JPS63206043A - Transmittal acknowledgement equipment in loop network - Google Patents

Abstract

PURPOSE:To allow the secondary station to discriminate whether or not it receives a normal frame in a short time by utilizing a characteristic that a frame sent by the primary station is returned again to its own station via the secondary station. CONSTITUTION:A primary station 1 sends a frame of a prescribed transmission frame format and secondary stations 2a-2c send the frame to the subsequent station in this order. The secondary stations 2a-2c send a frame different depending whether reception frame is normal or abnormal to the subsequent station by a transmission frame transmission means 51. The primary station 1 uses a reception data comparison means 52 to compare the received frame with the transmission frame to discriminate whether or not the secondary station receives the frame normally.

Description

[Detailed Description of the Invention] [Summary] The present invention is a delivery confirmation device for a loop type network that performs multicast communication, which polls each of a plurality of secondary stations individually and obtains responses from them to confirm delivery. In order to solve the conventional problem that it takes a long time to confirm delivery, the secondary station sequentially transmits frames corresponding to normal/abnormal received frames to the next station, and the primary station By determining the frame returned from the next station and confirming delivery, the time required for delivery confirmation is reduced and network processing can be performed efficiently.

[Industrial application field]

The present invention provides a delivery confirmation device in a loop network;
In particular, the present invention relates to a device for checking whether a plurality of secondary stations have correctly received a frame in multicast communication. In this case, it is necessary to be able to confirm delivery in as short a time as possible and to be able to perform network processing efficiently.

[Conventional technology]

Conventionally, in multicast communication, in order to check whether the secondary station was able to correctly receive the frame transmitted by the primary station,
Each secondary station is polled individually, and it is determined whether or not the secondary frequency has been correctly received based on the response from each secondary station.

[Problem that the invention seeks to solve]

In the conventional system mentioned above, delivery confirmation is performed by polling each secondary station individually and obtaining a response from it, so there is a problem that it takes a lot of time to confirm delivery and is inefficient. Ta.

[Means for Solving the Problems] FIG. 1 shows a principle block diagram of a delivery confirmation device in a loop type network according to the present invention. In the same figure, 50 is a received data checking means, and the secondary stations 2a, 2b, 2c
means for checking whether the received frame is normal or abnormal; 51 is a frame transmitting means, and depending on whether the frame is normal or abnormal, the secondary station transmits a different frame corresponding to normality or abnormality to the next station. Means 52 is received data comparison means in the primary station 1 and the secondary stations 2a, 2b.

The secondary station 2a receives the frame sent from the 2c side.
, 2b, 2c side means for determining whether or not the frame has been received normally; 53 is a frame transmitting means; if the frame is not normally received at the secondary station, means for transmitting retransmission frames until it is normally received; be.

[Effect]

In a loop network, the frame transmitted by the primary station returns to the local station via each secondary station, and the secondary station sends a different frame depending on whether the received frame is normal or abnormal. The data is transmitted from the transmitting means 51 to the next station, and the primary station compares the received frame with the transmitted frame using the received data comparing means 52, thereby making it possible to determine whether or not the secondary station has received the data normally.

〔Example〕

FIG. 2 shows a block diagram of an embodiment of the present invention.
A) is the primary station, and (B) is the secondary station.

FIG. 3 shows a flowchart of the processing procedure of the present invention, in which (A) is for the primary station and (B) is for the secondary station.

The primary station 1 transmits a frame shown in the transmission frame format shown in FIG. 4, and the frame is sent to the secondary stations 2a and 2b.

2c transmits the frames to the next station in this order. As shown in Fig. 4, the transmission frame includes a flag, the address of the secondary station, and a retransmission frame identification section RC (this is a retransmission determination flag ("1" if it is a retransmission frame, "0" if it is not a retransmission frame).
) and sequential NO], a control section, an information section, a frame check sequence FC8, and a flag.

The primary station 1 sets the sequential number as "1" and the retransmission determination flag as "0" and transmits it to the secondary station 2a. 2
The frame is received by the frame receiving unit 3 of the next station 2a, and the received data check unit 4 checks whether the received frame is normal (step 100 in FIG. 3 (8)), and if it is normal, the address check unit 5 It is checked whether it is a local address or a global address (step 10).
1) If the frame is abnormal, abort frame creation unit 6
7 bits or more and 15 bits or less as shown in Figure 5.
1" is created and transmitted from the frame transmitter 7 to the next secondary station 2b (step 10).
6), and if the address is not the local address or the global address, the received frame is sent as it is from the frame transmitter 7 to the 2
Next! : Sent to XJ2b (steps 101 and 105
).

Here, for example, if it is a local address or a global address and is a normal frame, the RC check unit 8 detects that the retransmission determination flag is rOJ (OFF) (that is, it is not a retransmission frame) (
Step 102), sequential NorI in memory 9
While "J" is entered, the terminal 10 takes in data for its own station (step 104), and then the frame is transmitted as is from the frame transmitter 7 to the secondary station 2b (step 105). In addition, RC Bueck Department 1
1 is a flag r1J for retransmission determination in the RC check unit 8
It operates only when (ON) is detected.

Next, if the received frame is abnormal in the secondary station 2b, or if the frame that should be captured cannot be captured due to processing capacity (step 100), the abort frame creation unit 6 generates an abort as shown in FIG. A frame is created and transmitted from the frame transmitter 7 to the next secondary station 2c (
Step 106). This abort frame is received in the next secondary B2c, and when it is checked by the received data checking unit 4 to be an abort frame, it is transmitted as is to the primary station 1 via the frame transmitting unit 7.

In the primary station 1, the frame receiving unit 15 receives the abort frame from the secondary station, and the received data comparing unit 16 compares it with the transmission frame that was previously transmitted and stored in the transmission buffer 17. It is checked whether the frame is the same as the transmitted frame, an abort frame, or an abnormality (step 110 in FIG. 3(A)). In this case, since it is an abort frame, the RC retransmission determination flag control unit 18 sets the retransmission determination flag to "1" indicating that it is a retransmission frame (step 111), and a retransmission frame is created, and the transmission buffer 17 and is transmitted again to the secondary station 2a via the frame transmitter 19 (
Step 112).

Note that if the reception data comparison unit 16 determines normal reception, the 80811111 unit 20 determines the next 7L/-m(7)R(J
B is created (clearing the retransmission determination flag and incrementing the sequential number by 1), and the transmission frame creation section 21 creates transmission data including the RC part, and supplies it to the transmission buffer 17.

In the secondary station 2a, the RC check unit 8 detects that the retransmission determination flag MJ (ON) (that is, it is a retransmitted frame) (step 102 in FIG. 3(B)).
, in the next RC check unit 11, the RC part 1 of the sequential number previously written in the memory 9 and the sequential number rRc=IJ of the retransmitted frame that will be transmitted from now on match (that is, it has already been normally received). This is detected (step 103), data is not captured, and the retransmission frame is transmitted from the frame transmitter 7 to the next secondary station 2b (step 105).

Assuming that the secondary station 2b receives the frame normally from now on, the RC check unit 8 detects that the retransmission determination flag is "1" (ON) (that is, it is a retransmitted frame) (step 102), and the RC The sequential number rRc of the retransmission frame that will be transmitted in the future by the checking unit 11 is rRc = 1J
and the sequential number in the memory 9 (the sequential number is not written in the memory 9 because the secondary station 2b has previously transmitted an abort frame), and a mismatch is detected. As a result, the sequence number “
1'' is written in the memory 9, and after the terminal 10 imports data for the own station (step 1).
04), the frame is transmitted as it is from the frame transmitter 7 to the next secondary station 2c (step 105).

Here, assuming that the secondary station 2c also receives the frame normally, the same frame as the transmitted frame is returned to the primary station 1.

At the primary station 1, the received data comparison unit 16 compares the transmission buffer 1
It is detected that the transmission frame is the same as the previous transmission frame stored in the secondary stations 2a, 2b, and 2c (step 110 in FIG. 4(A)). Can be confirmed. Here, if there is no need to transmit the next frame, the process is terminated at this stage, while if it is necessary to transmit the next frame, the retransmission determination flag is cleared to "0" in the RC control unit 20, and the sequential N
O is increased by 1 to become "2" (steps 113, 11
4). Next, the transmission frame creation section 21 creates transmission data including the retransmission frame identification section RC, and a new transmission frame is transmitted via the transmission buffer 17 and frame transmission section 19 (step 115).

Thereafter, the same operation as described above is repeated, and the secondary stations 2a, 2b
, 2c and the primary station 1, delivery confirmation to each secondary station 2a, 2b, 2c can be performed in a loop network instead of individually.

〔Effect of the invention〕

According to the present invention, it is possible to judge in a short time whether or not a plurality of secondary stations have received a normal frame in a loop network, and especially in the case of multicast communication, it is possible to judge whether or not a normal frame has been received by a plurality of secondary stations in a loop network. There is no need to perform polling, obtain a response, and confirm delivery, and it has the advantage of efficient network processing.

[Brief explanation of the drawing]

Figure 1 is a block diagram of the principle of the present invention, Figure 2 is a block diagram of an embodiment of the present invention, Figure 3 is a flowchart of the processing procedure of the present invention, Figure 4 is a diagram of the transmission frame format, and Figure 5. is a diagram of an abort frame. In the figure, 1 is a primary station, 2a, 2b, 2c are secondary stations, 3.15 is a frame receiving section, 4 is a received data check section, 5 is an address check section, 6 is an abort frame creation section, 7.19 is a frame transmission section, 8.11 is an RC check section, 9 is a memory, 10 is a terminal, 16 is a received data comparison section, 17 is a transmission buffer, 18 is a flag control section for determining RC retransmission, 20 is an RC control section, 21 is a transmission frame creation section. (A) Cape Kon [River primary station I = kudzu rr-ta! The first meeting Takaguno flowchart Figure 3 (Ki no 1) (B) This invention / 12th order 1 = asu 1 month [Reiken 70-←) Figure 3 (Yari 2)

Claims (1)

[Claims] A network in which a primary station (1) and a plurality of secondary stations (2a, 2b, 2c) are connected in a loop, wherein the primary station (1)
The frame transmitted from the secondary station (2a, 2b, 2c
), the reception data checking means (50) checks whether the frames received at the secondary stations (2a, 2b, 2c) are normal or abnormal. frame transmitting means (51) for transmitting different frames corresponding to normality/abnormality from the secondary station to the next station depending on whether the secondary station is normal or abnormal; 2a, 2b, 2
c) The received data comparison means (52) determines whether or not the frame transmitted from the secondary station (2a, 2b, 2c) side is normally received. A delivery confirmation device for a loop type network, characterized in that it is provided with a frame transmitting means (53) for transmitting a retransmitted frame until the frame is normally received if the frame is not received normally.