JP2008136052A - Data transmission and receiving devices - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a data transmission device which can transmit data with high transmission efficiency not depending on other data structures. <P>SOLUTION: The data transmission device 1 has a data structure arrangement means 10 for arranging data structures of transmission data for every data area of a transmission frame, a TMCC arrangement means (control area pointer addition means) 14 for adding pointer information that indicates a position of the head data structure which has the head data in the data structure to a control area to control the data area, and a framing means 16 for structuring a prespecified transmission frame included with the data area and the control area as a modulation stream signal. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a data transmission device that transmits a digital signal and a data reception device that receives a digital signal.

In recent years, various transmission methods have been standardized as methods for transmitting digital signals. For example, in satellite digital broadcasting, ISDB-S (Integrated Services Digital Broadcasting-Satellite; see Non-Patent Document 1) developed in Japan and DVB-S (Digital Video Broadcasting-Satellite; Non-Patent Document) developed in Europe. 2).
These ISDB-S and DVB-S are systems suitable for transmission of MPEG-2 (Moving Picture Experts Group-2) transport stream (hereinafter referred to as TS), which is encoded data obtained by encoding video and audio. .

Recently, with the diversification of broadcasting, it is necessary to transmit other digital signals such as IP (Internet Protocol) packets as broadcast waves in addition to MPEG-2TS.
In this case, in ISDB-S and DVB-S, an IP packet or the like is transmitted as MPEG-2TS data. That is, in ISDB-S and DVB-S, IP is positioned as an upper layer of MPEG-2TS, and IP packets are transmitted as MPEG-2TS data.
ISDB-S: ARIB (Association of Radio Industries and Businesses) STD-B20, “Transmission System for Satellite Digital Broadcasting”, May 31, 2001, version 3.0 DVB-S: ETSI (European Telecommunications Standards Institute) EN 300 421, “Digital broadcasting systems for television, sound and data services; Framing structure, channel coding and modulation for 11/12 GHz satellite services”, 1997 August, V1.1.2

However, in the above-mentioned ISDB-S and DVB-S, when transmitting a digital signal such as an IP packet, it is necessary to encapsulate and transmit the MPEG-2TS even if the signal is not related to the MPEG-2TS protocol. There is.
In this case, there is a problem that the protocol for transmitting and receiving digital signals becomes complicated, and the load on the data transmission device and the reception device increases.
In addition, for example, when an IP packet is transmitted, a signal such as an MPEG-2TS TS header that is not directly related to IP must be transmitted.

  The present invention has been made to solve the above-described problems. When transmitting a digital signal, not only MPEG-2TS transmission but also other data structures such as IP packets are mixed. Even so, it is an object of the present invention to provide a data transmission device and a data reception device capable of transmitting each data structure with higher transmission efficiency without depending on other data structures.

  The present invention has been developed to achieve the above object. First, the data transmission device according to claim 1 is configured such that continuous transmission data in a data structure is independent of the structure of the data structure. A data transmission apparatus for transmitting as a digital modulation signal having a data area and a control area for controlling the data area as a transmission frame structure, the data structure arrangement means, the control area pointer addition means, a frame And a means for making it.

  In such a configuration, the data transmission apparatus arranges the data structure of the transmission data for each data area by the data structure arrangement means. Here, the data structure means data having a specific data structure such as a TS packet or an IP packet, and the data length may be a fixed length or a variable length. As a result, the transmission data is divided according to the length of the data area.

The data transmission apparatus adds pointer information indicating the position of the earliest data structure having the head data in the data structure to the control area by the control area pointer adding means. In this case, because the structure of the data structure is independent of the data area, that is, the length of the data area is not an integral multiple of the length of the data structure, the data structure is Even in the case of being divided into frames, the position of the first data structure that is not divided is added to the control area as pointer information. Thus, on the receiving side, by interpreting the control area, the position of the data structure in the data area can be grasped, and the data structure can be synchronized.
In addition, the data transmission apparatus uses the framing means to format the data area and the control area into a predetermined transmission frame structure to form a transmission frame, thereby obtaining a modulated stream signal. The modulated stream signal may be provided with a modulation means in the data transmission device, and may be modulated into a digital modulation signal by the modulation means, or may be modulated into a digital modulation signal by an external modulation device. .

  According to a second aspect of the present invention, there is provided a data transmission device for controlling a plurality of transmission data composed of different data structures, a plurality of data areas independent of the structure of the data structures, and the data areas. Is a data transmission apparatus that transmits a digital modulation signal having a transmission frame structure as a transmission frame structure, and includes a plurality of data structure array means, control area pointer / type addition means, and framing means .

In such a configuration, the data transmission apparatus arranges the data structure of the transmission data for each data area by each of the plurality of data structure arrangement means.
Then, the data transmission device uses the control area pointer / type adding means to provide pointer information indicating the position of the earliest data structure having the first data in the data structure and type information indicating the type of transmission data in the data area. Is added to the control area. As a result, the receiving side can identify the type of the data area by interpreting the control area and can grasp the position of the data structure in the data area. Synchronization can be achieved.
In addition, the data transmission apparatus uses the framing means to format the data area and the control area into a predetermined transmission frame structure to form a transmission frame, thereby obtaining a modulated stream signal. The modulated stream signal may be provided with a modulation means in the data transmission apparatus, and may be modulated into a digital modulation signal by the modulation means, or may be modulated into a digital modulation signal by an external modulation apparatus.

  Furthermore, the data transmission apparatus according to claim 3 is the data transmission apparatus according to claim 1 or 2, wherein the framing means configures the control area and the data area when the control area and the data area are configured. The area is framed into an area where modulation is performed using a modulation scheme having higher transmission error tolerance than the data area.

  In such a configuration, the data transmission apparatus frames the control area and the data area into areas modulated by different modulation schemes by the framing means. At this time, the control area is framed into an area having a modulation scheme having a higher transmission error tolerance than the data area, so that the information for synchronizing the data structure is more strongly protected.

  According to a fourth aspect of the present invention, there is provided the data transmission device according to the first or second aspect, wherein the framing means configures the control area and the data area when the control area and the data area are configured. The area is framed into an area where error correction is performed using an error correction method having higher transmission error tolerance than the data area.

  In such a configuration, the data transmission apparatus frames the control area and the data area into areas modulated by different modulation schemes by the framing means. At this time, the control area is framed into an area having a modulation scheme having a higher transmission error tolerance than the data area, so that the information for synchronizing the data structure is more strongly protected.

  The data transmission device according to claim 5 is a data transmission device for transmitting continuous transmission data of a data structure as a digital modulation signal having a data area independent of the structure of the data structure as a transmission frame structure. The data structure arranging means, the data area pointer adding means, and the framing means are provided.

In such a configuration, the data transmission apparatus arranges the data structure of the transmission data for each data area by the data structure arrangement means.
Then, the data transmission device adds pointer information indicating the position of the earliest data structure having the head data in the data structure to the data area by the data area pointer adding means. As a result, on the receiving side, by interpreting the pointer information added to the data area, the position of the data structure in the data area can be grasped, and the data structure can be synchronized. .
Further, the data transmission apparatus formats the data area into a predetermined transmission frame structure by the framing means to form a transmission frame, thereby obtaining a modulated stream signal. The modulated stream signal may be provided with a modulation means in the data transmission apparatus, and may be modulated into a digital modulation signal by the modulation means, or may be modulated into a digital modulation signal by an external modulation apparatus.

  Furthermore, the data transmission device according to claim 6 is a digital modulation signal having a plurality of transmission data composed of different data structures as a transmission frame structure having a plurality of data areas independent of the structure of the data structures. As a data transmission device for transmission, a plurality of data structure arrangement means, a data area pointer / type addition means, and a framing means are provided.

In such a configuration, the data transmission apparatus arranges the data structure of the transmission data for each data area by each of the plurality of data structure arrangement means.
Then, the data transmission device uses the data area pointer / type adding means to provide pointer information indicating the position of the earliest data structure having the first data in the data structure in the data area, and type information indicating the type of transmission data. Is added to the data area. As a result, the receiving side can identify the type of the data area by interpreting the information added to the data area, and can grasp the position of the data structure in the data area. And data structures can be synchronized.
Further, the data transmission apparatus formats the data area into a predetermined transmission frame structure by the framing means to form a transmission frame, thereby obtaining a modulated stream signal. The modulated stream signal may be provided with a modulation means in the data transmission apparatus, and may be modulated into a digital modulation signal by the modulation means, or may be modulated into a digital modulation signal by an external modulation apparatus.

  The data transmission device according to claim 7 is the data transmission device according to any one of claims 1 to 6, wherein the data area does not include leading data in the data structure. In this case, the pointer information is a value indicating a position larger than a maximum position indicating the data area.

  In such a configuration, when the data transmission apparatus does not include the top data in the data structure, for example, when the length of the data structure is longer than the length of the data area, When there is no break in the data structure, a value indicating a position larger than the maximum position indicating the data area is used as the pointer information. This makes it possible to determine the validity of the pointer information on the receiving side.

  According to an eighth aspect of the present invention, there is provided a data receiving apparatus for receiving a digital modulation signal transmitted from the data transmitting apparatus according to the first aspect, wherein the demodulating means, the frame detecting means, and the data area are received. An extraction unit, a control area pointer extraction unit, and a data structure extraction unit are provided.

In such a configuration, the data receiving apparatus demodulates the digital modulation signal by the demodulation unit using the modulation scheme predetermined by the transmission scheme.
Then, the data receiving apparatus detects a transmission frame by detecting a frame synchronization signal or the like from the modulated stream signal demodulated by the demodulating means by the frame detecting means.
Then, the data receiving device extracts the data area constituting the transmission frame from the transmission frame by the data area extraction means.
Further, the data receiving apparatus extracts pointer information indicating the position of the data structure from the control area for controlling the data area constituting the transmission frame by the control area pointer extracting means.
Then, the data receiving apparatus sequentially extracts the data structures from the data area based on the pointer information by the data structure extracting unit.

  Furthermore, a data receiving device according to claim 9 is a data receiving device for receiving a digital modulation signal transmitted from the data transmission device according to claim 2, wherein the demodulating means, the frame detecting means, the data region, An extraction unit, a control area pointer / type extraction unit, and a data structure extraction unit are provided.

In such a configuration, the data receiving apparatus demodulates the digital modulation signal by the demodulation unit using the modulation scheme predetermined by the transmission scheme.
Then, the data receiving apparatus detects a transmission frame by detecting a frame synchronization signal or the like from the modulated stream signal demodulated by the demodulating means by the frame detecting means.
Then, the data receiving device extracts the data area constituting the transmission frame from the transmission frame by the data area extraction means.
Further, the data receiving device uses the control area pointer / type extracting means to control the data area constituting the transmission frame from the control area for indicating the position of the data structure and the type information indicating the type of transmission data. And extract.
Then, the data receiving apparatus sequentially extracts the data structure for each type from the data area based on the pointer information and the type information by the data structure extracting unit.

  A data receiving apparatus according to claim 10 is a data receiving apparatus for receiving a digital modulation signal transmitted from the data transmission apparatus according to claim 5, wherein the demodulating means, the frame detecting means, and the data area An extraction unit, a data area pointer extraction unit, and a data structure extraction unit are provided.

In such a configuration, the data receiving apparatus demodulates the digital modulation signal by the demodulation unit using the modulation scheme predetermined by the transmission scheme.
Then, the data receiving apparatus detects a transmission frame by detecting a frame synchronization signal or the like from the modulated stream signal demodulated by the demodulating means by the frame detecting means.
Then, the data receiving device extracts the data area constituting the transmission frame from the transmission frame by the data area extraction means.
Further, the data receiving apparatus extracts pointer information indicating the position of the data structure from the data area by the data area pointer extracting means.
Then, the data receiving apparatus sequentially extracts the data structures from the data area based on the pointer information by the data structure extracting unit.

  Furthermore, a data receiving apparatus according to claim 11 is a data receiving apparatus for receiving a digital modulation signal transmitted from the data transmission apparatus according to claim 6, and comprises a demodulating means, a frame detecting means, a data area, An extraction unit, a data area pointer / type extraction unit, and a data structure extraction unit are provided.

In such a configuration, the data receiving apparatus demodulates the digital modulation signal by the demodulation unit using the modulation scheme predetermined by the transmission scheme.
Then, the data receiving apparatus detects a transmission frame by detecting a frame synchronization signal or the like from the modulated stream signal demodulated by the demodulating means by the frame detecting means.
Then, the data receiving device extracts the data area constituting the transmission frame from the transmission frame by the data area extraction means.
Further, the data receiving apparatus extracts pointer information indicating the position of the data structure and type information indicating the type of transmission data from the data area by the data area pointer / type extracting means.
Then, the data receiving apparatus sequentially extracts the data structure for each type from the data area based on the pointer information and the type information by the data structure extracting unit.

The present invention has the following excellent effects.
According to the first to seventh aspects of the present invention, it is not necessary to arrange the data structure constituting the transmission data in an aligned state at the beginning of the data area of the transmission frame. A data structure can be transmitted. Further, according to the present invention, since the position of the data structure is specified based on the pointer information, an arbitrary data structure that does not depend on a specific protocol can be transmitted.
Furthermore, according to the second and fifth aspects of the invention, a plurality of different types of transmission data can be multiplexed in different data areas. Thereby, transmission data of different protocols can be individually transmitted in parallel. In addition, transmission efficiency can be improved compared to the case where transmission data of different protocols is conventionally transmitted in parallel as compared with the case where processing such as encapsulation is required.

  According to the third and fourth aspects of the present invention, it is possible to protect the information for synchronizing the data structures with higher strength.

  According to the seventh aspect of the present invention, the pointer information indicates that the data area does not include the head of the data structure even when the head of the data structure is not included in the data area. Can be expressed as Thus, as pointer information, information indicating the position of the pointer and information indicating that the head of the data structure is not included can be expressed in the same area, and transmission efficiency can be improved.

According to the eighth to eleventh aspects of the present invention, it is not necessary to receive the data structure constituting the transmission data in a state of being aligned (aligned) at the head of the data area of the transmission frame. A data structure can be received. Further, according to the present invention, since the position of the data structure can be recognized based on the pointer information, an arbitrary data structure that does not depend on a specific protocol can be received.
Furthermore, according to the ninth and eleventh aspects, it is possible to receive a plurality of different types of transmission data multiplexed in different data areas. Thereby, transmission data of different protocols can be individually received in parallel. In addition, transmission efficiency can be improved compared to the case where transmission data of different protocols is conventionally transmitted in parallel as compared with the case where processing such as encapsulation is required.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[Transmission frame structure]
First, a structure of a transmission frame of a digital modulation signal transmitted by a data transmission apparatus according to an embodiment of the present invention to a transmission path will be described with reference to FIG. FIG. 1 is an explanatory diagram for explaining the structure of a transmission frame of a digital modulation signal transmitted by a data transmission apparatus according to an embodiment of the present invention.

As shown in FIG. 1, the transmission frame includes a plurality of slots (Slot # 1 to #n) indicating a data area and error correction codes (error correction inner / outer codes) of the data area. It includes a transmission control signal (TMCC: Transmission add Multiplexing Configuration Control) indicating control information such as the number of slots in the data area and modulation scheme.
Conventionally, fixed-length data structures (for example, TS packets) are arranged (aligned) from the top of each data area (slot). That is, the data structure is always arranged from the head of the slot by setting the slot length to be an integral multiple of the data length of the fixed data structure.

  However, when the data structure has a variable length, the data structure cannot always be arranged from the beginning of the slot. Furthermore, when the structure of the data structure and the data area are independent, even if the data structure has a fixed length, the data structure cannot always be arranged from the beginning of the slot.

Therefore, in the data transmission apparatus according to the embodiment of the present invention, the position (pointer) of the leading packet among the packets (data structures) in the slot is managed as pointer information. Here, the head packet does not include a packet continuing from the previous frame.
As a result, in addition to fixed-length packets such as TS packets, variable-length packets such as IP packets can be allocated in the slots, and the position of the first packet in each slot is specified, so synchronization is achieved on the receiving side. Is possible.

In FIG. 1, an error detecting code (EDC) is added to each data structure (TS packet, variable length packet, etc.), but this EDC is not necessarily added. In addition, when an EDC is added, the structure to which the EDC is added is regarded as a data structure.
Hereinafter, a data transmission apparatus that transmits digital signal transmission data in units of transmission frames and a data reception apparatus that receives the transmission frames will be described.

[Configuration of data transmission equipment]
First, the configuration of the data transmission apparatus according to the first embodiment of the present invention will be described with reference to FIG. FIG. 2 is a block diagram showing the configuration of the data transmission apparatus according to the first embodiment of the present invention.

The data transmission apparatus 1 multiplexes a plurality of continuous transmission data (stream data) of a data structure and transmits the multiplexed data as a digital modulation signal having a transmission frame structure. Here, the data transmission apparatus 1 includes a data structure arrangement means 10, a data area multiplexing means 11, a data area error correction addition means 12, a data area arrangement means 13, a TMCC arrangement means 14, and a TMCC error correction addition. Means 15, framing means 16, and modulation means 17 are provided. In FIG. 2, a solid line indicates the flow of data, and a broken line indicates the flow of control information.
Further, here, the data transmission device 1 includes data structure arrangement means 10 (10a, 10b,...) Corresponding to the number of transmission data to be multiplexed. The transmission data to be multiplexed may be different types of data (TS packets, IP packets, etc.), or may be the same type of data.

The data structure arrangement means 10 (10a, 10b,...) Arranges input transmission data for each data area (slot). As a result, the transmission data is divided for each slot length.
Here, the data structure arrangement means 10 arranges transmission data in a data area in units of data structures (TS packets, IP packets, etc.) of transmission data, and outputs the data to the data area multiplexing means 11. Further, the data structure array means 10 generates pointer information indicating the position of the data structure in the arrayed data area and data type information indicating the data type of each data area as TMCC information, Output to the region multiplexing means 11.

The data area multiplexing means 11 multiplexes data area data for the number of transmission data output from the data structure array means 10 and also multiplexes TMCC information for the number of transmission data. Here, multiplexing refers to associating data in a plurality of data areas and TMCC information as information for one transmission frame. Thus, data in the data area constituting one transmission frame and TMCC information are prepared.
The multiplexed data area data is output to the data area error correction adding means 12, and the TMCC information is output to the TMCC arranging means 14.

The data area error correction adding means 12 adds a predetermined error correction code for each data area. This enables error correction of the data area on the receiving side.
Here, the data area error correction adding means 12 adds error correction codes such as convolutional codes, BCH (Bose Chaudhuri Hocquengham) codes, RS (Reed Solomon) codes, LDPC (Low-Density Parity Check) codes, etc. It outputs to the region arrangement means 13. Further, the data area error correction adding means 12 outputs the type of the error correction code (outer code and / or inner code) added to the data area to the TMCC arranging means 14 as TMCC information.

  The data area arrangement means 13 formats the data area into a predetermined slot format for transmission as a transmission frame. As a result, the data area is arranged in the slot format of the transmission frame.

  The TMCC arrangement means (control area pointer / type adding means) 14 is pointer information output from the data area multiplexing means 11, data type information indicating the type of transmission data, and correction code output from the data area error correction adding means 12. TMCC information such as the type of information is arranged (added) in the TMCC (control area).

Here, a configuration example of TMCC will be described with reference to FIG. FIG. 5 is a configuration diagram illustrating a configuration example of TMCC. Here, only the configuration added to realize the present invention with respect to the conventional TMCC will be described, and the description of the conventional configuration will be omitted.
As shown in FIG. 5, in the present invention, “slot / data type information” and “slot / pointer information” are added to constitute a TMCC.

  “Slot / data type information” indicates the type of data arranged in the slot (data area). This data type is information for identifying, for example, TS packets, IP packets, other packets, or unbroken stream data.

  The “slot / pointer information” indicates a pointer (relative position) from the start position of the slot (data area) to the start position of the data structure (packet) arranged in the slot. This pointer information indicates the pointer of the head data structure when a plurality of data structures are included in the slot. Here, the first data structure refers to a data structure that includes at least the first data of the data structure, and includes a data structure that is divided from the previous transmission frame and arranged from the intermediate data. Make it not exist.

When the stream data without discontinuities is arranged in the slot (or when the head of the data structure is not in the slot), the pointer information is set to a value larger than the maximum position indicating the slot.
For example, when the slot length (data area length) is 32800 bytes, the pointer information is composed of 16 bits (2 bytes). If the head of the data structure does not exist in the slot, “65535 (= 0xffff)” is set in the pointer information.

  In general, the value that can be taken by the pointer information is “0” or more and less than the length of the data area. Therefore, the pointer information field needs the number of bits that can represent “the length of the data area−1”. is there. However, when the length of the data structure is limited for a certain data type, the possible value of the pointer information is “0” or more and less than the length of the data structure. , “The length of the data structure−1” can be set to the number of bits that can be expressed. Even when the data structure has a variable length, the number of bits that can represent the maximum length of the data structure can be set.

For example, when the slot length (data area length) is 32800 bytes, the pointer information generally needs to be composed of 16 bits (2 bytes). However, when the packet (data structure) to be transmitted is a TS packet, the length is 188 bytes, and thus the possible value of the pointer information is limited to “0” or more and less than “188”. Therefore, the pointer information can be composed of 8 bits (1 byte).
By doing so, the number of bits of the pointer information can be saved and the transmission efficiency can be increased. This is particularly effective when pointer information is transmitted in the data area.

  Here, with reference to FIG. 6 (refer to FIG. 2 as appropriate), the arrangement of the data structures in the data area will be described. FIG. 6 is a schematic diagram showing an example of the arrangement of data structures in the data area of the transmission frame.

As shown in FIG. 6A, when the packet is arranged from the head in the slot (data area) (when the slot and the packet are matched), the pointer of the head packet is “0”. Therefore, the TMCC array unit 14 sets “0” as TMCC as pointer information.
In addition, as shown in FIGS. 6B and 6C, in the IP packet and other general packets, the packet is arranged following the packet continuous from the previous frame. Therefore, the TMCC arrangement unit 14 sets the pointers (A and B in the figure) of the packets following the consecutive packets from the previous frame to the TMCC as pointer information.

Also, as shown in FIG. 6D, when there is no head of the data structure in the slot, the TMCC arrangement means 14 sets a value larger than the maximum position indicating the inside of the slot (for example, the maximum value of the boyer information field) TMCC is set as pointer information.
As a result, the position of the head data structure in the slot is specified by the pointer information.
The data type information of each data area (slot) is arranged in the TMCC (not shown).
Returning to FIG. 2, the description of the configuration of the data transmission apparatus 1 will be continued.

The TMCC error correction adding means 15 adds a predetermined error correction code to the TMCC arranged by the TMCC arranging means 14. As a result, TMCC (control area) error correction can be performed on the receiving side. Here, the TMCC error correction adding means 15 uses, for example, a convolutional code, a BCH (Bose Chaudhuri Hocquengham) code, an RS (Reed Solomon) code, an LDPC (Low-Density Parity Check) code, etc. as an error correction code.
The TMCC error correction adding means 15 preferably uses an error correction code system having higher transmission error tolerance than the data area because of the importance of the contents of the TMCC (control area).

The framing means 16 constitutes a data area (slot) and a control area (TMCC) as a predetermined transmission frame. As a result, the framing means 16 generates the transmission frame (modulated stream signal) described with reference to FIG. The framing means 16 adds a frame synchronization signal for each transmission frame.
Further, when the data area and the control area are configured as a transmission frame, the framing means 16 performs framing by configuring the control area as a TMCC having higher transmission error tolerance than the data area.

The modulation means 17 modulates the transmission frame framed by the framing means 16 by a predetermined modulation method and generates a digital modulation signal.
Here, the modulation means 17 modulates the control area (TMCC) and the data area (slot) by the designated modulation schemes. For modulation in the control region, it is desirable to use a modulation scheme having higher transmission error tolerance than modulation in the data region because of the importance of the contents. For example, the modulation means 17 modulates the control area (TMCC) with BPSK and the data area (slot) with 8 PSK.

  By configuring the data transmission device 1 in this way, the data transmission device 1 can transmit a plurality of transmission data in which data structures such as TS packets and IP packets are continuous as a digital modulation signal having a frame structure. it can. Further, the data transmission apparatus 1 can transmit the transmission data as a digital modulation signal having a frame structure that does not include the packet head even if the transmission data is data having no data structure such as stream data.

  Here, the data transmission device 1 is configured to include the modulation unit 17, but the modulation unit 17 may be provided outside as a modulation device. In this case, the modulation stream signal is output from the framing means 16 to the modulation device.

Also, here, the data transmission device 1 is configured to transmit a plurality of types of transmission data in a transmission frame having a plurality of slots (data areas), but one type of transmission data is used as a digital modulation signal. It is good also as a structure which transmits. In this case, for example, one data structure array means 10 is provided, the data area multiplexing means 11 is omitted, and the TMCC array means 14 is a TMCC array means (control area pointer adding means) 14B to which no data type is added. Thus, the data transmission device 1B (second embodiment) shown in FIG. 3 is configured.
As a result, the data transmission device 1B can transmit one kind of predetermined transmission data as a digital modulation signal having a frame structure, like the data transmission device 1.

  The data transmission apparatuses 1 and 1B can be configured by a general computer including a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), etc. (not shown). Can be operated by a data transmission program that functions as each means described above.

[Operation of data transmission equipment]
Next, the operation of the data transmission apparatus according to the first embodiment of the present invention will be described with reference to FIG. 4 (refer to FIG. 2 as appropriate for the configuration). FIG. 4 is a flowchart showing the operation of the data transmission apparatus according to the first embodiment of the present invention.
First, the data transmission apparatus 1 arranges (divides) the input transmission data for each data area (slot) by the data structure arrangement means 10 (step S11). The data structure arrangement means 10a and 10b arrange transmission data for each data area in parallel. Furthermore, the data transmission device 1 generates pointer information indicating the positions of the arranged data structures and data type information indicating the data types of the individual data areas as TMCC information by the data structure array unit 10. (Step S12).

Then, the data transmission apparatus 1 multiplexes data for each data area corresponding to the number of transmission data by the data area multiplexing means 11 and multiplexes TMCC information corresponding to the number of transmission data (step S13).
Thereafter, the data transmission apparatus 1 adds a predetermined error correction code for each data type by the data area error correction adding means 12 (step S14).
Then, the data transmission device 1 formats the data area into a predetermined frame format to be transmitted as a transmission frame by the data area arrangement unit 13 (step S15).

Furthermore, the data transmission apparatus 1 arranges the pointer information generated in step S12 and the data type information generated in step S12 in the TMCC (control area) by the TMCC arrangement unit 14 (step S16).
Thereafter, the data transmission device 1 adds a predetermined error correction code to the TMCC by the TMCC error correction adding means 15 (step S17).

Then, the data transmission apparatus 1 configures the data area formatted in step S15 and the TMCC arranged in step S16 as a transmission frame by the framing means 16 (step S18).
Then, the data transmission apparatus 1 modulates the control area (TMCC) and the data area (slot) with different modulation schemes by the modulation means 17 to generate a digital modulation signal (step S19).

With the above operation, the data transmission device 1 can transmit a plurality of transmission data in which data structures such as TS packets and IP packets are continuous as a digital modulation signal having a frame structure.
The operation of the data transmission apparatus 1B (second embodiment) shown in FIG. 3 is basically the same as the operation of the data transmission apparatus 1 except that one piece of transmission data is input. Is omitted.

[Data receiver configuration]
Next, with reference to FIG. 7, the structure of the data receiver which concerns on 3rd Embodiment of this invention is demonstrated. FIG. 7 is a block diagram showing a configuration of a data receiving apparatus according to the third embodiment of the present invention.

  The data receiving device 2 receives the digital modulation signal having the transmission frame structure transmitted from the data transmission device 1 described in FIG. 2, and extracts a plurality of transmission data multiplexed on the digital modulation signal. It is. Here, the data receiving apparatus 2 includes a demodulating unit 20, a frame decoding unit 21, a data region extracting unit 22, a TMCC error correcting unit 23, a TMCC information extracting unit 24, a data region error correcting unit 25, a data An area demultiplexing unit 26 and a data structure extraction unit 27 are provided.

  The demodulating means 20 demodulates the input digital modulation signal. The demodulating means 20 performs demodulation using the same modulation method as the modulation performed in the modulating means 17 of the data transmission apparatus 1. For example, when the control area (TMCC) is modulated by BPSK and the data area (slot) is modulated by 8PSK, the demodulator 20 demodulates the control area by BPSK and the data area by 8PSK, respectively. The demodulated digital modulation signal (demodulation signal) is output to the frame decoding means 21.

The frame decoding means 21 detects a frame synchronization signal from the demodulated signal demodulated by the demodulation means 20, and decodes the transmission frame. The decoded transmission frame has the transmission frame structure described with reference to FIG. Here, the frame decoding means 21 outputs the decoded transmission frame to the data area extraction means 22.
Further, the frame decoding means 21 outputs the TMCC in the transmission frame to the TMCC error correction means 23.

  The data area extracting unit 22 extracts a data area from the transmission frame output from the frame decoding unit 21.

  The TMCC error correction means 23 performs TMCC error correction based on the error correction code added to the TMCC. For example, the TMCC error correction means 23 performs error correction on the TMCC using a convolutional code, a BCH (Bose Chaudhuri Hocquengham) code, an RS (Reed Solomon) code, an LDPC (Low-Density Parity Check) code, or the like. Then, the TMCC error correction means 23 outputs the TMCC subjected to error correction to the TMCC information extraction means 24.

  The TMCC information extracting means (control area pointer / type extracting means) 24 extracts information arranged in the TMCC. The TMCC information is, for example, the data type information and pointer information shown in FIG. The TMCC information extracted by the TMCC information extracting means 24 is output to the data area error correcting means 25 and the data area demultiplexing means 26.

  The data area error correction means 25 performs error correction of the data area based on the error correction code added to the TMCC. For example, the data area error correction means 25 performs error correction of the data area using a convolutional code, a BCH (Bose Chaudhuri Hocquengham) code, an RS (Reed Solomon) code, an LDPC (Low-Density Parity Check) code, or the like.

  The data area demultiplexing means 26 separates a plurality of data areas for each type based on the data type information in the TMCC information. The data area demultiplexing means 26 also separates pointer information from TMCC information at the same time. This pointer information is output to the data structure extraction unit 27 for each data type. The contents of the data areas for each type of data separated by the data area demultiplexing means 26 are referred to by the data structure extracting means 27 based on the pointer information.

The data structure extraction unit 27 extracts a data structure from the data area. The data receiving device 2 includes a plurality of data structure extracting means 27 (27a, 27b,...) For each data type.
Here, the data structure extraction means 27 synchronizes the data structures by detecting the head position of the data structure in the data area based on the pointer information output from the data area demultiplexing means 26. To extract. When the data structure has a variable length, the data structure extraction unit 27 uses the data structure data included in the data structure in advance for the data after the data structure specified by the pointer information. The data structure is extracted sequentially with reference to the length.
Then, the data structure extracted by the data structure extraction unit 27 is output as continuous data, thereby generating transmission data for each data type.

By configuring the data receiving device 2 in this way, the data receiving device 2 extracts and receives a plurality of transmission data in which data structures such as TS packets and IP packets are continuous from a digital modulation signal having a frame structure. can do.
In addition, since the data receiving device 2 can synchronize the data structure based on the pointer information arranged in the control area (TMCC), even if the data structure has a variable length, the data receiving apparatus 2 Can be extracted. As a result, general data such as variable-length IP packets as well as fixed-length TS packets can be received.

Further, here, the data receiving apparatus 2 is configured to receive a digital modulation signal in which a plurality of types of transmission data are multiplexed in a plurality of slots (data areas), but receives one type of digital modulation signal. It is good also as a structure. That is, when receiving the digital modulation signal transmitted by the data transmission apparatus 1B described with reference to FIG. 3, the data reception apparatus 2 includes one data structure extraction unit 27, omits the data region demultiplexing unit 26, and The TMCC information extracting unit 24 is configured as a data receiving device 2B (fourth embodiment) shown in FIG. 8 by using a TMCC information extracting unit (control area pointer extracting unit) 24B that does not extract a data type.
As a result, the data receiving device 2B can receive a digital modulation signal having a frame structure including one kind of predetermined transmission data in synchronization with the data structure.

  The data receiving devices 2 and 2B can be configured by a general computer including a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), etc. (not shown). Can be operated by a data reception program that functions as each of the above-described means.

[Operation of data receiver]
Next, the operation of the data receiving apparatus according to the third embodiment of the present invention will be described with reference to FIG. FIG. 9 is a flowchart showing the operation of the data receiving apparatus according to the third embodiment of the present invention.
First, the data receiving apparatus 2 demodulates the input digital modulation signal by the demodulation means 20 (step S21).
Then, the data receiving device 2 detects the frame synchronization signal from the demodulated signal demodulated in step S20 by the frame decoding means 21, and decodes it for each transmission frame (step S22).

Thereafter, the data receiving apparatus 2 extracts a data area from the transmission frame decoded in step S21 by the data area extracting unit 22 (step S23).
Further, the data receiving device 2 performs TMCC error correction based on the error correction code added to the TMCC by the TMCC error correction means 23 (step S24). Then, the data receiving device 2 extracts information (for example, pointer information, data type information, etc.) arranged in the TMCC by the TMCC information extracting unit 24 (step S25).

Then, the data receiving apparatus 2 performs error correction on the data area based on the error correction code added to the TMCC by the data area error correction means 25 (step S26).
Thereafter, the data receiving device 2 separates the plurality of data areas for each type based on the data type information in the TMCC information extracted in step S25 by the data area demultiplexing means 26 (step S27).
Then, the data receiving device 2 detects the head position of the data structure in the data area based on the pointer information in the TMCC information extracted in step S25 by the data structure extracting unit 27, and synchronizes. At the same time, data structures are extracted sequentially (step S28).

With the above operation, the data receiving apparatus 2 can receive a digital modulation signal having a frame structure in which data structures such as TS packets and IP packets are continuous in synchronization with the data structure.
Note that the operation of the data receiving device 2B (fourth embodiment) shown in FIG. 8 is basically the same as the operation of the data receiving device 2 except that one data area is a processing target. Omitted.

As described above, the data transmission device according to the first and second embodiments of the present invention and the data reception device according to the third and fourth embodiments have been described. However, the present invention has various modifications other than these configurations. It can be carried out.
Here, the pointer information indicating the position of the data structure and the data type information are added to the TMCC (control information). However, the pointer information or the like may be added to the head of the data area.
Hereinafter, a data transmission device and a data reception device that transmit continuous transmission data of a data structure by adding pointer information or the like to the head of the data area will be described.

[Other configuration of data transmission device]
First, another configuration of the data transmission apparatus will be described with reference to FIG. FIG. 10 is a block diagram showing a configuration of a data transmission apparatus according to the fifth embodiment of the present invention.
The data transmission apparatus 1C multiplexes a plurality of transmission data having a continuous data structure and transmits the multiplexed data as a digital modulation signal having a transmission frame structure. Here, the data transmission apparatus 1C includes a data structure arrangement means 10, a data area multiplexing means 11, a data area error correction addition means 12, a data area arrangement means 13, a TMCC arrangement means 14B, and a TMCC error correction addition. Means 15, framing means 16, modulating means 17, and pointer / data type adding means 18 are provided.

Further, here, the data transmission apparatus 1C includes data structure arrangement means 10 (10a, 10b,...) And pointer / data type addition means 18 (18a, 18b,...) Corresponding to the number of transmission data to be multiplexed. ing.
Since the configuration other than the TMCC arrangement unit 14B and the pointer / data type adding unit 18 is the same as the configuration of the data transmission apparatus 1 described with reference to FIG.

  The TMCC arrangement means 14B arranges the information of the error correction code output from the data area error correction addition means 12 in the TMCC (control area). The TMCC arrangement means 14B is different from the TMCC arrangement means 14 (see FIG. 2) in that pointer information and data type information are not set in TMCC. The pointer information and data type information are set in the data area by the pointer / data type adding means 18 described later.

  The pointer / data type adding means (data area pointer / type adding means) 18 is a pointer indicating the position of the head of the data structure included in the data area at the head of the data area output from the data structure array means 10. Information and data type information indicating the type of data in the data area are added. The data area to which the pointer information and the data type information are added is multiplexed in the data area multiplexing means 11.

Here, the arrangement of the data structures in the data area will be described with reference to FIG. FIG. 12 is a schematic diagram illustrating an arrangement example of the data structures in the data area of the transmission frame.
As shown in FIG. 12, the pointer information and the data type information are arranged at the head in the slot (data area). The pointer information may indicate a relative position from the head of the slot, or a position shifted from the head of the slot by the data length of the pointer information and data type information (position immediately after the pointer information and data type information). May be used as a reference position, and a relative position from the reference position may be indicated.
Returning to FIG. 10, the description of the configuration of the data transmission apparatus 1C will be continued.

  By configuring the data transmission apparatus 1C in this way, the data transmission apparatus 1C can transmit a plurality of transmission data in which data structures such as TS packets and IP packets are continuous, as in the data transmission apparatus 1 (see FIG. 2). It can be transmitted as a digital modulation signal having a frame structure. Further, the data transmission apparatus 1C can transmit the transmission data as a digital modulation signal having a frame structure without including the packet head even if the transmission data is data having no data structure such as stream data.

Further, here, the data transmission device 1C is configured to transmit a plurality of types of transmission data in a transmission frame having a plurality of slots (data areas), but one type of transmission data is used as a digital modulation signal. It is good also as a structure which transmits. In this case, for example, one data structure array means 10 is used, and a plurality of pointer / data type adding means 18 is one pointer adding means (data area pointer adding means) 18B to which no data type is added. By omitting the means 11, the data transmission device 1D (sixth embodiment) shown in FIG. 11 is configured.
Thereby, the data transmission device 1D can transmit one kind of predetermined transmission data as a digital modulation signal having a frame structure, like the data transmission device 1C.

The data transmission apparatuses 1C and 1D can be configured by a general computer including a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), etc. (not shown). Can be operated by a data transmission program that functions as each means described above.
The operations of the data transmission apparatuses 1C and 1D are the same as the operations of the data transmission apparatuses 1 and 1B, except that the arrangement destination of pointer information and the like is changed from the TMCC (control area) to the data area. The description is omitted.

[Other configuration of data receiving apparatus]
Next, another configuration of the data receiving apparatus will be described with reference to FIG. FIG. 13 is a block diagram showing a configuration of a data receiving apparatus according to the seventh embodiment of the present invention.
The data receiving device 2C receives the digital modulation signal having the transmission frame structure transmitted from the data transmission device 1C described in FIG. 10, and extracts a plurality of transmission data multiplexed on the digital modulation signal. It is. Here, the data receiving apparatus 2C includes a demodulating unit 20, a frame decoding unit 21, a data region extracting unit 22, a TMCC error correcting unit 23, a TMCC information extracting unit 24B, a data region error correcting unit 25, a data An area demultiplexing unit 26B, a data structure extracting unit 27, and a pointer / data type extracting unit 28 are provided.

  Further, here, the data receiving apparatus 2C includes data structure extraction means 27 (27a, 27b,...) And pointer / data type extraction means 28 (28a, 28b,...) Corresponding to the number of multiplexed transmission data. I have.

  Since the configuration other than the TMCC information extracting unit 24B, the data area demultiplexing unit 26B, and the pointer / data type extracting unit 28 is the same as the configuration of the data receiving apparatus 2 described with reference to FIG. Is omitted.

  The TMCC information extraction unit 24B extracts information arranged in the TMCC. Since no pointer information or data type information is set in the TMCC, the TMCC information extracting unit 24B extracts information such as an error correction code other than the pointer information and the data type information. 24 (see FIG. 7).

  The data area demultiplexing means 26B separates a plurality of data areas for each data type based on the data type information multiplexed in the data area. The data area for each data type separated by the data area demultiplexing means 26B is referred to by the pointer / data type extracting means 28a, 28B,... Corresponding to the data type.

The pointer / data type extracting means (data area pointer / type extracting means) 28 separates and extracts pointer information and data type information from the data area separated by the data area demultiplexing means 26B, and extracts the data area as a data structure. Are separated into regions having only The pointer information extracted by the pointer / data type extracting unit 28 is output to the data structure extracting unit 27 for each data type. Further, the data structure for each data type separated by the pointer / data type extracting unit 28 is referred to by the data structure extracting unit 27 based on the pointer information.
By configuring the data receiving device 2C in this way, the data receiving device 2C can, like the data receiving device 2 (see FIG. 7), a data structure such as a TS packet or an IP packet from a digital modulation signal having a frame structure Can extract and receive a plurality of continuous transmission data.

Here, the data receiving device 2C is configured to receive a digital modulation signal in which a plurality of types of transmission data are multiplexed in a plurality of slots (data areas). However, the data reception device 2C receives a single type of digital modulation signal. It is good also as a structure. That is, when receiving the digital modulation signal transmitted by the data transmission apparatus 1C described in FIG. 10, the data reception apparatus 2D (eighth embodiment) illustrated in FIG. 14 is configured.
This data receiving apparatus 2D has a single data structure extracting means 27 in the data receiving apparatus 2C (see FIG. 13), and a plurality of pointer / data type extracting means 28 is used to extract only pointer information. Means (data area pointer extracting means) 28B, and the data area demultiplexing means 26B is omitted.
As a result, the data reception device 2D can receive a digital modulation signal having a frame structure including one kind of predetermined transmission data in synchronization with the data structure.

  The data receiving devices 2C and 2D can be configured by a general computer including a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), etc. (not shown). Can be operated by a data reception program that functions as each of the above-described means.

  The operations of the data receiving devices 2C and 2D are the pointers attached to the data area instead of referring to the pointer information attached to the TMCC (control area) in the operations of the data receiving devices 2 and 2B, respectively. Since it is the same except that information is referred to, the description is omitted.

As described above, the data transmission device and the data reception device that transmit the continuous transmission data of the data structure by adding pointer information or the like to the head of the data area have been described. However, the present invention is not limited to these. is not.
For example, if the head of the data structure does not exist in the data area, or if it is stream data and pointer information is not required, a flag indicating the presence or absence of pointer information is added to TMCC. When the pointer information is not required by this flag, the data transmission efficiency can be improved by deleting the pointer information area from the data area.

It is explanatory drawing for demonstrating the structure of the transmission frame which the data transmission apparatus which concerns on embodiment of this invention transmits. It is a block diagram which shows the structure of the data transmission apparatus which concerns on 1st Embodiment of this invention. It is a block diagram which shows the structure of the data transmission apparatus which concerns on 2nd Embodiment of this invention. It is a flowchart which shows operation | movement of the data transmission apparatus which concerns on 1st Embodiment of this invention. It is a block diagram which shows the structural example of TMCC. It is a schematic diagram which shows the example of arrangement | positioning of the data structure in the data area of a transmission frame. It is a block diagram which shows the structure of the data receiver which concerns on 3rd Embodiment of this invention. It is a block diagram which shows the structure of the data receiver which concerns on 4th Embodiment of this invention. It is a flowchart which shows operation | movement of the data receiver which concerns on 3rd Embodiment of this invention. It is a block diagram which shows the structure of the data transmission apparatus which concerns on 5th Embodiment of this invention. It is a block diagram which shows the structure of the data transmission apparatus which concerns on 6th Embodiment of this invention. It is a schematic diagram which shows the example of arrangement | positioning of the data structure in the data area of a transmission frame. It is a block diagram which shows the structure of the data receiver which concerns on 7th Embodiment of this invention. It is a block diagram which shows the structure of the data receiver which concerns on 8th Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Data transmission apparatus 10 Data structure arrangement means 11 Data area multiplexing means 12 Data area error correction addition means 13 Data area arrangement means 14 TMCC area arrangement means (control area pointer / type addition means)
14B TMCC area arranging means (control area pointer adding means)
15 TMCC error correction adding means 16 Framing means 17 Modulating means 18 Pointer / data type adding means (data area pointer / type adding means)
18B Pointer adding means (data area pointer adding means)
2 Data receiving device 20 Demodulating means 21 Frame decoding means 22 Data area extracting means 23 TMCC error correcting means 24 TMCC information extracting means (control area pointer / type extracting means)
24B TMCC information extraction means (control area pointer extraction means)
25 Data area error correction means 26 Data area demultiplexing means 27 Data structure extraction means 28 Pointer extraction means (data area pointer / type extraction means)
28B pointer extraction means (data area pointer extraction means)

Claims (11)

Data transmission apparatus for transmitting continuous transmission data of a data structure as a digital modulation signal having a data area independent of the structure of the data structure and a control area for controlling the data area as a transmission frame structure Because
Data structure arrangement means for arranging the data structure of the transmission data for each data area;
In the data area arranged by the data structure arrangement means, control area pointer adding means for adding pointer information indicating the position of the earliest data structure having the first data in the data structure to the control area;
Framing means for configuring the data area and the control area as a predetermined transmission frame;
A data transmission device comprising: A digital modulation signal comprising a plurality of transmission data composed of different data structures as a transmission frame structure having a plurality of data areas independent of the structure of the data structures and a control area for controlling the data areas A data transmission device for transmitting as
A plurality of data structure arrangement means for arranging data structures of the plurality of transmission data for each of the data areas;
In the data area arranged by the data structure arrangement means, pointer information indicating the position of the earliest data structure having the first data in the data structure and type information indicating the type of the transmission data are displayed in the control area. A control area pointer / type adding means to be added to,
Framing means for configuring the data area and the control area as a predetermined transmission frame;
A data transmission device comprising:   The framing means, when configuring the control area and the data area, framing the control area into an area where modulation is performed using a modulation scheme having higher transmission error resistance than the data area. The data transmission device according to claim 1, wherein the data transmission device is a data transmission device.   When the framing means configures the control area and the data area, the control area is framed into an area where error correction is performed using an error correction method having higher transmission error tolerance than the data area. The data transmission device according to claim 1, wherein the data transmission device is a data transmission device. A data transmission apparatus for transmitting continuous transmission data of a data structure as a digital modulation signal having a data area independent of the structure of the data structure as a transmission frame structure,
Data structure arrangement means for arranging the data structure of the transmission data for each data area;
In the data area arranged by the data structure arrangement means, data area pointer addition means for adding pointer information indicating the position of the earliest data structure having the first data in the data structure to the data area;
Framing means for configuring the data area as a predetermined transmission frame;
A data transmission device comprising: A data transmission device for transmitting a plurality of transmission data configured with different data structures as a digital modulation signal having a plurality of data regions independent of the structure of the data structure as a transmission frame structure,
A plurality of data structure arrangement means for arranging data structures of the plurality of transmission data for each of the data areas;
In the data area arranged by the data structure arrangement means, pointer information indicating the position of the earliest data structure having the first data in the data structure and type information indicating the type of the transmission data are stored in the data area. A data area pointer / type adding means to be added to
Framing means for configuring the data area as a predetermined transmission frame;
A data transmission device comprising:   2. The pointer information according to claim 1, wherein when the first data in the data structure is not included in the data area, the pointer information is set to a value larger than a maximum position indicating the data area. The data transmission device according to any one of claims 6 to 7. A data receiving device for receiving a digital modulation signal transmitted from the data transmission device according to claim 1,
Demodulation means for demodulating the digital modulation signal;
Frame detection means for detecting a transmission frame from the signal demodulated by the demodulation means;
Data area extraction means for extracting a data area constituting the transmission frame from the transmission frame detected by the frame detection means;
Control area pointer extraction means for extracting pointer information indicating the position of the data structure from a control area for controlling the data area constituting the transmission frame;
Data structure extraction means for sequentially extracting data structures from the data area based on the pointer information extracted by the control area pointer extraction means;
A data receiving apparatus comprising: A data receiving device for receiving a digital modulation signal transmitted from the data transmission device according to claim 2,
Demodulation means for demodulating the digital modulation signal;
Frame detection means for detecting a transmission frame from the signal demodulated by the demodulation means;
Data area extraction means for extracting a data area constituting the transmission frame from the transmission frame detected by the frame detection means;
A control area pointer / type extracting means for extracting pointer information indicating the position of the data structure and type information indicating the type of the transmission data from a control area for controlling the data area constituting the transmission frame;
Based on the pointer information and type information extracted by the control area pointer / type extracting means, data structure extracting means for sequentially extracting the data structure for each type from the data area;
A data receiving apparatus comprising: A data receiving device for receiving a digital modulation signal transmitted from the data transmission device according to claim 5,
Demodulation means for demodulating the digital modulation signal;
Frame detection means for detecting a transmission frame from the signal demodulated by the demodulation means;
Data area extraction means for extracting a data area constituting the transmission frame from the transmission frame detected by the frame detection means;
A data area pointer extracting means for extracting pointer information indicating the position of the data structure from the data area extracted by the data area extracting means;
Data structure extraction means for sequentially extracting data structures from the data area based on the pointer information extracted by the data area pointer extraction means;
A data receiving apparatus comprising: A data receiving device for receiving a digital modulation signal transmitted from the data transmission device according to claim 6,
Demodulation means for demodulating the digital modulation signal;
Frame detection means for detecting a transmission frame from the signal demodulated by the demodulation means;
Data area extraction means for extracting a data area constituting the transmission frame from the transmission frame detected by the frame detection means;
A data area pointer / type extracting means for extracting pointer information indicating the position of the data structure and type information indicating the type of the transmission data from the data area extracted by the data area extracting means;
Based on the pointer information and type information extracted by the data area pointer / type extracting means, data structure extracting means for sequentially extracting the data structure for each type from the data area;
A data receiving apparatus comprising:

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