JPS63209336A - Time division multiplex packet communication system - Google Patents

Abstract

PURPOSE:To accurately decode a packet signal at a reception side by constituting the titled system by a time division multiplex transmitter including a divider and an information inserting device and a receiver restoring the original packet signal so as to attain multiple access. CONSTITUTION:A packet signal coming from an input terminal 1001 is divided so as to be in matching with the slot by a divider 3 in a time division multiple transmitter 1. An information inserting device 4 gives a packet number, a split number, head information, final information and capacity information to a specified division packet signal and outputs the result to a transmission line 1003. In this case, the signal has a form in matching with the time division multiplex format. The signal sent to the transmission line 1003 is inputted to a receiver 2. The receiver 2 restores the packet signal from the packet number, split number, head information, final information and capacity information.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to packet communication using time division multiplexed communication channels.

(Prior Art) Conventionally, packet signals are transmitted through time division multiplexing-multiple access (TDM) in wireless communication.
A (Tirne Division Multiple
A method of transmitting data using the Internet Access) is being considered. For example, time division multiplexing has already been experimentally used in packet communications conducted via satellites and the like.

(Problem to be solved by the invention) However, the transmitter/receiver used in the conventional system does not insert a specific pattern of signals called flags between data, such as the commonly used HDLCforrTIat. Since it corresponds to signals and is handled in the same way as circuit switching, no special improvements were required.

This flag is useless information from the viewpoint of information transmission, and there are problems in that it not only makes it impossible to effectively utilize the transmission path, but also makes it unsuitable for point-to-multipoint communication.

An object of the present invention is to provide a time-division multiplexed packet communication system that directly handles signals from bucket 1, does not include this useless information, and is also compatible with multiple access, and accurately restores packet signals on the receiving side. It's about doing.

(Means for Solving the Problems) The present invention provides that in packet communication using a time division multiplexing/multiple access system, a signal sent to a bucket 1 larger than a given slot has a large size suitable for the slot. A divider that divides the signal into multiple divided packet signals uses a packet number for each consecutive packet obtained by a modulo of a specific number, and a divided number corresponding to the divided packet signal of the divided packet signal. are added to each divided packet signal, leading information indicating that it is the first divided packet signal, final information indicating that it is the last divided packet signal, and capacity information indicating the size of the last divided packet signal. a time division multiplex transmitter including an information inserter that appends and outputs a specific divided packet signal to a specific divided packet signal;
This is a time division multiplex packet communication system characterized by being configured with a receiver that restores the original packet signal.

(Operation) FIG. 1 is a diagram showing the basic configuration of the present invention. The packet signal input from the 10-inch input terminal is sent to the time division multiplex transmitter 1.
The packet is divided by a divider 3 to match the slot size, and an information inserter 4 (described later) adds a packet number, division number, start information, final information, and capacity information, and outputs it to a transmission path 1003. Ru. At this time, the signal is in a format compatible with the time division multiplex format. Transmission line 100
3, the transmitted signal is input to the receiver 2.

The receiver 2 receives the packet number, division number, start information,
The packet signal is restored from the final information and capacity information. There is no problem with transmission line 10 port 3, whether it is a wired line or a wireless line.
Any transmission line that allows multiple access may be used. The need to divide packet signals is based on the following constraints.In time division multiplex communication, the area in which the own station's signal can be output, or slot, is determined and is set to a certain size. Since the packet signal often takes a larger value than this size, it becomes necessary to divide it.

Furthermore, on the receiving side, it is necessary to add restoration information in order to restore this divided signal. Furthermore, since noise is always present in the transmission path, there is a possibility of erroneous restoration.

Due to this erroneous signal, it cannot be helped that only the bucket 1 ~ signal is erroneous, but because of this erroneous signal, it affects the packets before and after that packet signal, and the packet signals after that packet signal. It is problematic to have this effect. Other buckets like this? - The spread of errors in signal synthesis should also be avoided. Below, in order to more accurately restore the packet signal, the bucket numbers,
The following describes how to restore a packet signal from the division number, start information, end information, and capacity information.

First, it is assumed that erroneous bursts are discarded because it is not clear which information was incorrect. In order to detect burst errors, Fe2 (frame check sequence) (CCITT, Yellow book data communication network X series recommendation P132.1980) is used. This is a diagram for explaining the principle of adding each number and information. In the diagram, 6 is a packet signal with a size of 7. At this time, 1
Assuming that the amount of information allocated per slot is 3, the packet signal 6 is divided into three divided packet signals 16.26.3.
Divided into 6 parts. The size of each is 3.3.1.

Each divided packet signal has a packet number 11.21.
．． 31, divided packet number 12.22.32, leading information 13.23.33, final information 14.24.34, and capacity information 35 are added. The meaning of each is as follows. The head information is information indicating that it is the first head of the divided packet signal, and here information indicating that it is the lead is added to 13. The final information indicates that the divided packet signal with this information is the last part of the burst signal. The division number is a number that is consecutively assigned to the divided packet signals from the beginning when one packet signal is divided. The packet number is given as a number modulo a certain number, and one number is given to one packet. i.e. packet number 11.21.31
are the same number, and the next packet number is assigned to the packet signal input next to packet signal 6. The size of the packet I signal is not necessarily divisible by the size of the slot. As shown in FIG. 2, while the size of the throwers 1 to 3 is 3, the size of the divided packet signal number 3 is only 1. In this case, the slot will be empty. Therefore, capacity information 35 for indicating the size is added only to the last divided packet signal. Fe217.27.37 is added to each entire burst (11, 12, 13,
14, 1, 6>, (21, 22, 23, 24, 26),
<31.32, 33, 34, 35.36).

The receiver 2 restores the packet signal from these packet I/number, division number, start information, end information, and capacity information. It is assumed that erroneous burst signals in Fe2 are discarded (there is no way to combine them because it is unknown what information was erroneous). The restoration method is to check whether the division numbers are consecutive for signals with the same packet number, and if they are consecutive, to combine them one after another. If even one division number is missing during the transmission, the packet signal of that packet number becomes an erroneous packet signal (an error has occurred on the transmission path). The start information and the end information indicate the division of the packet signal. Using only the packet number and division number, if an error occurs in the first or last burst of the division number, the next or previous burst will be mistaken as the first or last burst, respectively. To prevent this error, start information and end information are added. As a result, the beginning information or the end information is added to the transition point of the packet number, and if these pieces of information are not present, the packet signal of that packet number will be an erroneous packet signal.

Capacity information is added to the final divided packet signal. This is because only the last divided packet number 36 does not necessarily match the size of the slot, so it is necessary to indicate its size. Therefore, for a burst with final information, the packet signal can be restored by extracting a signal of the size indicated by the capacity information from the slot in addition to the signal synthesized up to the previous burst.

The packet number prevents erroneous restoration not only against burst errors but also against long-term continuous errors for packet signal restoration. FIG. 3 shows how the receiver 2 restores the packet I and signal when an error occurs when no packet number is added. Packet signal 6 to transmitter 1
Assume that 1.62 is input one after another. packet signal 61
is divided into two divided packet signals 611 and 612, and a division number 1.2 is added to each of them. Moreover, the packet signal 62 is divided into three divided packet signals 621.622.6.
It is divided into 23 parts, and division numbers 1, 2, and 3 are added to each part. When transmitting this divided packet signal, if errors occur continuously during interval 5 on the transmission path, the receiving side discards the erroneous bursts, and as a result, the divided packet signal 611.
622 and 623 are obtained. A packet number is attached to this signal, and when it is restored using the division number, the division numbers of each divided packet signal are consecutive, such as 1, 2, and 3, so they are combined as a packet signal 63 and are restored incorrectly. Ru.

At this time, if 1.2 is added to each packet I number, the divided packet I signal 611.6]2.621.622
．． 623 is o, iy.

(1, 2), < 2.1), (2, 2), (2, 3) and even if 611, 622, 623 are received, each (1,
1), (2, 2), and (2, 3), so erroneous restoration will not occur.

(Example) Now, as a packet I/signal, the maximum value is 4 Kbytes (
1 byte = 8 bits), and the size of a divided packet that can be allocated to one slot is 128 bytes.

FIG. 4 shows an example of FortTIat that combines the packet number, division number, head information, end information, and capacity information at this time. In the figure, each divided packet contains 2 bytes.
Insert the information 501 or 502 of
Multiply by e2 and add 2 bytes as a result. In the figure, information 501 is Forrnat for the head divided packet signal or the Φ interval divided packet signal;
02 is the format for the final packet signal or the undivided packet signal (bucket 1 - the signal size is smaller than thrower 1 -). Packet number 51.54 is 1
28 laws, 0, 1.2.・・・・・・126,1
The numbers continue as 27.0... The division number is
It is determined by the maximum value of the packet signal/capacity of the slot, and in this embodiment, 4096/1024·32=25, and 5 bits is sufficient. For example, when the number of divisions is N, this packet number is indicated by a continuous number that decreases by 1 from N-1. The delimiter information 53.55 includes the first information and the last information, and when the 7 bits of the lth byte are “1”, it indicates the starting divided packet signal, and the Q of the 2nd byte
When the bit is 0.1'', it indicates the final divided packet signal.

Therefore, the following things are related by the combination of these 2 bits.

10...First divided bucket I-signal 00...Middle divided bucket 1-signal 01...Final divided packet signal number 11...Undivided packet signal (because it is the first and last) This This clarifies the beginning and defines the maximum value of the division number. Furthermore, the final divided packet signal has division number 52.
Alternatively, it is defined by the delimiter information value ゛吋'' or ``11''.However, it is necessary to add capacity information 56 to the final divided packet signal.Bucket 1 to signals are defined by the size in bytes. Therefore, it includes information on the size 128 of slots 1 to 1. Therefore, 7 bits are required.Also, since the division number of the final bucket 1- is naturally '00', it can be calculated from only the delimiter information value ''ot'. It is possible to judge. Therefore, the division information is removed from the final divided packet I signal and the non-divided packet signal, and capacity information is added instead. This Fo
rITlat brings together information that includes all the functions described in the action section.

(Effects of the Invention) The present invention is necessary for restoration when transmitting and receiving signals from bucket 1 in a time division multiplexing system, and is capable of erroneously restoring bit errors and block errors in wireless transmission channels. It has the effect of being difficult to eliminate. Add this information to
By having all receiving stations check the destination indication of the transmitted data, development to multiple access and repeat communication can be expected.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing the configuration of the present invention, FIGS. 2 and 3 are diagrams for explaining the invention in detail, and FIG. 4 is a diagram showing one embodiment. In the figure, 1...Time division multiplex transmitter 2...Receiver 3...Divider 4...Information inserter 6...Packet signal 1.1, 21.31...Bucket 1~ Number 1, 2, 22
．． 32...Division number 13.23.33...Start information 1.4, 24.34...Last information 35...Capacity information 1 14-

Claims (1)

[Claims] In packet communication using time division multiplexing/multiple access, a packet signal larger than a given slot is divided into a plurality of divided packet signals of a size suitable for the slot, and a specific The packet number for each consecutive packet obtained by the modulo of numbers,
A division number corresponding to the division order of the divided packet signal is added to each divided packet signal, and head information indicating that the divided packet signal is the first divided packet signal, and head information indicating that it is the last divided packet signal. an information inserter that attaches final information and capacity information indicating the size of the last divided packet signal to a specific divided packet signal and outputs the same;
A time division multiplexing device comprising: a time division multiplex transmitter; and a receiver that restores the original packet signal from the packet number, division number, head information, end information, and capacity information. Packet communication method.