JPS59153353A - Data transmission system - Google Patents

Abstract

PURPOSE:To operate efficiently the system without competition of response between different data devices by including response delay information in a command when a batched status read command is given from an optional data transmitter. CONSTITUTION:Data transmitter 1-4 transmit response in response to the response time decided by the response delay information included in the batched status read command and the identification information of the corresponding device. Thus, data transmitters respond to the batched status read command from the transmission side with different delay time at the receiving side respectively and the data is received sequentially in the interval of response depending on the processing speed of the transmission side without collision of response at the data transmitters at the transmission side.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a data transmission system comprising a data transmission device d that can respond to a status response to a batch status read command from any data transmission device. .

(Prior art) Conventionally, in the data transmission system of this building, when any data transmission device collects and reads the status information of all other stations, this data transmission device is of the broadcast type. However, when status information was collected all at once, there was a problem that the responses would conflict. Therefore, by specifying the address of each station, a command had to be sequentially sent to each other station to read the status information, and a response had to be obtained. Moreover, in this case, each data transmission device must remember the addresses of stations from other operations, so it is necessary to set all the addresses of other stations in the data transmission device when installing the system. Similar measures were required when adding other stations. For this reason, there are disadvantages in that troublesome procedures are required when installing the system, and it is not easy to add other stations.

On the other hand, if you want to memorize the addresses of all other stations and do not die, it is necessary to sequentially transmit up to the maximum address allowed by the data transmission system and determine the connection relationship based on the presence or absence of a response. There is also a drawback that an extra amount of time multiplied by the response timeout time is consumed.

In order to eliminate this drawback, a method has already been proposed in which the read command is of the broadcast type, but a mechanism is provided to stagger the responses for each station so that the responses are not overlapped at the data transmission device on the transmitting side. There is. This method can solve the above drawbacks, but in order to delay the response for each station, each station has its own delay time information and the response time is fixedly delayed.
There was no other way out. Therefore, it is necessary to set a fixed delay time for each station in accordance with the processing speed of the data transmission device on the originating side, resulting in the disadvantage that the data transmission device on the originating side remains fixed. If you choose the slowest device with a processing speed as the data transmission device on the sending side and set a delay time that suits this device, there will be a drawback that the response processing will be delayed and the processing speed will be slow. If it is adapted to a faster device, it has the disadvantage that the response processing cannot keep up and the problem returns to response conflict.

The disadvantage that the data transmission device d on the sending side is fixed is that
In a system in which multiple data transmission devices are connected to a data transmission path, each data transmission device is functionally basically in an equal position, and any data transmission device can act as a transmitting device, which hinders the flexibility. This caused limitations in system construction and operation.

, (Object of the Invention) The object of the present invention is to provide the necessary information for the arbitrary data transmission device to receive and process the response from the data transmission device of another station when issuing a bulk status read command from any data transmission device. By including time information in this command as response delay information consisting of multiples of unit time, responses from data transmission devices of other stations in the ring number can be sent at intervals that are compatible with the processing speed of any data transmission device l mentioned above. So, 111 without military anger.
It is an object of the present invention to provide a data transmission system consisting of a plurality of data transmission devices configured so that the next reception is possible.

(First aspect of the invention) The data transmission system according to the present invention is constituted by a data transmission path for coupling between data transmission devices t for several bales and data transmission devices for several rice grains.

Each data transmission device used in the data transmission system according to the present invention includes a command sending means, a response delay information setting means,
It is equipped with a receiving means and a response delay means.

The command sending means is means for sending a batch status read command from the data transmission device t, which is the sending side, to other data transmission devices.

The response delay information setting means is a means for including response delay time information representing a preset delay time in the batch status read command.

The receiving means is a means for receiving a batch status read command sent from another data transmission device serving as the sending side.

The response delay means is a means for delaying the response time by a preset delay time based on response delay information received while the receiving means is operating.

According to the present invention, it is possible to obtain a configuration in which, when a bulk status read command is sent from a data transmission device serving as a transmitting side to another, the confusion of responses from a plurality of receiving sides can be avoided on the transmitting side.

(Embodiment) Next, an embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 shows an embodiment of the configuration of a data transmission system according to the present invention, where 1.degree.2.3.4 are first to fourth data transmission devices, and 5 is a data transmission path. FIG. 2 is a block diagram of an embodiment of the second data transmission device 2, which is a component of FIG. Although the second data transmission device 2 is shown in FIG. 2, the other data transmission devices t have a similar configuration. In FIG. 2, reference numeral 201 is a receiving unit for receiving a batch status successive command necessary for reading status information all at once from the data transmission line 5.

Reference numeral 202 denotes a first comparison unit for determining whether the received command is a batch status continuous output command. 203 indicates that if the output of the first comparison unit 202 indicates affirmation,
This is a timekeeping section for starting a clock operation for timekeeping. 2
Reference numeral 04 denotes a response delay information storage unit for storing response delay information included in the batch status read command if the output of the first comparison unit 202 indicates affirmation.

Reference numeral 205 denotes a storage unit for recording device identification information specific to this data transmission device 2. 206 is a calculation unit for calculating the output of the response delay information storage unit 204 based on the output of the device identification information storage unit 205. 207 is the clock section 2
This is a second comparison unit for comparing the output of the calculation unit 206 with the output of the calculation unit 206.

Reference numeral 208 denotes a response transmitting unit for sending a response to the calling side if the output of the second comparing unit 207 indicates affirmation. Reference numeral 210 is a transmission buffer section for transmitting a batch status read command as a transmitting side data transmission device. Reference numeral 213 denotes a third comparison unit for determining whether the content to be transmitted from the transmission buffer unit 210 is a batch status read command. 209 is response delay information (4
This is the sending section. Reference numeral 211 denotes a transmission synthesis section that synthesizes the output of the transmission buffer section 210 and the output of the response delay information transmission section 209 if the output of the third comparison section 213 is positive. 212 is a transmitting unit for transmitting the output of the transmission combining unit 211 to a transmission path.

Next, with reference to FIG. 2, the operation of the present invention will be sequentially explained, focusing on the operation of issuing a batch status successive command. When a command is stored in transmission buffer unit 2]0, this command is stored in the third
The third comparison unit 213
Now compare this command with the batch status read command.

If it is determined that both commands are equal from this comparison result, the third
The comparator 213 sends the signal in state 1 to the transmission combiner 211. If the state of the signal sent from the third comparison section 213 is 1, the transmission combination section 211 combines the output of the response delay information transmission section 209 with the output of the transmission buffer section 210. The transmission combining section 211 outputs the combination information to the transmitting section 212, and the transmitting section 212 further outputs this signal to the data transmission path 5. With the above steps, the series of transmission operations is completed, and a response from another station is awaited.

Next, the reception operation will be explained. When the receiving section 201 receives a command from the data transmission path 5, the receiving section 201 sends this command to the first comparing section 202. 1st
The comparison unit 202 compares this command with the batch status read command. As a result of comparison, if both signals are equal, the first
An output signal in state l is sent from the comparison section 202 to the time measurement section 203. If the state of the output signal from the first comparator 202 is 1, the timer 203 starts the operation of that block. At the same time, if the state of the output signal from the first comparing section 202 is 1, the response delay information included in the batch status read command is extracted and stored internally in the response delay information storage section 204. The time value at which the block operation is executed by the clock section 203 is sent to the second comparison section 207 . The output of the response delay information storage section 204 and the output of the device identification information storage section 205 are added to the calculation section 206 for calculation, and the obtained value is compared with the output of the time measurement section 203.

If it is determined from the comparison result that the two are equal, a signal in state 1 is sent from the second comparing section 207 to the response transmitting section 208. Therefore, the response transmitter 208 transmits a response to the sender of the batch status read command. Similarly, the second
The signal in state 1 obtained as the output of the zero comparator 207 is sent to the timer 203, and the timer 203 uses the signal to stop the clock operation and reset the timer. This completes the series of reception operations.

As explained above, according to the present invention, the data transmission device sends a response according to the response time determined by both the response delay information included in the batch status read command and the identification information of the applicable device. Therefore, each data transmission device on the receiving side will respond with a different delay time to a batch status read command from the sending side, and there will be no collision of responses on the side of the data transmission device on the sending side. , can be received sequentially at response intervals depending on the processing speed of the sender.

(Effects of the Invention) As explained above, the present invention enables a data transmission device to respond to data transmitted with a delay time given by A based on response delay information of A included in a batch status read command. By configuring the system to respond to each other, there is no conflict in responses between different data transmission devices, and the sending side can efficiently collect responses from all data transmission devices connected to the system. It has the effect of being able to operate effectively and efficiently.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an example of the configuration of a data transmission system related to the present invention. FIG. 2 is a block diagram showing an embodiment of a data transmission device used in the data transmission system according to the present invention. 1 to 4... Data transmission device 5... Data transmission path 201... Receiving section 202
, 207 , 213... Comparison section 203... Timing section
204, 205...Storage unit 206...Calculation unit
208...Response transmission section 209...Response delay information transmission section 210...Transmission buffer section 211...Transmission synthesis section 212...Transmission section Patent applicant NEC Corporation Agent Patent attorney Inoro Juju

Claims (1)

[Claims] In a data transmission system comprising a plurality of data transmission devices that can serve as a sender or a receiver, and a data transmission path that connects the plurality of data transmission devices, the plurality of data transmission devices a command sending means for sending a batch status read command to the other receiving data transmission device, and a response delay representing a preset delay time in the batch status read command. response delay information setting means for including time information; receiving means for receiving the bulk status read command sent from another data transmission device serving as the sending side; and during operation of the receiving means. The response delay information received in the preset 11! and a response delay means for delaying response time by an extension time, and the range of responses from the plurality of receiving sides when the sending side sends the bulk status read command to the plurality of receiving sides. A data transmission system 0 characterized in that the data transmission system is configured to avoid occurrence on the transmitting side.