KR20110065152A - Method and apparatus for outputing ensemble transport interface in digital multimedia broadcast - Google Patents

Abstract

PURPOSE: An ensemble transport interface output method and device of digital multimedia broadcasting are provided to consecutively keep ETI output even when a broadcasting signal is disconnected or an error thereof occurs. CONSTITUTION: An ETI(Ensemble Transport Interface) signal input unit(110) receives an ETI signal from an ETI signal source. An ETI frame analysis unit(120) analyzes the CRC(Cyclic Redundancy Check) values of an ETI frame and the configuration of the ETI frame. An ETI frame management unit(140) stores ETI frame information having not error which is recently received. An ETI frame generation unit(150) transfers a generated EIT frame to an ETI frame buffer(130). An ETI signal output unit(160) outputs the ETI frame received from the ETI frame buffer as the ETI signal.

Description

METHOD AND APPARATUS FOR OUTPUTING ENSEMBLE TRANSPORT INTERFACE IN DIGITAL MULTIMEDIA BROADCAST}

The present invention relates to an ETI (Ensemble Transport Interface) output method and apparatus for digital multimedia broadcasting.

The present invention is derived from a study conducted as part of the IT growth engine technology development of the Ministry of Knowledge Economy [Task Management Number: 2006-S-017-04, Task name: Development of terrestrial DMB transmission advancement technology].

Terrestrial Digital Multimedia Broadcasting (“Terrestrial DMB”) adds a standard for providing video services to the European Eureka-147 Digital Audio Broadcasting (DAB) system. Provides a variety of multimedia services including data, audio and video. In general, the terrestrial DMB transmits a plurality of services provided from a plurality of service providers through one terrestrial DMB channel. The ensemble multiplexer generates a signal (hereinafter, referred to as an ETI frame) of an Ensemble Transport Interface (ETI) standard obtained by multiplexing a plurality of services. The ETI frame is delivered to the transmitting device through the ETI network.

The transmitting device generates a transmission frame by encoding data of the ETI frame by forward error correction (FEC), and encodes the transmission frame by a coded orthogonal frequency division multiplexing (COFDM) method to transmit the terrestrial DMB frequency band to the receiving device.

On the other hand, due to poor broadcast conditions, the signal may be cut off or an error may occur in the signal. At this time, there is a need for a method of continuously maintaining the output of the ETI so that the transmission flow is not interrupted.

The technical problem to be achieved by the present invention relates to a method and apparatus for continuously outputting the ETI.

An ensemble transport interface (ETI) output method of a digital multimedia broadcasting according to an aspect of the present invention comprises the steps of: receiving an ETI signal, converting the ETI signal into a plurality of ETI frames in sequence, and errors in each ETI frame Confirming, storing frame information of an error-free ETI frame among the plurality of ETI frames. Generating a new ETI frame to replace a faulty ETI frame among the plurality of ETI frames using the frame information, and outputting an ETI signal using the error-free ETI frame and the new ETI frame. do.

An ensemble transport interface (ETI) output device for digital multimedia broadcasting according to an aspect of the present invention receives an ETI signal and converts the ETI signal into a plurality of ETI frames in sequence, each of which has an ETI frame. An ETI frame analyzer which checks an error, stores frame information of an error-free ETI frame among the plurality of ETI frames, and generates a new ETI frame that replaces an error ETI frame among the plurality of ETI frames from the frame information. An ETI frame management unit for extracting information for performing the information, an ETI frame generation unit for generating the new ETI frame using information extracted by the ETI frame management unit, and an ETT signal using the error-free ETI frame and the new ETI frame. And an output ETI signal output unit.

The present invention can provide a method and apparatus for continuously maintaining an ETI output even when a signal is broken due to poor broadcast conditions or an error occurs in the signal. If the ETI output is continuously maintained, the radio signal transmission and reception between the transmitting device and the receiving device can be maintained without interruption. Therefore, the operation of the broadcasting system may not be overwhelmed.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

1 is a diagram schematically illustrating a hierarchical structure of an ETI according to an embodiment of the present invention.

Referring to FIG. 1, the hierarchical structure of the ETI is defined as a Logical Interface (LI) layer, a Network Independent (NI) layer, and a Network Adaptation (NA) layer. The LI layer is a basic logical structure that defines basic information for generating an ensemble. The NI layer is the physical interface layer that maps the LI layer and contains the basic interface to ETI-related devices. The NA layer is a physical interface layer that can be used in an error-prone network environment compared to the NI layer, and has a structure mapped to the LI layer. The LI layer, the NI layer, and the NA layer are interconvertible, and the LI layer, which is the core data part, is the same.

2 is a diagram illustrating a frame structure of an LI layer among the hierarchical structures of an ETI according to an embodiment of the present invention.

Referring to FIG. 2, a frame of the LI layer (hereinafter, referred to as an "ETI (LI) frame") includes a state (STATus, STAT) field and a logical interface data (LIDATA) field. The STAT field includes an Error (ERR) status field, and the Error Status field carries information on the error status of the ETI (LI) frame. The logical interface data (LIDATA) field includes a header and a payload. The header includes a Frame Characterization (FC) field, a Stream Characterization (STC) field, and a Header End of Header (EOH) field. The payload includes a Main Stream Data (MST) field, an End of Frame (EOF) field, and a Time Stamp (TIST) field.

The Frame Status (FC) field of the header includes Frame Count (FCT), Fast Information Channel Flag (FICF), Number of Streams (NST), Frame Phase (FP), Mode Identity (MID) and Frame Length (FL). The Stream Characteristic (STC) field includes a plurality of SubStream Characterizations (SSTCs), each representing the characteristics of the plurality of data streams. The header end (EOH) field includes a Multiple Network Signaling Channel (MNSC) and a Header Cyclic Redundancy Check (CRC _h ).

The frame characteristic (FC) field transmits a general data characteristic applied to a frame corresponding to the entire LI layer. Among the frame characteristic (FC) fields, the frame number FCT has a value of 0 to 249 corresponding to the number of common interleaved frames (CIFs). Here, at least one CIF is included in a main service channel (MSC) of a transport frame and corresponds to at least one main stream data (MST) field. The fast information channel flag FICF indicates whether FIC data exists in the main stream data (MST) field. The stream number NST carries information on the number of data streams for information that can be transmitted by the stream characteristic (STC) field and the main stream data (MST) field. The frame phase FP includes transmitter identification information required for COFDM modulation. Mode identification (MID) includes information for mode identification required for COFDM modulation. The frame length FL represents the length of each of the stream characteristic (STC) field, frame end (EOF) field and main stream data (MST) field.

In the header field, the stream characteristic (STC) field indicates information on characteristics of the plurality of subchannel data streams corresponding to the main stream data (MST) field, respectively. That is, the stream characteristic (STC) field includes a plurality of substream features (SSTC), and the plurality of SSTCs respectively correspond to a plurality of stream subchannels of the main stream data (MST) field. Each of the plurality of SSTCs includes a subchannel identification (SCID), a start address (Start Address, SAD), a protection level (TPL), and a stream length (STL) field. In any SSTC, subchannel identification (SCID) represents information for identification indicating a stream subchannel. The start address (SAD) represents the start address of the stream subchannel, and the protection level (TPL) represents information about the protection level and type of the stream subchannel. The stream length (STL) represents the length of the stream subchannel.

The multiple network signaling channel (MNSC) in the header end (EOH) field represents the signaling channel between the ensemble multiplexer and the sending device. The header cyclic redundancy check (CRC _h ) indicates information necessary for cyclic redundancy checking of the frame characteristic (FC) field, the stream characteristic (STC) field, and the multiple network signaling channel.

The main stream data (MST) field of the payload includes at least one fast information channel (FIC) data and a plurality of streams Stream1 to StreamNST. The frame end (EOF) field includes a Cyclic Redundancy Check (CRC) and a Reserved (Rfu).

In the main stream data (MST) field, the FIC data may be present from the fast information channel flag (FICF) and represent uncoded fast information channel data. The plurality of stream subchannels Stream1 to StreamNST are each allocated to transmit a plurality of streams corresponding to the plurality of services, respectively.

Cyclic redundancy check (CRC) in the EOF field indicates information necessary for circular redundancy check in the mainstream data (MST) field, and reserved (Rfu) is a spare resource prepared in advance.

The TIST field indicates information required for transmission of a transmission frame corresponding to the corresponding ETI (LI) frame.

The ETI frame described above is transmitted to the transmitting apparatus through the ETI network. The transmitting apparatus generates a transmission frame by performing FEC coding and COFDM modulation of the data of the ETI frame, and transmits the transmission frame to the receiving apparatus.

3 is a diagram illustrating a structure of a transmission frame according to an embodiment of the present invention.

Referring to FIG. 3, the transport frame includes a synchronization channel (SC), a fast information channel (FIC), and a main service channel (MSC).

The synchronization channel (SC) is a channel for transmitting decoding information on digital communication, and has a predetermined form so that the terrestrial DMB receiving apparatus can recognize that the frame is at the beginning.

The fast information channel (FIC) provides information on which common interleaved frame (CIF) data is transmitted in the main service channel (MSC) and information required by a receiving device to receive terrestrial DMB. send. The fast information channel (FIC) includes at least one fast information block (FIB).

The main service channel (MSC) is a channel through which actual data is transmitted. The main service channel (MSC) includes at least one common interleaved frame (CIF).

On the other hand, the structure and length of the transmission frame is determined according to the transmission mode (Transmission mode). In the terrestrial DMB system, a fast information block (FIB) and a common interleaved frame (CIF) are introduced to provide a transmission mode regardless of the type of data transmitted through the fast information channel (FIC) and the main service channel (MSC). That is, data is transmitted in units of a fast information block (FIB) or a common interleaved frame (CIF) regardless of a transmission mode. However, only the number of fast information blocks (FIB) and common interleaved frames (CIF) input according to the transmission mode are set differently.

Table 1 shows an example of the configuration of the transmission frame for each transmission mode of the terrestrial DMB system.

Referring to Table 1, the transmission mode I is a transmission mode for digital broadcasting having a single frequency network. The fast information channel (FIC) includes 12 fast information blocks (FIBs), and the main service channel (MSC) is 4 It includes two common interleaved frame (CIF), the total length of the transmission frame is 96ms. Transmission mode II is a transmission mode for digital broadcasting with a multi-frequency network. The fast information channel (FIC) includes three fast information blocks (FIB), and the main service channel (MSC) is one common interleaved frame (CIF). The total length of the transmission frame is 24 ms. Transmission mode III is a transmission mode for digital broadcasting with a cable network. The fast information channel (FIC) includes four FIBs, and the main service channel (MSC) includes one common interleaved frame (CIF). The total length of the frame is 24ms. Transmission mode IV is a transmission mode for digital broadcasting with a terrestrial / satellite mixed network. The fast information channel (FIC) includes six fast information blocks (FIBs), and the main service channel (MSC) has two common interleaved frames. Including (CIF), the total length of the transmission frame is 48 ms.

The ETI frame is 6144 bytes in size and is transmitted every 24ms. In addition, the ETI frame is transmitted to the transmitting apparatus in three fast information blocks (FIBs), each of which is 32 bytes, through the FIC data. Therefore, in transmission mode I, four ETI frames are transmitted in one transmission frame every 96 ms. In addition, one fast information channel (FIC) is FEC applied, and includes 12 FIBs of 32 bytes each.

4 is a diagram illustrating a structure of a fast information block (FIB) according to an embodiment of the present invention.

Referring to FIG. 4, a fast information block (FIB) includes a 30-byte FIB data field and a 2-byte CRC. The FIB data field includes at least one fast information group (FIG), an end marker, and a padding byte. The fast information group (FIG) is a unit for loading information, the end marker includes end information of the fast information group (FIG), and the padding byte is a spare area for matching a fixed length (30 bytes) of the FIB data field. The fast information group (FIG) includes a FIG header and a FIG data field. The length of the fast information group (FIG) is variable, but cannot exceed 30 bytes including the FIG header, and one fast information group (FIG) can not be divided into two or more fast information blocks (FIB) and transmitted. The FIG header includes FIG type and extension information, and the FIG data field includes a base of multiplex configuration information (MCI) and service information (SI), for example, time and date. Service information, labels for display, other information for defining labels, and the like.

5 is a view showing the structure of FIG 0/0 according to an embodiment of the present invention.

Referring to FIG. 5, FIG 0/0 means a case in which the FIG type is 0 and the extension field is zero. FIG 0/0 carries ensemble information. FIG 0/0 includes a CIF Count. The CIF count includes the upper five bits (b ₁₂ -b ₈ ) and the lower eight bits (b ₇ -b ₀ ). The lower 8 bits are modulo-250 lower counters 0 through 249, and the upper 5 bits are modulo-20 counters 0 through 19. The CIF count is a modulo-5000 counter that increments by 1 in the range of 0 to 4999. The relationship between the CIF count and the frame number (FCT) is expressed by Equation 1 below, and the relationship between the CIF count and the frame phase (FP) is expressed by Equation 2

FCT = CIF Count% 250

Here, the frame number FCT is equal to the modulo-250 lower counter, which is the lower 8 bits of the CIF count.

FP = CIF count% 8

The transmission position and transmission period of FIG 0/0 may be fixed. For example, when in transmission mode I in Table 1, FIG 0/0 is located at the beginning of the fast information channel (FIC) of every transmission frame. That is, FIG 0/0 is transmitted once every four ETI frames, and the transmission position of FIG 0/0 is in an ETI frame including a CIF having a CIF count value corresponding to 0, 4, 8, ..., 4996. It is located at the very beginning of the first FIB.

In this case, it is possible to determine whether the ETI frames are randomly continuous by using the CIF count in FIG 0/0 transmitted once every four ETI frames, the continuity of the frame number FCT and the frame phase FP of each ETI frame.

6 is a diagram illustrating an ETI output device 100 according to an embodiment of the present invention. Hereinafter, the ETI signal means an ETI (NA) signal or an ETI (NI) signal, and the ETI frame means an ETI (LI) frame. The ETI input unit 110 and the ETI output unit 160 can process both an ETI (NA) signal and an ETI (NI) signal, and convert the ETI (NA) signal and the ETI (NI) signal into an ETI (LI) frame. Assume that it can be done.

Referring to 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 reception 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 ETI signal reception state, the synchronization detection state, and the ETI frame to the ETI frame analyzer 120.

The ETI frame analyzer 120 analyzes the CRC values of the ETI frame and the configuration of the ETI frame to check an error of the ETI frame. In addition, the ETI frame analyzer 120 determines whether there is a break or an error in receiving the ETI signal using the ETI signal reception state and the synchronization detection state received from the ETI signal input unit 110.

When the ETI frame analyzer 120 determines that there is no error in receiving the ETI frame and the ETI signal, the ETI frame analyzer 120 transmits the ETI frame to the ETI frame buffer 130 and delivers the error-free ETI frame information to the ETI frame manager 140. . The ETI frame information may be at least one of frame characteristic (FC), stream characteristic (STC), and fast information channel (FIC) data.

The ETI frame manager 140 stores the ETI frame information without error most recently received from the ETI frame analyzer 120. For example, the ETI frame manager 140 stores a fast information block (FIB) transmitted through frame characteristics (FC), stream characteristics (STC), and fast information channel (FIC) data of an error-free ETI frame. At this time, some of the fast information blocks (FIB) include FIG 0/0 for transmitting the ensemble information, FIG 0/0 includes the CIF count. The ETI frame manager 140 manages the CIF count and provides information for the ETI frame generator 150 to generate a new ETI frame.

On the other hand, when the ETI frame analyzer 120 determines that there is an error in receiving the ETI frame or the ETI signal, the ETI frame generator 150 generates a new ETI frame. The ETI frame generator 150 receives information for generating a new ETI frame from the ETI frame manager 140 and generates a new ETI frame using the information. In this case, the ETI frame analyzer 120 may directly transmit an error in the corresponding ETI frame to the ETI frame generator 150, or may transmit the ETI frame generator 150 to the ETI frame generator 150 through the ETI frame manager 140. It is not limited to this. The ETI frame generation unit 150 may generate a new ETI frame by filling arbitrary data to fit the size of each subchannel. The ETI frame generation unit 150 may generate a new ETI frame as a stream indicating that the broadcast is to be waited in an abnormal state, for example, due to a broadcast accident.

The ETI frame generator 150 transmits the generated ETI frame to the ETI frame buffer 130. In this case, the ETI frame generator 150 may transfer the generated ETI frame to the ETI frame buffer 130 according to the control signal of the ETI frame analyzer 120. The control signal of the ETI frame analyzer 120 may include information for controlling the output from 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 received from the ETI frame analyzer 120 and the generated ETI frame received from the ETI frame generator 150, and the ETI frame without errors and the generated ETI. The frame is transmitted to the ETI signal output unit 160 so as to continue the frame. The ETI frame buffer 130 uses 6144 bytes, which is the length of one ETI frame, as a basic unit. The size of the ETI frame buffer 130 may be set to store 2 ETI frames or 3 ETI frames, but is not limited thereto.

The ETI signal output unit 160 processes the ETI frame received from the ETI frame buffer 130 and outputs the ETI signal. In this case, the ETI signal output unit 160 may output an ETI frame as an ETI signal using a reference clock of 2.048 MHz. Here, the reference clock of 2.048 MHz may be synchronized with the ETI signal input to the ETI signal input unit 110. For example, when the ETI signal received by the ETI signal input unit 110 is generated using the GPS, a reference clock of 2.048 MHz may also be generated using the GPS. When the reference clock and the input ETI signal are synchronized, the ETI frame buffer 130 may be prevented from overflowing or emptying, thereby ensuring a continuous output of the ETI signal. The reference clock of 2.048 MHz may be used as a reference for generating one ETI frame in units of 24 ms in the ETI frame manager 140 and the ETI frame generator 150 as well as the ETI signal output unit 160.

In order to continuously output the ETI even when there is an error in receiving the ETI signal or there is an error in the ETI frame, the ETI frame generator 150 generates a new ETI frame to replace the defective ETI frame. To this end, the ETI frame manager 140 provides information for causing the ETI frame generator 150 to generate an ETI frame.

7 illustrates an operation of the ETI frame manager 140 according to an embodiment of the present invention.

Referring to FIG. 7, the ETI frame manager 140 operates a CIF count synchronized with the ETI frame. To this end, the ETI frame manager 140 obtains error-free ETI frame information from the ETI frame analyzer 120. The error free ETI frame information may be at least one of a frame property (FC), a stream property (STC), and FIC data of an error free ETI frame.

The ETI frame manager 140 detects a CIF count value of FIC 0/0 from the fast information block (FIB) transmitted through the FIC data. The ETI frame manager 140 sets the first CIF count value of FIC 0/0 detected as the initial CIF count value. The CIF count synchronizer 141 in the ETI frame manager 140 increments the CIF count value by one for every ETI frame. In this case, the ETI frame manager 140 may increase the CIF count value every 24 ms, which is a transmission period of the ETI frame, by using a reference clock of 2.048 MHz.

FIC 0/0 is transmitted once every four ETI frames, and is located at the beginning of the first fast information block among the three fast information blocks (FIBs) of the ETI frame in which FIG 0/0 is transmitted. In this case, the ETI frame manager 140 may check the continuity of the ETI frame by comparing the CIF count value and the frame number FCT or by comparing the CIF count value and the frame phase FP. The number of frames FCT and the frame phase FP can be known from the frame characteristics FC. Alternatively, the ETI frame manager 140 may check the continuity of the ETI frame by comparing the CIF count value whenever FIC 0/0 is detected.

When an error occurs in receiving an ETI frame or an ETI signal, the CIF count synchronizer 141 increases the CIF count value by one from the last synchronized CIF count value. This may be done every 24ms, which is the transmission period of the ETI frame. Accordingly, even when the ETI signal is interrupted or an error occurs in the ETI frame during transmission, the continuity of the ETI frame can be maintained.

At this time, the frame characteristic corrector 142 of the ETI frame manager 140 modifies the frame characteristic FC using the CIF count value synchronized by the CIF count synchronizer 141. For example, the frame characteristics FC are the number of frames FCT and the frame phase FP. The frame number FCT and the frame phase FP may be modified based on Equations 1 and 2 below. Also, the FIG 0/0 correction unit 143 of the ETI frame management unit 140 synchronizes the CIF count value of the FIG 0/0 when the synchronized CIF count is 0, 4, 8, ..., 4996. Modify to the CIF count value and perform CRC on the fast information block (FIB) to which FIG 0/0 is transmitted.

When the ETI frame manager 140 transmits the modified frame characteristics FC and the fast information block FIB to the ETI frame generator 150, the ETI frame generator 150 generates a new ETI frame using the same. Can be.

The embodiments of the present invention described above are not only implemented through the apparatus and the method, but may be implemented through a program for realizing a function corresponding to the configuration of the embodiments of the present invention or a recording medium on which the program is recorded.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

1 is a diagram schematically illustrating a hierarchical structure of an ETI according to an embodiment of the present invention.

2 is a diagram illustrating a frame structure of an LI layer among the hierarchical structures of an ETI according to an embodiment of the present invention.

3 is a diagram illustrating a structure of a transmission frame according to an embodiment of the present invention.

4 is a diagram illustrating a structure of a fast information block (FIB) according to an embodiment of the present invention.

5 is a view showing the structure of FIG 0/0 according to an embodiment of the present invention.

6 is a diagram illustrating an ETI output device 100 according to an embodiment of the present invention.

7 illustrates an operation of the ETI frame manager 140 according to an embodiment of the present invention.

Claims (17)

In the ensemble transport interface (ETI) output method of digital multimedia broadcasting, Receiving an ETI signal; Sequentially converting the ETI signals into a plurality of ETI frames; Checking an error of each ETI frame; Storing frame information of an error-free ETI frame among the plurality of ETI frames; Generating a new ETI frame to replace an erroneous ETI frame among the plurality of ETI frames using the frame information; And Outputting an ETI signal using the error free ETI frame and the new ETI frame. The method of claim 1, The ETI signal is a signal of a Network Independent (NI) layer or a Network Adaptation (NA) layer. The ETI frame is a frame of the LI (Logical Interface) layer. The method of claim 1, The frame information includes at least one of frame characterization (FC), stream characterization (STC), and fast information channel (FIC) data. The method of claim 1, Checking the error of each ETI frame, And analyzing the Cyclic Redundancy Check (CRC) value of each ETI frame to identify an error. The method of claim 1, Checking the error of the ETI frame, If there is an error in receiving the ETI signal, ETI output method comprising the step of determining that there is an error in the ETI frame corresponding to the error portion of the ETI signal. The method of claim 5, The error in the reception of the ETI signal is confirmed using the reception state and the synchronization detection state of the ETI signal. The method of claim 1, Generating the new ETI frame, Obtaining a common interleaved frame (CIF) count value synchronized with the faulty ETI frame; Obtaining a frame characteristic and fast information block for a new ETI frame from the CIF count value; And Generating the new ETI frame using the frame characteristic and the fast information block. The method of claim 7, wherein Obtaining the synchronized CIF count value, Setting an initial CIF count value from the frame information; And And incrementing the CIF count value by one in units of ETI frame periods using a reference clock. The method of claim 1, The outputting of the ETI signal may include: ETI output method comprising the step of synchronizing the received ETI signal and the output ETI signal using a reference clock. In the ensemble transport interface (ETI) output device of digital multimedia broadcasting, An ETI signal input unit which receives an ETI signal and sequentially converts the ETI signal into a plurality of ETI frames; An ETI frame analyzer for checking an error of each ETI frame; An ETI frame management unit that stores frame information of an error-free ETI frame among the plurality of ETI frames, and extracts information for generating a new ETI frame that replaces an errored ETI frame among the plurality of ETI frames from the frame information. ; An ETI frame generator for generating the new ETI frame using information extracted by the ETI frame manager; And And an ETI signal output unit configured to output an ETT signal using the error free ETI frame and the new ETI frame. 11. The method of claim 10, The frame information includes at least one of frame characterization (FC), stream characterization (STC), and fast information channel (FIC) data. 11. The method of claim 10, The ETI frame analyzer checks an error by analyzing a cyclic redundancy check (CRC) value of each ETI frame or checking a reception state and a synchronization detection state of the ETI signal. 11. The method of claim 10, The ETI frame manager obtains a common interleaved frame (CIF) count value synchronized with the faulty ETI frame using the frame information, and extracts information for generating the new ETI frame from the CIF count value. Device. The method of claim 13, And the information for generating the new ETI frame includes at least one of a frame characteristic and a fast information block to be applied to the new ETI frame. 11. The method of claim 10, And an ETI frame buffer which stores the error free ETI frame and the new ETI frame and delivers the error free ETI frame and the new ETI frame to the ETI signal output to continue. The method of claim 15, And the ETI frame generator transfers the new ETI frame to the ETI frame buffer according to the new ETI frame random output control signal. 11. The method of claim 10, And the signal output unit synchronizes an ETI signal received from the ETI signal input unit with an ETI signal to be output using a reference clock.

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