JPH031631A - Network communication system - Google Patents

Abstract

PURPOSE:To send a signal with a small traffic with the small delay by stopping data transmission/reception with a slave station having a sending right for the prescribed number of times and giving the sending right to other slave station when a transmission request comes to a 2nd polling at other slave station while a master station makes data transmission/reception with one slave station. CONSTITUTION:Polling is applied from a master station 1 to plural slave stations (e.g. 4 slave stations TE1-TE4), the slave station TE1 makes a transmission request R1, the slave station TE1 acquires the sending right to apply data transmission/reception, then the master station 1 continues the data reception/ transmission with the slave station TE1 by applying a 1st polling TENOPp to the slave station TE1 and applies the 2nd polling TENOr to the other slave stations TE2-TE4. Consequently, when a transmission request R3 comes from the slave station TE3, the data transmission/reception with the slave station TE1 is stopped for the prescribed number of times and the sending right is transferred to the slave station TE3 after data transmission/reception.

Description

[Detailed Description of the Invention] [Summary] Network communication system, particularly network communication in which a master station polls a plurality of slave stations one after another, issues a transmission request from the slave station, acquires the right to transmit through the polling, and sends and receives data. The purpose of this method is to enable a slave station with large traffic to send and receive data to other slave stations with small traffic. In a network communication system in which the slave station acquires the transmission right based on a transmission request and exchanges data, the master station continues the first polling of the slave station that has acquired the transmission right and exchanges data with the slave station. At the same time, the slave station that has acquired the transmission right performs a second polling on other slave stations, and when there is a transmission request from another slave station polled by the second polling, the slave station that has acquired the transmission right The tenth polling is performed on the adjacent slave station in order to terminate the data exchange with the slave station after a predetermined number of times and give the transmission right to the other slave station.

[Industrial application field]

The present invention relates to a network communication system, and particularly to a network communication system in which a master station polls a plurality of slave stations in sequence, issues a transmission request from the slave station, acquires a transmission right through the polling, and sends and receives data.

[Conventional technology]

In a normal network system in which multiple slave stations are connected to one master station in a ring, star, or bus configuration, the master station sequentially polls the slave stations, and the polled slave stations also send transmission requests. If there is, the slave station acquires the transmission right and exchanges data,
During this time, the main station did not perform polling, but polled again after the slave station that had acquired the transmission right finished transmitting. In this case, it takes time to poll the slave station that will next try to acquire the transmission right, resulting in wasted time.

Therefore, the applicant of this application continues polling of the slave stations that have already acquired the transmission right, and also performs another poll of other slave stations in order to memorize in advance the other slave stations that have transmission requests. The proposed method is to immediately give transmission rights to other stored slave stations after the slave station finishes transmitting, thereby eliminating wasted time (see Japanese Patent Application No. 62-326118).

[Problem to be solved by the invention]

However, in the network communication system proposed above, while a slave station is transmitting, the master station continues polling the slave station, so if there is a slave station with large traffic, other slave stations will be unable to transmit data. be.

In recent years, it has become common practice to integrate and communicate signals of different media such as audio, images, and computer data over a single network. In this case, although the audio signal traffic for poetry is small, the delay has a sensitive effect on the audio characteristics. Therefore, for example, if a computer terminal outputs a large amount of data in a burst, an audio terminal connected to the same network will not be able to output a signal.
This will lead to deterioration of voice quality.

[Means to solve the problem]

A means for solving the above problem is shown in FIG.

That is, a plurality of, for example, four slave devices ~T
In a network communication system in which the slave station T81 acquires the transmission right in response to a transmission request R1 from the polled slave station, for example, Tel, and sends and receives data, as shown in FIG. Station 1 sends the first poll T[EN
O, and continues to exchange data with the slave station Tel, and as shown in FIG. 1(B), the other slave stations Tε2 to T
A second polling TεNO is performed on B4. As a result, when there is a transmission request R3 from another slave station polled by the second polling TεNO, such as TE3, data exchange with the slave station Tε1 that has acquired the transmission right is terminated after a predetermined number of times, and the first As shown in figure (C),
The first polling T
EPO, to slave station TB3.

[For production]

According to the above-mentioned means, even if the slave station, for example TEL, which has currently acquired the transmission right has a large traffic, that is, has a large signal amount, if there is another slave station TE3 that wants to request transmission, The transmission right of the slave station Tel is transferred to the slave station TE3 after data has been exchanged a predetermined number of times, for example once. Therefore, if slave station T83 has small traffic, for example even if it is a voice terminal, the voice delay is small.

〔Example〕

FIG. 2 is a block circuit diagram showing an embodiment of the network communication system according to the present invention. In Figure 2, main station 1
has four slave stations Tε1. TE2. TE3°TB4 are connected like a bus by an R line and a T line.

The main station 1 includes a separation unit 11 that separates packet data received from the slave stations 1 to TE4 and distributes it to each part,
Polling table 12 that stores the transmission request bits from I to TE4, TENOp register 13 that stores the first polling number TENO, (slave station number), T that stores the second polling number TENOr (slave station number)
It is equipped with a multi-electrification section 15 that multiplexes the END, register 14, polling number, reception information, etc. and sends packet data to each slave device to TIE 4, and a control section 16 that controls each section.

As shown in the figure, a bucket) P + containing received information to each slave station TE 1 , TB2 , TB3 , TB4 is sent from the multiplexing unit 15 of the master station 1 to the R line. Here, DL: Delimiter TEND indicating the beginning of the signal; TENOr: Number of the slave station receiving the first polling; TENOr: Number of the slave station receiving the second polling; .

TB2. TB3. Bucket containing information sent from TIE 4 to main station 1) P2. P3 is sent. Here, G:
Guard time PA to prevent collision of signals from different slave stations: Preamble for extracting clocks from signals from different slave stations DL = Delimiter R indicating the beginning of the signal: Transmission request Note that if there is no transmission information, No transmission information is sent.

FIG. 3 is a flowchart showing the operation of the control section 16 of the main station 1 shown in FIG. First, the first polling information TE for the transmitting slave station, for example TEI, is sent via the R line.
It is assumed that a packet P1 containing a NO and second polling information TENO specifying the slave station to which the transmission request is to be sent, for example TB3, has been sent. As a result, in step 301, the slave station TEND on the T line, (=TE3
) Separating unit 1 extracts the transmission request bit R from the packet P2 from
1 and is written to address 3 of the polling table 12 in step 302. In addition, as shown in FIG. 7, each slave device, TB2, TB3, TB4, has the following:
Assign the following address.

TBI: “1′” TB2: “2” TB3:”3” TB4: “4” Similarly, in step 303, the slave station T8NO on the T line.

(=TE L) From packet P3, the transmission request signal is transmitted.
Soto R is input through the separation unit 11 and written to address "1" of polling tables 1 and 2 in step 304.

For example, as shown by arrow X in FIG.
When Or (TB 3 ) sends out the transmission request bit R (="1") and the slave station TEND (TE 1 ) sends out the transmission request bit R <= "1"°, the arrow X in FIG.
As shown in FIG. 2, a transmission request bit is written into the polling table 12.

In step 305, the first value stored in the register 13 is
The polling (TEPOp) value is updated. That is,
“1” (Btl) starts from the address next to address TEPO, (1 in this case) on the polling table
SY bit), and as a result, all bits are “0” (
IDLIE bit), the value of register 13 is incremented by +1. Note that the value of register 13 is 1 → 2 → 3 → 4.
It is assumed that the cycle goes like →1→2→... On the other hand,
If there is even one “l” (BUSY bit), the next “1”
An address having a bit is set in register 13. For example, when the contents of the polling table 12 are as shown by arrow x2 in FIG. 7, TEND, = 3 is stored in the register 13 (arrow X3). Of course, in the case shown by arrow x4 in FIG. 7, the value of register 13 is not changed. Note that step 305 will be explained in detail later.

In step 306, the second value stored in the register 14 is
The polling (TEPOp) value is updated. That is,
Starting from the address next to address TEPO, (3 in this case) on the polling table 12,
As a result, all bits are “l” (
If B [ISY bit), the value of the register 14 is incremented by +1. Note that the value of register 14 also changes from l→2→3→4.
It is assumed that the cycle goes like →1→2→... On the other hand,
If there is even one par 0"" (IOLE bit), the next "1"
”Set the address with the bit in register 14.

For example, if the contents of the polling table 12 are as shown by arrow X2 in FIG.
4 (arrow X3). Note that step 306 will be detailed later.

In step 307, it is determined whether the value TENO of the register 13 and the value TEND of the register 14 match, and only when TENO,=TENO, step 30
8 to 310, TEND is increased by +1 step. The slave station TEND currently transmitting, the slave station TE transmitting the transmission request
This is because it is meaningless to specify it as ND.

Note that steps 309 and 310 are for cycling the value of the register 14 within the range of 1.2 and 3.4 as described above.

In step 311, the updated value of the register 13.14 is used as polling information to send the packet P along with the received information.
It is sent to the R line as In this case, TENDp=3,7
8NO,=4 (arrow X3 in FIG. 7).

Thereafter, the above-described operation is repeated.

Figure 4 shows the register value TENO in Figure 3, update step 3.
10 is a flowchart showing details of 05. Step 40
1 clears the counter N. This counter N is used to execute the flow from step 402 up to four times in order to detect the first BUSY bit from the polling table 12. In step 402, the value TENO, of the register 13 is read and incremented by +1, and in steps 403 and 404, the value TENO, is cycled through the range of 1 to 4.

Next, in step 405, the transmission request bit R is read from the address TENO of the polling table 12, and R=
It is determined whether the bit is "1", that is, the BtlSY bit.

If it is not the BUSY bit, the flow of steps 402 to 405 is repeated up to 4 times in steps 406 and 407,
If the BUSY bit (R="1") is detected, the value TENDp is stored in the register 13 in step 411.
Store in. On the other hand, if there is no BUSY bit after repeating the above four times, that is, all IDLE beeps) (" 0
'''), in step 408 TBNO, is +1
It is incremented and cycled through steps 409 and 410 before proceeding to step 411. That is, in this case, the address following the first address TEND is stored in the register 13.

Then, in step 412, the process returns to step 306 in FIG.

Figure 5 shows the register value TENO in Figure 3, update step 3.
06 is a flowchart showing details of step 06. Step 50
1 clears the counter N. This counter N is used to execute the flow from step 502 up to four times in order to detect the first 10LE bit from the polling table 12. In step 502, the value TENO, of the register 14 is read and incremented by +1, and in steps 503 and 504, the value TIENO, is cycled through the range of 1 to 4.

Next, in step 505, the transmission request bit R is read from address TIENO of the polling table 12, and R
="0", that is, the IDLε bit.

If it is not the IDLE bit, the flow of steps 502 to 505 is repeated up to 4 times in steps 506 and 507,
If the IDLE pin (R="0") is detected, the value TENO is stored in the register 14 in step 511.
Store in. On the other hand, if there is no IDLE bit even after repeating the above four times, that is, all BUSY bits (“'1”
), in step 508 TENO, is incremented by +1, and in steps 509 and 510 it is cycled to step 5.
Proceed to step 11. That is, in this case, the address following the first address TEND will be stored in the register 14.

Then, in step 512, the process returns to step 307 in FIG.

FIG. 6 is a flowchart showing the operation of the slave station, for example Ta2, in FIG. In step 601, the bucket) Pl from the main station 1 is input from the R line, and in step 602, it is determined whether the second poll 78NO, is the local station (3), and only if it is the local station, step 603~ Proceed to 606. For example, in the case shown by arrow Y1 in Fig. 7, step 6
Proceed to 03-606. In step 603, slave station TE3
As a result, if the signal amount is 0, a transmission request beep is sent in step 604.
On the other hand, if the signal amount is 1 or more, the transmission request bit R is set to "1" in step 605. In the case shown by arrow Y2 in FIG. 7, the process proceeds to step 605. At step 606, the bucket P2 containing the transmission request message R is sent to the main station 1 via the T line.

In this way, if there is no signal amount held, the transmission request bit (P)R is set to the IDLE bit.

In step 607, it is determined whether or not the first polling TBNOp is the local station (3), and only if it is the local station, step 60
Proceed to steps 8-611. For example, in the case shown by arrow x3 in FIG. 7, the process proceeds to steps 608-611.

In step 608, the signal amount held by slave station TE3 is 1.
As a result, if the signal amount is 1 or less, the transmission request bit R is set to “0” in step 609, and on the other hand, if the signal amount is 2 or more, a transmission request is made in step 610. Set bit R to "1".

Note that in the case shown by arrow Y3 in FIG. 7, step 610
Proceed to. Then, in step 611, the transmission request via)R
P3 is sent to the main station 1 via the T line.

In this way, if the amount of signal held is 0, the transmission request bit R is set to 10LH bit. In this case, there is no transmission information in bucket P3. On the other hand, if the amount of signal held is 1, the transmission request bit R is still set to IDL8 bits, but in this case, there is transmission information in bucket P3.

Note that in the above embodiment, if there is a slave station that has the BUSY bit (transmission request bit) other than the slave station currently transmitting, the polling TE is sent after one data exchange.
Although the slave station is switched to NO0, it is also possible to switch the polling TENO after two or more data exchanges using the BUSY bit in the polling table 12. In this case, in FIG.
If the data R at the address TENDp continues to have the BUSY bit, the execution of the flow in steps 305 and 306 may be stopped twice or more.

〔Effect of the invention〕

As explained above, according to the present invention, even when there is a slave station with large traffic, it is possible to
Transmission rights are forcibly granted to other slave stations with small traffic after the data exchange (times), and it is guaranteed that signals with small traffic can be transmitted with a small delay.

[Brief explanation of drawings]

FIG. 1 is a block circuit diagram showing the basic configuration of the present invention, FIG. 2 is a circuit diagram showing an embodiment of the network communication system according to the present invention, and FIGS. 3 to 6 show the operation of FIG. 2. Flowchart FIG. 7 is a state transition diagram supplementary explanation of the flowcharts of FIGS. 3 to 6. ■...Main station, TEI~TE4...Slave station, 12...Polling table, 1.3.14...Register, TIENOp...First polling, TENQ,...
-Second polling.

Claims (1)

[Claims] 1. A main station (1) polls a plurality of slave stations (TE1 to TE4), and in response to a transmission request from the polled slave station, the slave station acquires the transmission right and exchanges data. In the network communication method, the master station continues to perform first polling (TENO_p) on the slave station (TE1) that has acquired the transmission right, and continues to exchange data with the slave station (TE1), and also transmits data to the slave station (TE1) that has acquired the transmission right. Second polling (TENO_r) is performed on the slave stations (TE2 to TE4), and other slave stations (TENO_r) polled by the second polling are
When there is a transmission request from TE3), the first polling is performed to terminate data exchange with the slave station (TE1) that has acquired the transmission right after a predetermined number of times, and to give the transmission right to the other slave station. (TEPO_p) to the other slave station.