FR2953674A1 - Ensemble transport interface producing method for terrestrial digital multimedia broadcasting field, involves generating new frame so as to replace frame with error, and producing signal using error-free frame and new frame - Google Patents

Abstract

The method involves receiving an ensemble transport interface (ETI) signal, and sequentially converting the signal into a set of ETI frames. The error is searched in each ETI frame by an ETI frame analyzer (120). The frame information is recorded on the error-free ETI frame, by an ETI frame controller (140). A new ETI frame is generated using the frame information by an ETI frame generator (150), so as to replace the ETI frame with error. The ETI signal is produced using the error-free ETI frame and the new ETI frame, by an ETI signal output unit (160). An independent claim is also included for a device for producing an ensemble transport interface in the digital multimedia broadcasting.

Description

FIELD OF THE INVENTION The present invention relates to a method and a device for producing a digital transport interface. together (Ensemble Transport Interface - ETI) as part of a digital multimedia broadcast. 2. Background technology Terrestrial digital multimedia (terrestrial DMB) has added the standard of providing a video service to the Euréka 147 digital sound broadcasting system (DAB) to provide mobile users with a variety of multimedia services including data , sound and video. In general, the terrestrial DMB transmits a plurality of services provided by a plurality of service providers through a single terrestrial DMB channel. An ensemble multiplexer generates signals (hereinafter referred to as "ETI frames") of the Ensemble Transport Interface (ETI) generated by multiplexing a plurality of services. The ETI frame is transmitted to a transmitter through an ETI network. The transmitter generates a transmission frame by executing a forward error correction (FEC) coding method on the ETI frame data, encodes the transmission frame according to the orthogonal frequency division multiplexing method with encoding (COFDM), and transmits the encoded transmission frame to the receiving device by the frequency band of the terrestrial DMB. On the other hand, the broadcast is not necessarily of good quality and may result in disconnection of signals or errors in the signals. In this case, a process is needed to maintain the production of the ETI, thus preventing disconnection of the transmission. The above example is intended only to facilitate understanding of the context of the invention, and is therefore likely to contain elements that do not fall within the prior art already known to those skilled in the art in this country. 3. Disclosure of the Invention The present invention has been made to provide a method and apparatus for continuously producing ITS. A particular embodiment of the present invention provides a method for producing Ensemble Transport Interfaces (ETI) in the context of a digital media broadcast, comprising the steps of: receiving an ETI signal; sequentially converting the ETI signal into a plurality of ETI frames; searching for an error in each ETI frame; recording frame information on the error-free ETI frame from the plurality of ETI frames; generating a new ETI frame for replacing the erroneous ETI frame from the plurality of ETI frames, using the frame information; and generating the ETI signal using the error-free ETI frame and the new ETI frame.

Another embodiment of the present invention provides a device for producing an Ensemble Transport Interface (ETI) as part of a digital media broadcast, comprising: an ETI signal input unit for receiving an ETI signal and sequentially converting the ETI signal into a plurality of ETI frames; an ETI frame analyzer for searching for an error in each ETI frame; an ETI frame controller for storing frame information on the error-free ETI frame from the plurality of ETI frames, and extracting information for generating a new ETI frame for replacing the erroneous ETI frame derived from the plurality of ETI frames from the frame information; an ETI frame generator for generating the new ETI frame using the information extracted by the ETI frame controller; and an ETI signal output unit for producing an ETI signal using the error-free ETI frame and the new ETI frame. According to one embodiment of the present invention, there is provided a method and apparatus for consecutively maintaining the production of ETI while the signal is disconnected or an error has occurred because of a poor state. of diffusion. When the production of ETI is continuously maintained, the wireless transmission / reception of signals between the transmitter and the receiving device is maintained. Thus, the broadcast system can function normally. 4. List of Figures Figure 1 shows the hierarchical structure of an ETI according to a particular embodiment of the present invention.

Figure 2 shows the frame structure of a LI layer from the hierarchical structure of an ETI according to a particular embodiment of the present invention. Figure 3 shows the structure of a transmission frame according to a particular embodiment of the present invention. Figure 4 shows the structure of a fast information block (FIB) according to a particular embodiment of the present invention. Figure 5 shows the structure of a FIG 0/0 according to a particular embodiment of the present invention. Figure 6 shows an ETI transmitter 100 according to a particular embodiment of the present invention. Figure 7 shows the operation of an ETI frame controller 140 according to a particular embodiment of the present invention. 5. DETAILED DESCRIPTION OF THE EMBODIMENT In the following detailed description, only certain particular embodiments of the present invention are shown and described for purely illustrative purposes. As will be understood by those skilled in the art, it is possible to modify the described embodiments in various ways without departing from the spirit or scope of the present invention. Therefore, the drawings and the description should be considered as illustrative and not limiting. In the whole memory, the same numerical references are used to designate the same elements. In this brief, unless expressly stated otherwise, it should be understood that the term "understand" and its variants "includes" or "comprising" imply the inclusion of the elements stated but not the exclusion of any other element. Figure 1 shows the hierarchical structure of an ETI according to a particular embodiment of the present invention. In Figure 1, the hierarchical structure of the ETI comprises a logical interface layer (LI), a network-independent layer (NI), and a network adaptation layer (NA). The LI layer represents a basic logical structure and defines basic information for generating a set.

The NI layer represents a physical interface layer for applying the LI layer and includes a basic interface for ETI type equipment. The NA layer represents a physical interface layer that can be used for a network state in which errors are likely to occur more easily than in the NI layer, and is applied to the LI layer. The LI layer, the NI layer and the NA layer are interchangeable, and the LI layer that corresponds to the central data portion is identical.

Figure 2 shows the frame structure of a LI layer from the hierarchical structure of an ETI according to a particular embodiment of the present invention.

In FIG. 2, a frame of the LI layer (ETI frame) comprises a state field (STAT) and a logical interface data field (LIDATA). The status field (STAT) includes an error status field (ERR) which transmits error state information of the ETI (LI) frame. The logical interface data field (LIDATA) includes a Header and a Payload. The header includes a frame characterization field (FC), a flow characterization field (STC), and an end-of-header field (EOH). The payload includes a main stream data field (MST), an end-of-frame field (EOF) and a timestamp field (TIST). The frame characterization field (FC) of the header comprises a frame counter (FCT), a fast information channel indicator (FICF), a number of streams (NST), a frame phase (FP) ), a mode identity (MID), and a frame length (FL). The flow characterization field (STC) includes a plurality of auxiliary flow characterization elements (SSTCs) for displaying the respective characteristics of a plurality of data streams. The header end field (EOH) comprises a multiplex network signaling channel (MNSC) and a cyclic header redundancy check (CRCh).

The frame characterization field (FC) transmits a general data characterization that can be applied to a frame that corresponds to the entire LI layer. In the frame characterization field (FC), the frame counter (FCT) has values from 0 to 249 which correspond to the common interlaced field count (CIF). Here, the at least one CIF is included in the main service channel (MSC) of a transmission frame, and corresponds to at least one main stream data field (MST). The fast information channel indicator (FICF) indicates whether or not the main flow data field (MST) has FIC data. The number of streams (NST) transmits information on a number of data streams for the information to be transmitted by the stream characterization field (STC) and the main stream data field (MST). The frame phase (FP) is a modulo 8 counter which indicates the phase of the frame and which must be used to signal to the COFDM generator when to insert the identification information of the transmitter (III). The mode identification (MID) includes mode identification information used for COFDM modulation. The frame length (FL) indicates the total number of words in each stream characterization field (STC) length, the end of frame (EOF) field, and the main stream data field (MST). In the header field, the flow characterization field (STC) provides information on the characteristics of a plurality of auxiliary channel data streams corresponding to the main stream data field (MST). Specifically, the flow characterization field (STC) comprises a plurality of auxiliary flow characterizations (SSTCs) that correspond to a plurality of auxiliary flow channels of the main flow data field (MST). Each of the OSTCs includes an Auxiliary Channel Identification (SCID), Start Address (SAD), Protection Level (TPL), and Stream Length (STL) field. In the SSTC, the auxiliary channel identification (SCID) provides identification information indicating a flow auxiliary channel.

The start address (SAD) indicates a CIF flow auxiliary channel capacity unit (CU) start address, and the protection level (TPL) provides information about the protection level and the types of the CIF flow channel. Auxiliary flow channel. The stream length (STL) indicates the length of the non-coded stream auxiliary channel. In the end-of-header (EOH) field, the multiplex network signaling channel (MNSC) indicates a signaling channel between an ensemble multiplexer and a transmitter. The Cyclic Header Redundancy Check (CRCh) provides information to perform a cyclic redundancy check on the frame characterization field (FC), the flow characterization field (STC), and the multiplex network signaling. The main payload data (MST) field of the payload includes at least one fast information channel (FIC) data and a plurality of streams (Stream1 - StreamNsT). The End Of Frame (EOF) field includes a cyclic redundancy check (CRC) and a reserved (Rfu) check.

In the main flow data (MST) field, the existence of the FIC data can be determined from the fast information channel indicator (FICF), the FIC data designating fast information channel data which are not coded. Auxiliary Stream Channels (Stream1-StreamNST) are assigned to transmit a plurality of streams respectively corresponding to a plurality of services. In the EOF field, the cyclic redundancy check (CRC) provides information that is used to perform a cyclic redundancy check on the main flow data field (MST), and the reserved (Rfu) represents a resource reserved. The TIST field provides information that serves to produce a transmission frame corresponding to the ETI (LI) frame. The aforementioned ETI frame is routed to the transmitter through the ETI network. The transmitter performs forward error correction (FEC) coding on the ETI frame data and COFDM modulation thereon to generate a transmission frame, and transmits the transmission frame to a device reception. Figure 3 shows the structure of a transmission frame according to a particular embodiment of the present invention. In FIG. 3, the transmission frame comprises a synchronization channel (SC), a fast information channel (FIC), and a main service channel (MSC).

The synchronization channel (SC) transmits decoding information for the digital communication, and has a predetermined format so that a receiving device of the terrestrial DMB can recognize the initial state of the frame. The Fast Information Channel (FIC) transmits information regarding that of Common Interleaved Frames (CIFs) within the main service channel (MSC) through which data is transmitted, as well as information whose device reception needs to receive a terrestrial DMB service. The fast information channel (FIC) comprises at least one fast information block (FIB).

The data is transmitted through the main service channel (MSC). The main service channel (MSC) comprises at least one common interlaced frame (CIF). The structure and length of the transmission frame are determined by the mode of transmission. The terrestrial DMB system uses the fast information block (FIB) and the common interleaved frame (CIF) to provide the transmission mode regardless of the type of data that is transmitted by the fast information channel (FIC) and the main service channel (MSC). More precisely, the data is transmitted by fast information block (FIB) or by common interlaced frame (CIF) regardless of the mode of transmission. However, the number of Fast Information Blocks (FIBs) and Common Interleaved Frames (CIFs) that are input depending on the transmission mode is set differently. Table 1 shows an exemplary configuration of a transmission frame for each transmission mode of the terrestrial DMB system.

(Table 1) FIB Number Length Mode Number of CIF transmits frame per frame per transmission frame transmission I 96 ms 12 4 II 24 ms 3 1 III 24 ms 4 1 IV 48 ms 6 2 On the board 1, the transmission mode I is a transmission mode for digital broadcasting with a single frequency network, the fast information channel (FIC) comprises 12 fast information blocks (FIB), the main service channel (MSC) ) comprises 4 common interlaced frames (CIF), and the total length of the transmission frame is 96 ms. The transmission mode II is a transmission mode for digital broadcasting with a multiplex frequency network, the fast information channel (FIC) comprises 3 fast information blocks (FIB), the main service channel (MSC) ) comprises a common interlaced frame (CIF), and the total length of the transmission frame is 24 ms. The transmission mode III is a transmission mode for digital broadcasting with a wired network, the fast information channel (FIC) comprises 4 FIB, the main service channel (MSC) comprises a common interlaced frame (CIF), and the total length of the transmission frame is 24 ms. The IV transmission mode is a transmission mode for digital broadcasting with a terrestrial or satellite network, the fast information channel (FIC) comprises 6 fast information blocks (FIB), the main service channel (MSC) ) comprises 2 common interlaced frames (CIF), and the total length of the transmission frame is 48 ms. The ETI frame has 6,144 bytes and is transmitted for 24 ms. In addition, the ETI frame is routed to the transmitter through FIC data in the form of 32-bit fast information blocks (FIBs). Therefore, in the I transmission mode, 4 ETI frames are transmitted as a transmission frame every 96 ms. In addition, an FEC encoding is applied to a fast information channel (FIC), and this fast information channel (FIC) comprises twelve 32-byte FIBs. Figure 4 shows the structure of a fast information block (FIB) according to a particular embodiment of the present invention.

In Fig. 4, the fast information block (FIB) comprises a 30-byte FIB data field and a 2-byte CRC. The FIB data field comprises at least one fast information group (FIG), an end marker, and a padding byte (or padding). The fast information group (FIG) loads the information, the end marker includes the end information of the fast information group (FIG), and the fill byte is a reserved area for controlling the fixed length (in the occurrence, 30 bytes) of the FIB data field. The fast information group (FIG) comprises a FIG header and a FIG data field. The length of the fast information group (FIG) is variable but should not exceed 30 bytes including FIG heading, and a fast information group (FIG) can not be divided into at least two fast information blocks (FIB) to transmit. The FIG header includes information on the type and extent of the FIG, and the FIG data field includes multiplexing configuration information (MCI) and service information (SI), for example service information. a reference including the time and date, a label to display, and other information to define the label. Figure 5 shows the structure of FIG 0/0 according to a particular embodiment of the present invention. In FIG. 5, FIG 0/0 illustrates the case in which the FIG type is 0 and the extension field is 0. FIG 0/0 transmits overall information. FIG 0/0 comprises a CIF counter. The CIF counter has 5 upper bits (b12-b8) and 8 lower bits (b7-bo). The lower 8 bits are a modulo 250 lower counter from 0 to 249 and the upper 5 bits are a modulo counter 0 to 19. The CIF counter is a modulo 5000 counter that increases by 1 in the range of 0 to 4999 , the relation between the CIF counter and the frame counter (FCT) is expressed in equation 1, and the relation between the CIF counter and the frame phase (FP) is expressed in equation 2. (equation 1) FCT = CIF counter% 250

Here, the frame counter (FCT) corresponds to the lower modulo counter 250 which is represented by the lower 8 bits of the CIF counter.

(Equation 2) FP = CIF counter% 8 A transmission position and a transmission period of FIG 0/0 can be set. For example, in the case of the transmission mode (I) of Table 1, FIG 0/0 is in the first position of the fast information channel (FIC) for each transmission frame. In other words, FIG 0/0 is transmitted once for each unit of 4 ETI frames, and the transmission position of FIG 0/0 is the first position of the first FIB of the ETI frame comprising a CIF whose values of the counter of FIG. CIF correspond to 0, 4, 8, ..., 4996. In this case, it is possible to determine a continuous state of the ETI frame using the CIF counter of FIG 0/0 transmitted once for each unit of 4 30 ETI frames, the frame counter (FCT) of each frame ETI, and the continuity of the frame phase (FP). FIG. 6 shows an ETI transmitter 100 according to a particular embodiment of the present invention. The signal ETI represents an ETI signal (NA) or an ETI signal (NI), and the ETI frame designates an ETI frame (LI). It is assumed that an input unit ETI 110 and an output unit ETI 160 process the signal ETI (NA) and the signal ETI (NI) and convert the signal ETI (NA) and the signal ETI (NI) into an ETI frame (LI).

In Fig. 6, the ETI signal input unit 110 receives an ETI signal from an ETI signal source. The ETI signal input unit 110 detects an ETI signal receiving state and a synchronization detection state from the received ETI signal, and converts the ETI signal into an ETI frame. The ETI signal input unit 110 transmits the signal receiving state ETI, the synchronization detection state, and the ETI frame to an ETI frame analyzer 120.

The ETI frame analyzer 120 looks for an error in the ETI frame by analyzing the CRC values of the ETI frame and the configuration of the ETI frame. Further, the ETI frame analyzer 120 determines whether the reception of the ETI signal is disconnected or erroneous using the ETI signal receiving state and the synchronization detection state provided by the ETI signal input unit. 110. After determining that the ETI frame and the receipt of the ETI signal are error-free, the ETI frame analyzer 120 transmits the ETI frame to the ETI frame buffer 130 and also transmits error-free ETI frame information. to an ETI frame controller 140. This ETI frame information may be at least one of frame characterization (FC), stream characterization (STC), or fast information channel (FIC) data. The ETI frame controller 140 stores the ETI frame information that has been received from the ETI frame analyzer 120 and is error-free. For example, the ETI frame controller 140 records the frame characterization (FC) of the error-free ETI frame, the flow characterization (STC), and the fast information block (FIB) transmitted through the data. fast information channel (FIC). In this case, a part of the fast information block (FIB) comprises a FIG 0/0 which transmits set information, and FIG 0/0 comprises a CIF counter. The ETI frame controller 140 controls the CIF counter, and the ETI frame generator 150 provides information for generating a new ETI frame. When the ETI frame analyzer 120 has determined that the ETI frame or the receipt of the ETI signal were erroneous, the ETI frame generator 150 generates a new ETI frame. The ETI frame generator 150 receives information that generates a new ETI frame from the ETI frame controller 140, and generates a new ETI frame using this information. In this case, the ETI frame analyzer 120 may transmit the fact that the corresponding ETI frame has an error to the ETI frame generator 150 either directly or through the ETI frame controller 140, but the present invention is not not limited to these two possibilities. The ETI frame generator 150 can generate a new ETI frame by interpolation of random data adapted to the size of the auxiliary channel. For example, the ETI frame generator 150 may generate a new ETI frame in the form of a stream for notifying an expectation due to an abnormal state of the broadcast, for example an interruption of the broadcast. The ETI frame generator 150 transmits the generated ETI frame to the ETI frame buffer 130. In this case, the ETI frame generator 150 can transmit the generated ETI frame to the ETI frame buffer 130 as a function of a control signal of the ETI frame. ETI frame analyzer 120. The control signal of the ETI frame analyzer 120 may include information for controlling the production by the ETI frame generator 150 of the ETI frame generated by the ETI frame generator 150.

The ETI frame buffer 130 stores the error-free ETI frame provided by the ETI frame analyzer 120 and the generated ETI frame provided by the ETI frame generator 150, and transmits the error-free ETI frame and the ETI frame. generated at the ETI signal output unit 160. The ETI frame buffer 130 has 6144 bytes, which corresponds to the length of an ETI frame as a base unit. The size of the ETI frame buffer 130 may be set to allow the storage of 2 ETI frames or 3 ETI frames, but the present invention is not limited to these numbers.

The ETI signal output unit 160 processes the ETI frame provided by the ETI frame buffer 130 and produces the ETI signal as a result of processing. In this case, the ETI signal output unit 160 can produce the ETI frame as an ETI signal using the 2.048 MHz reference clock signal. Here, this reference clock of 2.048 MHz can be synchronized with the signal ETI which is transmitted to the signal input unit ETI 110. For example, when the signal ETI received by the signal input unit ETI 110 is generated using GPS, the 2.048 MHz reference clock signal can also be generated using GPS. The synchronization of the reference clock and the transmitted ETI signal makes it possible to avoid a situation in which the ETI frame buffer 130 overflows or would be empty, and therefore makes it possible to guarantee a continuous production of the ETI signal. The reference clock signal of 2.048 MHz can be used as a reference for the ETI frame controller 140 and the ETI frame generator 150 as well as the ETI signal output unit 160 for generating an ETI frame every 24 ms. When the receipt of the ETI signal is erroneous or the ETI frame has an error, the ETI frame generator 150 generates a new ETI frame to replace the erroneous ETI frame to produce the ETI consecutively. To do this, the ETI frame controller 140 provides information that enables the ETI frame generator 150 to generate the ETI frame.

Figure 7 shows the operation of an ETI frame controller 140 according to a particular embodiment of the present invention. In Fig. 7, the ETI frame controller 140 controls the CIF counter synchronized with the ETI frame. For this, the ETI frame controller 140 receives error-free ETI frame information from the ETI frame analyzer 120. This error-free ETI frame information can be at least one of the frame characterization (FC) error-free ETI frame, flow characterization (SIC), and FIC data. The ETI frame controller 140 detects the CIF counter value of the FIC 0/0 from the fast information block (FIB) transmitted through the FIC data. The ETI frame controller 140 sets the first detected CIF counter value of the FIC 0/0 as the initial value of the CIF counter. A CIF counter timer 141 of the ETI frame controller 140 increases the CIF counter value by 1 for each ETI frame. In this case, the ETI frame controller 140 can increase the value of the CIF counter every 24 ms, which corresponds to the transmission period of the ETI frame, using the reference clock signal of 2.048 MHz. The FIC 0/0 is transmitted once for each unit of 4 ETI frames, and FIG 0/0 is in the first position of the first fast information block from the three fast information blocks (FIB) of the transmitted ETI frame. . In this case, the ETI frame controller 140 can check the continuity of the ETI frame by comparing the value of the CIF counter and the frame counter (FCT) or by comparing the CIF counter value and the frame phase (FP). ). The frame counter (FCT) and the frame phase (FP) can be obtained from the frame characterization (FC). In addition, the ETI frame controller 140 can check the continuity of the ETI frame by comparing the CIF counter value each time the FIC 0/0 is detected.

When the ETI frame or the reception of the ETI signal comprises an error, the CIF counter synchronizer 141 increases the value of the CIF counter by 1 from the value of the CIF counter finally synchronized, this operation can be done every 24 hours. ms, which corresponds to the transmission period of the ETI frame. Therefore, the continuity of the ETI frame can be maintained when the ETI signal is disconnected or the ETI frame has generated an error during its transmission.

In this case, a frame characterization corrector 142 of the ETI 140 frame controller corrects the frame characterization (FC) using the value of the CIF counter synchronized by the CIF 141 counter synchronizer. For example, the frame characterization (FC) includes the frame counter (FCT) and the frame phase (FP). The frame counter (FCT) and the frame phase (FP) can be corrected from Equation 1 and Equation 2. In addition, when the synchronized CIF counters are 0, 4, 8, .. ., 4996, a corrector of FIG 0/0143 of the ETI 140 frame controller corrects the value of the CIF counter of the corresponding FIG 0/0 by the value of the synchronized CIF counter and performs a CRC on the fast information block (FIB) to transmit the FIG 0/0. When the ETI frame controller 140 transmits the corrected frame characterization (FC) and the fast information block (FIB) to the ETI frame generator 150, the ETI frame generator 150 uses these to generate a new ETI frame. The embodiments described above can be realized through a program for performing functions corresponding to the configuration of these embodiments or a recording medium for recording the program, as well as through device and / or method described above, easily achievable by the skilled person. Although the present invention has been described in light of certain particular embodiments, it should be understood that the invention is not limited to the described embodiments but is intended to, on the contrary, cover different modifications and arrangements. equivalents within the spirit and scope of the appended claims.

Claims (17)

REVENDICATIONS1. A method for producing an ensemble transport interface (ETI) of a digital media broadcast, comprising the steps of: receiving an ETI signal; sequentially converting the ETI signal into a plurality of ETI frames; searching for an error in each ETI frame; recording frame information on the error-free ETI frame from the plurality of ETI frames; generating a new ETI frame for replacing the erroneous ETI frame from the plurality of ETI frames, using the frame information; and generating the ETI signal using the error-free ETI frame and the new ETI frame. The method of claim 1, wherein the ETI signal is a network independent layer (NI) signal or a network adaptation layer (NA), and the ETI frame is a frame of a logical interface layer (LI). The method of claim 1, wherein the frame information comprises at least one of Frame Characterization (FC), Stream Characterization (STC), and Fast Information Channel (FIC) data. The method of claim 1, wherein searching for an error in each ETI frame is to look for an error by analyzing a cyclic redundancy check (CRC) value of the ETI frame. 5. Method according to claim 1, wherein the search for an error in the ETI frame comprises the step consisting when the received ETI signal has an error, to determine that the ETI frame corresponding to the part in which the error occurred in the received ETI signal is erroneous. The method of claim 5, wherein the error in the received ETI signal is sought by means of an ETI signal receiving state and a synchronization detection state. The method of claim 1, wherein generating a new ETI frame comprises the steps of: acquiring a common interlaced frame (CIF) counter value synchronized with the erroneous ETI frame; Acquiring a frame characterization and a fast information block for a new ETI frame from the Common Interleaved Frame (CIF) counter value; and generating the new ETI frame using the frame characterization and the fast information block. The method of claim 7, wherein acquiring the value of the synchronized common CIF interleaved counter includes the steps of: setting an initial value of the CIF common interleaved frame counter from the frame information; and increasing the value of the CIF common interlaced frame counter by 1 for each ETI frame period using a reference clock. The method of claim 1, wherein generating an ETI signal comprises the step of synchronizing the received ETI signal using the reference clock and the generated ETI signal. A device (100) for producing an ensemble transport interface (ETI) of a digital media broadcast, comprising: an ETI signal input unit (110) for receiving an ETI signal and for converting sequentially the ETI signal into a plurality of ETI frames; an ETI frame analyzer (120) for searching for an error in each ETI frame; an ETI frame controller (140) for recording frame information on the error-free ETI frame from the plurality of ETI frames, and extracting information for generating a new ETI frame for replacing the errored ETI frame from the plurality of ETI frames from the frame information; an ETI frame generator (150) for generating the new ETI frame using the information retrieved by the ETI frame controller (140); andan ETI signal output unit (160) for producing an ETI signal using the error-free ETI frame and the new ETI frame. Apparatus according to claim 10, wherein the frame information comprises at least one of Frame Characterization (FC), Stream Characterization (SIC), and Fast Information Channel (FIC) data. 10 The apparatus of claim 10, wherein the ETI frame analyzer (120) searches for an error by analyzing the cyclic redundancy check (CRC) value of each ETI frame or by checking a receive state and a state of contention. ETI signal synchronization detection. The apparatus of claim 10, wherein the ETI frame controller (140) acquires a common interlaced frame (CIF) counter value synchronized with the errored ETI frame using the frame information, and retrieves information that enables to generate the new ETI frame from the value of the common CIF interlaced field counter. The apparatus of claim 13, wherein the information for generating the new ETI frame comprises at least one of a frame characterization and a fast information block applicable to the new ETI frame. The apparatus of claim 10, further comprising an ETI frame buffer (130) for storing the error-free ETI frame and the new ETI frame, and for sequentially transmitting the error-free ETI frame and the new frame. ETI to the ETI signal output unit (160). The apparatus of claim 15, wherein the ETI frame generator (150) transmits the new ETI frame to the ETI frame buffer (130) based on an output control signal of the new ETI frame. The apparatus of claim 10, wherein the signal output unit (160) synchronizes the ETI signal received by the ETI signal input unit (110) and the generated ETI signal using a reference clock. .