JPWO1997000577A1 - Data transmission equipment - Google Patents

Abstract

(57) [Abstract] A data transmission device (1) comprises a data transmitting device (10) and a data receiving device (20). The data transmitting device (10) compresses and encodes input data (VIN) using an interframe compression encoding method or the like, stores the encoded data in the payload portion of a transmission packet together with playback data indicating a playback method for variable speed playback on the receiving side, and transmits the result to the receiving device (20). That is, the transmission data to be transmitted, such as AV data, and the playback data required for processing such as variable speed playback are included in the same transmission packet and transmitted. The data receiving device (20) separates the compressed AV data and playback data from the received SDDI transmission packet, decompresses and decodes the compressed AV data, and performs variable speed playback of the AV data, such as fast forwarding, based on the separated playback data.

Description

Detailed Description of the Invention: Data Transmission Device Technical Field The present invention relates to a data transmission device (data transmission system) in which the transmitting side performs predetermined signal processing such as compression on audio/video data and transmits the data, and the receiving side receives and reproduces the transmitted data. In particular, the present invention relates to a data transmission device that enables information to be subjected to variable speed reproduction processing on the receiving side, such as audio/video data, to be efficiently transmitted from the transmitting side to the receiving side.

BACKGROUND ART The serial digital interface (SDI) system is used as a signal transmission method for transmitting digital audio and video data (hereinafter simply referred to as AV data) between devices used for video editing and other purposes. The SDI signal format is standardized as SMPTE-295M by the Society of Motion and Television Engineering (SMPTE) as a standard for digital video and audio signals.

The SDI standard is used to transmit digital AV data in the D1 component video format and the D2 composite video format, with a transmission speed of 270 MHz.

However, the SDI format is limited in its use, transmitting only one channel of uncompressed AV data and eight channels of baseband audio signals. This makes the SDI format unsuitable for meeting the growing demand for multimedia and multi-channel content in the fields of broadcasting and video editing.

Recently, Sony has proposed the SDDI (Serial Digital Data Interface) system, which is capable of transmitting multiple uncompressed AV data streams, AV data compressed using interframe predictive coding, or computer data, and which can utilize the existing SDI transmission facilities.

In television broadcasting stations, video equipment such as VTRs used for video editing and video editing equipment are connected by routers, and SDDI AV data sent from any device is input to any other device via the router.

In a system (e.g., an AV server system) in which multiple video devices are connected via such a router, it may be necessary to perform variable-speed playback, which changes the playback speed of AV data during playback.

To perform variable speed playback, it is necessary for the AV data transmitter to transmit data indicating how to play the AV data to the receiver.

For example, if you want the receiving video equipment to perform variable-speed playback of compressed AV data, the transmitting video equipment must transmit to the receiving video equipment write control data for writing the AV data into frame memory after decompressing and decoding the compressed AV data, and read control data for reading the stored AV data from frame memory.

However, transmitting transmission data such as AV data and playback data, such as control data related to the frame memory, which indicates how to play back the transmitted AV data, separately poses the problem of requiring separate equipment for transmitting the transmission data and the playback data.

Furthermore, if the transmission data and playback data are transmitted via separate facilities, it becomes difficult to synchronize the transmission data and playback data.

DISCLOSURE OF THE INVENTION The object of the present invention is to provide a data transmission device capable of transmitting, in the same transmission packet, transmission data (e.g., AV data) and playback data indicating a playback method for the transmission data, such as variable-speed playback.

Another object of the present invention is to provide a data transmission device that can transmit both transmission data and playback data in the same transmission packet, thereby enabling these data to be transmitted using the same equipment.

It is still another object of the present invention to provide a data transmission device which can transmit transmission data and playback data in the same transmission packet, thereby easily achieving synchronization between these data.

The data transmission device of the present invention transmits transmission data from a transmitting device to a receiving device using transmission packets having at least a control portion containing data for transmission control and a data portion containing the transmission data to be transmitted. The transmitting device includes a playback data generation means for generating playback data indicating how to play back the transmission data, a data storage means for storing the playback data and the transmission data in the transmission packet, and a transmitting means for transmitting the transmission packet containing the playback data and the transmission data to the receiving device. The receiving device includes a receiving means for receiving the transmission packets sent by the transmitting device, a data separation means for separating the playback data and the transmission data from the received transmission packet, and a data reproduction means for reproducing the transmission data based on the playback data.

The transmission data is preferably audio and video data.

The data reproduction means of the receiving device includes memory control means and memory means for storing the transmission data separated by the data separation means under the control of the memory control means and outputting the stored transmission data. The reproduction data generation means of the transmitting device generates the reproduction data indicating the storage area of the memory means in which the transmission data is stored and the storage area of the transmission data to be output from the memory means. The memory control means of the data reproduction means of the receiving device sequentially stores the transmission data separated by the data separation means in the storage areas of the memory means indicated by the reproduction data separated by the data separation means, and outputs the transmission data stored in the storage areas of the memory means indicated by the reproduction data separated by the data separation means.

The data transmission device according to the present invention transmits transmission data from a transmitting device to a receiving device using the above-described SDDI transmission packets, i.e., transmission packets having a control portion (ancillary data portion; ANC) containing data for transmission control, and a data portion (payload portion; PAD) containing the transmission data to be transmitted. Here, the transmission control data refers to synchronization signals such as horizontal (H) synchronization, vertical (V) synchronization, and frame synchronization.

In the transmitting device of the data transmission device according to the present invention, the playback data generating means generates playback data indicating which storage area in the frame memory of the receiving device is to store the transmission data and which storage area in the frame memory is to output the stored transmission data.

The data storage means stores playback data and transmission data (uncompressed AV data, compressed AV data, or computer data) in SDDI transmission packets.

The transmitting means transmits the transmission packets in which the playback data and transmission data are stored by the data storing means to the receiving device via a predetermined transmission path.

In addition, in the receiving device of the data transmission device according to the present invention, the receiving means receives an SDDI transmission packet transmitted by the transmitting device from a predetermined transmission path.

The data separating means separates the playback data and the transmission data from the SDDI transmission packets received by the receiving means.

For example, when the transmission data is compressed AV data, the data playback means first performs decompression/decoding processing, then sequentially stores the decompressed/decoded transmission data in storage areas of the frame memory specified by the separated playback data, and then sequentially outputs the decompressed/decoded transmission data stored in the storage areas specified by the separated playback data.

For example, if the playback data specifies that the transmitted data be stored in contiguous storage areas within the frame memory and that every other frame be output, the data playback method would be forward double speed playback; if the playback data specifies that the frames be output in reverse, the data playback method would be reverse playback.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects and features of the present invention will become more apparent from the following description taken in conjunction with the accompanying drawings. Figure 1 shows the configuration of a data transmission device according to the present invention.

2A-2C show the frame structure of the SDDI format, an improved version of the SDI format standardized in SMPTE-295M that can be used for compressed data transmission, etc. Fig. 2A shows the frame structure of the SDDI format, Fig. 2B shows a transmission packet for the SDDI format, and Fig. 2C is a graph showing a transmission signal for the SDDI format.

FIG. 3 shows the contents of the playback data included in the payload portion of the transmission packet on line 12 of the SDDI frame shown in FIGS. 2A to 2C.

FIG. 4 is a diagram showing the configuration of a data transmission system having a plurality of data transmitting devices and a plurality of data receiving devices shown in FIG.

BEST MODE FOR CARRYING OUT THE INVENTION First Embodiment A first embodiment of the data transmission device of the present invention will now be described.

As shown in FIG. 1, data transmission device 1 comprises a data transmitting device 10 and a data receiving device 20 connected by a predetermined transmission path 50 suitable for transmission signals of the SDDI system proposed by Sony Corporation. Data transmitting device 10 comprises an AV data processing device 12, an SDDI encoder circuit 14, a playback control data generating circuit 16, and a transmitting circuit 18. Data receiving device 20 comprises a receiving circuit 22, an SDDI decoder 24, an AV data processing circuit 26, a frame memory 28, a memory control circuit 30, and a device control circuit 32.

Before describing each component of the data transmission device 1, the structure of an SDDI frame, the structure of a transmission packet, and a transmission signal will be described.

As shown in Figure 2A, in the SDDI format, one frame consists of 525 lines (or 625 lines; hereafter, the numbers in parentheses indicate the 625-line configuration), just like in the SDI format. As shown in Figure 2B, SDDI transmission packets are handled internally by the data transmitting device 10 and the data receiving device 20 as 10-bit parallel data at 27 Mbps. The first four words of each line in the transmission packet are used as the end of active video (EAV), the next 276 words (268 words) are used as an ancillary data section (ANC) that stores specified control data, the next four words are used as the start of active video (SAV), and the next 1,440 words are used as the payload section (PAD) that stores uncompressed AV data, compressed AV data, or computer data. The transmission packet shown in Figure 2B is transmitted over the transmission path 50 as a 270 Mbps 1-bit serial transmission signal, as shown in Figure 2C.

Next, each component of the data transmission device 1 will be described.

The data transmitter 10 of the data transmission device 1 first stores the input data VIN in the payload section PAD of the SDDI transmission packet shown in FIG. 2B as the transmission data to be transmitted, either uncompressed or compressed and encoded using an inter-frame compression encoding method or the like. Next, playback data indicating a playback method for variable-speed playback or the like on the receiving side is stored in the payload section PAD of the transmission packet corresponding to a predetermined line of the frame, and these transmission packets are transmitted to the data receiving device 20 via the transmission path. In this embodiment of the present invention, the playback data is stored in the 12th line of the frame for transmission.

In the data transmission device 10, the AV data processing device 12 compresses and encodes input data VIN, such as uncompressed AV data played back from an AV data recording device such as a digital video tape recorder (digital VTR) or computer data, using an inter-frame predictive coding method such as an image compression method specified by the Moving Picture Expert Group (MPEG), in response to external operations, or outputs the compressed data directly to the SDDI encoder circuit 14 as transmission data S12.

The playback data generation circuit 16 generates write memory addresses and read memory addresses in accordance with instruction data for variable speed playback input by the operator of the data transmission device 1 from an external device, such as a terminal device (not shown), connected to the playback data generation circuit 16, and outputs each of these to the SDDI encoder circuit 14.

Of these addresses generated by the playback data generation circuit 16, the write address indicates the storage area in the frame memory 28 where the frame data containing the transmission packet is stored. The read memory address indicates the storage area where the frame data to be read from the frame memory 28 is recorded.

The SDDI encoder circuit 14 stores the write memory address and read memory address output from the playback data generation circuit 16 in the payload section PAD of the transmission packet for the 12th line and subsequent lines of the frame shown in FIG. 3, and stores the transmission data S12 output from the AV data processing device 12 in the payload section PAD of the transmission packet for each line of the frame shown in FIG. 2A from the 13th line and subsequent lines. Furthermore, the SDDI encoder circuit 14 stores predetermined transmission control data in the ancillary data section ANC of the transmission packet for a predetermined line (in this embodiment, the same line as the 12th line of the frame in which the playback data is stored), and outputs the transmission packet to the transmitter circuit 18.

The transmission circuit 18 sequentially converts the transmission packets output from the SDDI encoder circuit 14 from parallel to serial, as shown in FIG. 2C, to generate a transmission signal, which is then transmitted to the transmission path 50.

The data receiving device 20 first separates the transmission data, such as uncompressed or compressed AV data, and the playback data from the SDDI transmission packets sent from the data transmitting device 10. If the transmission data is compressed AV data, for example, it decompresses and decodes it, and performs variable-speed playback of the AV data, such as normal playback or fast-forward or slow-forward playback, based on the separated playback data.

In the data receiving device 20, the receiving circuit 22 receives the transmission packets transmitted from the data transmitting device 10 via the transmission line, performs serial-to-parallel conversion, and outputs the converted packets to the SDDI decoder 24.

The SDDI decoder 24 first separates the write memory address and read memory address stored in the payload section PAD of the transmission packet for the 12th line of an SDDI-formatted frame received by the receiving circuit 22, and outputs them as control signal C30 to the memory control circuit 30. Next, it separates the transmission control data stored in the ancillary data section ANC of the transmission packet for the 12th line of the frame, and outputs this as control signal C32 to the device control circuit 32. It also separates the transmission data stored in the payload section PAD of the transmission packets for the 13th and subsequent lines, and outputs this as transmission data S24 to the AV data processing circuit 26.

The device control circuit 32 controls the operation of each component of the data receiving device 20 based on the control signal C30.

If the transmission data S24 is compressed AV data, the AV data processing circuit 26 decompresses and decodes the transmission data S24 output from the SDDI decoder 24. If the transmission data S24 is uncompressed AV data or data for computer use, the AV data processing circuit 26 outputs the transmission data S24 as is to the frame memory 28 as transmission data S26.

Based on the control signal C30, the memory control circuit 30 controls the frame memory 28 using the control signal C28 to first store the received transmission data S26 in a storage area in the frame memory 28 indicated by the write memory address separated by the SDDI decoder 24. Next, the data stored in the storage area indicated by the read memory address of the transmission data S26 stored in the frame memory 28 is output as output data VOUT.

The frame memory 28 has a storage area divided into multiple areas corresponding to each frame. Under the control of the memory control circuit 30, the transmission data S24 input from the AV data processing circuit 26 is stored sequentially in frame units and output as output data VOUT. By adjusting the write and read speeds of data to and from the frame memory 28, normal playback or variable-speed playback can be achieved. In other words, the playback speed is determined by the write and read addresses of the frame memory 28 provided by the transmitting side as playback data.

If multiple data receiving devices 20 are connected to a data transmission system to which the data transmitting device 1 is applied, it is preferable to share the storage area of the frame memory 28, since this simplifies address management in the data transmitting device 10 and eliminates the need to manage addresses for each data receiving device.

The operation of the data transmission device 1 will be described below using as an example a case where compressed AV data is transmitted from the data transmission device 10 to the data reception device 20 as transmission data.

In the data transmission device 10, the AV data processing device 12 compresses and encodes uncompressed AV data using an inter-frame predictive coding method.

AV data compressed and encoded using an inter-frame predictive encoding method such as MPEG must be decompressed and decoded in units called GOPs (Groups of Pictures). Therefore, in the data transmission device 1, the transmission data compressed and encoded in the AV data processor 12 must be handled in GOP units until it is decompressed and decoded in the AV data processing circuit 26 of the data receiving device 20.

To meet this need, the playback data generation circuit 16 receives a timing signal for generating a GOP from the AV data processor 12 via the control signal C12, as shown by the dotted line in FIG. 1, and generates write memory addresses indicating areas in the frame memory 28 where the transmitted data is to be stored, in synchronization with this timing signal. The playback data generation circuit 16 then generates read memory addresses based on instruction data instructing variable speed playback and outputs them to the SDDI encoder circuit 14.

The operation of the playback data generation circuit 16 will be explained using a specific example. If the frame memory 28 is divided into storage areas 0 through p, each corresponding to a frame, the playback data generation circuit 16 generates write memory addresses that cyclically address each frame's data into the frame memory 28, for example, 0, 1, 2, ..., p, 1, 2, 3, ..., where p is an integer.

Furthermore, the playback data generation circuit 16 generates read memory addresses that enable variable-speed playback. For example, in the case of 1x playback, read memory addresses are generated that circularly address memory areas 0, 1, 2, ..., p, 0, 1, 2, 3, ..., similar to the write memory addresses. In the case of 2x playback, read memory addresses are generated that skip every other memory area, such as memory areas 0, 2, 4, ..., 2q, 0, 2, 4, ..., or memory areas 1, 3, 5, ..., (2q - 1), 1, 3, ..., where q is an integer; this example assumes p = 2q. For example, in the case of reverse playback, read memory addresses are generated to address storage areas p, p-1, ..., 1, 0, p, ... in that order. In the case of forward playback at twice the speed, read memory addresses are generated to address storage areas 0, 0, 1, 1, ..., p, p0, 0, ... in that order.

The write memory address and read memory address generated by the playback data generation circuit 16 are generated and used independently. For example, if the transmitted data is compressed AV data, the data is received by the receiving device, decoded, and expanded, and then stored in the memory area specified by the write memory address transmitted simultaneously in the same transmission packet. In this case, because the transmitted data is decoded and expanded, it may take several frames' worth of time for it to actually be stored in the frame memory and become available for reading.

Therefore, the read address may be generated after a time that takes into account the decoding and decompression processing time, stored in the transmission packet, and transmitted.

In this way, read memory addresses can be generated and transmitted independently of write memory addresses, eliminating the need to wait for compressed AV data to be decoded and decompressed before reading frame data from the frame memory.

If the transmitted data is uncompressed AV data or computer data, no decoding/decompression processing is required. Therefore, when the transmission packet is received by the receiving device, the address at which the data of the frame to be read from the frame memory is stored is generated as the read memory address and transmitted.

The above-described read memory address generation method by the playback data generation circuit 16 is the same when AV data is played back by the data receiving device 20 in a faster forward direction, a faster reverse direction, frame-by-frame playback, or still playback.

The SDDI encoder circuit 14 stores the write memory address and read memory address output from the playback data generation circuit 16 in the payload section PAD of the transmission packet for the 12th line of the SDDI frame. It also stores the transmission data S12 output from the AV data processing device 12 in the payload section of each line from the 13th line onwards. The transmission circuit 18 sequentially transmits the transmission packets output from the SDDI encoder circuit 14 to the transmission path.

In the data receiving device 20, the receiving circuit 22 receives the transmission packet sent from the data transmitting device 10.

The SDDI decoder 24 separates the write memory address and read memory address from the payload section PAD in the transmission packet for the 12th line of the SDDI frame shown in FIG. 3, and separates the transmission data from the payload section PAD of the transmission packets for each line from the 12th line onwards. The separated write memory address and read memory address are output as control signal C30 to the memory control circuit 30. The separated transmission data is output as transmission data S24 to the AV data processing circuit.

The AV data processing circuit 26 expands and decodes the transmission data S24.

The memory control circuit 30 controls the frame memory 28 using the control signal C28 to sequentially store the AV data (transmission data S26) decompressed and decoded by the AV data processing circuit 26 in the storage area of the frame memory 28 indicated by the write memory address, and also outputs the frame data stored in the storage area of the frame memory 28 indicated by the read memory address as output data VOUT.

As described above, by configuring the data transmission device 1, it is possible for the data transmitting device 10 to instruct the data receiving device 20 on the variable speed playback method, etc.

Furthermore, SDDI transmission packets can contain multiple compressed AV data streams in a single payload, making it possible to simultaneously control variable speed playback of multiple AV data streams.

In the first embodiment, the operation of the data transmission device 1 has been described in connection with a case where compressed AV data is used as the transmission data, but the same applies to a case where uncompressed AV data is used as the transmission data.

Furthermore, the data transmission device 1 may be configured to transmit, for example, data for applying special effects to the transmitted data as playback data, data required for decompressing and decoding the transmitted data, or data used for editing AV data.

The frame memory 28 may be configured as a semiconductor memory, a hard disk drive (HDD), a magneto-optical (MO) disk drive, or the like.

Furthermore, in the data transmission device 1, it is preferable to transmit all frames contained in the AV data from the data transmitting device 10 to the data receiving device 20, regardless of whether normal playback or variable speed playback is being performed. This is because variable speed playback at any desired speed is possible simply by changing the playback data. However, depending on the application of the data transmission device 1, it may be configured to transmit only the data necessary for variable speed playback during variable speed playback.

Second Embodiment A second embodiment of the data transmission device of the present invention will now be described.

Figure 4 shows the configuration of a data transmission system 4 having a plurality of data transmitting devices 10 and a plurality of data receiving devices 20 shown in Figure 1. Note that among the components of the data transmission system 4 shown in Figure 4, components that are the same as those of the data transmission device 1 shown in Figure 1 are designated by the same reference numerals.

As shown in FIG. 4, the data transmission system 4 includes m data transmission devices 10₁ ~10_m, data transmission device 10₁~10_mConnected to each other are digital VTR devices, image processing devices, computers, and other data generating devices 42₁~42_m, n data receiving devices 20₁~20_n, n data receiving devices 20₁~20_nVideo equipment 44 such as a monitor device connected to each₁~44_n, any data transmission device 10₁~10_m and any data receiving device 20₁~20_n(m, n are integers) and a routing control device 46 that controls the connection relationships between the router devices 40.

As shown in FIG. 4, a data generating device 42 for generating AV data etc.₁~42_m Data transmission device 10 in one-to-one correspondence₁~10_mThe router device 40 is provided to transmit the data to the data transmission device 10.₁~10_mand the data receiving device 20₁~20_nBy connecting between the data transmission device 10₁~10_mA transmission signal sent from either of the data receiving devices 20₁~20_nIt is possible to perform variable speed playback etc. at one or more of the above. In this case, as mentioned in the first embodiment, the data transmission device 10₁~10_mIt is preferable that the addresses for specifying the storage areas in the frame memories 28 are common to all the frame memories 28.

The present invention is not limited to the specific configuration and processing described above, and various modifications are possible.

As described above, the data transmission device according to the present invention allows transmission data, such as AV data, to be transmitted and playback data required for playback of the transmission data to be included in the same transmission packet and transmitted over the same transmission path.

Furthermore, the data transmission device of the present invention allows transmission data and playback data to be transmitted in the same transmission packet, enabling these data to be transmitted using the same equipment. This reduces the amount of wiring required when installing the data transmission device of the present invention and simplifies installation work.

Furthermore, according to the present invention, the transmission data and the playback data can be transmitted in the same transmission packet, which facilitates synchronization between these data.

Although the above embodiment has been described with reference to variable speed playback, the present invention is not limited to variable speed playback. Transmission data and command data for processing the data can be simultaneously stored and transmitted in packets using the SDDI format.

INDUSTRIAL APPLICABILITY The data transmission device of the present invention can be applied to the transmission of digital data in a variety of fields.

───────────────────────────────────────────────────── (Note) This publication is based on the publication published internationally by the International Bureau of Patents (WIPO). The effect of the international publication of the Japanese patent application (Japanese utility model registration application) related to this publication arises pursuant to Article 184-10, Paragraph 1 of the Patent Act (Article 48-13, Paragraph 2 of the Utility Model Act) and is unrelated to this publication.

Claims (1)

[Claims] 1. A data transmission device (1) transmits transmission data from a transmitting device (10) to a receiving device (20) via a transmission path (50) using transmission packets having at least a control portion containing data for transmission control and a data portion containing the transmission data to be transmitted. The transmitting device (10) comprises: a playback data generating means (16) for generating playback data indicating how to play back the transmission data; a data storing means (12 and 14) for storing the playback data and the transmission data in the transmission packet; a transmitting means (18) for transmitting the transmission packet containing the playback data and the transmission data to the receiving device; The receiving device (20) comprises: a receiving means (22) for receiving the transmission packet transmitted by the transmitting device; a data separating means (24) for separating the playback data and the transmission data from the received transmission packet, and data reproduction means (26, 28, 30) for reproducing the transmission data based on the reproduction data. 2. The data transmission device according to claim 1, wherein the data reproduction means of the receiving device comprises: memory control means (30); and memory means (28) for storing the transmission data separated by the data separation means under control of the memory control means and outputting the stored transmission data. 3. The data transmission device according to claim 2, wherein the reproduction data generation means (16) of the transmitting device generates the reproduction data indicating a storage area within the memory means in which the transmission data within the data reproduction means of the receiving device is stored and a storage area within the memory for the transmission data output from the memory means. 6. The data transmission device of claim 3, wherein the memory control means of the data reproduction means of the receiving device sequentially stores the transmission data separated by the data separation means in storage areas within the memory means indicated by the reproduction data separated by the data separation means, and outputs the transmission data stored in storage areas within the memory means indicated by the reproduction data separated by the data separation means. 7. The data transmission device of claim 1, wherein the transmission data is audio data and/or video data. 8. The data transmission device of claim 7, wherein the reproduction data is data indicating conditions for normal reproduction or variable speed reproduction of the transmission data. 9. The data transmission device of claim 8, wherein the reproduction data generated by the reproduction data generation means comprises a write memory address indicating the storage area within the memory means where the transmission data is stored, and a read memory address indicating the storage area within the memory means of the transmission data output from the memory means. 10. The data transmission device of claim 7, wherein the video data of the transmission data is compression-encoded video data. 11. The data transmission device of claim 10, wherein the data storage means includes compression-encoding means for compression-encoding uncompressed transmission data. 12. The data transmission device of any one of claims 6 to 11, wherein the playback data is stored in the payload section of a predetermined line of a data format in which ancillary sections and payload sections are arranged in multiple rows in a second direction, the playback data is stored in the payload section of a line following the predetermined line in which the playback data is stored, and the playback data and transmission data are transmitted in packets. 13. A data transmission device transmits transmission data from a transmitting device to a receiving device via a transmission path (50) using transmission packets having at least a control portion containing data for transmission control and a data portion containing the transmission data to be transmitted, wherein the transmitting device comprises: a playback data generation means for generating playback data indicating a method for reproducing the transmission data; a data storage means for storing the playback data and the transmission data in the transmission packet; and a transmission means for transmitting the transmission packet containing the playback data and the transmission data to the receiving device; and the playback data generation means of the transmitting device generates the playback data indicating a storage area in a memory means in which the transmission data in the receiving device is stored and a storage area in the memory for the transmission data to be output from the memory means. 14. A data transmission device transmits transmission data from a transmitting device to a receiving device using transmission packets having at least a control portion containing data for transmission control and a data portion containing the transmission data to be transmitted. The receiving device includes: a receiving means for receiving the transmission packets transmitted by the transmitting device and containing the transmission data and playback data indicating how to play back the transmission data; a data separation means for separating the playback data and the transmission data from the received transmission packets; and a data playback means for playing back the transmission data based on the playback data. The data playback means of the receiving device includes: a memory control means; and a memory means for storing the transmission data separated by the data separation means under the control of the memory control means and outputting the stored transmission data. The memory control means of the data means of the receiving device includes: A data transmission device characterized in that the transmission data separated by the data separation means is sequentially stored in storage areas within the memory means indicated by the playback data separated by the data separation means, the transmission data stored in storage areas within the memory means indicated by the playback data separated by the data separation means is output, and the playback data generated by the playback data generation means comprises a write memory address indicating the storage area within the memory means in which the transmission data is stored and a read memory address indicating the storage area within the memory means of the transmission data to be output from the memory means. 15. A data transmission device transmits transmission data from a data transmitting device to a receiving device via a transmission path using transmission packets having at least a control portion containing data for transmission control and a data portion containing the transmission data to be transmitted. The transmitting device comprises: a playback data generating means for generating playback data indicating how to play back the transmission data; a data storing means for storing the playback data and the transmission data in the transmission packet; and a transmitting means for transmitting the transmission packet containing the playback data and the transmission data to the receiving device. The receiving device comprises: a receiving means for receiving the transmission packet transmitted by the transmitting device; a data separating means for separating the playback data and the transmission data from the received transmission packet; and a data reproducing means for reproducing the transmission data based on the playback data. The video data in the transmission data is compression-encoded video data. The reproduction data generation means of the transmitting device generates reproduction data indicating the storage area within the memory means where the transmission data is stored and the storage area within the memory of the transmission data output from the memory means; The data reproduction means of the receiving device includes memory control means and memory means for storing the transmission data separated by the data separation means under the control of the memory control means and outputting the stored transmission data; The memory control means of the data reproduction means of the receiving device sequentially stores the transmission data separated by the data separation means in the storage areas within the memory means indicated by the reproduction data separated by the data separation means and outputs the transmission data stored in the storage areas within the memory means indicated by the reproduction data separated by the data separation means; The reproduction data generated by the reproduction data generation means comprises a write memory address indicating the storage area within the memory means where the transmission data is stored and a read memory address indicating the storage area within the memory means of the transmission data to be output from the memory means. 16. The data transmission device of claim 15, wherein the transmission data is audio data and/or video data. 17. The data transmission device of claim 16, wherein the playback data indicates conditions for normal playback or variable speed playback of the transmission data, and the playback data generated by the playback data generation means comprises a write memory address indicating a storage area within the memory means in which the transmission data is stored, and a read memory address indicating a storage area within the memory means for the transmission data output from the memory means. 18. The data transmission device of claim 17, wherein the video data of the transmission data is compression-encoded video data. 19. The data transmission device of claim 18, wherein the data storage means includes compression-encoding means for compression-encoding uncompressed transmission data. 20. The data transmission device of any one of claims 16 to 19, wherein the playback data is composed of an ancillary section and a payload section in a first direction, and is stored in the payload section of a predetermined line of a data format in which these ancillary sections and payload sections are arranged in multiple rows; the transmission data is stored in the payload section of the line following the line in which the playback data is stored; and the playback data and transmission data are transmitted in packets.