JP2530686B2 - Broadcast response confirmation method - Google Patents

Description

The present invention relates to a response confirmation method for broadcast communication in a bus type transmission line.

[Conventional technology]

In a system in which a plurality of stations are connected by one transmission line, there is a case where broadcast communication is performed in which the same message is simultaneously transmitted from one station to all other stations. When this broadcast communication is performed, it is important to confirm whether or not all the stations that should receive it have surely received the response, especially in the case of the control computer network. A conventional example of this response confirmation method will be described.

Figure 2 shows a station (ST) in a bus type transmission line.
And shows the general configuration of the transmission line, the station
111-116 to branch cables 121-126 and branch device 13, respectively
This is a system in which one transmission line 14 is connected via 1-136. Terminators 15 for termination are attached to both ends of the transmission line 14.

FIG. 3 shows one station 11 in the system of FIG.
3 shows the state of becoming a transmitting station. The transmitting station 113 transmits the broadcast frame to the transmission line 14 (S in the figure),
All other stations receive this simultaneously, all at once.
However, in this example, only the transmission and reception of the broadcast frame is performed, and the response confirmation is not performed.

In FIG. 4, similarly to FIG. 3, the station 113 transmits a broadcast frame as a transmitting station (S), and all other stations simultaneously receive it. Further, in this example, following the reception, each receiving station returns a response to the transmitting station 113 in the order of R ₁ , R ₂ , ..., By which the transmitting station confirms the response. This method has been further improved, and is referred to as "broadcast communication method" (JP-A-57-2).
04658) etc., the details are shown, but the point that each station returns a response in order does not change.

In the case of the method of FIG. 3, the above-mentioned conventional technique does not confirm the response, and therefore it is not known whether or not the information has been transmitted to all the receiving stations. Therefore, it cannot be applied to control each station in synchronization with the information. Further, in the case of the method of FIG. 4, since the response confirmation is performed for each individual station, it takes a long time to confirm the response and the throughput of the broadcast frame is lowered.

On the other hand, in Japanese Patent Laid-Open No. 61-6552, when a station (transmission device) cannot correctly receive a broadcast frame, a response signal (alarm signal) indicating that the station could not be received correctly is provided. There is described a technique for returning to the transmitting station to inform the transmitting station that normal reception has failed. In addition, JP-A-58-109
According to Japanese Patent Laid-Open No. 43, when a station correctly receives a broadcast frame, one station returns a response signal (response confirmation signal) notifying normal reception to the transmitting station, thereby informing the transmitting station that normal reception is possible. The technology is described.

According to the techniques disclosed in JP-A-61-6552 and JP-A-58-10943, at least one receiving station cannot normally receive the broadcast frame when the alarm signal is returned. In addition, when the alarm signal is not returned and the acknowledgment signal is returned from one station that should return the acknowledgment signal,
It can be seen that the broadcast frame was transmitted and received normally.

[Problems to be Solved by the Invention]

In the techniques described in the above-mentioned JP-A-61-6552 and JP-A-58-10943, it can be understood that the broadcast frame could not be normally received by the receiving station and that the broadcast frame was normally received. However, there is a problem that it is not possible to judge whether or not the broadcast frame is normally transmitted from the transmitting station to the transmission line.

The present invention is a system in which broadcast communication is performed.
To provide a broadcast communication response confirmation method capable of confirming whether or not a broadcast frame is normally transmitted from a transmitting station to a transmission line, and not causing a decrease in broadcast frame throughput due to the confirmation. It is in.

[Means for solving the problem]

The purpose of the above is to provide the receiving station with means for returning an alarm signal when it detects that an error has occurred in the broadcast frame, and the transmitting station confirms this alarm signal for a specified time after transmitting the broadcast frame. This is accomplished by checking whether or not an error has occurred and returning a response confirmation frame when at least one of the receiving stations normally receives it, and the transmitting station checking whether or not this frame has been returned.

[Action]

The alarm signal from each receiving station is wired-ORed on the transmission path (it becomes valid if at least one alarm is issued). If there is no wired OR alarm signal on the transmission line and there is no response confirmation frame from the station to which the response confirmation frame should be returned, it can be seen that the broadcast frame was not normally transmitted from the transmitting station to the transmission line. At this time, the alarm signal from each receiving station is sent out at the same time, wired-ORed, and then taken into the transmitting station as one signal to be processed even if it is sent out from a plurality of stations. You can check the response of all stations without using it.

〔Example〕

Hereinafter, the present invention will be described in detail. FIG. 5 is a block diagram showing an embodiment of a station to which the method of the present invention is applied, and shows the internal configuration of the station 113 as an example, but other stations are the same. In the figure,
Central processing unit (CPU) 22 and system memory (MS) 23
And a network control processor (NCP) 21 are connected by a system bus 24. The network control processor 21 includes a microcomputer bus 25, an address buffer (ADDR BUF) 27, and a data buffer (DATA B
UF) 30 and system bus 24 control unit (BUS)
Information is exchanged with the central processing unit 22 and the memory 23 by the ABTR, BUS CTL) 28, 29 and the bus port (PORT) 31. The microcomputer bus 25 has a memory (MEMORY) 34 and other LSIs (P
In addition to the PI) 35, it has the function of implementing the method of the present invention.
A token control LSI (TBC) 32 and a controller 36 that manage a protocol related to transmission on the transmission path 14 side are connected. The modulator / demodulator (CBM) 33 modulates the output signal 32a of the token control LSI 32 and sends it to the transmission line 14, demodulates the signal from the transmission line 14 and sends the demodulation signal 33a to the token control LSI 32. Controller 36
Is the operation of the token control LSI 32 and the modulator / demodulator 33,
Also, the signal information 32a, 32b, 33a is monitored and the modulator / demodulator 33 is controlled by the control signal 36a.

FIG. 6 is a block diagram showing details of the controller 36 and the modulator / demodulator 33. When sending, token control LS
The output signal 32a from I32 is modulated by the modulation / demodulation circuit (MOD / DEM) 41, and the multiplexer (MPX) 4 via the driver 44.
Enter in 3. The output signal 43a of the multiplexer 43 is output to the branch cable 123 via the insulating transformer 42.
At this time, the output signal 32a from the token control LSI 32
Is also input to the dummy frame detector 46 of the controller 36, and the control circuit 47 gives the command signal 36a to the multiplexer 43 so that the signal is output from the signalless multiplexer 48 by the signal 46a output when the dummy frame is detected. This operation is a procedure for producing SILENCE 3 shown in FIG. 8 which will be described later. The dummy frame detected at this time will also be described with reference to FIG.

Next, when receiving from the branch cable 123, the transformer 4
The signal input to 2 is input to the modulation / demodulation circuit 41 via the receiver 45 as the signal 42a. Demodulated signal here 33
The a is received by the token control LSI 32. At the same time, the signal 33a is also input to the broadcast frame detector 49, and the signal 49a indicating that the broadcast frame is being received is input to the control circuit 47.
If the token control LSI 32 detects that an error has occurred in the frame being received, the error detection signal 32b is input to the control circuit 47, and the control circuit 47 is output from the alarm signal generator 50 at this time. Alarm signal
The command signal 36a is given to the multiplexer 43 so that 50a is outputted from the multiplexer 43. This operation is a mechanism for sending an alarm signal from the receiving side.

Figure 7 shows the format of the transmission frame.
Pattern used for synchronous pull-in of LEH reception, SD is a frame start delimiter, FC is a frame control code such as a command, DA is a destination address, SA is a destination address, and I is a response confirmation at the time of a broadcast frame. It is an indicator showing whether or not. This indicator stops the response confirmation if the response confirmation is not necessary for the broadcast frame,
This makes it possible to realize higher throughput communication. DATA is information, FCS is frame check sequence, E
D is the end-of-frame delimiter.

FIG. 1 is a processing flowchart in the transmitting station for realizing the method of the present invention, and FIG. 8 is an explanatory diagram of this processing.

In these figures, when the transmitting station receives the transmission permission signal token 1 (step 201), it transmits the transmission frame 2 (step 202). In step 203, it is determined whether or not the broadcast frame is transmitted. If not, the process proceeds to the next transmission operation in step 208. If it is the broadcast frame, the process proceeds to step 204, in which field I in FIG. 7 is examined. When the response confirmation is required, the dummy frame 7 for ensuring the alarm signal detection window is transmitted (step 205). In the first half of SILENCE 3, the alarm signal reception window 4 receives the alarm signal returned from each receiving station by the mechanism described in FIG. 6 (step 206). This alarm signal is a signal that is returned to the broadcast frame 2 from the transmitting station when each receiving station detects an error.
On 14 is wired or. Therefore, if an alarm signal is received in the alarm signal reception window 4, it means that at least one station has detected an error in the broadcast frame 2. In step 206, if nothing is received in the alarm signal reception window 4, either the broadcast frame 2 has been correctly transmitted to all the signal stations, or all the reception stations have not recognized the broadcast frame 2 at all. Is shown. At this time, in the latter half of SILENCE3, the response frame 5 is received from one station on the transmission path (step 207). The receiving station that returns the response frame 5 may be defined by a method such as one specified station defined on the transmission path or the next station in the token circulation order. When the response frame 5 is detected by the transmitting station, it is a proof that the normal broadcast frame 2 is transmitted at least on the transmission path.

From the judgment results of steps 206 and 207 above, the transmitting station can make the following judgments.

(1) When there is no alarm and the response frame is returned normally, the broadcast frame transmission is successful. (Step 206 → 207 →
208) (2) When there is an alarm and the response frame is returned normally, at least one station fails to receive. (Step 20
6 → 210) (3) When there is no alarm and there is no response frame, the broadcast frame has not been normally transmitted to the transmission path and transmission has failed. (Step 206 → 207 → 210) (4) When there is an alarm and the response frame is an abnormal response or no response, at least one station fails to receive. (Step 206 → 210) After the above judgment, when the process moves to Step 210, the frame transmission is retried, and it is confirmed in Step 211 that the number of retries has not reached the specified value (when it reaches Step 209). Send the token to the next station NS), step 205
Return to and repeat the reception confirmation operation. On the other hand, success (1)
If it is, the presence or absence of another frame to be transmitted is checked in step 208, and if not, the token is moved to the next station NS (step 209). If there is, the token holding timer is checked in step 212. If the time is up, the flow goes to step 209. If not, the next frame is sent in step 213 and the flow returns to step 203.

In the above description, the alarm signal from each receiving station and the response signal from one station are provided in separate time slots and received by the broadcast frame transmitting station. May be sent to normal bus occupancy control, and a broadcast frame transmitting station that receives these may be provided with a function of distinguishing which signal. Also, no time slot for receiving the alarm signal is provided, and the receiving station immediately returns when an error is detected, so that even if the receiving frame is transmitting a broadcast frame, the broadcast frame transmitting station can receive this alarm signal. Good.

〔The invention's effect〕

According to the present invention, in the broadcast communication, it is possible to confirm whether or not the broadcast frame is normally transmitted from the transmitting station to the transmission path, and the throughput is hardly reduced for confirming the response.

[Brief description of drawings]

FIG. 1 is a flowchart of a process for realizing the method of the present invention, FIGS. 2 to 4 are diagrams for explaining the prior art, FIG. 5 is a block diagram showing an embodiment of a station, and FIG. FIG. 7 is a block diagram showing details of a circuit which is a feature of the present invention, FIG. 7 is a diagram showing a frame format,
FIG. 8 is an explanatory diagram of the process of FIG. 1 ... Token, 2 ... Broadcast frame, 3 ... No signal status SILENCE, 4 ... Alarm signal reception window, 5 ...
Response frame, 6 ... Token, 7 ... Dummy frame, 14 ... Transmission path, 32 ... Token control LSI, 3
3 ... Modulator / demodulator, 36 ... Controller, 111-116 ... Station.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Ken Onuki 52-1 Omika-cho, Hitachi-shi, Ibaraki Hitachi Omika factory (72) Masato Satake 5-2 Omika-cho, Hitachi-shi, Ibaraki No. 1 Inside the Omika Factory of Hitachi, Ltd. (72) Seiichi Yasumoto 52-1 Omika-cho, Hitachi City, Hitachi City, Ibaraki Prefecture Inside the Omika Factory of Hitachi, Ltd. (72) Junji Fukuzawa Aso-ku, Kawasaki City, Kanagawa Prefecture 1099 Ozenji, Hitachi Systems Development Laboratory

Claims (6)

(57) [Claims] 1. A receiving station when one of a plurality of stations connected to a transmission line transmits a broadcast frame as a transmitting station and another station becomes a receiving station of the broadcast frame. Each of them sends an alarm signal when it detects an error in receiving the broadcast frame, and sends a response confirmation signal when one of the receiving stations normally receives the broadcast frame, and then The transmitting station has a process of receiving the alarm signal and the response confirmation signal separately, and when neither the alarm signal nor the response confirmation signal is received in this process, a broadcast frame is transmitted to the transmission line. A method of confirming a broadcast communication response, which comprises determining that the transmission has not been normally performed. 2. The broadcast system according to claim 1, wherein the transmission line is a token bus which is transmitted by a station which receives the token from the bus-shaped transmission line and which transmits the token to the next station upon completion of the transmission. Communication response confirmation method. 3. The method according to claim 1, wherein the transmission line has a ring shape. 4. The broadcast communication according to claim 1, wherein the transmitting station is configured to receive the alarm signal reception and the response confirmation signal reception separately by providing separate time slots. Response confirmation method. 5. The broadcast communication response according to claim 1, wherein the transmitting station is configured to receive the alarm signal reception and the response confirmation signal reception separately according to their signal contents instead of time slots. Confirmation method. 6. The method according to claim 1, wherein the transmitting station has a function of receiving the alarm signal even while the broadcast frame is being transmitted.