KR100333338B1 - Bluetooth interface module and method for transmission ofhi-quality audio data - Google Patents

Abstract

In the present invention, in transmitting high quality audio data between the master side Bluetooth interface module and the slave side Bluetooth interface module using the Bluetooth protocol, the payload of the data packet used for data transmission in the Bluetooth protocol is L_channel audio. Generating a high quality audio data into an audio data packet by dividing it into a data field and an R_channel audio data field, and inserting an access code including an address of a slave-side Bluetooth interface module into the audio data packet to transmit an RF packet. Formatting the data into a data; and loading a high quality audio data packet formatted with the RF transmission packet data on an arbitrary RF frequency generated according to a frequency hopping method and wirelessly transmitting it to a slave-side Bluetooth interface module. After receiving the high quality audio data packet transmitted from the master, the access code of the packet is analyzed to determine whether the packet is transmitted to itself, and the packet data is restored to decode the high quality audio data loaded on the payload. And converting the decoded high quality audio data into an analog audio signal and outputting the analog audio signal.

Description

BLUETOOTH INTERFACE MODULE AND METHOD FOR TRANSMISSION OFHI-QUALITY AUDIO DATA}

The present invention relates to short-range wireless communication using Bluetooth, and relates to a Bluetooth interface module and a high-quality audio data transmission method for transmitting high-quality audio data in a Bluetooth protocol.

In recent years, the wireless communications and computer industries have realized that low cost, low power wireless devices or wireless links are practically possible. The recent development of such wireless communication provides a basis for the elimination of complicated connection cables between office equipment and communication between devices that emphasizes the compactness and portability gradually.

Various studies have been conducted on this, and a professional code, namely 'Bluetooth' has been defined by Ericsson. The goal of Bluetooth is to provide mobility and convenience services for business users due to the small, short-range radio. Bluetooth has defined technical characteristics that optimize the usage model of portable computers and communication devices. Bluetooth is specifically designed to provide low cost, robustness, efficiency, high capacity, especially voice and data networking. Such Bluetooth is applicable to a computer system consisting of a personal computer, a keyboard, a mouse, a monitor, a printer, and the like.

However, the above-mentioned Bluetooth cannot be applied to the transmission of high-quality audio data such as MP3, because only Bluetooth supports sound quality of 64 kbps for the audio data.

That is, as shown in FIG. 1, which shows an audio data packet format supported by the conventional Bluetooth, a payload for audio data is allocated only 0 to 30 bytes. Since the capacity of the audio data that can be loaded in the audio is too limited, for example, transmission of high-quality audio data applicable to wireless speakers, wireless headphones, and the like cannot be realized.

As described above, there is a problem in that transmission of high-quality audio data cannot be realized because the capacity of audio data that can be carried in the payload of an audio packet supported by Bluetooth is too limited.

Accordingly, an object of the present invention is to provide a Bluetooth interface module and a high quality audio data transmission method for high quality audio data transmission.

1 is an audio packet format diagram of a conventional Bluetooth protocol;

2 is a DH5 data packet format diagram of a conventional Bluetooth protocol;

3 is a high quality audio data packet format diagram according to an embodiment of the present invention;

4 is a diagram illustrating timeslot lengths of high-quality audio data packets according to an exemplary embodiment of the present invention.

5 is a block diagram of a Bluetooth interface module according to an embodiment of the present invention.

The present invention for achieving the above object in the transmission of high-quality audio data using the Bluetooth protocol between the master-side Bluetooth interface module and the slave-side Bluetooth interface module, the data packet of the data used for data transmission in the Bluetooth protocol Dividing a payload into an L_channel audio data field and an R_channel audio data field to generate an audio data packet carrying the high-quality audio data, and an access code including an address of a slave-side Bluetooth interface module in the audio data packet. Inserting the data into an RF transmission packet data, and loading a high-quality audio data packet formatted with the RF transmission packet data on an arbitrary RF frequency generated according to a frequency hopping method, and performing a slave-side Bluetooth interface. And wirelessly transmitting the data to the payload module, and receiving the high quality audio data packet transmitted from the master side, analyzing the access code of the packet to determine whether the packet is transmitted to itself, and restoring the packet data to the payload. And decoding the received high quality audio data and converting the decoded high quality audio data into an analog audio signal and outputting the same.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description and the annexed drawings, numerous specific details are set forth in order to provide a thorough understanding of the present invention. It will be apparent to those skilled in the art that the present invention may be practiced without these specific details. And a detailed description of known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

Figure 2 illustrates the format of the DH5 packet for data transmission in the conventional Bluetooth protocol. Referring to FIG. 2, it can be seen that 0 to 339 bytes of data can be loaded in the payload of the DH5 packet for data transmission. Therefore, when the audio data is loaded on the DH5 packet and modulated by 4FSK (Frequency Shift Keying), the payload of the packet for the conventional voice of FIG. 1 can carry 0 to 9 bytes of data. It can be seen that a large amount of audio data can be transmitted.

3 illustrates a format of an audio data packet according to an embodiment of the present invention in which the DH5 data packet is converted for high quality audio data transmission. Referring to FIG. 3, as shown in FIG. 3, an audio data packet includes an access code, a header, and a payload.

Now, the components of the audio data packet will be described in detail. First, an access code is 64-bit sync word data representing a unit Bluetooth group identifier for allowing data to be transmitted only between communication devices in a unit Bluetooth group. And four bits of preamble data and trailer data for protecting the syncword data. The head includes three bits of AM_Addr (Active member address) data representing address information of slaves to which the audio data in the unit Bluetooth group is to be transmitted, four bits of type data for determining a packet type, and flow control. It consists of one bit of Flow data, one bit of ARQ and SEQN data representing retransmission and sequence numbers, and eight bits of HEC (Head error correction) data for checking errors of header information. The payload divides the payload of the existing DH5 packet shown in FIG. 2 into L_channel and R_channel to distinguish between L_channel audio data and R_channel audio data. In each of the L_channel and R_channel fields, 4 bits of sample bit data representing the number of sampled bits, 10 bits of sample interval data representing the time interval of the sample bits, and It consists of 10-bit length data representing the effective length and a data field of 2781 bits carrying actual L_channel or R_channel audio data. The RF packet shows the length of an access code, a header and a payload when modulated with 4FSK, and FIG. 4 shows the length of time slots according to time of the high quality audio data packet of FIG.

FIG. 5 is a block diagram of a Bluetooth interface module that enables transmission of a high quality audio data packet configured as shown in FIG. 3 using a Bluetooth protocol according to an embodiment of the present invention. Referring to FIG. 2, the Bluetooth interface module 500 divides the payload of the DH5 packet for data into an L_channel audio data field and an R_channel audio data field into audio data packets carrying the high quality audio data. An RF (Radio Frequency) unit for wirelessly transmitting and receiving the packet generation unit 508 to generate and the high-quality audio data packet generated from the packet generation unit 508 using a Bluetooth protocol between the master and the slave. 502, a packet recovery unit 506 for recovering high quality audio data from the payload of the audio data packet received from the RF unit 502, and audio data restored from the packet recovery unit 506 The audio codec unit 510 converts an analog audio signal and outputs the same, and controls the audio codec unit 510 to receive audio data. Is sikimyeo outputs audio data to an analog audio signal, and encoding the audio signal to be input at the time of audio data sent to the high-quality audio data, it consists of a link controller 512 to output to the packet generating unit 508. The

Referring to the operation of the detailed block belonging to each component, the clock recovery unit (514) to recover the clock to recognize the data received from the RF unit (502). Since the clock is not included in the audio data received from the master side, the clock recovery unit 514 must recover the clock from the received data. The correlator 516 examines an access code of the received audio data packet to determine whether the received audio data packet is a data packet that it should receive. That is, when the access code analysis result includes itself in the slave address where the audio data is to be received, the audio data is received and applied to the FEC decoding unit (Forward Error correction) 518. The FEC decoding unit 518 performs forward error correction on the received audio data packet and applies it to the de-whitening unit 520. The de-whitening unit 520 restores the whitened data to its original state during digital transmission. That is, during transmission, the whitening unit 540 performs whitening coding so that the digital sum value of the data approximates '0', which means to restore the original data. The HEC checker 522 checks an error of a header portion of the audio data packet. The header decompressor 526 extracts the header information of the audio data packet and outputs the header information to the link control unit 512. The CRC checker 524 checks a payload error by checking a cyclic redundancy check (CRC) of the payload. The payload decompressor 528 extracts payload information of the audio data packet and transmits the payload information to the audio codec 552. The audio codec 552 codes audio data to be transmitted by using a μ-law, an A-law, a log PCM, a CVSD scheme, and the like, and decodes the received audio data as it is. The D / A and A / D units 548 digitally output analog audio data input for transmission and output digital audio data decoded and applied from the audio codec 552 by a speaker (not shown). To the outside through).

The payload composer 532 configures audio data coded and input from the audio codec 552 into a payload data format. A header composer 534 configures header information of the input audio data in a header data format. The HEC generator 538 and the CRC generator 536 generate HEC data and CRC data for checking errors of the header and payload. The whitening unit 540 codes the audio data packet such that the digital sum value approximates '0', and the FEC encoder 542 performs forward error correction coding on the audio data packet. An access code & packet generator 544 inserts an access code into the audio data packet to generate a final audio data packet and applies it to the RF unit 502. Accordingly, the audio data packet is transmitted to the master or slave side Bluetooth interface module through the RF unit 502. The frequency selector (Hop_Sel) 546 selects an RF frequency for wirelessly transmitting the audio data packet generated from the access code & packet generator 544 according to a frequency hopping method and applies the RF frequency to the RF unit 502. Accordingly, the RF unit 502 generates an RF frequency applied from the frequency selector 546 to carry an audio data packet on the frequency and wirelessly transmit it to the other party.

Therefore, high quality audio data can be transmitted by converting the data packet of the Bluetooth protocol into an audio packet for high quality audio data.

As described above, the present invention has an advantage in that high-quality audio data can be transmitted by converting a packet for data of the Bluetooth protocol into an audio packet for high-quality audio data.

Claims (8)

A Bluetooth interface device that enables transmission of high quality audio data packets, A packet generation unit for dividing a payload of a packet for data for data transmission of a Bluetooth protocol into an L_channel audio data field and an R_channel audio data field to generate an audio data packet carrying the high quality audio data; An RF unit for wirelessly transmitting / receiving a high quality audio data packet generated from the packet generation unit between a master and a slave by using a Bluetooth protocol; A packet recovery unit for recovering high quality audio data from the payload of the audio data packet received from the RF unit; An audio codec unit for decoding the audio data recovered from the packet recovery unit and converting the audio data into an analog audio signal and outputting the analog audio signal; The audio codec unit controls the audio codec to output audio data as an analog audio signal when receiving audio data, and when the audio data is transmitted, a link control unit encodes the input audio signal into high quality audio data and outputs the audio signal to the packet generator. Bluetooth interface module for high quality audio data transmission. The method of claim 1, wherein the high quality audio data packet, Bluetooth for transmitting high-quality audio data, characterized by inserting header information indicating sample bits, sample intervals, and data lengths of the audio data mounted in each field divided into the L / R_ channels into the payload. Interface module. The packet for data of the Bluetooth protocol according to claim 2, Bluetooth interface module for high-quality audio data transmission, characterized in that the DH5 packet having a payload length of 0 to 339 bytes. The method of claim 3, wherein the high quality audio data packet, Bluetooth interface module for high-quality audio data transmission, characterized in that the 4FSK modulated. In the method for transmitting high quality audio data between the master Bluetooth interface module and the slave Bluetooth interface module using the Bluetooth protocol, Generating a payload of a packet for data for data transmission of a Bluetooth protocol into an L_channel audio data field and an R_channel audio data field to generate an audio data packet carrying the high quality audio data; Inserting an access code including an address of a slave-side Bluetooth interface module into the audio data packet and formatting the packet data for RF transmission; Transmitting a high-quality audio data packet formatted as the RF transmission packet data on an arbitrary RF frequency generated according to a frequency hopping method and wirelessly transmitting it to a slave-side Bluetooth interface module; Receiving a high quality audio data packet transmitted from the master, analyzing the access code of the packet to determine whether the packet is transmitted to the master, and restoring the packet data to decode the high quality audio data carried in the payload; , And converting the decoded high quality audio data into an analog audio signal and outputting the converted high quality audio data. The method of claim 5, wherein the high quality audio data packet, The payload of the packet for data of the Bluetooth protocol is divided into L / R_channel fields, and the corresponding L / R_channel audio data is loaded in each field, and the sample bits, sample intervals, and data lengths of the audio data loaded in each field are shown. And inserting header information indicating the payload into the payload. The packet for data of the Bluetooth protocol according to claim 6, A high quality audio data transmission method characterized by a DH5 packet having a payload length of 0 to 339 bytes. The method of claim 7, wherein the high quality audio data packet, A high quality audio data transmission method characterized by being modulated by 4FSK.