KR100922000B1 - Simultaneous interpretation system for bidirectional audio data communication based on binary cdma - Google Patents

Abstract

PURPOSE: A real-time interpretation system using bidirectional audio data communication based on the binary code division multiplexing access is provided to realize the real-time interpretation without restriction on places. CONSTITUTION: A real-time interpretation system using bidirectional audio data communication based on the binary code division multiplexing access comprises a performer terminal(10,100), a simultaneous interpreter terminal(20,100), and a participant terminal(30). The performer terminal transceives audio data and approves/release the right to speak. The simultaneous interpreter terminal receives the audio data from the performer terminal, simultaneously interprets the contents of the received audio data and then transmits the interpreted result to a corresponding channel terminal.

Description

Simultaneous interpretation system using two-way audio data communication based on binary code division multiple access {SIMULTANEOUS INTERPRETATION SYSTEM FOR BIDIRECTIONAL AUDIO DATA COMMUNICATION BASED ON BINARY CDMA}

The present invention relates to a simultaneous interpretation system using two-way audio data communication based on binary code division multiple access, and more particularly, to secure wireless communication between hosts, simultaneous interpreters, and participants through short-range wireless voice data transmission and reception based on binary code division multiple access. The present invention relates to a simultaneous interpretation system using two-way audio data communication based on binary code division multiple access that enables simultaneous simultaneous interpretation with good call quality.

In general, simultaneous interpretation is performed by interpreters, speakers, presenters, or presenters, in order to facilitate the communication of languages among people with different language systems in seminars, lectures, and exhibitions. To participants who listen in different languages.

Such simultaneous interpretation includes short-range simultaneous interpretation and long-range simultaneous interpretation. In the case of the short-range simultaneous interpretation, simultaneous interpreters are directly interpreted and transmitted in each language through a short-range communication system using a wired / wireless communication modulation method. In the case of simultaneous interpretation, the telephone is connected to the simultaneous interpreter by wired / wireless voice telephone using a separate wired / wireless communication system, and then the simultaneous interpreter is directly interpreted in each language.

However, most of the simultaneous interpretations, such as the short-range simultaneous interpretation or the long-range simultaneous interpretation, consist of one-way interpretations delivered from the facilitator to the simultaneous interpreter and the simultaneous interpreter to the participant. There is a problem that can not be bidirectional simultaneous interpretation because it is not possible to deliver to.

SUMMARY OF THE INVENTION An object of the present invention is to provide a bidirectional simultaneous interpretation system capable of simultaneously interpreting and receiving each other in both directions between a presenter, a simultaneous interpreter, and a participant.

Another object of the present invention is to provide a two-way simultaneous interpretation system that allows the presenter, simultaneous interpreter, participant to easily carry and interpret simultaneously regardless of the place.

In order to realize the above object, the present invention provides a facilitator terminal for transmitting and receiving audio data, and approving and releasing a voice;

Receives audio data from the host terminal, directly interprets the contents of the received audio data and transmits to the corresponding channel terminal, and simultaneously interprets the audio data of the approved voice when approving the right to speak from the corresponding channel terminal. A simultaneous interpreter terminal transmitting to the terminal and releasing the speaking right when the speaking is completed from the terminal of the corresponding channel;

A participant terminal receiving the audio data transmitted from the simultaneous interpreter, requesting and receiving the right to speak to the presenter; And

The presenter and the simultaneous interpreter, the simultaneous interpreter and the participant terminal is divided into different channels according to the languages of each country, and the different channel divisions are characterized by different time division multiple access.

The simultaneous interpreter and the participant terminal may be divided into different channels according to the use of different languages, and the different channel divisions may be operated in different frequency channels by setting different frequency offset values.

The time division multiple access is a binary code division multiple access to prevent crosstalk and interference between channels.

Therefore, according to the present invention, the presenter, the simultaneous interpreter, the participant, each carrying a terminal, the host and the simultaneous interpreter terminal, the simultaneous interpreter and the participant terminal is divided into different time division multiple access, between the simultaneous interpreter and the participant terminal By dividing the frequency offset values into different frequency channels according to the use of different languages, it is possible to provide smooth two-way simultaneous interpretation without confusion and interference between the host and the simultaneous interpreter terminal, the simultaneous interpreter and the participant terminal. do.

In addition, the present invention is easy to move the host, simultaneous interpreter, each participant to carry the terminal to provide an effect that can be conveniently received in both directions at any time, regardless of location.

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

1 is a hierarchical diagram of a bidirectional simultaneous interpretation system of the present invention, FIG. 2 is an entire block diagram of a terminal of the bidirectional simultaneous interpretation system of the present invention, FIG. 3 is one cycle configuration diagram of the bidirectional simultaneous interpretation system of the present invention, and FIG. 5 is a transmission payload frame diagram of each terminal of the bidirectional simultaneous interpretation system of the present invention, FIG. 5 is a transmission and payload frame diagram of each terminal of the bidirectional simultaneous interpretation system of the present invention, and FIG. FIG. 7 is a payload frame diagram of each terminal in the same channel. FIG. 7 is a payload frame diagram of each terminal in another channel when a right to speak in the bidirectional simultaneous interpretation system according to the present invention.

Bi-directional simultaneous interpretation system of the present invention, as shown in Figure 1, separated into a participant (10), one or more simultaneous interpreters 20, participants 30 listening to the simultaneous interpretation from the one or more simultaneous interpreters (20) The host 10, the simultaneous interpreter 20, and the participants 30 are each provided with a terminal 100.

The facilitator 10 transmits and receives the synchronization signal broadcast and audio data through the terminal 100, and approves and releases the right to speak.

The simultaneous interpreter 20 scans the synchronization signal of the coordinator 10, receives audio data from the coordinator 10 terminal, directly interprets the contents of the received audio data, and transmits the audio data to the corresponding channel terminal. When the speech is approved by the user, simultaneous interpretation of the audio data of the approved speech is transmitted to the other channel terminal and the corresponding channel terminal, and the speech is released when the speech is completed from the terminal of the corresponding channel.

The participant 30 scans the synchronization signal of the coordinator 10, receives the interpreted audio data from the simultaneous interpreter 20, and requests the right to speak.

As shown in FIG. 2, the terminal 100 includes a key input unit 110, a radio frequency module 120, a memory 130, the host 10, a simultaneous interpreter 20, and a participant 30. The wireless modem 140, the display unit 150, the audio codec 160 and the power supply unit 170.

The key input unit 110 has a matrix form and includes a power switch, a sound control switch, and a use mode selection switch.

The radio frequency module 120 transmits and receives audio data at a radio frequency between the facilitator 10, the simultaneous interpreter 20, and the participant 30, and the radio frequency module 120 receives a radio signal through an antenna. A receiving end for receiving, a transmitting end for converting the data signal into a radio signal to be transmitted to the outside, and the duplexer for separating the radio signal transmitted and received at the receiving end and the transmitting end.

The memory 130 is a read / write memory in which a control program necessary for the operation of the facilitator 10, the simultaneous interpreter 20, and the participant 30 terminal is stored.

The wireless modem 140 is divided into a channel of different time division multiple access between the host 10 and the simultaneous interpreter 20 terminal, the simultaneous interpreter 20 and the participant 30 terminal, and the simultaneous interpreter 20 and the participant. (30) The terminals are divided into different channels according to the use of different languages at the same time, and the different channels are configured by logically distinguishing frequency channels by setting different frequency offset values.

In the logical frequency channel division method, time division multiple access (TDMA) of transmitting and receiving data is coded into a multi-level signal of a code division multiple access method and then converted into a binary signal and then transmitted through a time division multiple access (TDMA) method. Binary code division multiple access (BINARY CDMA) is a transmission module.

The binary code division multiple access scheme is operated in a manner in which a network cycle of 256 ms is cyclically repeated to transmit and receive audio and control signals.

One network cycle consists of 16 cycles, and each cycle section is designed and implemented to include one control signal transmission frame and 12 audio data transmission / reception frames.

Here, one cycle has a time length of 256/16 = 16 ms as shown in FIG. 3, one control frame CF for transmitting and receiving control messages, and 12 (0-11) payloads for transmitting and receiving audio data. The frame PF consists of 13 frames.

As shown in FIG. 4, each user terminal is assigned a transmission (TX) frame in one cycle. The host terminal sets payload frames 0/1/6/7 to the transmission (TX) mode and simultaneously. The interpreter terminal assigns payload frames 2/3/8/9 to transmit (TX) mode, and the participant terminal assigns payload frames 4/5/10/11 to transmit (TX) mode.

In this case, when the terminal for each user transmits (TX), the remaining terminals and the like are switched to the receive (RX) mode or the idle state (IDLE) state at the same time.

The display unit 150 displays a channel and a link state controlled by the wireless modem 140, and consists of a liquid crystal element (LED).

The audio codec 160 compresses and outputs an input audio signal, or decodes and outputs a received audio data signal as an audio signal. The audio codec 160 includes a microphone (MIC) for inputting an audio signal; A speaker SP or an earphone EAR PHONE for receiving an audio signal is configured.

The power supply unit 170 supplies power for each of the presenter, the simultaneous interpreter, and the participant terminal, and the power supply unit 170 includes a battery and a constant voltage unit.

The present invention configured as described above is divided into a simultaneous interpreter 20 and a participant 30 listening to the corresponding language from one coordinator 10, the coordinator 10, the simultaneous interpreter 20, the participant 30 Each one is provided with one terminal (100).

The simultaneous interpreters 20 are divided into different channels for each language, and the simultaneous interpreters 20 of the different channels are provided with a plurality of participants 30.

Subsequently, when the presenter 10 applies power to the terminal 100 for progress and presentation, simultaneous interpreters 20 and a plurality of participants 30 of different channels for each language also power the terminal 100. When the host 10 broadcasts a synchronization signal through the terminal 100 and proceeds or announces through the microphone of the terminal 100, the progress and announcement voice is transmitted through an audio codec ( 160, as shown in FIG. 5 through the radio modem 140 and the radio frequency module 120, are transmitted to the simultaneous interpreter 20 of different channels for each language.

The simultaneous interpreter 20 of the different channels receives the progress and presentation of the presenter 10 through the radio frequency module 120, the wireless modem 140, the audio codec 160 and the speaker or earphone, respectively, the corresponding language. Simultaneous interpretation and the interpreted content is transmitted to the terminal 100 of the plurality of participants 30 through the microphone of the terminal 100, the audio codec 160, the wireless modem 140 and the radio frequency module 120, The plurality of participants 30 were simultaneously interpreted from the simultaneous interpreter 20 of different channels through the radio frequency module 120, the wireless modem 140, the audio codec 160 and the speaker or earphone of the terminal 100. Listen to the content.

At this time, simultaneous interpretation between the terminal 100 of the coordinator 10 and the terminal 100 of the participant 30 is a payload frame 0/1/6/7 which is a transmission (TX) frame by a preset offset value in one cycle. To transmit audio data.

The terminals 100 of the simultaneous interpreters 20 of the different channels receive 0/1/6/7 of the payload frame in the receive (RX) mode by a preset offset value of the terminal 100 of the coordinator 10. Set to receive audio data from the terminal 100 of the coordinator 10 and simultaneously interpret the contents of the received data in a corresponding language of each country to preset the terminal through the terminal 100 of the simultaneous interpreter 20 of the different channels. The offset value is used to transmit to the terminal 100 of each participant 30 using payload frames 2/3/8/9 in the transmission (TX) mode.

Here, the terminal 100 of each participant 30 receives the payload frame 2/3/8/9 by a preset offset value from the terminal 100 of the simultaneous interpreter 20 of different channels (RX). Mode is set to receive audio data from the simultaneous interpreters 20 of the different channels to listen to the contents of the simultaneous interpretation.

At this time, since the terminal 100 of each participant 30 cannot understand the speech or the announcement content from the terminal 100 of the coordinator 10, the respective participant 30 is payload frame 0/1/6. By setting / 7 to an idle mode, only the interpreted contents transmitted from the simultaneous interpreters 20 of different channels are received without receiving the contents transmitted from the terminal 100 of the coordinator 10.

In addition, since the simultaneous interpreter 20 and each participant 30 of two different channels have two payload frames allocated for transmission and reception, the time division channel cannot be implemented. Available, voice and music can be transmitted), so that the frequency is not overlapped with different offset values for each language channel of each country to receive the interpreted contents.

As described above, the terminal 100 of each participant 30 may simultaneously speak or announce contents from the host 100 of the host 10 through the terminal 100 of the simultaneous interpreter 20 for each channel. When the participant 30 of any one channel receives a request to speak to the coordinator 10 for inquiry during the reception, as illustrated in FIG. 6, the terminal 100 of the participant 30 of the one channel 30 Pressing a utterance request button through a key input unit transmits a utterance request message to the terminal 100 of the simultaneous interpreter 20 and the facilitator 10.

The terminal 100 of the simultaneous interpreter 20 and the coordinator 10 analyzes the content of the request message and determines whether to approve or reject the voice request, and generates a voice right approval or rejection message based on the approval or rejection of the voice. To the terminal 100.

The terminal 100 of the participant 30 maintains or changes the payload frame according to a voice approval or rejection message, and whether the terminals 100 of the simultaneous interpreter 20 belong to the same channel. Change the payload frame so that it can relay what is said if it belongs.

At this time, the terminals 100 of the simultaneous interpreters 20 of different channels also change or maintain the frame according to the right to approve or reject the message, and also receive the contents of the participant 30 in the same channel. The payload frame is changed and set to relay the content to the terminal 100.

Accordingly, a request for a speaking right is transmitted from the terminal 100 of the participant 30 belonging to the terminal 100 of the simultaneous interpreter 20 of the different channels to the terminal 100 of the coordinator 10 to the participant 30. Referring to FIG. 6, the terminal 100 of the participant 30 who has received the right to speak has a transmission (TX) mode according to a preset offset value. The payout frame 4/5/10/11 is used to transmit the utterance, and the terminal 100 of the simultaneous interpreter 20 and the other participant 30 of the simultaneous interpreter 20 who have received the right to speak are payload frame 4 /. 5/10/11 is changed to a reception (RX) mode to receive the contents of the speaking of the terminal 100 of the participant 30 who has received the speaking right.

In addition, the terminal 100 of the simultaneous interpreter 20 transmits the contents of the speech of the terminal 100 of the participant 30 who has received the right to speak by a preset offset value to transmit the frame 2/3/8 / 9 is transmitted to the terminal 100 of the coordinator 10, and at this time, the frequency offset of the payload frame 2/3/8/9 of the terminal 100 of the coordinator 10 is received (RX) mode. The terminal 100 of the coordinator 10 receives the contents of the speaking of the terminal 100 of the participant 30 simultaneously interpreted through the terminal 100 of the simultaneous interpreter 20.

Meanwhile, as shown in FIG. 7, in the different channels for which the right to speak is not requested, the simultaneous interpreter 20 of the channel for which the right to speak is requested by the terminal 100 of the simultaneous interpreter 20 of the different channels is simultaneously interpreted. In order to deliver the contents of the speech transmitted to the moderator 10 to the participants 30 of different channels who did not request the right to speak, the payload frame 2/3/8/9 is changed to the receive (RX) mode, and the contents of the speech are spoken. After receiving the simultaneous interpretation and transmit the payload frame 4/5/10/11 of the terminal 100 of the simultaneous interpreter 20 to inform the terminal 100 of each participant 30 (TX) mode Set to.

At this time, the terminal 100 of the participant 30 changes the payload frame 4/5/10/11 of the terminal 100 of the simultaneous interpreter 20 to the transmission (TX) mode, and thus the existing payload frame 2/3. Change the payload frame 4/5/10/11 to receive (RX) mode to receive what was received (RX) using / 8/9 as payload frame 4/5/10/11, Since the contents of the simultaneous interpretation of the simultaneous interpreter 20 of other channels are not understood, the payload frames 2/3/8/9 of the terminal 100 of the participant 30 are switched to the idle mode. .

Therefore, as the payload frame 4/5/10/11 of the terminal 100 of the simultaneous interpreter 20 is changed to the reception (RX) mode, the contents of the simultaneous interpretation of the simultaneous interpreter 20 of the other channel are different. The participant 30 of the channel is not only listened to, but also the participant 30 of the other channel listens to the coordinator 10 through the simultaneous interpreter 20 to the contents of the speech according to the request for the right to speak and the contents of the speech of the host 10. Will be.

1 is an overall block diagram of a terminal of the present invention bi-directional simultaneous interpretation system

2 is a hierarchical diagram of a bidirectional simultaneous interpretation system of the present invention.

3 is a cycle configuration diagram of the present invention bi-directional simultaneous interpretation system

Figure 4 is a transmission mode payload frame diagram of each terminal of the bidirectional simultaneous interpretation system of the present invention

5 is a transmission and reception payload frame diagram of each terminal of the bidirectional simultaneous interpretation system of the present invention.

6 is a transmission / reception payload frame diagram of each terminal in the same channel when requesting a right to speak in the bidirectional simultaneous interpretation system of the present invention;

7 is a payload frame diagram of each terminal in another channel upon request for a voice in the bidirectional simultaneous interpretation system of the present invention;

* Description of the symbols for the main parts of the drawings *

10; Facilitator 20; Simultaneous Interpreter

30; Participant 100; terminal

110; A key input unit 120; Radio frequency module

130; Memory 140; Wireless modem

150; Display unit 160; Audio codec

170; Power supply

Claims (5)

Host terminal for transmitting and receiving audio data, and approving and releasing the right to speak; Receives audio data from the presenter terminal, simultaneously interprets the contents of the received audio data and transmits the same to the corresponding channel terminal, and simultaneously interprets the audio data of the authorized right when approving the right to speak from the corresponding channel terminal. A simultaneous interpreter terminal transmitting to the channel terminal and releasing the speaking right when the speaking is completed from the terminal of the corresponding channel; A participant terminal receiving the audio data transmitted from the simultaneous interpreter, requesting and receiving the right to speak to the presenter; And The binary code of the presenter and the simultaneous interpreter, the simultaneous interpreter and the participant terminal is divided into different channels according to the languages of each country, and the different channel is divided into different time division multiple accesses to transmit and receive audio data in both directions. Simultaneous interpretation system using split multi-access based bidirectional audio data communication. The method of claim 1, The section between the simultaneous interpreter and the participant terminal may be divided into different channels according to the use of different languages at the same time, and the different channel divisions may be operated by different frequency channels by setting different frequency offset values. Simultaneous interpretation system using two-way audio data communication based on binary code division multiple access. The method of claim 1, The time division multiple access is a simultaneous interpretation system using binary code division multiple access based bidirectional audio data communication using binary code division multiple access to prevent crosstalk and interference between channels. The method of claim 3, wherein The binary code division multiple access method is a binary code division multiple access based bidirectional audio data communication including one control frame (CF) for transmission and reception of control messages and 12 (0 to 11) payload frames (PF) for transmission and reception of audio data. Simultaneous interpretation system using. The method of claim 3, wherein In the binary code division multiple access method, a payload frame 0/1/6/7 is allocated to a transmission mode in a host terminal, and a payload frame 2/3/8/9 is assigned to a transmission mode in a simultaneous interpreter terminal. Participant terminal assigns payload frame 4/5/10/11 to the transmission mode, and when each terminal transmits (TX), the remaining terminals switch to the receive (RX) or idle (IDLE) mode at the same time. Binary code division multiple access based simultaneous interpretation system using two-way audio data communication.

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