KR100542973B1 - Apparatus and method for using time division multiplexing path in satellite digital multimedia broadcastng system a - Google Patents

Abstract

The present invention relates to a digital multimedia broadcasting system using a satellite.

The satellite broadcasting system according to the present invention receives a predetermined multimedia data and control signals for broadcasting, generates a transmission signal of orthogonal frequency division multiplexing and time division multiplexing, and transmits it through upband. Transmit and transmit orthogonal frequency division multiplexing signal from 2.6 GHz band, and transmit time division multiplexing signal through predetermined downlink band, and time division multiplexing signal received from satellite is 2.6 GHz And a receiver receiving a signal from a satellite or a gap filler and converting the signal into a band orthogonal frequency division multiplexing signal.

Satellite Broadcasting System, DAB, DMB, Gap Filler

Description

Apparatus and method using time-division multiplexing path in satellite digital multimedia broadcasting system A {APPARATUS AND METHOD FOR USING TIME DIVISION MULTIPLEXING PATH IN SATELLITE DIGITAL MULTIMEDIA BROADCASTNG SYSTEM A}

1 is a configuration diagram of a system A scheme currently being considered as a satellite DMB system.

2 shows the structure of an OFDM transmission frame for generating an OFDM signal as defined in ETS 300 401.

3 is a block diagram of a satellite broadcasting system proposed in the present invention.

4 is a block diagram showing an embodiment of the transmission apparatus shown in FIG.

5 is a data frame diagram of a TDM scheme defined in ETS 300 421.

FIG. 6 is a diagram illustrating a relationship between an OFDM transmission frame as shown in FIG. 2 and a TDM transmission frame in units of 187 bytes.

FIG. 7 is a block diagram illustrating an embodiment of an OFDM-TDM converter included in the transmitter of FIG. 4.

FIG. 8 (a) shows a structure of a TDM transmission frame generated by using the first combination method proposed by the present invention for a plurality of different OFDM transmission frames, and FIG. 8 (b) shows a plurality of different OFDM transmission frames. It shows the structure of the TDM transmission frame generated by using the second combination method proposed in the present invention.

FIG. 9 is a block diagram illustrating an embodiment of a gap filler for receiving a TDM signal, converting it to an OFDM signal, and transmitting the same.

FIG. 10 is a block diagram illustrating an embodiment of a TDM-OFDM converter used for the gap filler of FIG. 9.

The present invention relates to a digital multimedia broadcasting (DMB) system using satellites.

Satellite DMB refers to a broadcasting service that enables satellites to receive high-quality audio, data such as traffic information, weather, games, and videos such as movies and sports through the mobile station through satellites using the 1400-2700 MHz frequency band. . Conventionally, digital audio broadcasting (hereinafter referred to as DAB: Digital Audio Broadcasting) has been called, but recently referred to as DMB in order to utilize the characteristics of mobile multimedia broadcasting.

Satellite DMB is still in its early stages in the world. Worldspace has been serving Asia and Africa since 1998. In the US, XM has been in service since September 2001 and Sirius has been in service since February 2002. Started. Europe and Japan plan to launch services in 2005 and 2004, respectively. The International Telecommunication Union (ITU) recommends systems A, B, D _H , and E in the ITU-R BO.1130-4 standard for satellite broadcasting. The company employs the system, and Sirius currently uses the System D _H method to deliver its services.

In general, in satellite broadcasting or satellite communication using a satellite, communication is possible only when a line of sight (LOS) is guaranteed. That is, when the line of sight is disturbed by the feature, an area of poor quality of the communication service through the satellite occurs. Such poor reception conditions are called gaps, and a system that relays signals from satellites and retransmits them to a receiver to improve reception conditions in these areas is called a gap filler. In order to provide uninterrupted service even when the receiver is moving, it requires a gap filler to eliminate gaps in addition to satellites. Therefore, when constructing satellite DMB, it is necessary to use a frequency suitable for a mobile service to ensure the mobility of a receiver, and to establish a gap filler system on the ground to ensure mobile reception. In addition, fading due to multipath propagation caused by the movement of the receiver must be overcome. Current technologies suitable for a multipath environment include orthogonal frequency division multiplexing (OFDM) and code division multiplexing (CDM). The OFDM scheme is applied to the system A scheme currently being used for the DAB service in Europe, and a more detailed description thereof is defined in the European telecommunication standard (hereinafter, ETS: European Telecommunication Standard).

System A is also called the Eureka-147 system, which provides services using the 30 MHz to 3 GHz frequency band and includes both terrestrial and satellite broadcasts. In 1985, the study of DAB began in 1985, and in 1987, the allied project Eureka-147, which studied DAB in Europe, was standardized in February 1995. A number of European countries, including the UK, have begun using terrestrial DAB services since 1995 using the System A approach to today. In Korea, the company is planning to launch a DMB service based on the system A method and applying video processing technology to it in 2004. In addition, Korea is considering the world's first satellite DMB service using System A in the 2.6 GHz band.

1 is a configuration diagram of a system A scheme currently being considered as a satellite DMB system. The frequency used here considers only the 2.6 GHz band.

As shown in FIG. 1, in the satellite DMB system based on the system A scheme, an OFDM scheme signal using a Ku-band is transmitted from the ground station transmitter 102 to the satellite 104. In 104, the OFDM 106 signal in the 2.6 GHz band is transmitted to the receiver 106 and the gap filler 108, and the gap filler 108 also transmits an OFDM signal to the receiver 106. The receiver 106 receives a good signal between the OFDM signal from the satellite 104 and the OFDM signal from the gap filler 108.

2 shows a structure of an OFDM transmission frame (OFDM_TF) for generating an OFDM signal as defined in ETS 300 401. As shown in FIG. 2, an OFDM transmission frame (OFDM_TF) includes a synchronization channel (SC), a fast information channel (FIC), and a main service channel (MSC). T _F is a parameter indicating the width of a transmission frame)

The Sync Channel (SC) is used for basic demodulation functions such as Transmission Frame Synchronization, Automatic Frequency Control, Channel State Estimation, and Transmitter Identification in the transmission system. Used internally, the Fast Information Channel (FIC) is used for quick access of information by the receiver and the Main Service Channel (MSC) is used for the transmission of voice and service data. Each channel is composed of a number of symbols. The synchronization channel SC is composed of a null symbol (N_S) and a phase reference symbol (PR_S), and a fast information channel (Sybol). FIC) and the main service channel (MSC) are a plurality of OFDM symbols (OFDM_S) consisting of a guard interval 202 and a pure signal portion 204 of OFDM symbols. It includes.

On the other hand, ETS 300 401 defines four transmission modes (MODE I, MODE II, MODE III, MODE IV) for transmitting the DMB broadcast signal. The first transmission mode (MODE I) is a terrestrial single frequency in the first frequency band (47 to 68 MHz, TV), the second frequency band (87.5 to 108 MHz, FM radio), and the third frequency band (174 to 230 MHz). Used for single frequency network (SFN) and local broadcasting. Both terrestrial DABs in Europe and terrestrial DMBs in Korea will use the first transmission mode. The second and fourth transmission modes MODE II and MODE IV are terrestrial waves in the first to third frequency bands, the fourth and fifth frequency bands (470 to 860 MHz, UHF), and the L-band (1452 to 1492 MHz). It is used for local broadcasting and L-band is used for satellite alone or satellite / terrestrial combined broadcasting. The third transmission mode (MODE III) is used for terrestrial, satellite, and satellite / terrestrial hybrid broadcasting of 3 GHz or less. Satellite DMB using the 2.6 GHz frequency band corresponds to the third transmission mode.

Occupied BW (Bandwidth) in each transmission mode is the same as 1.536 MHz, and the DMB signal occupying the 1.536 MHz band is called an ensemble, and in the case of a broadcast service using multiple ensemble, Considering the guard band, it is enough to use a frequency band of 2 MHz per ensemble. In Korea's terrestrial DMB, the TV channel band 6 MHz is used, and there are three ensembles each with 2 MHz, with the guard band being relaxed. In the satellite DMB in the 2.6 GHz band, there is a frequency bandwidth of 25 MHz. By applying the minimum necessary guard band, up to 14 ensembles can be used. In the third transmission mode, total data constituting the OFDM transmission frame (OFDM_TF) shown in FIG. 2 is 7344 bytes.

In the satellite DMB system of the system A method shown in FIG. 1 using the OFDM signal as described above, the gap filler receives the OFDM signal of the 2.6 GHz band from the satellite, amplifies it, and transmits the signal to the receiver. In this case, the oscillation of the signal is likely to occur because the signal of the same frequency band is received, amplified and transmitted. In order to prevent the oscillation of such a signal, it is necessary to separate the transmitting antenna and the receiving antenna of the gap filler spatially to increase the signal isolation. This method increases the space occupied by the gap filler, and the difficulty of installation There is a problem that it is difficult to apply many.

In order to solve the above problems, the present invention is to provide a satellite broadcasting system including a gap filler for receiving a time division multiplex signal, converts it to an orthogonal frequency division multiplex signal. In addition, in the present invention, an apparatus for converting an orthogonal frequency division multiplexing signal to a time division multiplexing signal, an apparatus for converting a time division multiplexing signal to an orthogonal frequency division multiplexing signal, and the present invention can be applied to such an apparatus. It also provides a signal conversion method.

(Configuration)

The satellite broadcasting system of the present invention generates a first signal of the orthogonal frequency division multiplexing method and a second signal of the time division multiplexing method by inputting predetermined multimedia data and control signals, and transmits it through a predetermined upband. And a satellite that transmits the frequency of the first signal to the first frequency band and transmits the second signal through a predetermined downlink band; And a receiver for receiving a signal from a satellite or a gap filler and converting the signal into a signal of a first frequency band, and transmitting the signal.

Hereinafter, the satellite broadcasting system of the present invention will be described in detail with reference to the accompanying drawings.

(Example)

3 is a block diagram of a satellite broadcasting system proposed in the present invention.

As shown in FIG. 3, the satellite broadcasting system of the present invention includes a transmitter 302, a satellite 304, a gap filler 308, and a receiver 306.

In the present invention, the transmission device 302 generates predetermined OFDM data and TDM signal by inputting predetermined multimedia data and control signals, and transmits different signals in uplink Ku-band (or Ka-band). Transmit over the band. At this time, the TDM signal is generated from the OFDM transmission frame (OFDM_TF) used to generate the OFDM signal shown in FIG.

4 is a block diagram showing an embodiment of the transmission apparatus shown in FIG. Referring to FIG. 4, the transmitter 302 may include OFDM transmitters 402, 402-2,..., 402 -N that generate and transmit OFDM signals by using input multimedia data and control signals. OFDM-TDM converter 404 and OFDM-TDM converter for converting OFDM transmission frames (OFDM_TF1, OFDM_TF2, ... OFDM_TFN) input from OFDM transmitters into a TDM transmission frame (TDM_TF) composed of 187 byte units. A TDM transmitter 406 generates and transmits a TDM signal using a TDM transmission frame (TDM_TF) and a frame boundary signal (FBS) from 404. As shown in FIG. 4, although the transmitter 302 of the present invention has a plurality of OFDM transmitters, for convenience of description, a case where one OFDM transmission frame is input will be described below.

Since the OFDM transmitter 402 and the TDM transmitter 406 used in the transmission apparatus 302 of the present invention can be easily understood by those skilled in the art, the detailed description thereof will be omitted.

On the other hand, the TDM transmission frame (TDM_TF) is composed of frames of 187 bytes because of the frame characteristics of the TDM signal defined in ETS 300 421, the standard for TDM signals. FIG. 5 is a frame diagram of a TDM signal defined in ETS 300 421. Referring to FIG. 5, a TDM modulator for generating a TDM signal divides input data into frames of 187 byte units, and between frames. 1 byte of sync byte (Sync) is inserted, and 1 byte of inverted sync byte (Syncb) is inserted every 8 frames. Thereafter, TDM signals are generated through processes such as energy dispersal, reed-solomon encoding, convolutional encoding, and quadrature phase shift modulation (QPSK modulation). Therefore, the TDM transmission frame (TDM_TF) generated by the OFDM-TDM converter 404 must be made of frames of 187 byte units.

FIG. 6 is a diagram illustrating a relationship between an OFDM transmission frame (OFDM_TF) and a TDM transmission frame (TDM_TF) in units of 187 bytes as shown in FIG. 2. Referring to FIG. 6, in order to convert the 7344-byte OFDM transmission frame (OFDM_TF) having the same structure as that of FIG. 2 input from the OFDM transmitter 402 into a TDM transmission frame in units of 187 bytes, the size of the OFDM transmission frame is first changed. It should be set to an integer multiple of 187. To do this, add the extra data fill byte (FB: Fill Byte) to the 187 bytes of the last frame. At this time, a 12-byte sync word (SW) indicating the start of a transmission frame, and 1-byte ensemble information (ENS) including information about the number of ensembles and an ensemble combination method are preceded by the OFDM transmission frame (OFDM_TF). Is added. That is, when 12-byte sync word (SW) and 1-byte ensemble information (ENS) are added to the 7344-byte OFDM transmission frame (OFDM_TF), it becomes 7357 bytes. Frames, and only 64 bytes of information remain in the last frame. To make it 187 bytes, add 123 bytes of fill bytes (FBs). Performing these processes is the OFDM-TDM converter 404 shown in FIG.

FIG. 7 is a block diagram illustrating an embodiment of an OFDM-TDM converter 404 included in the transmitter 302 of FIG. 4. Referring to FIG. 7, the above-described signal conversion method will be described in more detail. The OFDM-TDM converter 404 may have predetermined parameters for generating the TDM transmission frame TDM_TF from the input OFDM transmission frame OFDM_TF. Information generator 704 for generating a sync word (SW), ensemble information (ENS) and fill byte (FB) in response to the parameter values generated by parameter calculator 702 and parameter calculator 702, and The OFDM transmission frame (OFDM_TF) from the parameter calculator 702 and the sync word (SW), the ensemble information (ENS) and the fill byte (FB) from the information generator 704 are input and arranged in the order shown in FIG. The frame generator 706 generates a TDM transmission frame (TDM_TF) by dividing the data into frames of 187 bytes and generates a frame boundary signal (FBS) indicating a boundary of the transmission frame.

On the other hand, the parameter calculator 702 is the first parameter (N_WORD_FRAME) indicating the number of 187 bytes of OFDM transmission frame (OFDM_TF) input from the OFDM transmitter 402 and the fill byte (FB) filled in the last frame A second parameter (N_FILL_BYTE) indicating the size of is calculated using a predetermined equation, and the first parameter (N_WORD_FRAME) can be calculated by Equation 1 below.

N_WORD_FRAME = INT (((N_OFDM_TF + 13) -1) / 187) + 1

Where INT (A) is the largest integer not exceeding A. 1 is added to the second term in [Equation 1] because it is necessary to configure one unit of 187 bytes with the remaining bytes. In [Equation 1], 13 is a 12-byte sync word (SW) and 1 byte This is due to the ensemble information (ENS). The second parameter N_FILL_BYTE may be calculated by Equation 2 below.

N_FILL_BYTE = N_WORD_FRAME * 187-N_OFDM_TF-13

On the other hand, when a plurality of different OFDM transmission frame (OFDM_TF) is input, that is, when there are a plurality of different ensembles (ENS) is a plurality of OFDM transmission frame in one TDM transmission frame (TDM_TF) There may be two methods of the second combination.

The first combination method separately manages the ensemble information ENS (1,1) and ENS (1,2) for different OFDM transmission frames OFDM_TF1 and OFDM_TF2. That is, TDM transmission frames are generated by using the same method as described above for each OFDM transmission frame (OFDM_TF1, OFDM_TF2) and combined to form one TDM transmission frame (TDM_TF). Here, in ENS (1, N), 1 means the first combination method, and N means the number (OFDM_TFN) of the OFDM transmission frame. A TDM transmission frame made using this first combination method is shown in FIG. 8 (a). The second combination method first combines different OFDM transmission frames (OFDM_TF1 and OFDM_TF2) sequentially and regards them as one OFDM transmission frame, and then generates a TDM transmission frame (TDM_TF) in the same manner as described above. A TDM transmission frame made using this second combination method is shown in FIG. 8 (b). In FIG. 8 (b), ENS (2, *) means that the OFDM transmission frame is made by the second combination method.

The TDM transmission frame (TDM_TF) generated in this manner is converted into a TDM signal generated by the TDM transmitter 406 of the transmitter 302 and received by the gap filler 308 via the satellite 304. The gap filler 308 converts the received TDM signal into an OFDM signal and transmits the signal to the receiver 306.

FIG. 9 is a block diagram illustrating an embodiment of a gap filler for receiving a TDM signal, converting it to an OFDM signal, and transmitting the same. As shown in FIG. 9, the gap filler 308 of the present invention performs an OFDM transmission frame on a TDM receiver 902 and a TDM transmission frame (TDM_TF), which recover a TDM transmission frame (TDM_TF) from a TDM signal received from the satellite 304. (OFDM_TF1, OFDM_TF2, ... OFDM_TFN) and the TDM-OFDM converter 904 and OFDM transmitters to add the unique number of the gap filler to each OFDM transmission frame, converts to OFDM signal and then transmits (906, 906-2, ... 906-N). Each OFDM transmitter may recover several OFDM ensembles using respective ensemble information from one TDM signal. As in the case of the transmitter 302 described above, the TDM receiver 902 and the OFDM transmitter 906 may be understood by anyone having ordinary skill in the art, and thus a detailed description thereof will be omitted. TDM-OFDM converter 904, which is one of the characteristic components of the present invention, will be described in detail with reference to FIG.

10 is a block diagram illustrating an embodiment of a TDM-OFDM converter used in the gap filler of the present invention. Referring to FIG. 10, the TDM-OFDM converter 904 detects a sync word SW from an input TDM transmission frame TDM_TF and an ensemble detector 1004 for detecting ensemble information ENS. The OFDM transmission frame is removed by removing the sync word SW, the ensemble information ENS, and the fill byte FB detected by the FBS generator 1006 and the TDM transmission frame TDM_TF generating the frame boundary signal FBS. An information remover 1008 that restores (OFDM_TF).

In the TDM-OFDM converter 904, the sync word SW is repeated at a predetermined position for each T _{F, which} is a conceptual duration of the first OFDM transmission frame, and thus the original frame is restored. If the first transmission device 302 generates the TDM transmission frame using the first combination method, first, the sync word SW is detected, the ensemble ENS (1, N) is detected, and the frame boundary signal FBS is detected. ) Will be detected. The overall synchronization state between the OFDM transmission frame and the TDM transmission frame is a process in which the ensemble value after the synchronization word SW changes (ENS (1,1)-> ENS (1,2)-> ... ENS (1, N)-> ENS (1, 1)) can be maintained by continuing to observe. When the TDM transmission frame is generated using the second combination method in the first transmission device, the sync word SW + ensemble ENS (2, *) pattern is detected and the frame boundary signal FBS is detected.

In the above, the satellite broadcasting system according to the present invention has been described through the above drawings, but this is merely exemplary and various applications and modifications can be made without departing from the technical spirit of the present invention.

As described above, the satellite broadcasting system of the present invention can fundamentally solve the oscillation of the signal generated when transmitting and receiving signals in the same band by using a gap filler that receives a Ku-band signal and transmits a signal of 2.6 GHz band. have. As a result, the degree of freedom for installing the transmit / receive antenna of the gap filler can be reduced, thereby reducing the size of the gap filler facility. Therefore, the satellite broadcasting system of the present invention makes it possible to construct a more stable and efficient gap filler system.

Claims (16)

In a satellite broadcasting system, A transmitter for generating and transmitting a first signal of an orthogonal frequency division multiplexing method and a second signal of a time division multiplexing method; A satellite translating and transmitting the frequency of the first signal into a first frequency band and transmitting the second signal; A gap filler configured to convert the second signal of the time division multiplexing scheme received from the satellite into a signal of an orthogonal frequency division multiplexing scheme, and to shift and transmit the frequency of the second signal to the first frequency band; And A receiver for receiving a signal from the satellite or the gap filler, The transmitter comprises a first transmitter for generating and transmitting the first signal using predetermined multimedia signals; A first converter for generating a time division multiplexing second transmission frame from one or more orthogonal frequency division multiplexing first transmission frames input from the first transmitter; And a second transmitter for generating and transmitting the second signal using the second transmission frame. The first converter comprises: a parameter calculator that calculates predetermined parameters from the first transmission frame by performing a predetermined operation; An information generator configured to generate information necessary for generating the second transmission frame using the parameters; And a frame generator for combining the first transmission frame and the information from the information generator to generate the second transmission frame. The method of claim 1, And said first frequency band is a 2.6 GHz frequency band. delete delete The method of claim 1, The parameters include a first parameter indicating how many frames of the first transmission frame are divided into 187 byte units and a second parameter indicating how much fill byte information is required to make the frame of the last unit into 187 bytes. Satellite broadcasting system characterized in that. The method of claim 1, And the information generated by the information generator is a sync word, ensemble information and the fill byte. The method of claim 5, And the second transmission frame is divided into frames in units of 187 bytes. The method according to claim 5 or 6, And the second transmission frame is arranged in the order of the sync word, the ensemble information, and the first transmission frame and fill byte. The method of claim 1, The gap filler may include a receiver configured to receive the second signal from the satellite to generate a third transmission frame of time division multiplexing; A second converter for converting the third transmission frame into one or more fourth transmission frames of orthogonal frequency division multiplexing; And And a transmitter for transmitting the fourth transmission frame to the receiver. The method according to claim 1 or 9, And the first transmission frame and the fourth transmission frame are the same transmission frame, and the second transmission frame and the third transmission frame are the same transmission frame. The method of claim 9, The second converter includes a sync word detector for detecting a sync word from the third transmission frame; An ensemble detector for detecting ensemble information of the third transmission frame; A frame boundary signal generator for generating a frame boundary signal of the third transmission frame; And And an information eliminator for removing the detected sync word, ensemble information, and fill byte from the third transmission frame to generate the fourth transmission frame. A conversion method for converting an orthogonal frequency division multiplex transmission frame into a time division multiplex transmission frame, A first step of adding predetermined information data to the transmission frame of the orthogonal frequency division multiplexing scheme; Dividing a transmission frame including predetermined information data into frames in units of 187 bytes in the first step; And a third step of checking the size of the last frame among the frames divided in units of 187 bytes in the second step and inserting fill bytes into the last frame as much as 187 bytes. The method of claim 12, And the information data is ensemble information of a sync word and the first transmission frame. The method of claim 12, In case of converting a plurality of orthogonal frequency division multiplexing transmission frames into one time division multiplexing scheme, the transmission frames of each orthogonal frequency division multiplexing scheme are respectively divided by the first to third steps. And converting the transmission frame and combining the changed transmission frames to generate one time division multiplex transmission frame. The method of claim 12, In the case of converting a plurality of orthogonal frequency division multiplexing transmission frames into one time division multiplexing scheme, after combining the plurality of orthogonal frequency division multiplexing transmission frames, one time through the first to third steps is performed. A conversion method characterized by generating a transmission frame of the division multiplexing method. A converter for converting a time division multiplex transmission frame including a sync word, ensemble information, and fill bytes into a transmission frame of an orthogonal frequency division multiplexing scheme, Detecting the sync word from the time division multiplex transmission frame; Detecting the ensemble information from the time division multiplex transmission frame; And a third step of removing the detected sync word and ensemble information and the fill byte from the time division multiplex transmission frame.

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