as compared with the IP-based voice communication technology for the different radio described in the present invention, so that detailed description is omitted.

Hereinafter, an internal radio according to an embodiment of the present invention will be described in more detail with reference to FIG. 2 is a block diagram of an internal radio according to an embodiment of the present invention.

Each of the internal radios 100a to 100d includes a radio module 110 and an adapter 120. [

The radio module 110 is a communication module that enables radio communication with a corresponding commercial radio (at least one of 10 to 40) and can be replaced by a commercial radio (at least one of 10 to 40). If the radio module 110 is a commercial radio, it is a radio of the same product as the commercial radio used by the user, and is set to use the same communication channel.

The adapter 120 is located between one IP communication manager 200a to 200d and one wireless communication module 110 and transmits control signals and voice data between the IP communication manager and the radio module 110 Thereby enabling exchange of signals. At this time, the adapter 120 standardizes the difference between the hardware differences (for example, ports, etc.) of the respective radio modules 110 and the communicative manner, and exchanges signals with the IP communication manager 200, thereby transmitting all kinds of radios to the system 1000 ), And also plays a fundamental role in enabling the voice communication of the different radio time periods.

The adapter 120 is connected to the signal input terminal and the signal output terminal of the wireless module 110 by wire to receive or transmit the signal. The adapter 120 includes an amplifying unit 121, a voice signal transmitting unit 122, a voice signal detecting unit 123, and a PTT signal generating unit 124.

The amplifying unit 121 amplifies the voice signal received from the signal output terminal of the radio transmission module 110 or the voice signal received from the IP communication manager 200. The voice signal transmitting unit 122 transmits the voice signal received from the IP communication manager 200 to the IP communication manager 200 through the amplifying unit 121, 110).

 The voice signal sensing unit 123 senses the start of voice communication and transmits a COR (Carrier Operated Relay) signal for notifying the start of voice communication to the remote destination through the IP communication manager 200. At this time, the voice signal sensing unit 123 transmits a COR signal to be received when a voice signal is received together with a COR signal, but performs a function of generating and transmitting a COR signal when receiving a voice signal without the COR signal. Here, each radio uses a COR method and a VOX (Voice Operated Transmission) method as a voice communication start signal method for each model and model. The COR method is mainly used in some mobile radios, and the VOX method is used in some mobile radios or portable radios. The voice signal sensing unit 123 transmits the COR signal as it is when the signal of the COR system is inputted. However, when the signal of the VOX system is inputted, the voice signal detector 123 internally generates and transmits the COR signal.

The PTT signal generator 124 provides the PTT signal to the radio module 110 when the PTT signal is received from the IP communication manager 200 and when the PTT button is pressed in the commercial radio from the signal output terminal of the radio module 110 And provides the PTT signal to the IP communication manager 200.

Here, the adapter 120 first transmits the PTT signal to the IP communication manager 200, then transmits the voice signal output from the commercial radio, transmits the COR signal to the radio module 110 first, and then transmits the COR signal to the IP communication manager 200 To the commercial radio via the radio module 110.

On the other hand, since the adapter 120 is a device for connecting with commercial radios 10 to 40, it is not used when the system 100 according to the present invention is used in a situation room. In this case, the situation sharing system applied to the situation room connects to the microphone and earphone jack of the computer without using the adapter, and receives and transmits voice.

Hereinafter, an IP communication manager 200a to 200d according to an embodiment of the present invention will be described with reference to FIG. 3 is a block diagram of an IP communication manager according to an embodiment of the present invention.

The four IP communication managers 200a to 200d shown in FIG. 1 are different from each other only in the assigned IP address, but have the same internal configuration. Therefore, one IP communication manager 200 will be described below.

The IP communication manager 200 includes a voice processing unit 210, a signal processing unit 220, a group information management unit 230, a connection object DB 240 and an Ethernet voice communication unit 250.

Upon receiving the analog voice signal from the adapter 120, the voice processor 210 converts the analog voice signal into a digital codec. When the voice processor 210 receives digital voice data from the Ethernet voice communication unit 250, the voice processor 210 converts the analog voice signal into an analog voice signal, do. The signal processing unit 220 converts a control signal from the adapter 120 into a common data format. Here, the control signal is a PTT signal, a COR signal, a group change, a communication status inquiry signal, and the like.

The group information management unit 230 performs a group information management function in response to power-on or power-off of the IP communication manager 200. At this time, the group information management unit 230 accesses the local server 300 through the Ethernet voice communication unit 250 and registers its own IP address each time the power is turned on. When the group information is received from the local server 300 in response to the IP address registration, And temporarily stores the temporary group information in the connection target DB 240. [

The connection target DB 240 stores temporary group information (or group information) according to the management of the group information management unit 230.

The Ethernet voice communication unit 250 has a unique IP address and performs a call processing function and a voice transmission function through the Ethernet switch 300 using its own IP address. At this time, SIP-based call processing is performed, voice data is packetized using VoIP (Voice over IP) technology for voice transmission function, and voice packets are transmitted in real time based on Internet protocol. The Ethernet voice communication unit 250 supports Real-Time Transport Protocol (RTP) and Real Time Transport Control Protocol (RTCP) as an example of a protocol for a voice transmission function. The IP-based call processing function and the voice transmission function are common technologies, and a detailed description thereof will be omitted.

Referring to FIG. 4, a local server 300 interworking with a heterogeneous transceiver voice interlocking system according to an embodiment of the present invention will be described. 4 is a block diagram of a local server according to an embodiment of the present invention.

4, the local server 300 according to an exemplary embodiment of the present invention includes a group manager 410, a registration manager 420, and a group management DB 430. Of course, the local server 300 is provided with an interface (not shown) for connecting to the IP communication manager 200 and an interface (not shown) for connecting to the Internet network.

The group manager 410 is connected to the user manager 400 and performs new group assignment, group information deletion, group deletion, and group information change of the group according to user input, Allows information to be edited.

When the new commercial radio is connected to the system 1000, the registration management unit 420 receives the registration of the IP address from the IP communication manager 200 responsible for the IP-based voice communication of the newly added commercial radio, The IP communication manager 200 registers the power-on of the corresponding IP communication manager 200 in accordance with the registration and the group information or temporary group information of the group whose IP address of the IP communication manager 200 is a member to provide.

Here, the temporary group is created and managed by the registration management unit 420 as a group of members that remain powered on in the group to which the temporary group belongs. The group information provided to the IP communication manager 200 includes information on the current state (i.e., on / off state) of the members together with the IP address of the members.

The group management DB 430 stores group information and temporary group information of each group.

The state of the network between the heteroskedastic voice interlocking systems will now be described with reference to FIG. 5 is a network diagram of a heterogeneous transceiver voice interworking system according to an embodiment of the present invention.

5, the heterogeneous transceiver voice interworking system 1000 according to an embodiment of the present invention includes a heterogeneous transceiver voice interworking system 1000a according to an embodiment of the present invention located in another region, .

Accordingly, a commercial radio (at least one of 10 to 40) located in a first area (e.g., area A of Seoul) is capable of voice communication with a commercial radio (at least one of 10 to 40) located in the same area, Voice communication with commercial radio (at least one of 50 and 60) in the area is possible.

Here, the second area means the area outside the transmission range of the radio located in the first area, for example, area B in Seoul, area C in Seoul, area A in Daejeon, area B in Busan, and the like.

Hereinafter, a method of interworking with a different radio according to an embodiment of the present invention will be described with reference to FIGS. 6 to 8. FIG.

6 is an overall flowchart of a heterogeneous transceiver voice interworking method according to an embodiment of the present invention.

As shown in FIG. 6, group information of each group is registered (stored) in the local server 300 according to the input of the user provided from the user terminal 400 (S601).

When the IP communication manager 200 is powered on by the user, the IP communication manager 200 provides its IP address to the local server 300 for registration (S603), and the local server 300 transmits the IP address to the IP communication manager 200 (Or updates) the temporary group information reflecting the power-on state of the IP communication manager 200 and provides temporary group information to the IP communication manager 200 (S603). At this time, the local server 300 may provide the group information of the group having the IP communication manager 200 as a member to the IP communication manager 200 instead of the temporary group information.

In this state, when the user of the first transceiver 10 of the commercial transceiver 10 presses the PTT button of the first transceiver 10 (S604), the first internal transceiver 100a generates a COR signal informing the start of the call initiation, 1 IP communication manager 200a.

More specifically, the first radio module 110 of the first internal radio 100a detects the user by pressing the PTT button of the first transceiver 10 and notifies the adapter 120 of the first radio module 110, And then generates a COR signal and provides it to the first IP communication manager 200a. Of course, if the adapter 120 is designed such that it can not detect the PTT button press before inputting a voice signal, the adapter 120 recognizes that the call start is started when a voice signal is received from the first transceiver 10 through the first radio module 110 And generates a COR signal.

The first IP communication manager 200a converts the COR signal into a common data format, performs call processing according to the SIP protocol based on the IP address of each member according to the self-stored group information, connects the session with each member The COR signal is transmitted to the call destination side (S605).

Here, the object may be at least one of other IP communication managers connected to the Internet network in addition to the first IP communication manager 200a. Hereinafter, a fifth IP communication manager corresponding to the fifth radio module 100e (200e).

When the fifth IP communication manager 200e receives the COR signal from the first IP communication manager 200a, the fifth internal radio 100e informs the fifth internal radio 100e of the start of the voice start, And transmits the PTT signal to the transceiver 50.

On the other hand, when the first radio module 110 of the first internal radio 100a receives a voice signal from the first commercial transceiver 10, the voice signal is supplied to the adapter 120, Signal to the first IP communication manager 200a. The first IP communication manager 200a converts the received voice into a digital codec, packetizes it, and transmits it to the fifth IP communication manager 200e in real time through the established session (S606).

The fifth IP communication manager 200e converts the voice packet into an analog voice signal and transmits it to the fifth internal radio 100e. The adapter 120 of the fifth internal radio 100e transmits the voice Signal to the fifth commercial radio 50 through a fifth radio module (not shown) (S607).

Since the fifth commercial radio 50 has already received the PTT signal through step S605, the fifth commercial radio 50 recognizes the signal received through step S614 as a voice signal, performs voice signal processing, and outputs the voice signal to the speaker.

Meanwhile, if the user of the first commercial radio 10 inputting a voice while depressing the PTT button releases the depression of the PTT button, the first internal radio 10 recognizes the termination of the PPT button (S608) To the first IP communication manager 100a through the adapter 120 and the first IP communication manager 200a disconnects the session with the fifth IP communication manager 200e (S609).

As described above, in the process of transmitting the voice signal according to the start of communication of the first commercial radio 10 and the voice signal transmission to the fourth commercial radio 40, the fourth commercial radio 40 inputs the voice by pressing the PTT button The above-described procedure (S601 to S609) is repeated in the same manner even if the sender and the receiver are changed. By repeating this process, the user of the first commercial radio 10 and the user of the fifth commercial radio 50 can make voice communication even if they are different radio transceivers. In addition, voice communication between two different radios is possible even if the areas are different.

Hereinafter, with reference to FIG. 7, a process of sharing the group information of each IP communication manager according to the embodiment of the present invention will be described. FIG. 7 is a diagram illustrating a group information sharing process according to an embodiment of the present invention, in which the first IP communication manager 200 is taken as an example.

7, when the IP communication manager 200a is powered on by the user (S701), the IP communication manager 200a transmits an IP address registration request signal including its own IP address to the local server 300 (S702).

The local server 300 recognizes the IP address included in the IP address registration request signal and determines that the first IP communication manager 200a is on (S703). Then, the local server 300 identifies the group having the IP address of the first IP communication manager 200a as a group member from the information of each group stored in the group management DB 330 (S704) And temporary group information including the IP address of the mobile terminal 200a (S705). Here, if the group information is provided, information indicating that the IP address of the first IP communication manager 200 is in the active state (i.e., power-on state) is changed in the group information.

The local server 300 provides the generated temporary group information to the first IP communication manager 200a (S706), and provides the generated temporary group information to the other members in the temporary group information (S707).

The first IP communication manager 200a and other members also store the temporary group information generated from the local server 300 (S708).

Hereinafter, a voice communication process according to an embodiment of the present invention will be described in detail with reference to FIG. FIG. 8 is a diagram illustrating a call setup process and a voice communication process according to an embodiment of the present invention. Referring to FIG. 8, the first, second, and fifth IP communication managers 200a, 200b, and 200e are registered as temporary groups It is about the case.

Upon receiving the COR signal, the first IP communication manager 200a identifies the IP addresses of members in the group (S801), and performs SIP-based call setup with the IP communication administrators 200b and 200e in a unicast manner.

That is, the first IP communication manager 200a transmits an INVITE message including its IP address to the second IP communication manager 200b (S802a), and transmits the INVITE message including the IP address thereof to the second IP communication manager 200b in response to the INVITE message from the second IP communication manager 200b 100 Trying message is received (S803a).

The second IP communication manager 200b then transmits a 180 Ringing message to the first IP communication manager 200a indicating that it is sending a call waiting tone (804a), and then a message is received (generally, (YES in step S804), a 200 OK message is transmitted (step S805a).

Accordingly, the first IP communication manager 200a transmits an ACK message in response to the 200 OK message. Accordingly, the first IP communication manager 200a and the second IP communication manager 200b send an ACK message in response to the 200 OK message. A session is created (S807a).

When the first IP communication manager 200a connects a session with the second IP communication manager 100b, the first IP communication manager 200a performs the same process as the second IP communication manager 100b for session connection with the fifth IP communication manager 200e 5 IP communication manager 200e (S802b to S807b).

When a session is created between the first IP communication manager 200a and the second and fifth IP communication managers 200b and 200e as described above, the first IP communication manager 200a receives the session through the first internal radio 100a Converts the voice of the first commercial radiotelephone 10 into a digital voice signal, packets it, and transmits it to the second and fifth IP communication managers 200b and 200e in an RTP-based multicast manner (S808a and S808b) .

The first IP communication manager 200a receives the COR signal off from the first internal radio 100a when the user releases the PPT button and informs the second IP communication manager 200b of the termination of the session accordingly The SIP BYE message is transmitted (S809a), and the 200 OK message is received from the second IP communication manager 200b as a response message to terminate the session (S810a).

Also, the first IP communication manager 200a transmits a SIP BYE message informing the fifth IP communication manager 200e of the termination of the session (S809b), and transmits a 200 OK message from the fifth IP communication manager 200b to the response message And terminates the session (S810b).

The embodiments of the present invention described above are not only implemented by the apparatus and method but may be implemented through a program for realizing the function corresponding to the configuration of the embodiment of the present invention or a recording medium on which the program is recorded, The embodiments can be easily implemented by those skilled in the art from the description of the embodiments described above.

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, It belongs to the scope of right.

100a to 100d: internal radio 200a to 200d: IP communication manager
110: radio module 120: adapter
300: Ethernet switch 400: Local server
500: user manager 121: amplifying unit
122: audio signal transmission unit 123: audio signal detection unit
124: PTT signal generation unit 210:
220: signal processing unit 230: target IP management unit
250: Ethernet voice communication unit 410:
420: registration manager

Claims (8)

A plurality of disparate radios, N internal radios for performing radio communication, and
Wherein the radio base station is connected to one of the N internal radios in correspondence with the internal radio and is provided with an independent IP address and performs a group information management function in cooperation with a local server, And N IP communication managers performing a call processing function and a real time voice data transmission function,
Wherein the member is an IP communication manager, and the group information managed by the group information management function includes an IP address of itself and another member. The method of claim 1,
Each of the N IP communication managers,
A voice processor for converting the analog voice signal into a digital codec when it is received and converting it into an analog voice signal upon receiving the digital voice codec,
A signal processor for converting a control signal from the adapter into a common data format,
A group information management unit for accessing the local server when the power is turned on to perform the group information management function,
And an Ethernet voice communication unit having a unique IP address and performing the IP-based call processing function and the voice transmission function using an IP address of a group member to which the group member belongs. 3. The method of claim 2,
Each of the N internal radios being capable of radio-to-radio communication with at least one of the plurality of commercial radios,
(COR) signal of a common standard, which is connected to a signal input terminal and a signal output terminal of the communication module and is connected to one IP communication manager of the plurality of IP communication managers, And an adapter for generating a push to talk (PTT) signal of a standard and providing the voice signal to the communication module and transmitting the voice signal to the communication module during the IP communication management period. The method according to claim 1 or 3,
The group information includes information indicating an IP address and power on / off status of all members of the group to which the user belongs, temporary group information including IP address information on members that are in a power-on state among all members of the group to which the group information belongs, Wherein the voice communication system is a voice communication system. (a) registering an IP address to a local server through an Internet network when the first IP communication manager is powered on, receiving and storing the group information of the first group to which the first IP communication manager belongs from the local server,
(b) informing the first IP communication manager of the pressing of the PPT button when the first internal radio connected to the first IP communication manager grasps the pressing of the PPT button from the first commercial radio,
(c) the first IP communication manager performs an IP-based call processing function with a member of the group according to the group information of the first group to connect with the member,
(d) when the first IP communication manager receives a voice transmitted from the first commercial radio unit through the first commercial radio unit, transmitting the received voice to the connected member according to an Internet data transmission method, and
(e) transmitting the analog voice through the internal radio connected to the member receiving the voice,
Wherein the member is an IP communications manager, and wherein the group information includes an IP address of itself and another member. The method of claim 5,
In the step (b), the first internal radio watches the PPT button pressed to generate a COR (Carrier Operated Relay) signal of a common standard and informs the first IP communication manager,
The method of claim 1, wherein the step (e) comprises: after an internal radio connected to the member transmits a PPT (Push To Talk) signal according to the COR signal received from the first IP communication manager, To the mobile station. The method of claim 6,
Wherein the first IP communication manager performs a call processing function based on a session initiation protocol (SIP), and transmits voice based on the RTP (Real-Time Transport Protocol) Interworking method. The method according to claim 5 or 6,
The group information includes information indicating an IP address and power on / off status of all members of the group to which the user belongs, temporary group information including IP address information on members that are in a power-on state among all members of the group to which the group information belongs, And a second radio transceiver.

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