JPH0946390A - Digital signal transmitter and recordor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a transmitter and a recordor unnecessitating the internal analysis of digital signals and to control the buffer on a reception side so as not to overflow or underflow on a transmission side. SOLUTION: The arriving timing when each MPEG 2 data packet is outputted to a transmitter 1 is acquired by an arriving timing aquirer 4. In a time stamp generator 5, the value of a GTR 8 is latched by the arriving timing, further, the count values of the maximum delay time of prescribed transmitter to receiver are added and a transmission time stamp is generated. The transmission time stamp is added to an input data packet by a time stamp adder 7, the data packet is converted into a source packet, the source packet is further converted into the transmission packet where plural source packets are gathered by a transmission packet converter 10 and the transmission packet is converted.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmission device for transmitting digital signals.

[0002]

2. Description of the Related Art In recent years, development of a high-speed digital interface for transmitting digital signals in real time has been progressing, and particularly eye-to-eye (IEEE) 1
The 394 standard serial bus is expected as an interface suitable for multimedia transmission centered on images, because of its high rate and the advantage that simultaneous real-time transmission and asynchronous transmission can be performed.

FIG. 3 shows the configuration of a transmitter of a conventional digital signal transmission device. Here, for example, the MPEG2 signal is I
It is assumed that the data is transmitted by the EEE1394 transmission device.

In FIG. 3, 1 is a transmitter and 2 is MPEG.
2 decoder box, 3 buffer, 4 arrival timing acquirer, 5 time stamp generator, 30 time stamp adder, 8 cycle time register (CT)
R) and 10 are transmission packet converters.

The transmission time stamp is generated on the basis of the count value of the cycle time register (CTR) 8 which is a clock whose time is adjusted between the devices connected to the transmission path.

From the MPEG2 decoder box 2 to each MP
The arrival timing acquisition unit 4 acquires the arrival timing when the EG2 data packet is output to the transmitter 1.

In the time stamp generator 5, the value of CTR8 is latched at the arrival timing, and further, a predetermined transmitter-
A transmission time stamp is generated by adding the count value of the maximum delay time of the receiver. The input data packet is stored in the buffer, and then the transmission time stamp is added by the time stamp adder 30 to be converted into a source packet, and further converted by the transmission packet converter 10 into a transmission packet in which a plurality of source packets are collected. To be done. The transmission packet may be converted by dividing the source packet into some according to the rate or the like.

Input MPE by rate information extractor 100
The G2 signal is analyzed and information about the transmission rate, for example, Smoothing_Buffer_Descriptor (Smooth in the programming mapping table (PMT)).
ing_Buffer_descriptor) is extracted.

Transmission band determiner 101 based on the extracted information
Determines the transmission band. The determined transmission band is issued as a band reservation request on the transmission line.

FIG. 4 shows the configuration of a receiver of a conventional digital signal transmission device and a recorder connected to the receiver.

In FIG. 4, 11 is a transmission packet converter, 20 is a receiver, 21 is a recording device, 3 is a buffer, and 2 is a recording device.
2 is a time stamp separator, 23 is a read timing generator, 4 is an arrival timing acquirer, 40 is a PCR extractor, 41 is a 27 MHz PLL, 43 is a recording time stamp generator, 8 is a cycle time register (CTR),
Reference numeral 26 is a recording signal processing circuit, 27 is a recording medium, 102 is a rate information extractor, and 103 is a recording mode determiner.

The count value of the cycle time register (CTR) 8 is adjusted by each device connected to the transmission line.

The transmission packet converter 11 converts the transmission packet arriving at the receiver into a source packet.

The first time stamp separator 22 separates the transmission time stamp from the source packet, and the read timing generator 23 outputs the read signal to the buffer at the timing when the obtained transmission time stamp value and the count value of CTR8 match. send. As a result, a data packet is output from the buffer at a timing at which the delay amount between the input time to the transmitter and the output time from the receiver becomes constant.

In the recorder 21, the MPEG2 data in the data packet is analyzed by the PCR extractor 40, and the programming clock reference (ProgramClo).
ckReference (PCR) to obtain timing information. The 27 MHz PLL internally has a system clock of MPEG2, and has a 27 MHz oscillator which is also an operation clock of the recording device and a counter synchronized with the clock, and compares the obtained PCR value with the count value to correct the clock. By inputting MPEG
The 27 MHz clock at the time of encoding two signals is restored. This makes it possible to obtain an accurate operating frequency that absorbs transmission jitter.

The arrival timing acquisition unit 4 detects the arrival timing of each data packet. The time stamp generator 25 latches the 27 MHz counter according to the arrival timing of the data packet obtained by the arrival timing acquisition unit 4 to generate a recording time stamp.

The recording time stamp corresponding to each data packet is input to the recording signal processing circuit 26, is subjected to processing such as formatting, error correction coding and modulation suitable for the recording medium and is recorded on the recording medium 27.

In a recording apparatus in which the recording speed or the like is switched to a plurality of kinds of recording modes according to the input rate to make effective use of the recording medium, it is necessary to switch the recording modes depending on the input rate.

The rate information extractor 102 analyzes the input MPEG2 signal in the same manner as 100 and outputs information on the transmission rate, for example, a programming mapping table (PM).
Summing_buffer_descriptor in T)
(Smoothing_Buffer_descript
or) is extracted.

The recording mode determiner 10 based on the extracted information
The recording mode is determined by 3. The drive circuit is controlled based on the specified recording mode.

[0021]

However, in the conventional transmission apparatus, as shown in the rate information extractor 100 in order to determine the transmission band or the recording mode, the inside of the digital signal is analyzed to obtain the information on the rate. It had to be extracted, which had the drawback of increasing the amount of hardware on the receiving and recording side.

Further, if the buffer on the receiver side overflows or underflows, the data transmission will be broken, but conventionally it cannot be controlled on the transmission side.

In view of the above points, an object of the present invention is to provide a transmission device and a recording device that do not require internal analysis of a digital signal and can guarantee that the operation on the receiving side does not fail.

[0024]

In order to solve the above-mentioned problems, the transmission apparatus of the present invention has a measuring means for measuring the amount of data that has arrived within a predetermined fixed time, and a data measured by the measuring means. It is characterized in that it has a band determining means for determining a transmission band from the amount and a transmitting means for performing transmission in accordance with the transmission band determined by the determining means.

Alternatively, a judgment means for judging whether or not the transmission packet received from the transmission path by the receiver has passed the timing to be output from the receiver, and a value when the transmitter transmits one of the transmission packets. A counter that counts down and counts down the value when the determination means determines that each transmission packet has passed the timing to be output from the receiver; and each transmission packet so that the counter does not exceed a certain value. And a transmitting means for transmitting the digital data based on the transmission timing determined by the determining means.

Alternatively, in a transmission device for transmitting digital data input in packet units, a calculating means for calculating a delay time from the capacity of a buffer included in the reception device and the data rate of the digital data input to the reception device. And a judgment means for judging by comparing the delay time with a predetermined value, a transmission time stamp which is information of a timing at which the receiver should output the packet, the input time to the receiving device and the output of the judging means. And a transmission time stamp adding means for adding to each transmission packet, and a transmitting means for transmitting the packet to which the transmission time stamp is added.

Further, the digital signal recording apparatus of the present invention is an apparatus for transmitting a digital signal inputted in a predetermined transmission packet unit, and a predetermined number of transmission packets are inputted by the time information added to each transmission packet. A measuring means for measuring a recording time, a determining means for determining a recording mode at the time of recording from the time measured by the measuring means, and a recording means for recording according to the recording mode determined by the determining means. Characterize.

[0028]

With the above construction, the present invention makes it possible to provide a transmission device and a recording device which do not require internal analysis of digital signals.

Further, by adjusting the transmission timing, the transmission side can be controlled so that the buffer on the receiver side does not overflow or underflow.

[0030]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described with reference to the drawings.

FIG. 1 shows the configuration of the transmitter of the digital signal transmission apparatus according to the first embodiment of the present invention.

Here, for example, an MPEG2 signal is transmitted in IEEE
It is assumed that the data is transmitted by a 1394 transmission device.

In FIG. 1, 1 is a transmitter, 2 is a counter, 3 is a buffer, 4 is an arrival timing acquirer, 5 is a time stamp generator, 6 is a transmission band determiner, 7 is a time stamp adder, and 8 is Transmission timing, 9 is a cycle
Time register (CTR), 10 indicates a transmission packet converter.

FIG. 5 is a diagram showing the configuration of the transmission timing determiner 8. In the figure, 50 is an output time judgment device, 51 is a counter, and 52 is a transmission timing controller.

The transmission time stamp is generated based on the count value of the cycle time register (CTR) 8 which is a clock whose time is adjusted between the devices connected to the transmission path.

The arrival timing acquisition unit 4 acquires the arrival timing when each MPEG2 data packet is output to the transmitter 1.

In the time stamp generator 5, the value of CTR8 is latched at the arrival timing, and a predetermined transmitter to
A transmission time stamp is generated by adding the count value of the maximum delay time of the receiver.

The input data packet is stored in the buffer, and then the transmission time stamp is added by the time stamp adder 30 to be converted into a source packet.
Further, the transmission packet converter 10 converts the source packet into a transmission packet in which a plurality of source packets are collected and is transmitted.

Here, by the transmission timing judging device 8,
The timing of actual transmission from the transmission packet converter 10 to the transmission path is controlled.

The output time judgment unit 50 first inputs the time stamp value indicating the output time of each data packet at the receiver from the time stamp generator 5 and stores it. Each time stamp value is then compared to the current CTR value to determine if the data packet has already been output from the receiver.

Since the time is adjusted so that the CTR value is the same for all the connected nodes, the CTR of the receiver is the same as that of the transmitter. For this reason,
The above judgment is possible only by comparing two values.

The counter 51 counts down one by one for each data packet when the judgment of the output time judging device 50 is “already output”, and one data packet is transmitted from the transmission packet converter 10. To 1
Count up one by one.

That is, the value of the counter becomes the same as the number of data packets in the buffer of the current receiver. The transmission timing controller 52 outputs a signal for controlling the output timing from the transmission packet converter 10 according to the value of the counter 61. That is, when the count is increased and it is about to exceed a certain value, specifically, the buffer amount / data packet size value, the transmission packet converter 1
Delay transmission from 0 to the transmission path. Also, when the count value approaches zero, the transmission from the transmission packet converter 10 to the transmission line is accelerated. The controller 52 can be configured with the above logic by a microcomputer + software or the like.

By performing the above operation, the transmission timing judgment unit 8 can be controlled on the transmission side so that the buffer on the receiver side does not overflow or underflow.

Further, the count value is controlled so as to take as large a value as possible within the range not exceeding the above constant value. This control maximizes the number of data packets in the buffer on the receiving side within the range that does not overflow, and enables output on the receiving side when the transmitting packet does not reach the receiving side for a certain period due to a problem on the transmitting side or transmission line. It is possible to keep it as continuous as possible.

The counter 2 has a fixed period of time, for example, IEEE.
The amount of data input to the transmitter at a time that is a constant multiple of 24.576 MHz, which is the operation clock of 1394, here, the number of data packets is sequentially bit-counted. Since the size of the data packet is a constant 188 bytes in MPEG2 transmission, it is relatively easy to find the average rate.

The transmission band determiner 5 can know the average rate in a fixed period from the count value of the counter 2.

One of a plurality of transmission bands possessed by the transmitter is selected as a band capable of transmitting this average rate. When determining the transmission band, the transmission band determiner 5 considers a rate higher than the obtained average rate at a constant rate (example: 1.2 times),
Select the narrowest transmission band within the range that can absorb the fluctuation due to the deviation of the data arrival timing in the actual system.

In order to secure the selected transmission band, the transmission packet including the band securing request information is transmitted on the transmission path.

By the above operation, the data rate can be directly known without analyzing the inside of the MPEG2 signal,
Using this, the transmission band can be easily determined.

FIG. 4 shows the configuration of a digital signal transmission recording apparatus according to the second embodiment of the present invention. In FIG. 4, 11 is a transmission packet converter, 20 is a receiver, 21 is a recording device,
3 is a buffer, 22 is a time stamp separator, 23 is a read timing generator, 4 is an arrival timing acquirer,
Reference numeral 40 is a PCR extractor, 41 is a 27 MHz PLL, 43 is a recording time stamp generator, 8 is a cycle time register (CTR), 26 is a recording signal processing circuit, and 27 is a recording medium.

The count value of the cycle time register (CTR) 8 is adjusted by each device connected to the transmission line.

The operation of the receiver 20 will be described. The transmission packet converter 11 converts the transmission packet arriving at the receiver into a source packet.

The time stamp separator 22 separates the transmission time stamp from the source packet, and the read timing generator 23 uses the obtained transmission time stamp value and CT.
A read signal is sent to the buffer at the timing when the count values of R8 match. As a result, a data packet is output from the buffer at a timing at which the delay amount between the input time to the transmitter and the output time from the receiver becomes constant.

Next, the operation of the recording machine 21 will be described.
MPEG2 in data packet by PCR extractor 40
Data is analyzed and the program clock reference (ProgramClockReference, PC
Get the timing information called R). 27MHz PL
L41 is an internal MPEG2 system clock,
It has an oscillator of 27 MHz which is also an operation clock of the recording apparatus and a counter 42 synchronized with the clock, and compares the obtained PCR value with the count value to correct the clock to encode the input MPEG2 signal. Restore the 27MHz clock at the time. This makes it possible to obtain an accurate operating frequency that absorbs transmission jitter.

The arrival timing acquisition unit 4 detects the arrival timing of each data packet. The time stamp generator 25 latches the 27 MHz counter according to the arrival timing of the data packet obtained by the arrival timing acquisition unit 4 to generate a recording time stamp. With this recording time stamp, it is possible to absorb fluctuations in read-out jitter from the recording medium during reproduction, and to transmit data packets at the correct timing while maintaining the timing during recording.

The recording time stamp corresponding to each data packet is input to the recording signal processing circuit 26, subjected to processing such as formatting, error correction coding and modulation suitable for the recording medium and recorded in the recording medium 27. .

The counter 24 sequentially bit-counts the amount of data input to the transmitter, here, the number of data packets, for a fixed period, for example, a constant multiple of 27 MHz which is the operating clock of the recorder 21. Recording mode determiner 2
5 can know the average rate in a fixed period from the count value of the counter 24. A recording mode capable of transmitting this average rate is selected from a plurality of recording modes of the recording machine.

The recording mode determiner 25 determines a recording mode at a constant rate (eg:
(1.2 times), considering the high rate, the smallest recording rate recording mode is selected within a range that can absorb the fluctuation due to the deviation of the data arrival timing in the actual system.

The drive circuit is controlled based on the determined recording mode. By the above operation, the data rate can be directly known without analyzing the MPEG2 signal, and the recording mode can be easily determined using this.

As a second method of this embodiment, the counter 2
It is also possible to similarly realize and realize the average data rate by counting the time required to output a fixed number of packets instead of counting the amount of data (the number of packets) of 4 in a fixed period. At this time, the process after calculating the average data rate can be realized in exactly the same way as the first method of the second embodiment described above.

In the embodiment described above, the size of the data packet, the source packet, the transmission packet,
Bit arrangement is arbitrary. The number of bits of the first time stamp and the second time stamp is arbitrary.

The arrangement of the data packet and the recording time stamp on the recording medium and the number of bits are also arbitrary.

Further, the constant value for overflow determination for the processing of the transmission timing controller is defined as the buffer amount / transmission packet size, but this value is arbitrary.

[0065]

As described above, according to the present invention,
A transmission device and a recording device that do not require internal analysis of digital signals can be obtained, and hardware and cost can be reduced.

Further, by adjusting the transmission timing, the transmission side can be controlled so that the buffer on the receiver side does not overflow or underflow.

Further, even if a problem occurs on the transmission side or the transmission line and the transmission packet does not reach the reception side for a certain period of time, the output of the reception side can be prevented from being interrupted as much as possible.

[Brief description of drawings]

FIG. 1 is a block diagram of a transmitter of a digital signal transmission device according to a first embodiment of the present invention.

FIG. 2 is a configuration diagram of a receiver and a recorder of a digital signal transmission device according to a second embodiment of the present invention.

FIG. 3 is a block diagram of a transmitter of a digital signal transmission device in a conventional example.

FIG. 4 is a configuration diagram of a receiver and a recording device of a digital signal transmission device in a conventional example.

FIG. 5 is a configuration diagram of a transmission timing determiner according to the first embodiment of the present invention.

[Explanation of symbols]

1 transmitter 2 counter 3 buffer 4 arrival timing acquirer 5 time stamp generator 6 transmission band determiner 7 time stamp adder 8 transmission timing determiner 9 cycle time register (CycleTimeRe)
gister) 10, 11 transmission packet converter 20 receiver 21, 50 recording device 22 time stamp separator 23 read timing generator 24 counter 25 recording mode determiner 26 recording signal processor 27 recording medium 50 recording time stamp generator

Claims (13)

[Claims] 1. A measuring unit for measuring the amount of data arriving within a predetermined fixed time, a band determining unit for determining a transmission band from the amount of data measured by the measuring unit, and a transmission determined by the determining unit. A digital signal transmission device having a transmission means for transmitting in accordance with a band. 2. The bandwidth determining means adds a predetermined amount of data amount to the data amount measured by the measuring means, and determines the transmission band based on the data amount obtained by the addition. The digital signal transmission device according to claim 1. 3. Data arrives in a fixed length packet format,
2. The digital signal transmission device according to claim 1, wherein the measuring means measures the data amount by counting the number of packets that have arrived within a predetermined fixed time. 4. A judgment means for judging whether or not a transmission packet received from a transmission path by a receiver has passed a timing to be output from the receiver, and a value when the transmitter transmits one of the transmission packets. And a counter that counts down the value when the determination means determines that each transmission packet has passed the timing to be output from the receiver, and each transmission packet so that the counter does not exceed a certain value. A digital signal transmission device comprising: a deciding means for deciding the transmission timing of 1. and a transmitting means for transmitting the digital data based on the transmission timing decided by the deciding means. 5. A transmission time stamp generating means for generating a transmission time stamp, which is information on a timing at which the receiver should output each transmission packet, and a judging means, the transmission time stamp of each transmitted transmission packet The digital signal transmission device according to claim 4, wherein a value is stored and the timing output from the transmission time stamp is determined. 6. The digital signal according to claim 4, wherein the determining means determines the transmission timing so that the transmission packet is transmitted so that the counter takes a value as large as possible within a range in which the counter does not exceed a certain value. Transmission equipment. 7. A transmission device for transmitting digital data input in packet units, and calculating means for calculating a delay time from the capacity of a buffer included in the reception device and the data rate of digital data input to the reception device. And a judgment means for judging by comparing the delay time with a predetermined value, a transmission time stamp which is information of a timing at which the receiver should output the packet, the input time to the receiving device and the output of the judging means. A digital signal transmission device comprising: a transmission time stamp adding means for adding to each of the transmission packets, and a transmitting means for transmitting the packet to which the transmission time stamp is added. 8. The judging means outputs the predetermined value when the delay time is a predetermined value or more, and outputs the delay time when the delay time is a value smaller than the predetermined value. 8. The digital signal transmission device according to claim 7, which outputs the signal. 9. A measuring means for measuring the amount of data that has arrived at a predetermined fixed time, a determining means for determining a recording mode at the time of recording from the amount of data measured by the measuring means, and a determining means for determining the recording mode. A digital signal recording apparatus comprising recording means for recording according to a recording mode. 10. The digital signal recording apparatus according to claim 9, wherein the measuring means counts the number of said transmission packets that have arrived within a predetermined fixed time to measure the data amount. 11. The deciding means adds a predetermined amount of data amount to the data amount which has arrived at a predetermined constant time, and decides a recording mode based on the data amount obtained by the addition. 10. The digital signal recording device according to claim 9, which is characterized in that. 12. A device for transmitting a digital signal input in a unit of a predetermined transmission packet, and a measuring means for measuring a time for which a predetermined number of transmission packets are input according to the time information added to each transmission packet. A digital signal recording apparatus comprising: a determining unit that determines a recording mode at the time of recording from the time measured by the measuring unit; and a recording unit that performs recording according to the recording mode determined by the determining unit. 13. The deciding means reduces a predetermined proportion of time with respect to a time when a predetermined number of transmission packets are input, and decides a recording mode based on the time obtained by the reduction. 13. The digital signal recording device according to claim 12, wherein: