KR20080051591A - Broadcasting and receiverdata processing method of broadcasting receiver - Google Patents

Abstract

A broadcasting receiver and a data processing method for the broadcasting receiver are provided to packetize FIC(Fast Information Channel) and MSC(Main Service Channel) data to process channel-decoded DAB(Digital Audio Broadcasting) transmission data easily. A tuner unit(401) selects a desired broadcasting signal. A channel decoder(402) decodes the broadcasting signal selected in the tuner unit and outputs FIC and MSC data. An FIC decoder(403) receives the outputted FIC data and grasps a structure of a sub-channel. A packet encoder(404) adds a head configured by using the information grasped in the FIC decoder and packetizes the FIC and MSC data. A storing device(405) stores the packetized data. A packet decoder(406) depacketizes the corresponding packet by using header information in the stored packet, and configures real data. A decoding unit(407) decodes the depacketized data and outputs the decoded data.

Description

Data processing method of broadcast receiver and broadcast receiver {Broadcasting and Receiver Data Processing Method of Broadcasting Receiver}

1 is a diagram showing the structure of a typical DAB transport frame

2 illustrates an embodiment of packetizing data according to the present invention.

3 is a diagram illustrating an embodiment of a value of a header through packetization according to the present invention.

4 illustrates a broadcast receiver according to the present invention.

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

201: header 202: data

203: FIC_MSC 204: tr_mode

205: data_length 206: CIF_num

207: subch_ID 208: padding

402: channel decoder 403: FIC decoder

404: packet encoder 405: storage device

406: packet decoder

The present invention relates to a data processing method of a broadcast receiver, and more particularly, to a method of processing data by packetizing a transmission frame in a terrestrial DMB receiver.

Recently, as digital audio devices with excellent sound quality such as CD and DVD have been rapidly spread and popularized, the demand for listeners for digital broadcasts requiring high quality sound is increasing day by day, and thus the limitation of sound quality that existing FM broadcast can provide To overcome this, Digital Audio Broadcasting (DAB) is being implemented in Europe, Canada and the United States. The DAB system uses a technology completely different from the current AM or FM broadcast to show not only high quality sound quality but also excellent reception performance on the go, and has a characteristic of transmitting digital data such as video and text at high speed. have.

DMB adopted in Korea is based on Eureka-147 Digital Radio Broadcasting (DAB), adopted as the European terrestrial radio standard. In this case, in order to more efficiently perform the reception performance in a mobile environment, the addition to the DAB is a Reed-Solomon Code and a convolutional interleaver that are robust to burst errors that may occur on a transmission channel. . The two additional blocks are applied to the DAB Ensemble input signal at the transmitter and provide an error rate low enough for video service even in a mobile receiving environment.

The transmission channel of the DMB broadcast is a wireless mobile reception channel, and the amplitude of the received signal is not only time-varied, but also the Doppler Spreading of the spectrum of the received signal due to the influence of the mobile receiver. Occurs. In consideration of the transmission and reception in such a channel environment, the DMB transmission scheme is based on Orthogonal Frequency Division Multiplexing (OFDM). Since the OFDM scheme uses a plurality of multicarriers, it is very resistant to ghosts generated by the multipath channel, and channel estimation based on a pilot signal is easy.

At the DMB transmitter, each service signal (audio, video, data service) is individually encoded for error prevention and then interleaved in the time domain, and each service signal interleaved in the time domain is multiplexed and is a data channel. (MSC). The multiplexed signal is interleaved in the frequency domain together with the multiplexed array information (MCI) and the service information (SI) which are transmitted in a fast information channel (FIC) which is a control channel.

FIG. 1 illustrates a structure of a general DAB transmission frame and shows a frame structure of the Eureka-147 transmission mode I. Referring to FIG. In the DAB, information about an audio service, a data service, and each service is transmitted in units of frames. The transmission frame includes a synchronization channel (SC) 101, a fast information channel (FIC) 102, and a main service channel (MSC) ( 103).

SC 101, which is the first part of the frame, contains information necessary for transmission mode, OFDM symbol, and frequency synchronization. The FIC 102 is composed of Service Information (SI), Fast Information Data Channel (FIDC), Multiplex Configuration Information (MCI), and Conditional Access (CA). The MSC 103 transmits actual data such as text, video, and audio.

In one transmission frame, the SC 101 is composed of a null symbol and a phase reference symbol (PRS), the FIC is composed of three symbols, and the MSC is composed of 72 symbols for real data, and the total length is 96 ms. Data transmission is the transmission of the FIC and the MSC, the FIC is composed of a plurality of fast information blocks (FIBs), and controls the MSC arrangement.

The MSC 103 is composed of several Common Access Frames (CIFs). The minimum address unit of a CIF is 64 bits, which is called a unit capacity (CU). The subchannel consists of an integer multiple of the unit capacity. do. That is, the MSC 103 is composed of multiplexing of subchannels, which are time interleaved and channel coded. Each subchannel represents one or more service components, and the service components and the subchannels are combined to form a multiplexing arrangement.

The terrestrial DMB receiver receives the transmission frame and uses the SC 101 to find the start of the frame, and uses the MCI in the FIC 102 to identify the MSC subchannel structure using information such as the type, location, and type of service of the MSC. do. In the transmitted frame, the SC 101 is removed through channel decoding, leaving only the FIC and the MSC in the frame, making it difficult to know the start of the frame alone. In addition, in order to distinguish MSCs in units of subchannels, MSCs can be distinguished only if they have a decoded MCI.

In order to use the FIC and MSC data in an application, a function that separates the data into subchannels is required. However, the FIC and the MSC data may be handled by the hardware. Otherwise, there is a problem in that the FIC is always needed to know the structure of the MSC subchannel.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide a data processing method of a broadcast receiver for packetizing FIC, MSC data so as to easily process channel-decoded DAB transmission data.

Another object of the present invention is to provide a data processing method of a broadcast receiver for easily finding the start of a packet by using a rule of a packet header when a stored packet is lost.

In order to achieve the above object, the data processing method of the broadcast receiver according to the present invention includes the steps of decoding the control channel of the transmitted frame to obtain information about the structure of the frame and the sub-channel of the data channel; Packetizing frame data using the information obtained through the control channel decoding; Storing the packetized frame data; Depacketizing and reading the stored packet; And decoding and outputting the depacketized data.

In the packetizing step, in the case of a control channel among the transmitted frames, the packetizing is performed in a control channel unit in one transmission frame.

In the packetizing step, in the case of a data channel of the transmitted frames, the packetization is performed by subchannel units in one transmission frame.

The packetizing may be performed by adding a header to the actual data.

The header may include information indicating whether data in the packet is a control channel or a data channel, information indicating a transmission mode of a transmission frame, information indicating a length of actual data in a packet, information indicating a CIF order of a current packet, When the data is a data channel, at least one of information indicating an ID of a subchannel and information indicating the end of the packet header may be included.

The control channel is FIC, the data channel is characterized in that the MSC.

According to another embodiment of the present invention, there is provided a method of decoding a control channel of frame data to obtain information on a frame structure and subchannels of a data channel; Packetizing frame data by configuring a header using information obtained by decoding the control channel; Storing the packetized frame data; If a part of the frame is missing, it is characterized in that the step of finding the required packet using the information in the header of the stored packet.

The finding of the lost packet may include finding the lost packet using information in the stored packet header and information indicating the length of the actual data except for the header.

The broadcast receiver according to the present invention comprises a tuner unit for selecting a desired broadcast signal; A channel decoder for decoding the broadcast signal selected by the tuner and outputting FIC and MSC data; A FIC decoder configured to receive the output FIC data and determine a structure of a subchannel; A packet encoder for packetizing FIC and / or MSC data by adding a header constructed using the information found by the FIC decoder; A storage device for storing the packetized packet data; A packet decoder configured to depacketize a corresponding packet using header information in the stored packet to configure actual data; And a decoder which decodes and outputs the inverse packetized data.

Other objects, features and advantages of the present invention will become apparent from the following detailed description of embodiments taken in conjunction with the accompanying drawings.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention that can specifically realize the above object will be described. At this time, the configuration and operation of the present invention shown in the drawings and described by it will be described as at least one embodiment, by which the technical spirit of the present invention and its core configuration and operation is not limited.

2 illustrates one embodiment of a format for packetizing transmission data according to the present invention, and FIG. 3 illustrates one embodiment of a value of a header through packetization according to FIG. 2.

According to the present invention, a packet is formed by attaching a header 201 to actual data 202. In the case of FIC among the transmission frames, the packetization is performed in FIC units in one transmission frame, and in the case of MSC, subchannel units in one CIF. Packetize with In one embodiment, each packet is configured to have a packet header 201 of 4 bytes, and the packet header 201 includes FIC_MSC 203, tr_mode 204, data_length 205, CIF_num 206, and subch_d 207. , padding 208.

The FIC_MSC 203 field indicates whether the data in the packet is FIC or MSC. When the FIC_MSC has a value of 0, it can be seen that the data is MSC data. The tr_mode 204 field indicates a transmission mode of a DAB transmission frame. When tr_mode has a value of 00, the transmission mode is I. The data_length (205) field is a field indicating the length of actual data in a packet except for a packet header having a length of 4 bytes in byte units, and indicates the size of an FIC corresponding to a transmission mode when the frame data is FIC data. In case the frame data is MSC data, it indicates the byte unit size of the data field.

The CIF_num 206 field is a field indicating the number of CIFs included in one transmission frame according to a transmission mode, from 1 to 4, and the current CIF corresponds to the number of CIFs. If the frame data is MSC data, it has a value corresponding to the order of CIF to which the data belongs in the transmission frame.

The subch_id 207 field indicates the ID of a subchannel in case of MSC data and has a value of Ox00 in case of FIC data. The padding 208 field identifies the end of the packet header.

This is only one embodiment, and may be configured differently by adding or deleting necessary information in each field according to an application example of configuring a header, and the location of each field may be configured differently by a designer.

The form of the packet header configured through FIG. 2 may include information in 3 bytes and padding 208 in the remaining 1 byte to be used for the purpose of finding a lost packet when a certain part of the packet, which is another object of the present invention, is lost. .

As an example, when a packet is partially lost, find whether the lowest 1 byte where the padding field is located is OxFF every 4 bytes by using a padding field having a value of 0xFF, which is one of the header information of the packet, and skip the data_length if the lowest 1 byte is 0xFF. You can find the beginning of a packet again by running it and checking for the existence of the padding field.

      In other words, when processing the data stored in the memory, if the lower byte of the header 4 bytes is not 0xFF, the start of the packet is missed. Therefore, 0xFF is searched to find the start of the packet. At this time, it is not known whether the identified 0xFF belongs to the header of the actual packet or the data. Therefore, if 0xFF is found, the data_length in the previous header is skipped and the padding of the part considered to be the header of the next packet is read.

      If the initially found 0xFF is the correct padding value, the padding part of the second packet will have a value of 0xFF. If the first 0xFF is not the padding value, the probability that the 0xFF is other than 0xFF will be high. However, since the data of the second packet also has a value of 0xFF, it is also possible to check whether the value of the third padding is 0xFF by skipping again by data_length of the packet to which the second padding field belongs. Accordingly, the present invention will not be limited to the above embodiment because the number of 0xFFs in the software may be considered by the designer to be found.

In addition, one byte of sync_byte (not shown) may be used instead of the padding 208 field to find the lost packet. The sync_byte may be configured at the padding 208 field or at another position in the other header. In MPEG 2, if the value of 0x47 is set as sync_byte at the beginning of the 4 byte header, the value of 0x47 can be found, and the start of the packet can be found by skipping data_length to see if 0x47 reappears.

That is, if a certain portion of the packet is lost, the method for finding the lost packet is not limited to the above embodiment, and may be changed by the designer configuring a field in the packet header.

4 shows an embodiment of a structure of a broadcast receiver according to the present invention.

After the DAB broadcast signal of a specific channel is tuned by the tuner 401 and decoded by the channel decoder 402, FIC and MSC data remain in the transmission frame. The channel decoder 402 forwards this data to the FIC decoder 403 and the packet encoder 404. The FIC decoder 403 receiving the FIC data decodes the MCI to grasp the transmission channel information and subchannel structure necessary for packetization, and outputs the identified information to the packet encoder 404. The packet encoder 404 then packetizes the output data of the channel decoder 402 using the information found by the FIC decoder 403 and stores the packets in the storage 405. Header information added during packetization will be described with reference to FIGS. 2 and 3.

As described above, the present invention can eliminate the inconvenience of packetizing the FIC and / or MSC data and storing the FIC and / or MSC data in the storage device 405 to decode the FIC information in the next step or provide additional MCI information in a hardware interface.

The packet decoder 406 may depacketize the packet using the header information in the packet stored in the storage device 405 to configure actual data. These data may be delivered to the DAB audio decoder 407 in the case of DAB audio, and to the AV decoder 407 in the case of DMB AV data using the DAB standard, and to the application 407 in other cases. have.

According to the present invention, the frame data is packetized and stored in the storage device using information such as FIC or MSC, and in the case of MSC, which subchannel is used without FIC information. When processing the stored data, the packet is decoded to decode the FIC data or MSC. It is easy to distinguish which subchannel of.

On the other hand, the terms used in the present invention are defined in consideration of the functions in the present invention, which may vary according to the intention or customs of those skilled in the art and the definition should be changed based on the contents of the present invention. something to do.

In addition, the present invention is not limited to the above-described embodiments, and can be modified by those skilled in the art as can be seen from the appended claims, and such modifications are within the scope of the present invention.

According to the data processing method of the broadcast receiver according to the present invention described above, it is easy to distinguish data when decoding the stored packet data, and does not repeat the process of determining the structure of the MSC, thereby executing power-consuming additional functions. Even in this case, the user can use additional functions without worrying about power.

It also has the effect of finding the beginning of a packet easily by using the rules of the packet header even if you read from the middle of the stored packet.

From the above description, those skilled in the art can appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

Claims (9)

Decoding the control channel of the transmitted frame to obtain information about the structure of the frame and the subchannels of the data channel; Packetizing frame data using the information obtained through the control channel decoding; Storing the packetized frame data; Depacketizing and reading the stored packet; And And decoding and outputting the depacketized data. The method of claim 1, wherein the packetizing step The control channel of the transmitted frame, the data processing method of the broadcast receiver characterized in that the packetization in the unit of a control channel in one transmission frame. The method of claim 1, wherein the packetizing step In the case of the data channel of the transmitted frame, the data processing method of the broadcast receiver characterized in that the packetization in the unit of sub-channel in one transmission frame. The method of claim 1, wherein the packetizing step A data processing method of a broadcast receiver, comprising adding a header to actual data. The method of claim 4, wherein the header is Information indicating whether data in the packet is a control channel or a data channel, information indicating a transmission mode of a transmission frame, information indicating a length of actual data in a packet, information indicating a CIF order of a current packet, and the data And a data channel, at least one of information indicating an ID of a subchannel and information indicating the end of the packet header. The method of claim 1, And the control channel is FIC and the data channel is MSC. Decoding the control channel of the frame data to obtain information on the frame structure and subchannels of the data channel; Packetizing frame data by configuring a header using information obtained by decoding the control channel; Storing the packetized frame data; And searching for a required packet by using information in the header of the stored packet when a part of the frame is lost. 8. The method of claim 7, wherein finding the lost packet comprises  And searching for lost packets using information in the stored packet header and information indicative of the length of the actual data except the header. A tuner unit for selecting a desired broadcast signal; A channel decoder for decoding the broadcast signal selected by the tuner and outputting FIC and MSC data; A FIC decoder configured to receive the output FIC data and determine a structure of a subchannel; A packet encoder for packetizing FIC and / or MSC data by adding a header constructed using the information found by the FIC decoder; A storage device for storing the packetized packet data; A packet decoder configured to depacketize a corresponding packet using header information in the stored packet to configure actual data; And And a decoder which decodes and outputs the inverse packetized data.

Images