JP2000092020A - Digital signal transmission system, digital signal transmitter, digital signal receiver and digital signal transmission method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow a digital signal receiver side to control an operation of a digital signal transmitter in real time without using a high capacity buffer by allowing the receiver to transmit a control signal used to control the operation of the transmitter through the use of a frequency band reserved in advance in a transmission channel. SOLUTION: A buffer read control section 106 adjusts the data quantity from a 1st buffer section 103 so that the quantity of data stored in a 2nd buffer section 123 of a digital signal receiver 121 is constant. Just after start of operation, a buffer quantity management section 125 informs a buffer read control section 106 of a quantity of data according to which a quantity of data stored in the 2nd buffer section 123 is a designated quantity as a request data quantity via a 2nd digital interface 124 and a 1st digital interface 104. The information denoting the quantity of data is transmitted by using a time slot of a frame reserved exclusive for signal transmission from the digital signal receiver 121 to the digital signal transmitter 101.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital signal transmitting device for transmitting digital data to a transmission line, and a digital signal receiving device for receiving digital data from the transmission line and decoding the digital data.

[0002]

2. Description of the Related Art In recent years, DVDs (Digital Versatile Dis
c) -Video (hereinafter referred to as DVD) has been widely used. Digital signals including video, audio and other data are stored in the DVD, and are reproduced using a DVD player. For DVD, video data is ISO
/ IEC13818 standard (MPEG: Moving Pictu
re Expert Group), and compressed and recorded.

FIG. 2 is a block diagram showing an example of a DVD player.
Shown in In FIG. 2, reference numeral 201 denotes a DVD player;
Is a disk drive including a DVD, 203 is a buffer unit, 204 is a decoder unit, 205 is a read control unit,
06 is a user control processing unit.

[0004] Presentation data, which is information such as video, audio, and related data, and navigation data that describes the order of presentation data and the behavior during playback are written on the DVD. In the read control unit 205, the DV
An instruction is issued to read data from D, and the presentation data is transmitted to the buffer unit 203. Buffer unit 20
3, the supply of the presentation data to the decoder unit 204 starts when a certain amount of presentation data is accumulated. The decoder unit 204 sequentially decodes according to the timing information described in the presentation data, and outputs it as video, audio, and other data signals. Every time the decoder 204 decodes the presentation data, the decoder 204 requests the buffer 203 for the next presentation data to be decoded, and continuously decodes and outputs the data.

[0005] By inputting a user control command to the DVD player, the user can perform special reproduction such as menu selection, fast forward / rewind, and the like. The reproduction control signal from the user is sent to the decoder unit 204 or the read control unit 205 via the user control processing unit 206, and controls the presentation data. Decoder section 204
Is a process of switching data to be decoded, and one example is highlight information used in a menu. The control sent to the read control unit 205 is for performing macro reproduction control such as changing the read position of the disc.

In recent years, a transmitter / receiver that transmits data read from a DVD to a remote receiver via a transmission path and reproduces the data in the receiver has been actively studied. An example of a transmission path for performing such transmission is Patrick Heck et al., "Media Oriented Synchronous Transfer-A Network Protocol for High Quality, Low Cost Transfer of Synchro. Eggplant, Asynchronous, and, Control Data on Fiber Optics, 103rd AES Convention, 26-29 September 1997, New York (Patrick Heck, Hervert Hetzel, Dave Knapp, Kevin)
Rolfes, Venkat Srinivas, Andreas Stiegler, Tony Su
santo, andDavid Trager. Media Oriented Synchronous
Transfer-A Network Protocol for High Quality, Lo
w Cost Transfer of Synchronous, Asynchronous, and
Control Data on Fiber Optic. Presented at the 103r
d AES Convention, 1997 September 26-29, New York)
Media OrientedSyn presented at
There is a chronous transfer (hereinafter referred to as MOST).

[0007] In the MOST, data transmission is performed using frames delimited at predetermined time intervals. FIG. 3 shows a MOST transmission frame format. In FIG. 3, reference numeral 301 denotes a preamble, 302 denotes a boundary descriptor, 303 denotes a synchronization slot, 303-a denotes a first communication synchronization slot,
303-b is a second synchronous slot for communication, 304 is an asynchronous slot, 305 is a control frame, 306 is frame control, and 307 is parity. Boundary descriptor 3
02 indicates the position of the boundary between the synchronous slot and the asynchronous slot. The frame control 306 and the parity 307 are used for frame error detection and the like.

FIG. 4 shows an example of a transmission line configuration. 4, reference numeral 401 denotes a transmission path, 402 denotes a master node device, and 40
3,404,405,406,407 are connection devices. In the case of this example, each device is connected so as to form a ring-shaped transmission path. In MOST, all devices operate in synchronization with the clock of the master node device.

Hereinafter, data transmission will be described. Each device connected to the transmission path receives data from adjacent devices in frame units. Data is transmitted by transmitting the frame sequentially through the loop transmission path. A preamble 301 exists at the beginning of a frame. A special code is used for the preamble, and each device can recognize a frame by detecting the preamble.

Data transmission methods include a method using a synchronous slot, a method using an asynchronous slot, and a method using a control frame. Among them, the control frame is mainly used for simple command transmission / reception between devices having a low bit rate.

The synchronization slot 303 is allocated to each device using the synchronization slot in a required amount. For example, the first communication synchronization slot 303-a is
4 and the second communication synchronization slot 303-b is allocated to the device 405 / device 406. The master node device 402 holds a table of synchronization slot assignment, and a device using a synchronization slot refers to this table before starting use, and determines the required bandwidth,
That is, the number of bits used per frame is reserved to secure a synchronization slot. Communication for reservation is performed using the above-described control frame.

When the transmitting apparatus using the synchronization slot receives the frame, the transmitting apparatus inserts the transmission data into the allocated slot and transfers the frame to the next apparatus. The target receiving device receives the frame and receives the data by copying the data written in the assigned slot. The constant rate transmission can be guaranteed by securing the necessary number of synchronization slots for data transmission. Therefore, this transmission is required for transmission that requires the required data to reach the receiving side at a specified time (hereinafter referred to as isochronous transmission). Use slots. For example, CD-A
Used for transmission of audio data and the like.

Asynchronous slots can be used by each device. Unlike the case of the synchronization slot, there is no need to reserve. Therefore, when the asynchronous slot is being used by another device, it is necessary to wait until the next transmission timing. Therefore, the timing at which data can be transmitted is not usually constant, and is mainly used for data transmission not requiring isochronous transmission (hereinafter referred to as non-isochronous transmission). For example, it is download data of a computer.

[0014]

When transmitting DVD data via the above-described transmission path, the data is read from the disk by the transmission device and decoded by the reception device. The operation performed in step (1) is separated via the transmission path. In transmission, delays and time fluctuations occur based on the frame structure and transmission wait time. It is necessary to provide a configuration for removing the influence and operating the transmitting device and the receiving device in correct synchronization.

In order for the transmitting apparatus to correctly transmit data according to the state of the receiving apparatus, it is necessary to sequentially notify the transmitting apparatus of the state of the receiving apparatus. When an asynchronous slot or a control frame is used to perform this notification, in non-isochronous transmission, the timing at which data can be transmitted is usually not constant, so that the time required for notification (jitter) is not uniform.
Occurs. Since the influence of the jitter needs to be absorbed by the buffer on the receiving device side, an extra buffer amount is required, which causes a problem that a delay occurs and the cost of the buffer increases.

The present invention has been made to solve the above-mentioned problem, and does not use a large-capacity buffer.
It is an object of the present invention to realize a digital signal transmission system capable of controlling the operation of a transmitting device from a receiving device side in real time.

[0017]

To solve the above-mentioned problems, a digital signal transmission system according to the present invention (claim 1) uses a transmission line in which isochronous transmission is guaranteed by using a band reserved in advance. A digital signal transmitting device and a digital signal receiving device having a digital interface connected to the transmission line, wherein the digital signal transmitting device transmits data to the digital signal receiving device using the transmission line. In a signal transmission system,
The digital signal receiving apparatus transmits a control signal for controlling the operation of the digital signal transmitting apparatus to the digital signal transmitting apparatus by using a previously reserved band of the transmission path.

Further, in the digital signal transmission system according to the present invention (claim 2), in the digital signal transmission system according to claim 1, the digital signal receiving device includes a receiving buffer means for temporarily storing received data; Buffer amount management means for sending a data amount request signal when the amount of data stored in the reception buffer means falls below a reference value, and transmitting the data amount request signal as the control signal using a previously reserved band of the transmission line Transmission means to perform,
The digital signal transmitting apparatus includes: transmission buffer means for temporarily storing transmission data; receiving means for receiving the data amount request signal; and buffer read control means for reading and transmitting the requested data amount from the transmission buffer means. It is provided.

In the digital signal transmission system according to the present invention (claim 3), in the digital signal transmission system according to claim 1 or 2, data transmitted from the digital signal transmission device is a digital versatile disk. This is data reproduced from.

In the digital signal transmission system according to the present invention (claim 4), in the digital signal transmission system according to claim 3, the digital signal receiving device transmits the data amount request signal to a time interval of a video frame. Is transmitted every time.

Further, according to a digital signal transmission system according to the present invention (claim 5), in the digital signal transmission system according to any one of claims 1 to 4, the digital signal transmitting device is configured to receive the digital signal. The data is transmitted to the device by using the previously reserved band of the transmission path.

According to a digital signal transmission system according to the present invention (claim 6), in the digital signal transmission system according to any one of claims 1 to 4, the digital signal transmitting device is configured to receive the digital signal. Data is transmitted asynchronously to the device.

Further, the digital signal transmitting apparatus according to the present invention (claim 7) is connected to a transmission path in which isochronous transmission is guaranteed by using a band reserved in advance, and uses the transmission path. In a digital signal transmitting apparatus for transmitting data, control for receiving control information for controlling operation of the digital signal transmitting apparatus transmitted using a previously reserved band of the transmission path to which the digital signal transmitting apparatus is connected It is provided with information receiving means.

In the digital signal transmitting apparatus according to the present invention (claim 8), the data to be transmitted is data reproduced from a digital versatile disc in the digital signal transmitting apparatus according to claim 7.

The digital signal transmitting apparatus according to the present invention (claim 9) is the digital signal transmitting apparatus according to claim 7 or 8, wherein the digital signal transmitting apparatus is connected to the transmission line to which the digital signal transmitting apparatus is connected. And transmitting the data to a digital signal receiving apparatus that receives data transmitted by the digital signal transmitting apparatus, using a band reserved in advance on the transmission path.

According to a tenth aspect of the present invention, there is provided a digital signal transmitting apparatus according to the seventh or eighth aspect, wherein the digital signal transmitting apparatus is connected to the transmission path to which the digital signal transmitting apparatus is connected. The data is transmitted asynchronously to a digital signal receiving device that receives data transmitted by the digital signal transmitting device.

Also, the digital signal receiving apparatus according to the present invention (claim 11) is connected to a transmission path in which isochronous transmission is guaranteed by using a band reserved in advance, and uses the transmission path. In a digital signal receiving device for receiving data to be transmitted, transmitting the digital signal to a digital signal transmitting device connected to the transmission path to which the digital signal receiving device is connected and transmitting data to the digital signal receiving device The apparatus further comprises control signal transmitting means for transmitting a control signal for controlling the operation of the apparatus by using a previously reserved band of the transmission path.

The digital signal receiving apparatus according to the present invention (claim 12) is the digital signal receiving apparatus according to claim 11, wherein the second buffer means for temporarily storing received data, and the second buffer means. Buffer amount managing means for sending a data amount request signal when the accumulated data amount of the data falls below a reference value, and transmitting means for transmitting the data amount request signal as the control signal using a previously reserved band of the transmission line. It is provided with.

The digital signal receiving apparatus according to the present invention (claim 13) is the digital signal receiving apparatus according to claim 12, wherein the data to be received is data reproduced from a digital versatile disc, and the transmitting means is The data amount request signal is transmitted at each time interval of a video frame.

Further, according to the digital signal transmission method of the present invention (claim 14), a transmission path in which isochronous transmission is guaranteed by using a band reserved in advance, and a digital interface connected to the transmission path. A digital signal transmission method in a digital signal transmission system comprising a digital signal transmission device and a digital signal reception device, wherein the digital signal transmission device transmits data to the digital signal reception device using the transmission path. The digital signal receiving device transmits a control signal for controlling the operation of the digital signal transmitting device to the digital signal transmitting device by using a previously reserved band of the transmission path.

In the digital signal transmission method according to the present invention (claim 15), in the digital signal transmission method according to claim 14, the digital signal transmitting device transmits the digital signal to the digital signal receiving device in advance of the transmission path. Data is transmitted using the reserved band.

In the digital signal transmission method according to the present invention (claim 16), in the digital signal transmission method according to claim 14, the digital signal transmission device transmits data asynchronously to the digital signal reception device. Is what you do.

[0033]

(Embodiment 1) FIG. 1 is a diagram showing a configuration of a digital signal transmission system according to an embodiment of the present invention. In FIG. 1, 101 is a digital signal transmission device, 102 is a disk drive, 103 is a first buffer unit, 104 is a first digital interface,
05 is a disk read control unit, 106 is a buffer read control unit, 121 is a digital signal receiving device, 122 is a decoder unit, 123 is a second buffer unit, and 124 is a second buffer unit.
, 125 is a buffer amount management unit, and 126 is a user control processing unit. The digital signal transmitting apparatus 101 and the digital signal receiving apparatus 121 are shown in FIG.
Are connected to a loop-shaped transmission path 130 as in the transmission system shown in FIG. Here, the transmission line 130 is the MOS shown in FIG.
This is the same as the transmission path used in the transmission system based on T, and propagates a signal in the same frame configuration as the configuration shown in FIG.

Hereinafter, the present embodiment will be described. The mode in which the data read from the disk drive 102 is controlled by the disk read control unit 105 is the same as that of the DVD player in the conventional mode. The read data is temporarily stored in the first buffer unit 103.

The buffer read control unit 106 adjusts the data transmission from the first buffer unit 103 so that the amount of data stored in the second buffer unit 123 in the digital signal receiving device 121 becomes constant. The operation will be described below.

Immediately after the start of the operation, the buffer amount management unit 125 sets the amount of data necessary for the amount of data stored in the second buffer
To the buffer read control unit 106 via the digital interface 124 and the first digital interface 104 of FIG. Here, the second digital interface 124 is the time reserved in the MOST frame shown in FIG. 3 for exclusive use for signal transmission from the digital signal receiving device 121 provided in the synchronization slot 303 to the digital signal transmitting device 101. The requested data amount is transmitted using the slot.

The buffer read control unit 10 receiving the notification
6 sequentially transfers the data input to the first buffer unit 103 to the two buffer units 1 via the first digital interface 104 and the second digital interface 124.
23. The disk read control unit 105
The amount of data read from the disk drive 102 is adjusted so that the buffer unit 103 does not underflow or overflow.

When the transmission of the requested amount of data is completed, the buffer read control unit 106 stops reading data from the first buffer unit 103, thereby interrupting data transmission.

The specified value is, for example, VBV (Video Buffer Ver.) Defined in the MPEG standard.
(ifier) The size of the buffer is set to 229376 bytes, which is the size of the buffer, and is set to be equal to or larger than the sum of the data amount in consideration of the delay in the transmission path. According to the DVD standard, the data of 229376 bytes or more is not removed from the buffer at one time, so that the underflow of the second buffer unit 123 can be avoided.

As an example, if the maximum transmission delay in the transmission path, that is, the maximum time required from when the digital signal receiving device 121 requests data to the digital signal transmitting device 101 to when the data arrives is 10 msec, the DVD
10.08Mb, the maximum transfer rate defined by the standard
ps multiplied by this maximum transmission delay, 12600 Bytes
241976 By adding e to the size of the VBV buffer
Let te be a designated value, and make the size of the second buffer unit 123 larger than this.

Next, in the digital signal receiving apparatus 121, decoding of the data stored in the second buffer unit 123 is started. The operation of the decoder unit 122 is the same as the operation of the decoder unit of the DVD player in the conventional mode. Each time the decoder unit 122 decodes the presentation data, it requests the second buffer unit 123 for the next presentation data to be decoded, and continuously decodes and outputs the data.

Upon receiving the request, the second buffer unit 123 sequentially sends the data to the decoder unit 122. The buffer amount management unit 125 requests the buffer read control unit 106 of the digital signal transmission apparatus 101 for the reduced data amount. The buffer control unit 106 sends out the requested amount of data to the receiving device 121. By repeating this operation, the decoder unit 122 correctly reproduces the presentation data.

As described above, in the digital signal transmission system according to the present embodiment, the digital signal receiving device 1
21 to the digital signal transmitting apparatus 101,
A stop request is issued using the synchronization slot. That is, a part of the synchronization slot is reserved for request transmission and used for communication between the buffer amount management unit 125 and the buffer read control unit 106. By using this configuration, the speed of communication between the transmitting and receiving apparatuses is increased, whereby the size of the buffer (second buffer unit 123) provided on the receiving apparatus side for absorbing fluctuations in data transmission time on the transmission path can be reduced. .

In the digital signal transmission system according to the above embodiment, the digital signal receiving device 121
Among the user control commands input to the digital signal transmitting device 101 via the transmission path 130, the commands that need to control the operation of the digital signal transmitting device 101 (for example, stop, jump, search, etc.) The transmission is performed using the synchronization slot, so that the response to the user control command is performed at high speed and the bandwidth of the synchronization slot can be effectively used.

In this embodiment, the buffer amount management unit 125 stores the necessary data amount in the buffer read control unit 1.
06, but another method, for example, a read start command signal and a read stop command signal are defined. If the data amount of the second buffer unit 123 becomes smaller than a specified value, the read start command signal becomes a specified value. The same can be realized by notifying a read stop instruction signal.

Due to the structure of the DVD decoder, the decoder unit 122 requests data at intervals of one video frame. That is, since the data amount changes every frame time, the buffer amount management unit 125 may read the data amount of the second buffer unit 123 every frame time and request the insufficient data amount. .

There is a method of transmitting presentation data from a digital signal transmitting apparatus using a synchronization slot. In this case, transmission can be performed by securing a synchronization slot for 10.08 Mbps or more, which is the maximum transfer rate of DVD data.

On the other hand, when an asynchronous slot is used for transmitting presentation data, the second buffer unit 123
If the specified value of the amount of data to be stored in is increased by the maximum delay generated by using the asynchronous slot,
Similar isochronous transmission can be realized. By using this configuration, it is not necessary to secure a band during a time period when the transfer rate may be small, and the band can be used effectively. Further, the present invention is particularly effective in a transmission path having a mechanism in which a digital signal transmission device requiring isochronous transmission can use an asynchronous slot preferentially.

In the above embodiment, the transmission path is MOS.
Although the data transmission in the transmission frame format of T has been described, it goes without saying that another transmission path that can guarantee isochronous transmission may be used. The numerical values shown in the present embodiment are examples, and the present invention is not limited to these numerical values.

[0050]

As described above, according to the present invention (claim 1), a transmission path whose isochronous transmission is guaranteed by using a band reserved in advance, and a digital interface connected to the transmission path A digital signal transmission system comprising: a digital signal transmission device including a digital signal transmission device and a digital signal reception device, wherein the digital signal transmission device transmits data to the digital signal reception device using the transmission path. However, since the control signal for controlling the operation of the digital signal transmitting device is transmitted to the digital signal transmitting device using the band reserved in advance on the transmission path, the data receiving device receives the data from the receiving device side. A control signal for controlling the operation of the transmitting device that transmits the signal can be transmitted at the same time, and the transmitting device can transmit the control signal from the receiving device side. There is an effect that it is possible to realize digital signal transmission system which can control the operation in real time.

According to the present invention (claim 2), in the digital signal transmission system according to claim 1, the digital signal receiving device comprises: a receiving buffer means for temporarily storing received data; Buffer amount management means for transmitting a data amount request signal when the accumulated data amount falls below a reference value, and transmission means for transmitting the data amount request signal using the previously reserved band of the transmission path as the control signal. Wherein the digital signal transmitting apparatus includes a transmission buffer means for temporarily storing transmission data, a reception means for receiving the data amount request signal, and a buffer read for reading and transmitting a requested data amount from the transmission buffer means. Because it was configured with control means,
Even if the receiving buffer means for absorbing the fluctuation of the data transmission time in the transmission path has a small capacity, there is an effect that a digital signal transmission system capable of reliably transmitting and receiving data requiring isochronism can be realized. .

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration of a digital signal transmission system according to an embodiment of the present invention.

FIG. 2 is a block diagram illustrating a configuration of a DVD player.

FIG. 3 is a diagram showing a frame configuration of a MOST.

FIG. 4 is a diagram showing an example of a MOST transmission path configuration.

[Explanation of symbols]

 Reference Signs List 101 digital signal transmission device 102 disk drive 103 first buffer unit 104 first digital interface 105 disk read control unit 106 buffer read control unit 121 digital signal reception device 122 decoder unit 123 second buffer unit 124 second digital interface 125 buffer amount management unit 126 user control processing unit 130 transmission line 201 DVD player

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 5D044 AB07 BC06 CC04 DE03 FG10 GK11 HL11 5K028 AA03 AA14 DD03 EE03 EE09 KK01 KK03 LL41 MM12 SS24 5K031 AA10 BA06 CA08 DB11

Claims (16)

[Claims] 1. A transmission path in which isochronous transmission is guaranteed by using a band reserved in advance, a digital signal transmitting apparatus and a digital signal receiving apparatus having a digital interface connected to the transmission path, In the digital signal transmission system in which the digital signal transmission device transmits data to the digital signal reception device using the transmission path, the digital signal reception device operates the digital signal transmission device with respect to the digital signal transmission device. A digital signal transmission system for transmitting a control signal for controlling the transmission using a previously reserved band of the transmission path. 2. The digital signal transmission system according to claim 1, wherein said digital signal receiving device includes a receiving buffer means for temporarily storing received data, and a storage means for storing the received data when the amount of data stored in said receiving buffer means falls below a reference value. A buffer amount management unit for transmitting a data amount request signal; and a transmission unit for transmitting the data amount request signal as the control signal using a band reserved in advance on the transmission path, and the digital signal transmission The apparatus comprises transmission buffer means for temporarily storing transmission data, reception means for receiving the data amount request signal, and buffer read control means for reading and transmitting the requested data amount from the transmission buffer means. A digital signal transmission system, characterized in that: 3. The digital signal transmission system according to claim 1, wherein the data transmitted from the digital signal transmission device is data reproduced from a digital versatile disk. system. 4. The digital signal transmission system according to claim 3, wherein said digital signal receiving device transmits said data amount request signal at each time interval of a video frame. 5. The digital signal transmission system according to claim 1, wherein the digital signal transmission device uses a band reserved in advance on the transmission path for the digital signal reception device. A digital signal transmission system for transmitting data. 6. The digital signal transmission system according to claim 1, wherein the digital signal transmission device transmits data asynchronously to the digital signal reception device. Signal transmission system. 7. A digital signal transmitting apparatus connected to a transmission path in which isochronous transmission is guaranteed by using a band reserved in advance and transmitting data using the transmission path. A digital signal transmitting apparatus comprising: control information receiving means for receiving control information for controlling the operation of the digital signal transmitting apparatus, which is transmitted using a previously reserved band of the transmission path connected to the digital signal transmitting apparatus. . 8. The digital signal transmitting device according to claim 7, wherein the data to be transmitted is data reproduced from a digital versatile disc. 9. The digital signal transmitting device according to claim 7, wherein the digital signal is connected to the transmission path to which the digital signal transmitting device is connected and receives data transmitted by the digital signal transmitting device. A digital signal transmitting device for transmitting the data to a receiving device using a band reserved in advance on the transmission path. 10. The digital signal transmitting apparatus according to claim 7, wherein the digital signal is connected to the transmission path to which the digital signal transmitting apparatus is connected and receives data transmitted by the digital signal transmitting apparatus. A digital signal transmitting device for asynchronously transmitting the data to a receiving device. 11. A digital signal receiving apparatus connected to a transmission path in which isochronous transmission is guaranteed by using a band reserved in advance and receiving data transmitted using the transmission path. A control signal for controlling the operation of the digital signal transmitting apparatus is reserved in advance for the digital signal transmitting apparatus connected to the transmission path to which the signal receiving apparatus is connected and transmitting data to the digital signal receiving apparatus. A digital signal receiving device comprising control signal transmitting means for transmitting using a set band. 12. The digital signal receiving apparatus according to claim 11, wherein said second buffer means for temporarily storing received data, and a data amount request when the amount of data stored in said second buffer means falls below a reference value. A digital signal receiving apparatus comprising: a buffer amount managing unit for transmitting a signal; and a transmitting unit for transmitting the data amount request signal as the control signal by using a previously reserved band of the transmission path. 13. The digital signal receiving apparatus according to claim 12, wherein the data to be received is data reproduced from a digital versatile disk, and wherein said transmitting means transmits said data amount request signal every time interval of a video frame. A digital signal receiving device for transmitting. 14. A transmission path in which isochronous transmission is guaranteed by using a band reserved in advance, and a digital signal transmitting apparatus and a digital signal receiving apparatus having a digital interface connected to the transmission path. A digital signal transmission method in a digital signal transmission system in which the digital signal transmission device transmits data to the digital signal reception device using the transmission path, wherein the digital signal reception device transmits the digital signal to the digital signal transmission device. A digital signal transmission method, comprising transmitting a control signal for controlling an operation of a transmission device using a band reserved in advance on the transmission path. 15. The digital signal transmitting method according to claim 14, wherein the digital signal transmitting device transmits data to the digital signal receiving device using a band reserved in advance on the transmission path. Digital signal transmission method. 16. The digital signal transmission method according to claim 14, wherein the digital signal transmission device transmits data asynchronously to the digital signal reception device.