JPH027641A - Data transmission control system - Google Patents

Abstract

PURPOSE:To surely avoid the collision of data by sending a pattern specific to a node to a transmission line from a transmission request node and starting the data transmission when the specific pattern of its own node is detected on the transmission line. CONSTITUTION:When a carrier detection section 3 of a transmission request node detects the absence of a carrier on the transmission line 2, a pattern specific to the node is sent from a specific pattern transmission section 4 to the transmission line 2 and a specific pattern detection section 5 detects whether or not the pattern specific to its own node. If collision of a specific patterns is detected, the transmission is stopped, the carrier is detected again and the specific pattern is sent in case of the absence of the carrier. Furthermore, after the transmission of the specific pattern, when the specific pattern detection section 5 detects the specific pattern of its own node, it is discriminated as the absence of occurrence of collision, and a data is sent to the transmission line 2 from a data transmission processing section 6. Thus, the data collision is surely avoided.

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to a data transmission control system in which a plurality of distributed nodes are connected through a bus-type transmission line and data is transmitted under control at each node. % Expression % [Prior Art] Various data transmission control methods have been proposed for local area networks (LANs) depending on the network configuration. For example, as shown in Fig. 4, in a local area network where multiple nodes AB, C, and D are connected via transmission paths, the CS M A/
CD (CarrierSense Multipl
e Access 1with Co11ision
Detection) method is often adopted. This method is known as the IEEE802.3 standard, and detects carriers on the transmission path, and if there is no carrier,
Since the other nodes are not transmitting, the transmission requesting node starts transmitting data and monitors the data on the transmission path.

For example, as shown in the simplified diagram, the data format sent to the transmission path has a preamble P added to the beginning,
It consists of a destination address DA, a source address SA, and data DT, and a frame check sequence (not shown) is added for error detection.

Furthermore, if multiple nodes simultaneously issue transmission requests and multiple nodes start transmitting at the same time, a data collision will occur, so this is detected and the data transmission is stopped.

FIG. 5 is an explanatory diagram of the operation of the conventional example of the above-mentioned C3MA/CD system. As shown in FIG. 4, nodes A, B,
When nodes C and D are connected in this order and data is transmitted from node B to node D and from node C to node A, nodes B and C detect that there is no carrier on the transmission path and start transmitting data at the same time. Then, data from node B is propagated to nodes A, C, and D via the transmission path, and when that data reaches node C, data from node C is propagated to nodes A, B via the transmission path. , D side, and when the data reaches node B, the occurrence of a collision is detected. In order to ensure a collision state through this collision detection, jam transmission JM is performed for a certain period of time, and then transmission is stopped.

Then, retransmission is started after times Tb and Tc (backoff time) set to different values corresponding to nodes B and C. Even during this retransmission, carrier detection is performed, and data transmission is started if there is no carrier.

[Problem to be solved by the invention]

By starting data transmission when there is no carrier, there is a high possibility that there will be multiple nodes starting transmission at the same time, and data will be lost due to collisions in that case. This can be remedied by retransmission, but the retransmission process may be repeated, such as starting data transmission and then stopping it midway through. Also, depending on the selection of the backoff time, a particular node may A situation may occur where the road is occupied.

The present invention aims to reliably avoid data collisions.

[Means to solve the problem]

The data transmission control method of the present invention transmits a unique pattern when there is no carrier, determines whether or not a collision has occurred, and starts transmitting data when there is no collision.
As shown in the figure, each node 1-1 to 1-n has a transmission line 2
a carrier detection unit 3 that detects the above carrier; a unique pattern transmitting unit 4 that transmits a unique pattern corresponding to a node;
a unique pattern detection unit 5 that detects this unique pattern;
A data transmission processing section 6 and a data reception processing section 7 are provided,
In the transmission requesting node, the carrier detection unit 3 detects that no carrier exists on the transmission path 2, and sends the unique pattern from the unique pattern transmission unit 4 to the transmission path 2 via the switching unit 9. , the unique pattern on the transmission line 2 is detected by the unique pattern detection unit 5 via the switching unit 8, and when the unique pattern of the own node is detected, it is determined that no collision has occurred, and the data from the data transmission processing unit 6 is is sent to the transmission line 2 via the switching section 9.

[Effect]

When there is no carrier on the transmission path, a node-specific pattern is sent from the unique pattern transmitter 4 to the transmission path 2. Further, the unique pattern detection unit 5 detects whether a pattern unique to the own node exists on the transmission path 2 or not. In other words, if multiple nodes simultaneously send their own unique patterns to the transmission path 2, it will not be possible to detect the unique patterns of their own nodes, so it can be seen that multiple nodes are making transmission requests at the same time. .

If such a unique pattern collision is detected, C
Similar to the 3MA/CD method, transmission is stopped, carrier detection is performed again, and if there is no carrier, a unique pattern is transmitted. Further, after the unique pattern is transmitted, when the unique pattern detecting section 5 detects the unique pattern of the own node, it is determined that no collision has occurred, and the data is sent from the data transmission processing section 6 to the transmission line 2. Therefore, there is no data collision and data can be reliably transmitted.

〔Example〕

Embodiments of the present invention will be described in detail below with reference to the drawings.

FIG. 1 is a block diagram of an embodiment of the present invention.
1-n are nodes, 2 is a transmission path, 3 is a carrier detection unit, 4
5 is a unique pattern transmitting section, 5 is a unique pattern detecting section, 6 is a data transmitting processing section, 7 is a data receiving processing section, and 8.9 is a switching section. The unique pattern transmitter 4 has a function of generating node-specific patterns such as addresses assigned to the nodes 1-1 to 1-n and sends them to the transmission path 2, and the unique pattern detector 5 , has a function of detecting the unique pattern of its own node on the transmission line 2. Further, the switching unit 8 is switched to connect the transmission path 2 and the data reception processing unit 7, and is switched to connect the transmission path 2 and the unique pattern detection unit 5 as shown in the figure only when transmitting the unique pattern. It will be done. Further, the switching section 9 is switched to connect the transmission path 2 and the unique pattern transmitting section 4 as shown in the figure when transmitting a unique pattern, and to connect the transmission path 2 and the data transmission processing section 6 when transmitting data. Can be switched.

When a transmission request is issued to the node 1-1, the carrier detection unit 3 detects whether or not another node is transmitting data. If there is no carrier, the unique pattern transmission unit 4 is detected by the control unit (not shown). It is activated to generate a unique pattern, and sends the unique pattern to the transmission path 2 via the switching section 9. The unique pattern on the transmission path 2 is detected by the unique pattern detection unit 5, and when the unique pattern of own node l-1 is detected, it is determined that there is no collision, and the switching unit 9 switches the transmission path 2.
and the data transmission processing unit 6 are switched and connected, and data transmission is started.

FIG. 2 is a flowchart of an embodiment of the present invention, in which carrier detection is performed by the carrier detection unit 3, and when the carrier is detected, destination identification is performed, it is determined whether the data is addressed to the own node, and the data is addressed to the own node. In the case of data, the data reception processing unit 7 receives the data via the switching unit 8.

If there is no carrier at the time of a transmission request, the unique pattern is sent from the unique pattern transmitting unit 4, the unique pattern detecting unit 5 detects the fixed pattern on the transmission path 2, and detects patterns other than the unique pattern of the own node. If so, it is determined that a collision has occurred, the transmission is stopped, and it is determined whether the transmission path 2 is empty or not by carrier detection again. When the unique pattern of the own node on the transmission path 2 is detected, it is determined that there is no collision and data transmission is started. In this case, it is also possible to perform control such that the unique pattern is repeatedly transmitted a plurality of times and it is determined that there is no collision when the unique pattern can be detected a predetermined number of times in succession.

FIG. 3 is an explanatory diagram of the operation of the present invention, in which nodes 1-a, 1
-b, and when each transmission request occurs,
Carrier detection C8 is performed, and if there is no carrier, a unique pattern is sent out. In this case, simultaneously node 1-a
, 1 = b Since the transmission of the unique pattern starts, a collision occurs, so the transmission is stopped and the carrier detection C
Do S. In this case, the backoff time can be set similarly to the CSMA/CD method. That is, the retransmission waiting time of the unique pattern is set differently depending on the node. As a result, when node 1-a determines that there is no carrier and starts transmitting the unique pattern, node 1-b determines that there is a carrier by carrier detection C8, and transmits the unique pattern from node 1-b. The retransmission is further delayed, and node 1-a
Then, data transmission will start when it is determined that there is no collision by unique pattern transmission.

Therefore, there is no need to retransmit data, and data transmission efficiency can be improved.

〔Effect of the invention〕

As explained above, in the present invention, when the carrier detecting section 3 detects the absence of a carrier on the transmission path 2 in the transmission requesting node, the node-specific pattern is sent from the unique pattern transmitting section 4 to the transmission path 2. When the unique pattern detecting unit 5 detects the pattern on the transmission path 2 and detects the unique pattern of the own node, it is determined that there is no collision.
This is to start the transmission of data from the data transmission processing section 6, and by sending out the unique pattern before data transmission, it is possible to reliably avoid data collisions. Therefore, since data retransmission processing can be made unnecessary, there is an advantage that transmission efficiency can be improved.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of an embodiment of the present invention, FIG. 2 is a flowchart of an embodiment of the present invention, FIG. 3 is an explanatory diagram of operation of an embodiment of the present invention, and FIG. 4 is an explanatory diagram of a data transmission system. FIG. 5 is an explanatory diagram of the operation of the conventional example. 1-1-1-n is a node, 2 is a transmission path, 3 is a carrier detection section, 4 is a unique pattern transmission section, 5 is a unique pattern detection section, 6 is a data transmission processing section, 7 is a data reception processing section, 8
．． 9 is a switching section. Patent Applicant: Fujitsu Denso Co., Ltd. Representative Patent Attorney Shoji Aitani Representative Patent Attorney Hiroshi Watanabe - Blocks of embodiments of the present invention! Figure 1

Claims (1)

[Claims] A plurality of nodes (1-1 to 1-n) are connected to a transmission line (
2), each of the nodes (1-1 to 1-n) connects to the transmission path (2) and performs data transmission.
a carrier detection unit (3) that detects the above carrier; and a unique pattern transmitter (3) that transmits a unique pattern corresponding to a node.
4), a unique pattern detection unit (5) that detects the unique pattern, a data transmission processing unit (6), and a data reception processing unit (7), in the transmission request node, the carrier detection unit (3) detects that no carrier exists on the transmission path (2), sends the unique pattern from the unique pattern transmitter (4) to the transmission path (2), and transmits the unique pattern of the own node. is detected by the unique pattern detection unit (5), it is determined that no collision has occurred, and the data transmission processing unit (6)
) to the transmission path (2).