JPS59204338A - Channel assigning method of loop transmission system - Google Patents

Abstract

PURPOSE:To prevent a packet from being written in a time slot during circuit switching by informing a remote station of areas of a circuit switching channel and a packet switching channel every time a circuit connection is performed. CONSTITUTION:A center station CS1 and remote stations RS2-RS6 are connected mutually in a loop by a circuit 7, and synchronous terminals 8-11 and asynchronous terminals 12-14 are connected to the respective RSs. The CS1 allots a time slot TS for the circuit switching channel CH and a TR for the packet switching CH in a data frame which circulates in the loop variably at a request for circuit switching from a synchronous terminal. The data frame is divided into N units of group slots GS consisting of specific TSs, and a flag for indicating whether the circuit switching CHs in the N units of GSs are used or not is provided in a GS state field. When the CS1 assigns TSs for the circuit switching CH, the GS state field is updated to allow all the RSs to know areas of the circuit switching CH and packet switching CHs in the current frame.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a channel allocation method for a loop transmission system that is used for local communication and allocates packet-switched channels and circuit-switched channels within a data frame.

The configuration of the conventional example and its problems The first example of the conventional loop transmission system to which the present invention is applied is as follows.
As shown in the figure. This transmission system consists of a center station (O8) 1 and a remote station (R) for transmitting and receiving data.
8) 2, 3, 4.5 and 6 are connected in a loop by line 7, and synchronous terminals 8, 9, 1 are connected via each R52 to 6.
0.11 and asynchronous terminals 12, 13.14 are connected, and in the data frame circulating on this loop transmission path, time slots for circuit switching channels and time slots for packet switching channels coexist, and many types of transmission are possible. For synchronous terminals with different speeds, C8 is a loop transmission system that controls the allocation of time slots for circuit switching channels according to the speed and performs data transmission.

FIG. 2 shows a conventional example of a frame structure when circuit switching and packet switching are performed on one transmission path. In the figure, 0X-i is a time slot for a circuit switching channel, PX is a time slot for a packet switching channel,
FS is a frame synchronization signal, and C is a control field used for communications such as requests for allocation/release of time slots for circuit switching channels between R8 and O8. Conventionally, the allocation of circuit-switched channels and packet-switched channels was fixed, making it impossible to use bandwidth effectively. Therefore, it is necessary to vary the allocation of circuit switching channels and packet switching channels for each circuit switching request.

In this case, every R3 needs to know the circuit switching channel and the packet switching channel area in the frame each time a circuit switching request is made. occurs.

OBJECTS OF THE INVENTION The present invention solves the problems mentioned above. Each time a line is connected, the area of the circuit switching channel and the packet switching channel is notified to all R8s, thereby preventing packets from being written in the time slot during circuit switching. It is an object of the present invention to provide a channel allocation method for a loop transmission system that does not cause interference.

Structure of the Invention The present invention divides a certain number of time slots in a data frame into group slots (G slots), divides the frame into group slot units, and divides all group slots in the frame into circuit switched channels. By setting a flag in the frame to indicate whether the channel is in use or not, and updating this area (G slot status field) when O5 allocates a time slot for the circuit switching channel in response to a circuit switching request from R8. , which allows all R8s to know the circuit-switched channel in the current frame and the area division of the network switch channel.

Description of examples Embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 3 is an example of a frame structure according to the present invention, and the first
In the system configuration example shown in the figure, e
4KbPs, 1゜6seMbPs (24×64K
bPS) coexist. The frame structure in Fig. 3 consists of H G slots each consisting of a group time slot (G slot), which is a collection of 24 consecutive evening time slots (64 Kl in one time slot) in which PS lines can be exchanged.
A data area consisting of slots and a frame synchronization signal ('
FS), a frame consisting of a G slot status field consisting of bits corresponding to N G slots, and error detection bits therefor, and a knob (FH) section.

Connection sterilization commands can be sent and received between C8 and R8 using circuit switching, such as by providing a command area in the frame header, but in this example, packet switching is performed in a packet switching channel.

For line switching, if the line managed by aS and requested by calling R3 is 64KbPS, one time slot is allocated from the part of one G slot close to FH, and the next time slot is similarly allocated for overflowing calls. The G slots are allocated sequentially starting from the part closest to FH.

If the requested line is 1.636 Mb PS, one free G slot close to FH within the frame is allocated within the frame. C8 informs the calling 9 and the terminating R8 of the assigned time slot address, and completes the line setting.

In this way, if the packet-switched channel power changes every time the circuit-switched traffic (number of requests) power changes, all R8s need to know the position within the frame of the packet-switched channel at each circuit connection. Therefore, if one or more of the 24 time slots in the G slot is used for circuit switching, the bit corresponding to the corresponding 0 slot in the G slot status field is set to +11.
1 K, and if there are no circuit-switched channels in all 6 timeslots in the G slot, set the corresponding bit to “
0'''. This allows all R8s to know the packet switched channel in that frame by looking at the "o" bit position of the G slot status field in the FH.

In FIG. 3, the shaded area is the circuit switching channel, and the 64KbPS line is the dry time slot in the 1st and 2nd G slots, and the 1st time slot in the 3rd G slot. Assume that a 536 MbP8 line is using the light time slot of the fourth G slot. In this case, in the G slot status field, only the bits corresponding to the 1st to 4th G slots are °11''.In addition, in this figure, the error detection bit is at the rear of the G slot status field for convenience of explanation. All R8s decode the '0'' bit position of the G slot status field, and the 6th to Nth G slots are
Know that it is a packet switched channel.

In addition, R8 decodes the error protection bit and detects a bit error in the G slot status field, and uses the slot currently used for circuit switching as is for circuit switching, and packet switching uses the normal G slot status field. Until we get , access is prohibited and we just repeat the data from the loop. This process protects slot allocation from being corrupted such that packet-switched data is written on the circuit-switched circuit.

Next, configuration examples of R8 and C8 for carrying out the present invention are shown in FIG. 4 and FIG. 6, respectively. In Figure 4, transmission line a
The input signal from is decoded by the decoder 15 and inputted into R8 from the add/drop circuit 16. Input data is passed through the RX bus, FS is detected by a frame synchronization signal (FS) detector 17, and the frame synchronization protection circuit 18 is activated.The input data is then input to a time slot allocation decoder 19, and the frame synchronization signal (FS) is detected by the frame synchronization signal (FS) detector 17. In the header (DG S.

The value of the set state field is decoded, and a signal indicating the position of the packet switching channel within the frame is output to the packet switching charge C section 21 via the controller 2o. It is assumed that the packet switching control unit 21 operates only during a certain period of the instruction signal. When the time slot allocation decoder 19 detects that an error has occurred in the G slot status field in the frame, the controller 20 blocks the packet switching channel position instruction signal and prevents the packet switching control unit 21 from accessing the data frame. prohibited. The packet exchange procedure of the embodiment is performed by a token passing procedure, and when there is data to be sent from an asynchronous terminal, a data packet is assembled using the packet exchange fee portion 21 and sent to the add/drop circuit 16.
The signal is encoded by the encoder 22 and output to the transmission path C. In the case of line switching, a call request is input from a synchronous terminal to the line switching control unit 23. The connection request including the line speed from the circuit switching control section 23 is packetized by the packet switching control section 21 and sent to C8 using the packet switching channel in the frame. A time slot address instruction signal is sent to the packet switching fee H section 21. This address signal is sent to the controller 20YC, counts from the frame synchronization signal position to the time slot address -, and a used time slot instruction signal P is input to the line switching charge section 23. The line switching charge C unit 23 inputs the signal of the time slot designated by the signal P from the input data frame via the TIX bus, outputs it to the terminal, and also outputs the signal from the terminal to the designated time slot of the RX bus. insert.

FIG. 6 shows an example of the configuration of O8, and in the figure, circuits with the same numbers as in FIG. 4 have the same structure as R8. In the figure, 24 is a frame synchronization pattern (ys) generator, and 25 is a line side that inputs line control commands from R3 via the packet switching control unit 21, decodes the commands, and manages time slots. It is a diagonal controller. 26 is a G slot status field sending register which is set depending on the usage status of the circuit switching channel slot.

Effects of the Invention According to the present invention, by providing a group slot usage state table in a part of the frame header, all stations can allocate circuit switching channels and packet switching channels that change successively in response to calls at the same time. Since the notification can be made, each remote station can perform optimal circuit switching and packet switching according to the amount of calls, and the inconvenience of packets being written in time slots during circuit switching is eliminated.

[Brief explanation of drawings]

FIG. 1 is a block diagram of a loop transmission system to which the present invention is applied, and FIG. 2 is a configuration diagram of a transmission frame according to a conventional example.
FIG. 3 is a block diagram showing an embodiment of a transmission frame according to the present invention, FIG. 4 is a block diagram showing an embodiment of a remote station run implementing the present invention, and FIG. 6 is a block diagram showing an embodiment of a remote station run implementing the present invention. FIG. 1 is a block diagram illustrating one embodiment of a stacylan. 1...Center station, 2-6...
...Remote station, 8-11.Old...Synchronous terminal, 12-14...Asynchronous terminal, 16...
・Decoder, 16...Branch/insertion unit, 17...
... Frame synchronization signal detection circuit, 18 ... Frame synchronization protection circuit, 19 ... Time slot allocation decoder, 2o ... Controller, 21.
... Packet exchange antibacterial road, 22 ... Encoder, 23 ... Line control section, 24 ...
Frame synchronization pattern generator, 25...Line side secondary control, roller, 26...G slot usage status field sending register. Name of agent: Patent attorney Toshio Nakao and 1 other person No. 1
figure

Claims (2)

[Claims] (1) Multiple remote stations that perform data transmission by connecting synchronous and asynchronous terminals to a common transmission path configured in a loop, and a circuit-switched channel of time slots in data frames circulating on the loop. and a center station that variably allocates time slots for packet switching channels and time slots for packet switching channels in accordance with circuit switching requests of synchronous terminals, and each of the remote stations is controlled by the center station,
A loop transmission system that performs data transmission using the circuit-switched channel time slot or the packet-switched channel time slot in the data frame, the loop transmission system comprising a group scootlllc division in which a plurality of time slots in the data frame are grouped together. For each group slot, whether it is being used as a time slot for the circuit-switched channel in the data frame;
A channel allocation method for a loop transmission system, characterized in that a field indicating whether a time slot is being used as a time slot for the packet switching channel is provided in the data frame. (2) An error detection code is provided in the data frame for the field indicating the usage status of the group slot,
Channel allocation in a loop transmission system according to claim 1, wherein a remote station that detects an error using the error detection code continues to perform line switching and is prohibited from accessing packet switching. The method.