JP3654515B2 - Transmission equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a transmission apparatus that transmits and receives data on a network.
[0002]
[Prior art]
Conventionally, there is a technique called CTC (Centralized Traffic Control). In this method, one or more stations and one central control station are connected via a network, and operation control from the central control station to each station is performed centrally and collectively.
[0003]
In this regard, various transmission means on the network that are applied to the CTC system and the like are considered. For example, it is a transmission means for avoiding data collision during transmission / reception on a network between a plurality of transmission terminals.
[0004]
The polling method, which is one of the transmission means, is the presence / absence of data to be transmitted by the control station to each dependent station and the data on a system in which one control station and one or more dependent stations are network-connected. This is a system that inquires about reception capability and permits transmission / reception of dependent stations that meet conditions, that is, the dependent station performs transmission / reception after waiting for permission from the control station.
[0005]
In the token passing method, a plurality of transmission devices are connected, a token is circulated between the transmission devices through a network, and if there is data to be transmitted when the transmission device receives the token, In this scheme, the tokens with the data added are circulated between the transmission apparatuses and transmitted to the transmission apparatus to be received.
[0006]
In addition, there are transmission means that provide an exchange to avoid data collisions. A plurality of frame switches are installed on the transmission line, the data is divided into frames, the frame switch stores the frame and the transmission path is secured, ATM (Asynchronous Transfer Mode), etc. There is a cell relay system in which transmission is performed by installing an exchange that divides transmission data into fixed-length cells and transmits the data.
[0007]
In addition, there is a method in which data is mixed and multiplexed so that data collision does not occur on the transmission path. For example, a time division multiplex system in which each time slot is assigned to each different data and transmitted.
[0008]
[Problems to be solved by the invention]
However, the polling method is one-to-N communication, and the control station must make inquiries to the dependent stations one by one at the time of transmission, and only the dependent stations cannot communicate with each other, so the transmission efficiency is poor.
[0009]
Further, in the token passing method, transmission efficiency has to wait for receipt of a token, and since reconstruction takes time when the token is lost, transmission efficiency is poor. Incidentally, most of the conventional CTC systems are polling systems, and other token passing systems are also employed.
[0010]
The frame relay system is a relay through data accumulation in a frame switch. If the number of tandem connections in the frame switch is large, the end / end transmission delay increases. In addition, there is a problem that data is discarded at the time of data collision due to multiple data congestion in the frame exchange.
[0011]
The cell relay system is a non-storage relay of data and uses a hard switch, so that the relay is fast. However, since a fixed-length cell is used, transmission efficiency is low when data with a small amount of information is handled.
[0012]
In this case, data of various sizes cannot be efficiently mixed and transmitted, and regardless of the nature of the data, transmission is performed from what was sent first, and important data is delayed. There was also. Incidentally, CTC information in a CTC system is important data with a small amount of information.
[0013]
In addition, when failsafe control is performed in a conventional CTC system, the priority of the failsafe information that is important data is different, so that it is transmitted on a transmission line provided separately from the nonfailure safe information. The size of the system has become larger because it cannot be transmitted. Fail-safe is an idea that when a system fails, the operation of the device accompanying the failure always works on the safe side.
[0014]
Further, the time division multiplexing method has a complicated transmission procedure, a complicated transmission circuit configuration, and synchronous transmission, so that a failure in one place on the system affects the entire system. It was.
[0015]
The object of the present invention is to give priority to non-accumulated relay data, to avoid collision between data without discarding data, and to simplify transmission procedures, transmission circuit configurations, error countermeasures, The present invention also aims to enable transmission of variable amounts of data, thereby increasing transmission efficiency and reducing costs.
[0016]
In addition, asynchronous transmission that does not synchronize clocks on the system and an equalized configuration between transmission devices allow preferential transmission of data with rapid arrival demand without a single failure affecting the entire system. It is intended to be performed on the same traffic.
[0017]
  In order to solve the above problems, the present invention described in claim 1Left and right to configure a ring networkA transmission device connected to a transmission device (for example, transmission terminal devices A2 and C2 in FIG. 2), randomly accessing and transmitting information to each other, and connected to an external information input / output device,Left and rightFrom a transmission device (for example, transmission terminal devices A2 and C2 in FIG. 2)Has been transmittedVariable length relay information frameIs a priority relay information frame with priority or non-priority relay information frame with non-priorityReceiving logic means for discriminating (for example, R direction receiving logic circuit 4 and L direction receiving logic circuit 7 in FIG. 2);Priority determined by the receiving logic meansPriority relay storage means for storing at least one relay information frame (for example, the R-direction priority relay buffer 5a and the L-direction priority relay buffer 8a in FIG. 2);Non-priority determined by the receiving logic meansRelay storage means having non-priority relay storage means for storing at least one relay information frame (for example, R-direction non-priority relay buffer 5b, L-direction non-priority relay buffer 8b in FIG. 2), and the external information input / output device The output information from the synthesizer is converted into a variable-length transmission information frame so that it can be suppressed,Whether the converted transmission information frame is a priority priority transmission information frame or a non-priority non-priority transmission information frameTransmission processing means (for example, transmission processing CPU 10 in FIG. 2) having a function of determiningPriority converted and discriminated by the transmission processing meansPriority transmission storage means for storing at least one transmission information frame (for example, R direction priority transmission buffer 5c, L direction priority transmission buffer 8c in FIG. 2);Non-priority converted and discriminated by the transmission processing meansTransmission storage means having non-priority transmission storage means for storing at least one transmission information frame (for example, R-direction non-priority transmission buffer 5d, L-direction non-priority transmission buffer 8d in FIG. 2);The priority order is the order of the priority relay information frame, the priority transmission information frame, the non-priority relay information frame, and the non-priority transmission information frame.In order of priorityTherefore, the frames stored in the priority relay storage means, the priority transmission storage means, the non-priority relay storage means, and the non-priority transmission storage means areSwitching means (for example, the R direction transmission logic circuit 6 and the L direction transmission logic circuit 9 in FIG. 2) having a function of switching transmission,
  The reception logic means, the relay storage means, the transmission storage means, and the switching means are provided for right direction transmission and left direction transmission, respectively, and the non-priority relay storage means stores in the non-priority relay storage means A function of notifying the storage state of the non-priority relay information frame being transmitted to the switching means in the direction opposite to the transmission direction of the non-priority relay information frame, and the switching means includes the notified non-priority relay information frame Of transmitting the storage state of the packet to the switching means in the same direction as the notified non-priority relay information frame in the adjacently connected transmission deviceWhen,Accumulation state of non-priority relay information frames transmitted from switching means of adjacent transmission devicesIs a state in which more than a predetermined amount of non-priority relay information frames are accumulated,Non-priorityrelayFunction to suppress transmission of information framesWhen,HaveAndThe transmission processing means includesFrom the switching means of adjacently connected transmission devicesOf the transmitted non-priority relay information frameWhen the accumulation state is a state where more than a predetermined amount of non-priority relay information frames are accumulated,Has a function to suppress conversion of the output information.In addition, the suppression of the output information conversion by the transmission processing means suppresses accumulation of non-priority transmission information frames in the non-priority transmission storage means and transmission of non-priority transmission information frames.It is characterized by.
[0018]
  According to the first aspect of the present invention, the relay information frame can be transmitted in a non-accumulated manner with respect to the variable length information frame of asynchronous random access, and the transmission information frame is transmitted to both the left and right. Further, information frames depending on the transmission priority are mixedly transmitted on the same traffic in the order of the priority. In addition, based on the non-priority relay information frame accumulation state, non-priority in the adjacent transmission equipment in the opposite directionrelaySuppress information frame transmission.
[0019]
  Therefore, transmission efficiency can be improved without causing information collision and discard, tandem connection and system equalization can be performed, and transmission switching can be performed even if a failure occurs in one of the transmission paths. Therefore, error countermeasures can be taken, and preferential transmission of data with fast arrival demand can be performed on the same traffic without a single failure affecting the entire system. Moreover, the transmission efficiency by the priority transmission of the priority demand information is improved, and the cost can be reduced without constructing a transmission path for each priority information. In addition, extra non-priorityrelaySuppresses collisions between data due to the transmission of information frames before discarding the data.relayIt is possible to prevent collision and discard of information frame data.
[0031]
  further,Non-priorityrelayNon-priority information that is transmitted and transmitted to the transmission processing means of the transmission equipment adjacent in the transmission direction.relayThe output information conversion is suppressed based on information for suppressing transmission of the information frame.
[0033]
  Claim2The invention described in claim 11In the transmission apparatus described in item 1, the transmission processing unit has a function of transmitting the transmission information frame having the same content in both the left and right directions.
[0034]
  Claim2According to the invention described in (1), the first-priority reception process at the transmission destination device is performed by the same content transmission in both the left and right directions from the transmission device at the transmission source.
[0035]
Therefore, transmission efficiency can be improved and error countermeasures can be taken by improving the transmission speed.
[0036]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, with reference to the attached drawings, a first embodiment and a second embodiment of the present invention will be described in order.
[0037]
(First embodiment)
FIG. 1 is a block configuration diagram of a system including a transmission terminal apparatus according to the first embodiment.
[0038]
The transmission terminal device system α1 includes a transmission terminal device A1 that is a transmission device, a transmission terminal device B1 that is a transmission device connected to the transmission terminal device A1, and a transmission terminal device C1 that is a transmission device connected to the transmission terminal device B1. And an external information input / output device a1 connected to the transmission terminal device B1.
[0039]
The transmission terminal device B1 is connected to the transmission terminal device A1 and is a storage means for temporarily storing information frames. The transmission terminal device B1 is connected to the buffer 1 and the transmission terminal device C1 to switch transmission of information frames by hardware switching. And a transmission processing CPU 3 that is a transmission processing means that is connected to the transmission terminal device C1 and the buffer 1 and converts output information from the external information input / output device a1 as an information frame.
[0040]
The buffer 1 is connected to the transmission terminal device A1 and the changeover switch 2 and connected to the relay buffer 1a for storing the relay information frame from the transmission terminal device A1, and to the changeover switch 2 and the transmission processing CPU3 and transmitted from the transmission processing CPU3. It has a transmission buffer 1b for storing information frames.
[0041]
Each transmission terminal apparatus is assumed to be connected in a ring shape. Thus, the transmission terminal apparatus B1 has a very simple transmission circuit configuration.
[0042]
Next, the operation of the first embodiment will be described. In the transmission terminal device B1, when a relay information frame to be transmitted to the transmission terminal device C1 is transmitted from the transmission terminal device A1, the relay information frame is stored in the relay buffer 1a.
[0043]
When the output information is output from the external information input / output device a1, the transmission processing CPU 3 converts the output information into a transmission information frame to be transmitted to the transmission terminal device C1, and stores it in the transmission buffer 1b.
[0044]
Here, since the relay information frame and the transmission information frame are variable-length frames, they can contain various sizes of data. For example, small-capacity data such as control data of the CTC system is fixed length. The data can be transmitted more efficiently than a cell, and of course, the error can be prevented by the data frame structure, and the high reliability of the data can be obtained. Note that frame header information is minimized in order to increase transmission efficiency.
[0045]
Further, the relay buffer 1a and the transmission buffer 1b are buffers having a capacity larger than the maximum value of the size of each of the relay information frame and the transmission information frame, respectively. 1a and the transmission buffer 1b, and no error occurs depending on the size of the frame.
[0046]
When the relay information frame enters the relay buffer 1a, the changeover switch 2 performs switching to transmit the relay information frame to the transmission terminal device C1. Similarly, when the transmission information frame enters the transmission buffer 1b, the selector switch 2 performs switching to transmit the transmission information frame to the transmission terminal device C1.
[0047]
The changeover of the changeover switch 2 is very fast because it is a hardware changeover. Further, since the relay information frame and the transmission information frame are transmitted in a random access method, the system synchronization of the clock is not taken and the information frames can be transmitted continuously, so that the transmission efficiency is very good.
[0048]
When both the relay information frame and the transmission information frame are stored in the relay buffer 1a and the transmission buffer 1b, the changeover switch 2 is switched to the relay buffer 1a, and the relay information frame is transmitted to the transmission terminal device C1. To transmit. This is because the relay information frame is data transmitted with priority over the transmission information frame.
[0049]
In a state where the transmission information frame is stored in the transmission buffer 1b, the transmission processing CPU 3 does not output the next transmission information frame, waits for a procedure with the external information input / output device a1, and suppresses output information. And prevent the destruction of information.
[0050]
Except for the transmission waiting time of the relay information frame, the relay delay is very short because the transmission buffer 1a and the transmission buffer 1b are non-accumulated transmissions that do not store a plurality of transmission information frames and transmission information frames.
[0051]
Of course, when the destination of the relay information frame from the transmission terminal apparatus A1 is the transmission terminal apparatus B2, this is transmitted to the external information input / output apparatus a1.
[0052]
Since each transmission terminal device is connected in a ring shape, N-to-N communication between the transmission terminal devices is possible. Further, a transmission configuration in the opposite direction may be provided in each transmission terminal apparatus. For example, in the transmission terminal device B1, a buffer and a changeover switch that can transmit in the direction from the transmission terminal device C1 to the transmission terminal device A1 are provided. In this case, the shortest path of the two transmission paths from the transmission source to the transmission destination is taken, and transmission is possible even when the transmission time is shortened and one of the transmission paths fails. In this case, N-to-N communication between the transmission terminal devices is possible even if no ring connection is used.
[0053]
As described above, according to the first embodiment, it is possible to avoid collision between information frames, perform high-speed switching by hardware switches, simplify the transmission circuit configuration and transmission procedure, prevent discarding of information frames, Since the transmission terminal device can be connected in tandem, error countermeasures can be taken and N-to-N transmission of variable-length information frames can be carried out asynchronously and continuously, so the transmission efficiency is very good and the non-storage relay makes relay delay extremely high. Can be shortened.
[0054]
(Second Embodiment)
FIG. 2 is a block configuration diagram of a system including a transmission terminal apparatus according to the second embodiment.
[0055]
The transmission terminal device system α2 includes a transmission terminal device A2 as a transmission device, a transmission terminal device B2 as a transmission device connected to the transmission terminal device A2, and a transmission terminal device C2 as a transmission device connected to the transmission terminal device B2. And an external information input / output device a2 connected to the transmission terminal device B2.
[0056]
Here, the direction from the transmission terminal device A2 to the transmission terminal device C2 via the transmission terminal device B2 is the R direction (right direction), and the direction from the transmission terminal device C2 to the transmission terminal device A2 via the transmission terminal device B2 Is the L direction (left direction).
[0057]
  The transmission terminal device B2 is connected to the transmission terminal device A2 in the R direction from the transmission terminal device A2.Relay information frameR direction receiving logic circuit 4 which is a receiving logic means for determining the priority of the R direction receiving logic circuit 4 and connected to the R direction receiving logic circuit 4relayInformation frameAnd an R-direction transmission information frame to be described later (hereinafter, the relay information frame and the transmission information frame are collectively referred to as an information frame).And an R-direction transmission logic circuit 6 which is a switching means connected to the transmission terminal device C2 and the R-direction buffer 5 to switch transmission of information frames in the R direction.
[0058]
  The transmission terminal device B2 is further connected to the transmission terminal device C2 in the L direction from the transmission terminal device C2.relayDetermine the priority of an information frameReceive logic meansL-direction receiving logic circuit 7, L-direction buffer 8 that is connected to L-direction receiving logic circuit 7 and stores L-direction information frames, L-direction receiving logic circuit 7, L-direction receiving logic circuit 7, L-direction receiving logic circuit 7 L direction transmission logic circuit 9 which is switching means for switching transmission of direction information framesHave
  Also,The transmission terminal device B2 is connected to the external information input / output device a2, the R-direction buffer 5 and the L-direction buffer 8 to output information from the external information input / output device a2.Variable length transmissionIt has a transmission processing CPU 10 which is a transmission processing means for converting the information frame into an information frame.
[0059]
  The R-direction buffer 5 is connected to the R-direction reception logic circuit 4 and the R-direction transmission logic circuit 6 to receive the R-direction priority relay information frame from the R-direction reception logic circuit 4.At least oneStoreAs a priority relay storage meansThe R direction priority relay buffer 5a is connected to the R direction reception logic circuit 4, the R direction transmission logic circuit 6, and the L direction transmission logic circuit 9, and the R direction non-priority relay information frame from the R direction reception logic circuit 4 is transmitted.At least oneStoreAs a non-priority relay storage meansThe R-direction non-priority relay buffer 5b, the R-direction transmission logic circuit 6 and the transmission processing CPU 10 are connected to transmit the R-direction priority transmission information frame from the transmission processing CPU 10.At least oneStoreAs a priority transmission storage meansThe R direction priority transmission buffer 5c, the R direction transmission logic circuit 6 and the transmission processing CPU 10 are connected to transmit the R direction non-priority transmission information frame from the transmission processing CPU 10.At least oneStoreAs a non-priority transmission storage meansR direction non-priority transmission buffer 5d.
[0060]
  The L-direction buffer 8 is connected to the L-direction reception logic circuit 7 and the L-direction transmission logic circuit 9 to receive the L-direction priority relay information frame from the L-direction reception logic circuit 7.At least oneStoreAs a priority relay storage meansThe L-direction priority relay buffer 8a, the R-direction transmission logic circuit 6, the L-direction reception logic circuit 7, and the L-direction transmission logic circuit 9 are connected to receive the L-direction non-priority relay information frame from the L-direction reception logic circuit 7.At least oneStoreAs a non-priority relay storage meansThe L-direction non-priority relay buffer 8b, the L-direction transmission logic circuit 9 and the transmission processing CPU 10 are connected to transmit the L-direction priority transmission information frame from the transmission processing CPU 10.At least oneStoreAs a priority transmission storage meansThe L-direction priority transmission buffer 8c, the L-direction transmission logic circuit 9 and the transmission processing CPU 10 are connected to transmit the L-direction non-priority transmission information frame from the transmission processing CPU 10.At least oneStoreAs a non-priority transmission storage meansAnd an L-direction non-priority transmission buffer 8d.
[0061]
In FIG. 2, the connections between the R-direction priority transmission buffer 5c, the R-direction non-priority transmission buffer 5d, the L-direction priority transmission buffer 8c, the L-direction non-priority transmission buffer 8d, and the transmission processing CPU 10 are respectively (1), Omitted in the drawings due to (2), (3), and (4). Thus, the transmission terminal device B2 has a simple transmission circuit configuration.
[0062]
Next, the operation of the second embodiment will be described. In the transmission terminal device B2, when an R direction relay information frame to be transmitted to the transmission terminal device C2 is transmitted from the transmission terminal device A2, the R direction reception logic circuit 4 transmits the R direction relay information frame. Is determined.
[0063]
  The R-direction relay information frame is prioritizedrelayinformationflameIn this case, it is stored in the R direction priority relay buffer 5a as an R direction priority relay information frame. Not preferredrelayinformationflameIn this case, it is stored in the R-direction non-priority relay buffer 5b as an R-direction non-priority relay information frame.
[0064]
Further, when output information of R direction transmission is output from the external information input / output device a2, the transmission processing CPU 10 determines the priority of transmission and transmits the output information to the transmission terminal device C2 for R direction priority transmission information. Frame or R direction non-priority transmission information frame.
[0065]
When the R direction transmission information frame is the R direction priority transmission information frame, it is stored in the R direction priority transmission buffer 5c. In the case of the R-direction non-priority transmission information frame, it is stored in the R-direction non-priority transmission buffer 5d.
[0066]
Here, the R-direction priority relay information frame, the R-direction non-priority relay information frame, the R-direction priority transmission information frame, and the R-direction non-priority transmission information frame are variable-length frames, and the R-direction priority relay buffer 5a , R-direction non-priority relay buffer 5b, R-direction priority transmission buffer 5c, R-direction non-priority transmission buffer 5d are respectively the R-direction priority relay information frame, the R-direction non-priority relay information frame, and the R-direction priority transmission information frame. , A buffer having a capacity larger than the maximum value of the size of each one of the R-direction non-priority transmission information frames. In addition, the priority is determined based on whether information frame information should be transmitted with priority.
[0067]
The R direction transmission logic circuit 6 sends the stored R direction priority relay information frame, R direction non-priority relay information frame, R direction priority transmission information frame or R direction non-priority transmission information frame to the transmission terminal device C2. Switched transmission. There is no need to synchronize the clock system, and random access transmission is performed.
[0068]
When a plurality of the stored R-direction priority relay information frame, the R-direction non-priority relay information frame, the R-direction priority transmission information frame, and the R-direction non-priority transmission information frame are stored simultaneously, the priority is high. Information frames are preferentially transmitted. Arranged in descending order of priority, the R direction priority relay information frame, the R direction priority transmission information frame, the R direction non-priority relay information frame, and the R direction non-priority transmission information frame are obtained.
[0069]
  Here, the R-direction non-priority relay buffer 5bIs stored in the R-direction non-priority relay buffer 5b.R direction non-priority relayinformationflameofR direction non-priority relay in accumulation stateinformationFrame accumulation numberR direction Non-priority relay information frame transmission direction (R direction) opposite direction (L direction)Notify the L-direction transmission logic circuit 9. The L-direction transmission logic circuit 9, The accumulated number of notified R direction non-priority relay information framesThe data is transmitted to the transmission terminal device A2. The R-direction transmission logic circuit (not shown) in the transmission terminal device A2 istransmissionBased on the stored number of R-direction non-priority relay information frames, the transmission of the R-direction non-priority information frame to the transmission terminal device B2 is stepwise suppressed.
[0070]
This is to prevent the R-direction non-priority relay information frame from being discarded in the R-direction non-priority relay frame 5b due to an increase in the number of R-direction non-priority relay information frames. For example, when the number of accumulated R-direction non-priority relay information frames exceeds a certain amount, the stepwise suppression stops transmission of the R-direction non-priority information frames.
[0071]
  In the R-direction transmission logic circuit (not shown) in the transmission terminal device A2.R direction non-priority information frameThe information on stepwise suppression is also sent to the transmission processing CPU 10 of the transmission terminal device B2.notificationIs done.The transmission processing CPU 10 to which the information on the stepwise suppression of the R direction non-priority information frame is notified,Before discarding the R-direction non-priority transmission information frame in the R-direction non-priority transmission buffer 5d,Based on information on suppression of transmitted R direction non-priority information frameSimilarly, stepwise suppression is performed on the output information from the external information input / output device a2. This is because the transmission priority of the R-direction non-priority relay information frame is higher than that of the R-direction non-priority transmission information frame. This is because accumulation of the R direction non-priority transmission information frame having a low value should also be suppressed.
[0072]
By the two-stage suppression, the R-direction priority relay information frame and the R-direction priority transmission information frame can secure a transmission capacity within a certain value depending on the transmission speed between the transmission terminal apparatuses. Therefore, transmission capacity can be secured for priority information randomly generated in a plurality of transmission terminal apparatuses, and transmission can be performed with priority.
[0073]
Up to this point, the transmission operation in the R direction has been described, but the same applies to the L direction. In the transmission terminal device B2, when the L direction relay information frame transmitted from the transmission terminal device C2 to the transmission terminal device A2 is transmitted, the L direction reception logic circuit 7 sets the transmission priority of the L direction relay information frame. The L direction priority relay information frame is stored in the L direction priority relay buffer 8a, and the L direction non-priority relay information frame is stored in the L direction non-priority relay buffer 8b.
[0074]
Also, when output information is output from the external information input / output device a2, the transmission processing CPU 10 determines the priority of transmission of the output information and transmits it to the transmission terminal device A2, an L-direction priority transmission information frame, an L-direction The frames are converted into non-priority transmission information frames and stored in the L-direction priority transmission buffer 8c and the L-direction non-priority transmission buffer 8d, respectively.
[0075]
The L-direction transmission logic circuit 9 sends the stored L-direction priority relay information frame, L-direction non-priority relay information frame, L-direction priority transmission information frame, or L-direction non-priority transmission information frame to the transmission terminal device A2. When a plurality of L-direction information frames are stored, they are transmitted in order based on the priority.
[0076]
  At the same time, from the L-direction non-priority relay buffer 8bStored in the L-direction non-priority information buffer 8bL direction non-priority relay information frameofNumber of L-direction non-priority relay information frames that are storedButTo the transmission terminal C2TransmittedTransmission of L direction non-priority information frame from transmission terminal apparatus C2ButPhased deterrenceIsAnd the relevant deterrence informationIsIn transmission processing CPU10Also notifiedNon-priority information from external information input / output device a2ButPhased deterrenceBe done.
[0077]
The same contents of the priority transmission information frame and the non-priority transmission information frame from the output information from the external information input / output device a2 may be transmitted simultaneously in the R direction and the L direction.
[0078]
Of course, the R direction priority relay information frame from the transmission terminal device A2, the R direction non-priority relay information frame, the L direction priority relay information frame from the transmission terminal device C2, the L direction non-priority relay information frame, Is sent to the external information input / output device a2.
[0079]
As described above, according to this apparatus example, a transmission capacity of a certain amount or less is secured for priority information frames, and non-priority information frames are not discarded due to accumulation, avoiding collision between information frames, and having a variable length. Information frames can be transmitted asynchronously and continuously.
[0080]
【Example】
Hereinafter, Embodiment 1 and Embodiment 2 of the present invention will be described in order with reference to the accompanying drawings.
[0081]
  Example 1
  An example of this apparatus will be described with reference to FIG. FIG. 3 shows the present embodiment.1It is a block block diagram of the transmission terminal device system which is. Example1IsIn network systems in the railway field,The transmission terminal device B2 of the second embodiment described above is connected to a ring network and applied to the CTC system.
[0082]
The transmission terminal apparatus system β1 of the present embodiment includes transmission terminal apparatuses A3, B3, C3, D3, E3, F3, G3, and H3, which are transmission apparatuses connected in a ring shape so as to be able to transmit and receive each other, and the transmission terminal apparatus C3 and information. Operation management system 11 connected so as to be able to send and receive data, centralized monitoring system 12 connected so as to be able to send and receive information to transmission terminal device D3, and interlocking connected to transmission terminal devices E3, F3, G3 and H3 so as to be able to send and receive information. Devices 13, 14, 15, 16; a rain anemometer 17 connected so as to be able to send information to the transmission terminal device E3; a centralized monitoring terminal 18 connected so as to be able to send information to the transmission terminal device G3; and a transmission terminal device G3. And a TID terminal 20 connected so as to be able to receive information from the transmission terminal device H3.
[0083]
In the CTC system, transmission terminal apparatuses A3, B3, C3, D3, E3, F3, G3, and H3 are installed at stations on different routes. In addition, the operation management system 11, the centralized monitoring system 12, the interlocking devices 13, 14, 15, 16, the rain anemometer 17, the centralized monitoring terminal 18, the passenger guidance device 19, and the TID terminal 20 are the second embodiment described above. Corresponds to the external information input / output device a2.
[0084]
The operation management system 11 transmits operation control information control information to the transmission terminal C3 and receives display information. The centralized monitoring system 12 is a central control station in the CTC system, and transmits control information of CTC information to the transmission terminal device D3 and receives display information of CTC information. The interlocking devices 13, 14, 15, 16 receive the operation management information and the control information of the CTC information from the transmission terminal devices E3, F3, G3, and H3, respectively, and operate in conjunction with the control information. The operation information is transmitted as display information. For example, a relay interlocking device, an electronic interlocking device, or the like.
[0085]
The rainfall anemometer 17 transmits the rainfall anemometer information along the line as information along the line to the transmission terminal device E3. Not only the rainfall and wind speed information but also earthquakes and rockfall information along the line may be transmitted. The centralized monitoring terminal 18 transmits centralized monitoring information such as various signal device failure information to the transmission terminal device G3. The passenger guide device 19 receives passenger guide information from the transmission terminal device G3. The TID terminal 20 transmits TID (train operation information display device) information to the transmission terminal device H3. The route information, the centralized monitoring information, the passenger guidance information, and the TID information are included in the operation management information as content classifications.
[0086]
The transmission terminal devices A3, B3, C3, D3, E3, F3, G3, and H3 adopt standards such as RS-232C and Ethernet (registered trademark) as the external interface, the operation management system 11, and the centralized monitoring system. 12, interlocking devices 13, 14, 15, 16, rain anemometer 17, centralized monitoring terminal 18, passenger guidance device 19 and TID terminal 20.
[0087]
Since the transmission terminal apparatuses A3, B3, C3, D3, E3, F3, G3 and H3 are connected in a ring shape in this order, an R direction line and an L direction line are formed as a loop. Transmission information frames in each of the transmission terminal devices A3, B3, C3, D3, E3, F3, G3, and H3 are simultaneously transmitted from the transmission terminal device of the transmission source to the lines in the R direction and the L direction. Each transmission terminal apparatus is connected to another transmission terminal apparatus by connecting, for example, a modem or the like in the R direction and the L direction. For example, the metallic 4W standard is adopted as a connection line between the transmission terminal apparatuses, and a PCM (Pulse Code Modulation) line is adopted as necessary. However, the connection line is not limited to these, for example, TA, A digital line transmission line using a router or the like, a wireless transmission line, an optical transmission line, or the like may be employed.
[0088]
  The transmission terminal device at the transmission destination receives both the R direction information frame and the L direction information frame of the same content and the same transmission source. However, the transmission terminal device reaches the destination and adopts the content check OK, and discards the other. Performs first-priority reception processing. Therefore, no line switching time is required even when one line is abnormal, and transmission efficiency and error countermeasures are taken.Can improve the fail-safety.
[0089]
The transmission terminal apparatus system β1 converts the above-mentioned various information as a variable-length frame by determining the priority so that it can be randomly accessed, and secures transmission capacity and transmits the priority information frame preferentially. The priority information frame is transmitted without being discarded. As the priority information, the CTC information having a quick arrival request in a small amount is adopted, and the operation management information is adopted as the priority information.
[0090]
Since the priority information is not stored and transmitted, even if the tandem loop connection is used as in the present embodiment, the end / end transmission delay is extremely short.
[0091]
Therefore, in this embodiment, N-to-N communication is possible even when compared with a conventional polling CTC apparatus, and the transmission efficiency is remarkably improved. Compared to the conventional token passing system, there is no worry of losing the token, and even if the line is disconnected at one place, there is no need to make a return connection of the line, and the procedure is simplified.
[0092]
Further, since the transmission efficiency is significantly better than the conventional CTC device and the transmission capacity is increased, it is possible to transmit the non-prioritized passenger information, not limited to this, image information, station service, etc. Related information and the like can also be transmitted.
[0093]
(Example 2)
This embodiment will be described with reference to FIG. FIG. 4 is a block diagram of the transmission terminal apparatus system according to the present embodiment. In this example, the transmission terminal apparatus B2 of the second embodiment is connected to a network in a ring shape and applied to fail-safe control.
[0094]
The transmission terminal device system β2 of the present embodiment transmits and receives information to and from the transmission terminal devices A4, B4, C4, D4, E4, and F4, and the transmission terminal devices A4 and D4, which are transmission devices connected in a ring shape so as to be able to transmit and receive each other. Fail-safe terminals 21 and 22 that can be connected to each other, and general-purpose input / output devices 23, 24, 25, and 26 that are connected to transmission terminal apparatuses B4, C4, E4, and F4 so as to be able to transmit and receive information.
[0095]
The fail-safe terminals 21 and 22 and the general-purpose input / output devices 23, 24, 25, and 26 correspond to the external information input / output device a2 in the second embodiment described above. Transmission terminal apparatuses A4, B4, C4, D4, E4, and F4 are connected in a ring shape in this order to form an R-direction line and an L-direction line.
[0096]
The transmission terminal device system β2 converts the above-described various information as variable-length frames by determining the priority, and makes random access possible. For the priority information frames, a transmission capacity is secured and transmitted preferentially. The priority information frame is transmitted without being discarded. As the priority information, fail-safe information transmitted / received by the fail-safe terminals 21 and 22 that are urgent information at the time of failure is adopted, and as the non-priority information, non-fail-safe information that is information other than the fail-safe information. Is adopted.
[0097]
Conventionally, the fail-safe information and the non-fail-safe information are transmitted separately from each other. In this embodiment, the fail-safe information and the non-fail-safe information are transmitted on the same track. Therefore, the transmission apparatus system can be greatly simplified and downsized.
[0098]
Since the priority information secures a transmission capacity equal to or less than a certain value, the transmission terminal apparatus system β2 is designed so that the fail-safe information does not exceed the certain value, and the fail-safe information is always given priority. Is transmitted. Therefore, it is possible to transmit / receive the fail-safe information at a fixed cycle between the fail-safe terminals 21 and 22, which makes it very easy to ensure the fail-safe property.
[0099]
In addition, since the increase / decrease in the non-failsafe information that is non-priority information does not affect the failsafe information, the increase / decrease in the nonfailure safe information can be easily performed without restriction.
[0100]
Further, by making the information of the CTC system fail-safe, it becomes possible to use CTC information such as train presence lines, traffic lights, and driving directions for notification of approaching trains to maintenance workers, crossing control of railroad crossings, and the like.
[0101]
Although the embodiments and examples of the present invention have been described above, the present invention is not necessarily limited only to the above-described means and methods, and the object of the present invention is achieved and the effects of the present invention are achieved. Modifications can be made as appropriate within the scope of the change.
[0102]
【The invention's effect】
  As described above in detail, according to the transmission apparatus of the first aspect of the present invention, the relay information frame is non-stored and transmitted for the variable length information frame of asynchronous random access without causing information collision and discarding. Transmission efficiency can be improved, and tandem connection and system equalization are also performed. Further, by transmitting the transmission information frame in both the left and right directions, it is possible to take measures against errors without switching the transmission even if a failure occurs in one of the transmission paths. In addition, information frames that depend on the priority of transmission are mixedly transmitted on the same traffic in the order of priority, thereby improving the transmission efficiency due to the priority transmission of information on priority demand, and the transmission path for each priority information. Since the cost can be reduced without performing the construction, the fail-safe property can be secured very easily. In addition, based on the non-priority relay information frame accumulation state, non-priority in the adjacent transmission device in the reverse directionrelayExcessive non-priority by suppressing information frame transmissionrelaySuppresses collisions between data due to the transmission of information frames before discarding the data.relayIt is possible to prevent collision and discard of information frame data.
[0106]
  further,Information that suppresses transmission of non-priority information frames is transmitted to the transmission processing means of the transmission equipment adjacent in the transmission direction, and is transmitted.relayBased on information that suppresses transmission of information framesOutput informationBy suppressing the conversion of data, collision of data due to conversion of extra non-priority transmission information frames is suppressed before discarding it, and further non-prioritySendIt is possible to prevent collision and discard of information frame data.
[0107]
  Claim2According to the transmission device of the invention described in (1), the transmission efficiency is improved by improving the transmission speed by processing the first-priority reception at the transmission device of the transmission destination by the same content transmission in both the left and right directions from the transmission device of the transmission source. And take countermeasures against errors.
[Brief description of the drawings]
FIG. 1 is a block configuration diagram of a system including a first transmission terminal apparatus according to an embodiment of the present invention.
FIG. 2 is a block configuration diagram of a system including a second transmission terminal apparatus according to an embodiment of the present invention.
FIG. 3 is a block configuration diagram of a transmission terminal apparatus system in which the second transmission terminal apparatus system in FIG. 2 is applied to a CTC system.
4 is a block configuration diagram of a transmission terminal apparatus system in which the second transmission terminal apparatus system in FIG. 2 is applied to fail-safe control. FIG.
[Explanation of symbols]
α1, α2, β1, β2 ... Transmission terminal device system
A1, B1, C1, A2, B2, C2, A3, B3, C3, D3, E3, F3, G3, H3, A4, B4, C4, D4, E4, F4.
a1, a2 ... external information input / output device
1 ... Buffer
1a: Relay buffer
1b: Transmission buffer
2. Changeover switch
3, 10 ... Transmission processing CPU
4 ... R direction reception logic circuit
5 ... R direction buffer
5a: R direction priority relay buffer
5b: R direction non-priority relay buffer
5c: R direction priority transmission buffer
5d: R direction non-priority transmission buffer
6 ... R direction transmission logic circuit
7 ... L direction reception logic circuit
8 ... L direction buffer
8a ... L direction priority relay buffer
8b ... L direction non-priority relay buffer
8c ... L direction priority transmission buffer
8d ... L direction non-priority transmission buffer
9 ... L direction transmission logic circuit
11 ... Operation management system
12 ... Centralized monitoring system
13, 14, 15, 16 ... interlocking device
17 ... Rain anemometer
18 ... Centralized monitoring terminal
19. Passenger guidance device
20 ... TID terminal
21, 22 ... Fail-safe terminal
23, 24, 25, 26 ... General purpose input / output devices

Claims (2)

A transmission device connected to the left and right transmission devices to form a ring-shaped network, randomly accessing and transmitting information to each other, and connected to an external information input / output device,
Receiving logic means for determining whether the variable-length relay information frame transmitted from the left and right transmission apparatuses is a priority priority relay information frame or a non-priority non-priority relay information frame ;
Priority relay storage means for storing at least one priority relay information frame determined by the reception logic means ; and non-priority relay storage means for storing at least one non-priority relay information frame determined by the reception logic means. Having relay storage means;
The output information from the external information input / output device is converted into a variable-length transmission information frame so as to be suppressed, and the converted transmission information frame is a priority priority transmission information frame or a non-priority non-priority transmission information frame. Transmission processing means having a function of determining whether or not
Priority transmission storage means for storing at least one priority transmission information frame converted and determined by the transmission processing means, and non-priority transmission for storing at least one non-priority transmission information frame converted and determined by the transmission processing means Transmission storage means having storage means;
The order of priority, the priority relay information frame, the priority transmission information frame, the non-priority relay information frame, as the order of the non-priority transmission information frame, therefore in this order of priority, the priority relaying storage unit, the priority transmission storage Switching means having a function of switching and transmitting frames stored in each of the non-priority relay storage means and the non-priority transmission storage means ,
The reception logic means, the relay storage means, the transmission storage means and the switching means are provided for right direction transmission and left direction transmission, respectively.
The non-priority relay storage means includes
A function of notifying the storage means of the non-priority relay information frame stored in the non-priority relay storage means to the switching means in the direction opposite to the transmission direction of the non-priority relay information frame;
The switching means is
A function of transmitting the storage state of the notified non-priority relay information frame to the switching means in the same direction as the notified non-priority relay information frame in the adjacently connected transmission device ;
When the storage state of the non-priority relay information frame transmitted from the switching means of the adjacently connected transmission device is a state in which a predetermined amount or more of non-priority relay information frames are accumulated, the non-priority relay information frame is transmitted. A function to suppress ,
Have a,
The transmission processing means includes
The conversion of the output information is suppressed when the accumulation state of the non-priority relay information frames transmitted from the switching means of the adjacently connected transmission devices is a state in which a predetermined amount or more of non-priority relay information frames are accumulated. It has a function,
Transmission in which non-priority transmission information frames are inhibited from being stored in the non-priority transmission storage means and transmission of non-priority transmission information frames is inhibited by inhibiting the conversion of the output information by the transmission processing means. apparatus. The transmission apparatus according to claim 1 ,
The transmission processing means includes
Having a function of transmitting the transmission information frame of the same content in both the left and right directions;
A transmission device characterized by the above.

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