JPS63187942A - Data transmission system - Google Patents

Abstract

PURPOSE:To optionally change the number of data in every processing unit of continuous data by transmitting a flag showing the number of data in the processing units of data with data in every processing unit. CONSTITUTION:The objective number of continuous input data is transmitted with the flag FL showing the number of data in the data processing units... (c), (d), (e)... as the processing units... (c), (d), (e)... by a transmission line which has a faster transmission speed than that of the data and which is asynchronous to the data. For varying the number of data in every processing unit, the frequency of a processing unit clock and the content of the flag FL are accordingly varied. In a receiving side, data in every processing unit which has been transmitted by the transmission line is processed with using the flag FL which is simultaneously transmitted, whereby output data is reproduced.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention provides a method for processing consecutive data, with a desired number of data as a unit of processing, and having a transmission speed greater than the data speed. The present invention relates to a data transmission method in which the data is transmitted through a transmission path asynchronous to that data.

[Summary of the invention]

The present invention provides a data transmission method in which continuous data is transmitted using a desired number of pieces of data as a processing unit over a transmission path that has a transmission speed higher than the data speed and is asynchronous to the data. By transmitting a flag indicating the number of data in each processing unit along with the data for each processing unit over the transmission path, it is possible to arbitrarily change the number of data in each processing unit of continuous data. It was made so that it could be done.

[Conventional technology]

A conventional data transmission method of this type will be explained below. When transmitting continuous data using a transmission line whose transmission speed is higher than the data rate, a certain number of pieces of data to be transmitted are processed as a unit of processing and transmitted over the transmission line.

Then, the receiving side receives the original continuous data.

Here, as a method for putting data in units of processing onto a transmission path, there are cases where the position on the transmission path is determined and cases where it is not determined.

Next, this conventional data transmission system will be further explained with reference to FIG. 3C and F show the input data to be transmitted on the transmission path, and this input data is a predetermined number N
(N is a natural number) processing unit..., C% d s
e Sf 1g%... FIG. 3B shows the clock of this input data. Also, Figure 3A
, one processing unit clock (having a frequency of 1/N of the frequency of the input data clock) is shown for each processing unit of input data.

In addition, the third diagram and G indicate the state of data transmitted on the transmission path, respectively. D is the case where the position of the data on the transmission path is fixed, and G is the case where the position is asynchronous. be. Furthermore, FIGS. 3E and 3H show output data (continuous data) on the receiving side in each case.

[Problem that the invention seeks to solve]

One drawback of such conventional data transmission systems is that the number of data in a data processing unit cannot be changed arbitrarily.

In view of this point, the present invention is configured to transmit continuous data, using a desired number of pieces of data as a processing unit, through a transmission path that has a transmission speed higher than the data speed and is asynchronous with the data. This paper attempts to propose a data transmission system that can arbitrarily change the number of pieces of data for each continuous data processing unit.

[Means for solving problems]

In the data transmission method according to the present invention, continuous data is transmitted using a desired number of pieces of data as a processing unit through a transmission path that has a transmission speed higher than the speed of the data and is asynchronous with the data. The data transmission method is characterized in that a flag indicating the number of data in a data processing unit is transmitted along with the data for each processing unit over a transmission path.

[Effect]

According to the present invention, a flag indicating the number of data in a data processing unit is set together with data for each processing unit.
Since the data is transmitted via a transmission path, the number of data in a data processing unit can be changed arbitrarily.

〔Example〕

An embodiment of the present invention will be described below with reference to FIG. In this data transmission method, as shown in Fig. 1C, continuous input data is processed in units of processing of the desired number of pieces of data, c, d, e, etc., as shown in Fig. 1. Along with a flag FL indicating the number of data in a data processing unit, c, d, e, etc., the data is transmitted on a transmission path that has a transmission speed higher than that of the data and is asynchronous with that data. . Note that FIG. 1B shows an input data clock, and FIG. 1A shows a processing unit clock (asynchronous with the input data clock). When changing the number of data for each processing unit, the frequency of the processing unit clock and the contents of the flag FL are changed accordingly. Then, in reception ff1J, by processing the data for each processing unit transmitted through the transmission path using the flag FL transmitted at the same time, the output data (continuous data ).

Therefore, the number of data in a processing unit can be arbitrarily set, and the number of data in a processing unit can be changed even during transmission.

Next, with reference to FIG. 2, an example in which the above-described data transmission method is applied to a transmitting device of a television telephone device or a television conference device will be described. In FIG. 2, AS indicates an audio signal system, and VS indicates a video signal system. Here, the above-described data transmission method is applied to the audio signal system AS.

First, the audio signal system AS will be explained. The audio signal from the microphone (1) is passed through the amplifier (2) to the A/
The signal is supplied to a D converter (3) and converted into a digital audio signal based on the clock from the clock generator (4). This digital audio signal is controlled by the control circuit (11) to control the number of digital audio signals per processing unit (any desired number).
is supplied to the multiplexer (6) through the gate circuit (5) where the signal is set. The number of digital audio signals in this unit of processing is selected such that the time of this unit of processing matches the time of the unit of processing of digital video signals, which will be described later.

Further, a data counter (8) is provided, which receives a digital audio signal from the A/D converter (3) and a control circuit (11).
), the number of digital audio signals for each processing unit is counted. The count value by this counter (8) is supplied to an encoding circuit (9) and encoded, thereby forming a flag indicating the number of digital audio signals in a processing unit. This flag is supplied to the multiplexer (6) through a gate circuit (10) controlled by a control circuit (11).

Next, the video signal system will be explained. An imaging signal from a television camera (12) is supplied to an A/D converter (14) through an amplifier (13), and is input from a clock generator (independent of the clock generator (4) described above) (15). is converted into a digital video signal based on the clock.

, this clock generator (15) is controlled by reference horizontal and vertical synchronization signals from a reference synchronization signal generation circuit (16). Further, the reference horizontal and vertical synchronization signals from the reference synchronization signal generation circuit (16) are supplied to the control circuit (11). Further, the digital video signal from the A/D converter (14) is sent to the multiplexer (6) through a gate circuit (17) in which the number (fixed) of digital video signals per processing unit is set under the control of the control circuit (11). supplied to

In this way, the multiplexer (6) alternately and repeatedly outputs the digital audio signal for each processing unit, its flag, and the digital video signal for each processing unit, and this output is connected to a transmission line whose transmission speed is higher than the speed of these data. (not shown) and transmitted.

〔Effect of the invention〕

According to the present invention described above, continuous data is transmitted using a desired number of pieces of data as a processing unit over a transmission path that has a transmission speed higher than the speed of the data and is asynchronous with the data. In the data transmission method, the number of pieces of data for each continuous data processing unit can be arbitrarily changed.

[Brief explanation of the drawing]

FIG. 1 is an explanatory diagram of an embodiment of the present invention, FIG. 2 is a Brochure diagram showing an example of a transmitting device to which the present invention is applied, and FIG. 3 is an explanatory diagram of a conventional example.

Claims (1)

[Claims] Data transmission in which continuous data is transmitted using a desired number of pieces of data as a processing unit over a transmission path that has a transmission speed higher than the speed of the data and is asynchronous with the data. A data transmission method, characterized in that a flag indicating the number of data in the data processing unit is transmitted along with the data for each processing unit over the transmission path.