JPS62189834A - Data frame multiplex system - Google Patents

Abstract

PURPOSE:To eliminate the need for scramble processing and code conversion at the transmission by using the 1st data frame signal as a data code and the 2nd data signal as a transition rule violation signal so as to encode the signals by a specific transition rule and multiplex them. CONSTITUTION:A data frame multiplex signal including information of two data frame signals is inputted to a data station 11 via an interface 10 and an input transmission line 12a from a network 1 and its output is outputted to the network 1 via an output transmission line 12b. The two data frame signals are subjected to multiplex by a transmission code having a specific transition rule at the station 11, e.g., a CMI code. In this case, the 1st data frame is used as a data signal and the 2nd data frame signal is used as a transition violation code and the signals are subject to coding and multiplex.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] The present invention provides for a network having a plurality of data stations, where individual data stations, nn-vs.
l2bi-4e ++14tffllllJ+ l/-,
The present invention relates to a data frame multiplexing method for multiplexing and transmitting data frame signals formed in QNM.

[Prior Art] Conventionally, in a network having a plurality of data stations, as a method for multiplexing a plurality of data frame signals into one data frame signal, one data time slot is divided by a predetermined number of data frame signals. A time division data frame multiplexing method is known in which individual data frame signals are allocated to divided time slots and multiplexed.

FIG. 4 is a timing chart showing the principle of this conventional time-division data frame multiplexing system.

In FIG. 4, when multiplexing a data frame signal 3a and a data frame signal 3b consisting of 8 bits, for example, one time slot 31 is divided into a first half 32 and a second half 33 of the time slot 31 at the transmitting data station. Then, the data 34 which is "0" is assigned to the first half part 32, and the data 35 which is "0" is assigned to the second half part, and one data frame multiplexed signal 3c is generated.
, and was transmitted at twice the data transmission speed compared to the original data frame signals 3a and 3b.

That is, the data frame signal 3a "ooot.

110” and data frame signal 3b “020001O
When multiplexing the data frame multiplexed signal 3c ”
0001011000101100" is obtained. On the other hand, when the receiving data station receives the data frame multiplexed signal 3c, the data of each time slot of the data frame multiplexed signal 3c is divided into two data frame signals, and the data is reproduced. was being carried out.

[Problems to be solved by the invention However, in the above-mentioned conventional data transmission system,
The number of "0" and "B" in the data frame multiplexed signal 3c is the same as "0" and "B" in the two data frame signals 3a and 3b before multiplexing.
Because it depends on the number of "0" and "bi", the probability of occurrence of "0" and "pi" is different, and "0" and "bi" may be transmitted continuously, so the data frame multiplexed signal 3c There was a problem in that a DC component was generated in the signal, making it difficult to extract the timing at the receiving data station.

Also, if the frequency of occurrence of data to be transmitted by one data frame signal is lower than that of the other data frame signal, the same data of "0" or "B" will continue to be transmitted when the data frame signal is not transmitted. Furthermore, timing extraction at the receiving data station becomes difficult.

Therefore, in reality, before sending the data frame multiplexed signal to the transmission path, it is necessary to scramble the multiplexed data frame multiplexed signal or convert it to another code from which timing can be easily extracted. Ta.

As described above, in the conventional time-division data frame multiplexing method, the above-mentioned signal processing is required before transmitting the data frame multiplexed signal 3c, which makes the device complicated and uneconomical.

[Object of the Invention] An object of the present invention is to eliminate the need for signal processing such as scrambling or code conversion at the time of transmission when two data frame signals, one of which is smaller than the other, are multiplexed and transmitted. Another object of the present invention is to provide a data frame multiplexing method that allows easy timing extraction when receiving the multiplexed data frame multiplexed signal.

[Configuration of the Invention] The present invention provides multiplexing of a first data frame signal and a second data frame signal that occurs less frequently than the first data frame signal. multiplexing the first data frame signal and the second data frame signal by using the first data frame signal as a data code and encoding the second data frame signal in violation of the transition rule. It is characterized by

[Embodiment] FIG. 3 is a block diagram showing a data station on a network according to an embodiment of the present invention. In FIG. 3, 1 is connected to each interface device IO of a plurality of data stations 11. A network is provided between each interface device IO and the data station controller 11 from the interface device IO to the data station 1
1 through an input transmission line 12a for transmitting a data frame multiplexed signal, and an output transmission line 12b for transmitting a data frame multiplexed signal from the data station 11 to the interface device IO. A data frame multiplex signal composed of multi-bit data signals on network l includes information of two data frame signals including destination information, and the data frame multiplex signal includes:
A data frame multiplexed signal is input from the network l to the data station 11 via the interface device 10 and the input transmission line 12a, and on the other hand, the data frame multiplexed signal output from the data station 11 is input to the network via the output transmission line 12b and the interface device lO. output to l.

The above two data frame signals are multiplexed into a data frame multiplex signal at a data station 11, which will be described in detail later, and conversely, the data frame multiplex signal is separated into two data frame signals.

FIG. 1 is a block diagram of the data station IT of FIG. 3, showing an embodiment of the data frame multiplexing method of the present invention.

This data frame multiplexing method multiplexes two data frame signals in which the frequency of occurrence of one data frame signal is lower than that of the other data frame signal using a transmission code having a specific transition rule. . In this embodiment, a CMI code having a data code is used as a transmission code having a specific transition rule. As is well known, in the CMI code transition rule, “0” becomes “0 bit”,
"Bi" is encoded in such a way that "00" and "1bi" appear alternately. Therefore, the appearance of the code "lO" in the data string, and the fact that "00" or "lbi" appear consecutively regardless of whether they sandwich the "0bi code or "lO" code, are due to the above-mentioned CMI. This violates the sign transition rule.

Here, the code of the former data is called a "0" violation, and the code of the latter data is called a "bi violation."

In data station 11 of FIG. 1, a binary data frame multiplexed signal is received by CMI decoder 13 of data station 11 via input transmission line 12a from network l.

The CMI decoder 13 decodes the data frame multiplexed signal into two binary data frame signals, a main data frame signal and a sub data frame signal, which have a transmission rate 1/2 compared to the data frame multiplexed signal, The main data frame signal is output to the main communication processing section 14, and the sub data frame signal is output to the slave communication processing section 15. That is, when the input data frame multiplexed signal has the code "0bi", the CMI decoder 13 decodes it to "0" as the main data frame signal and to "0" as the sub data frame signal, Also input +I+-: #-yl,
) Yushin l Shisaku 8 fortune (When the bamboo tool is "10", it is decoded to "0" as the main data frame signal, and
Furthermore, the CMI decoder 13 decodes the input data frame multiplexed signal into a code "00° or "lbi" before inputting a code having the code "00° or "lbi". ” is input and the code is “10”
“or” the above code “l” regardless of whether or not there is a 0-bit in between.
If the code “lbi” is input before the above code is input, and the code “”lO” is entered, or if the above code “00” is entered manually regardless of whether “0bi” is inserted or not. , as the main data frame signal, and decodes it as the sub data frame signal to "0".Furthermore, the CMI decoder 13 decodes the input data frame multiplexed signal as the code "00" or as the code "0". “
The code “00” is input before inputting the code
is input and the code "00" is input regardless of whether or not the code "10" or 10bi is inserted, and if the code "11" is input before the above code is input and the code "
The above code “
When l-bi is input, it is decoded into "bi" as a main data frame signal and decoded into "bi" as a sub-data frame signal.

The main communication processing unit 14 receives the main data frame signal, performs predetermined signal processing such as inputting and outputting information in the data station 11, and then outputs the processed main data frame signal to the 0Ml encoder 16.

On the other hand, the slave communication processing unit 15 receives the sub data frame signal, performs predetermined signal processing such as inputting and outputting information at the data station, and then outputs the processed sub data frame signal to the 0Ml encoder 16.

Main communication processing unit 14 and slave communication processing unit 15 that are provided when the main data frame signal and sub data frame signal are not present on the input transmission path 12a on the network.
At , a continuous "0" signal is reproduced.

When the input main data frame signal is “0” and the input sub data frame signal is “0”, the 0Ml encoder 16 outputs a CM! of data “0”. code, that is, the code “0bi”, and when the input main data frame signal is “0” and the human input sub data frame signal is “bi”,
Violation code of CMI code with data “0”,
That is, it is encoded into the code "IO". Furthermore, when the input main data frame signal is "Bi" and the input sub data frame signal is "0", the 0Ml encoder 16 outputs the CMI code of the data "Bi", that is, code "00" or code "0". When the input main data frame signal is "1" and the input sub data frame signal is "bi", the violation code of the CMI code of the data "bi" is encoded alternately. , that is, the code "00" or the code "1 bit" is inserted into the code "0 bit" or the code "10" or not.
” or the code “lbi” is continuously encoded. After the above encoding, the 0M1 encoder 16 outputs an encoded binary data frame multiplexed signal having a transmission rate twice that of the main data frame signal and the sub data frame signal to the output transmission line 12b of the network. Output to.

It should be noted that the main communication processing section 14 and the slave communication processing section 15 are capable of mutually independent processing, and for example, the main communication processing section 1
Even when the main data frame signal is being processed in step 4, the slave communication processing section 15 can process the sub data frame signal. Therefore, it is possible to multiplex the main data frame signal with or without the main data frame signal and send the sub data frame signal to the output transmission path 12b on the network. The signal can be sent to the output transmission path 12b on the network.

FIG. 2 is a timing chart showing the operation of the 0Ml encoder 16 shown in FIG. Figure 2 2a”0001
0110'' and 8-bit sub data frame signal 2b''
When multiplexing and transmitting ``ottoooto'', 0Ml
The data frame multiplexed signal that is the output of the encoder 16 becomes a signal "011010110100000bi" having a transmission rate twice that of the main data frame signal 2a and sub data frame signal 2b shown in 2C. The multiplexed signal 2c is a CMI code having a pie ray scene in which the main data frame signal 2a is coded as a CML code data signal and the sub data frame signal 2b is coded as a CMI code data signal, that is, a violation signal. .

In FIG. 2, 21 is a CMI code of data "0" with no violation, 22 is a violation code of CMI code with data "0", 23 is a CMI code of data "bi" with no violation, and 24 is data " Bi CMI
This is a violation code.

Yenshi ^I-Hachi--Koshi Ishi ν-)h Gigifuko-
In John 1, the main data frame signal and sub data frame signal are separated and decoded from a data frame multiplexed signal having information on two data frame signals, a main data frame signal and a sub data frame signal, existing on network j. At the same time, it is also possible to multiplex the main data frame signal and the sub data frame signal to encode a data frame multiplexed signal having information of the two data frame signals.

Also, when there is no sub data frame signal,
Since a violation-free CMI code is transmitted as a data frame multiplexed signal, the data frame multiplexed signal does not include a DC component, and timing extraction during reception is easy. Furthermore, when the sub data frame signal exists, the DC component is included in the data frame multiplexed signal when it is a violation code of the data frame CMI code, that is, when the main data frame signal is “
Since this is only when the main data frame signal is "Bi" and the sub data frame signal is "1", if the probability that the main data frame signal is "Bi" and the probability that the sub data frame signal is "Bi" are each set to 1/2, then The probability that a violation code of the CMI code of data "B" will occur is 1/4.

Furthermore, if the frequency of occurrence of sub-data frame signals is low as described above, the probability that a violation code of the CMI code of data "l" will occur is even smaller, so its occurrence can be almost ignored. ,
Timing extraction during reception is easy.

CMI decoder 13 and CMI in the embodiment of FIG.
Since the encoder 16 can be used as an existing encoder, it has the advantage of being extremely easy to implement.

In multiplexing data frame signals in the above embodiments,
Although the transition rule for a CMI code having a violation is used, a transition rule for a code having another violation may be used.

[Effects of the Invention] As detailed above, according to the present invention, when multiplexing the first data frame signal, the first data frame signal is used as a data code, and a specific transition rule such as a CMT code is used. Since the data frame is multiplexed by encoding it, there is no need to perform signal processing such as scrambling or code conversion at the time of transmission, and moreover, it is easy to extract the timing when the multiplexed data frame multiplexed signal is received. There are advantages.

[Brief explanation of drawings]

FIG. 1 is a block diagram of a data station showing an embodiment of the data frame multiplexing method of the present invention, and FIG.
FIG. 3 is a block diagram showing the transmitter station in FIG. 1 on the network; FIG. 4 is a timing chart showing the conventional time-division data frame multiplexing method. be. l...Network, 2a...Main data frame signal, 2b...Sub data frame signal, 2
C...Data frame multiplexed signal, lO...Interface device 1, II...Data station,
12a... Input transmission line, 12b... Output transmission line, 13... CMI decoder, 14... Main communication processing section, 15... Slave communication processing section, 16... CMI
Encoder, 21... Data with no violation CMI code of "0", 22... Violation code of CMI code with data "0", 23... Data with no violation code "1" C
MI code, 24... Violation code of the CMI code of data "B". Patent applicant: Sharp Corporation Representative: Patent attorney: Aohaku, 2 people, Fig. 1, Fig. 2, Fig. 3

Claims (4)

[Claims] (1) When multiplexing a first data frame signal and a second data frame signal that occurs less frequently than the first data frame signal, the first data frame signal is used as a data code, and the second data frame signal is Data characterized in that the first data frame signal and the second data frame signal are multiplexed by encoding the data frame signal with a specific transition rule having the transition rule violation code as a transition rule violation code. Frame multiplexing method. (2) The data frame multiplexing method according to claim 1, wherein the second data frame signal can be multiplexed with the first data frame signal at any time. (3) When multiplexing a first data frame signal and a second data frame signal that occurs less frequently than the first data frame signal, the first data frame signal is used as a data code, and the second data frame signal is multiplexing the first data frame signal and the second data frame signal by encoding the data frame signal with a specific transition rule having the transition rule violation code as a transition rule violation code, Decoding a signal in which the signal and the second data frame signal are multiplexed, the data code into the first data frame signal and the transition rule violation code into the second data frame signal using the above-mentioned specific transition rule. A data frame multiplexing method characterized by separating data frames. (4) The data frame multiplexing method according to claim 3, wherein the second data frame signal can be multiplexed with the first data frame signal at any time.