KR101945742B1 - Broadcasting Data Seamless Decoding Output Apparatus of Digital Audio Broadcasting - Google Patents

Abstract

The present invention relates to a method and apparatus for continuously decoding broadcast data of a digital audio broadcast so as to enable continuous reproduction of audio data of the same broadcast program having different frequencies according to an AF (Alternative Frequency) technique of DAB + Output device.
In order to achieve the above object, according to an aspect of the present invention, there is provided a radio communication system including a first RF tuner for tuning and receiving a first broadcast frequency among different first and second broadcast frequency waves according to the same broadcast program of DAB + A second RF tuner for tuning and receiving a second broadcast frequency among the second broadcast frequency waves; and a second RF tuner for receiving audio data of the first and second broadcast frequencies received through the first and second RF tuners in units of superframes And performs Reed-Solomon (RS) decoding on the buffered audio data in the superframe unit at the time of entering a region where the signal strength of any of the first and second broadcast frequencies is large, And a multimedia processing unit for performing a swap process for the content.

Description

TECHNICAL FIELD [0001] The present invention relates to a broadcast data decode output apparatus for a digital audio broadcast,

The present invention relates to a continuous data decoding and output apparatus for digital audio broadcasting, and more particularly, to an apparatus and method for continuously outputting audio data of the same broadcast program having different frequencies according to DAB + broadcasting applied to a mobile system such as a vehicle, And outputting the decoded audio data to the digital audio broadcasting decoding apparatus.

As is well known, the digital audio broadcasting (DAB) in Europe is gradually expanding in the radio broadcasting technology market, and it is developing from the center of the existing DAB network to the center of the DAB + network.

In addition, the basic technologies and techniques applied in the existing European analog FM broadcasting are still applied to the digital broadcasting network. As one of the technologies, AF (Alternative Frequency) technology is applied to digital audio broadcasting technology ) Is applied as it is.

In the service following technology in digital audio broadcasting, when a radio broadcast of the same program content is transmitted using different frequencies, the frequency of the vehicle is automatically changed when moving from one frequency range to another frequency range So that the broadcast can be received.

To this end, a DAB receiver is provided for receiving and reproducing digital audio broadcasting in a vehicle. The DAB receiver broadcasts the same broadcast program, but has a main tuner and a sub tuner for receiving broadcast radio waves of different frequencies .

1, a DAB receiver receives a frequency wave including a specific broadcast audio data (N - N + 1 - N + 2 - N + 3 - ...) through a main tuner in a specific area , The AAC codec type is classified in the multimedia process unit, the audio data is decoded and then the audio output is proceeded. When the vehicle enters the adjacent area having a higher propagation intensity of another frequency according to the same broadcast program , The sub tuner receives the radio waves of different frequencies including the audio data (P - P + 1 - P + 2 - P + 3 - ...) of the same broadcast program and performs audio processing through the multimedia process have.

Related technology is disclosed in Korean Patent Laid-Open No. 2009-0004665 (Broadcast Receiver and Broadcast Signal Processing Method) (2009.01.12).

In the case of the conventional DAB receiver, in the case of the AAC codec of DAB +, the audio buffer is swapped and then RS decoding is performed. The audio data received from the main tuner is transmitted through the AAC codec When the audio data of the sub-tuner having the increased intensity of the radio wave is changed due to the change of the frequency propagation region in decoding, the RS decoding error occurs at the time when the switching point of the audio decoding is switched as shown in FIG. The audio frame is instantaneously broken and the pop noise is generated or the audio mute phenomenon occurs and the broadcast reception quality is inevitably poor.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a method and apparatus for continuously reproducing audio data of the same broadcast program having different frequencies according to the AF (Alternative Frequency) technique of DAB + And to provide a broadcast data continuous decoding output apparatus of a digital audio broadcasting which enables decoding processing.

The apparatus for continuously outputting a broadcast data of a digital audio broadcasting according to an aspect of the present invention includes a first RF tuner for tuning and receiving a first broadcast frequency among different first and second broadcast frequency waves according to the same broadcast program of a DAB + A second RF tuner for tuning and receiving a second broadcast frequency among different first and second broadcast frequency waves according to the same broadcast program of the DAB + broadcast, and a second RF tuner for receiving the first and second broadcast frequencies received through the first and second RF tuners The audio data of the broadcast frequency is buffered in units of super frames. When the audio data of one of the first and second broadcast frequencies enters a region having a large signal strength, And a multimedia processing unit for performing Reed-Solomon (RS) decoding and performing swap processing for switching audio switching And that is characterized.

In the present invention, the multimedia processing unit may include a first audio buffer for buffering DAB + broadcast audio data received from the first RF tuner in units of AAC superframes, and outputting audio data of DAB + broadcast received from the second RF tuner to an AAC A second audio buffer for buffering and outputting in units of superframes; an RS decoder for decoding RS encoded data for audio frame data of DAB + broadcast buffered in units of AAC superframes through the first audio buffer; A second RS decoder for performing RS decoding to decode RS encoded data for audio frame data of a DAB + broadcast buffered and output in units of AAC super frames through the second audio buffer, Audio frame data of the first broadcast frequency, An audio swap processor for performing a swap process on audio frame data of any one of audio frame data of a second broadcast frequency decoded by the coder, and audio frame data swapped through the audio swap processor, And an audio decoder for decoding the audio data.

The audio data buffered through the first and second audio buffers may be buffered in 120-ms AAC superframe units.

According to the present invention as described above, when a vehicle moves in an area where radio waves of different frequencies of the same broadcast program overlap in a DAB + broadcast receiver mounted on a vehicle, an RS decoder unit The audio data buffered in the super frame unit is swapped so as not to cause the RS decoding error so that when reception switching of the same broadcast program according to DAB + broadcasting is required for different frequencies, It is possible to prevent the occurrence of noise or audio mute phenomenon, thereby improving the broadcast reception quality for DAB + broadcasting.

1 is a diagram illustrating audio data received in a main tuner and a sub tuner in a conventional DAB + broadcast receiver.
2 is a diagram illustrating a state in which an RS decoding error occurs when audio decoding switching of audio data of the same broadcast program having different frequencies in a conventional DAB + broadcast receiver occurs.
3 is a block diagram of an apparatus for continuously outputting a broadcast data of a digital audio broadcasting according to an embodiment of the present invention.
4 is a diagram illustrating a state in which audio data received by the first tuner and the second tuner, respectively, are buffered in units of superframes in the apparatus for continuously outputting continuous data of a digital audio broadcast according to an embodiment of the present invention.
FIG. 5 is a diagram illustrating a state in which audio data buffered in a super frame unit is swapped in a broadcast data continuous decoding output apparatus of a digital audio broadcasting according to an exemplary embodiment of the present invention.

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

In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

3 is a block diagram of an apparatus for continuously outputting a broadcast data of a digital audio broadcasting according to an embodiment of the present invention.

3, the apparatus for continuously decoding and outputting broadcast data of digital audio broadcasting according to the present invention includes first and second RF tuners 10 and 20 and a multimedia processing unit 100.

The first RF tuner 10 tunes one frequency among different broadcast frequency waves according to the same broadcast program of DAB + broadcasting and receives the tuned frequency.

The second RF tuner 20 tunes and receives a radio wave of a broadcast frequency other than the radio wave of the frequency received by the first RF tuner 10 among different broadcast frequency waves according to the same broadcast program of the DAB + broadcast.

The multimedia processing unit 100 includes first and second audio buffers 30 and 40, first and second RS decoders 50 and 60, an audio swap processing unit 70, And an audio decoder 80.

4, the first audio buffer 30 receives Main Service Data (MSC) data from audio data of DAB + broadcasting received from the first RF tuner 10 as an AAC super frame of 120 ms, 4), and the second audio buffer 40 outputs the second audio buffer 40 (S - S + 1 - S + 2 - S + 3 - (T - T + 1 - T + 2 - T + 3 - ...) in units of 120 ms AAC superframes from the audio data of the DAB +

The first RS decoder 50 performs RS decoding processing for decoding RS (Reed-Solomon) encoded data for audio frame data of DAB + broadcast buffered and output in units of AAC super frames through the first audio buffer 30 .

The second RS decoder 60 performs an RS decoding process to decode RS encoded data for audio frame data of DAB + broadcast buffered and output in units of AAC super frames through the second audio buffer 40. [

The audio swap processor 70 extracts audio frame data according to a reception frequency from the first RF tuner 10 decoded through the first RS decoder 50, And performs audio swap processing with audio frame data according to the reception frequency from the tuner 20. [

The audio decoder 80 decodes the swapped audio frame data through the audio swap processor 70 to enable audio output through the speaker.

FIG. 5 is a diagram illustrating a state in which audio data buffered in a super frame unit is swapped in a broadcast data continuous decoding output apparatus of a digital audio broadcasting according to an exemplary embodiment of the present invention.

5, the audio swap processing unit 70 receives the audio frame (S-2-S-1-S) of the reception from the first RF tuner 10 Audio switching points are formed in units of superframes of audio data for switching to audio frames (T + 1 - T + 2 - T + 3 - ...).

Accordingly, the DAB + broadcast audio signal decoded and output through the audio decoder 80 does not generate instantaneous pop noise or mute, and has robustness against the error of AAC +.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand. Accordingly, the technical scope of the present invention should be defined by the following claims.

10, 20: RF tuner 30, 40: Audio buffer
50, 60: RS decoder 70: Audio swap processor
80: Audio decoder 100: Multimedia processor

Claims (3)

A first RF tuner for tuning and receiving the first broadcast frequency among different first and second broadcast frequencies according to the same broadcast program of DAB + broadcasting;
A second RF tuner for tuning and receiving the second broadcast frequency among different first and second broadcast frequencies according to the same broadcast program of the DAB + broadcast; And
Wherein the control unit buffers audio data of the first broadcast frequency and the second broadcast frequency received through the first and second RF tuners in units of superframes, (Reed-Solomon) decoding for the superframe-based buffered audio data at the time of entering a region where the signal intensity of one broadcast frequency is large, Performing a swap process on the second broadcast frequency received through the second RF tuner from the RS frame-decoded audio frame data with the RS frame-decoded audio frame data with respect to the first broadcast frequency And a multimedia processing unit for decoding the broadcast data. The method according to claim 1,
Wherein the multimedia processing unit comprises: a first audio buffer for buffering audio data of DAB + broadcasting received from the first RF tuner in units of AAC superframes;
A second audio buffer for buffering audio data of DAB + broadcasting received from the second RF tuner in units of AAC superframes,
A first RS decoder for performing RS decoding to decode RS encoded data for audio frame data of a DAB + broadcast buffered and output in units of AAC super frames through the first audio buffer,
A second RS decoder for performing RS decoding to decode RS encoded data for audio frame data of DAB + broadcast buffered and output in units of AAC super frames through the second audio buffer,
An audio swap processor for performing the swap process from audio frame data of the first broadcast frequency decoded by the first RS decoder to audio frame data of the second broadcast frequency decoded by the second RS decoder;
And an audio decoder for decoding the swapped audio frame data through the audio swap processor to audio output through a speaker. 3. The method of claim 2,
Wherein the audio data buffered through the first and second audio buffers are buffered in units of 120 ms AAC superframes.

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