DE2736858A1 - PACKAGE CONTROL CENTER - Google Patents

Description

"Parcel control center"

The invention relates to a packet switching center.

In telegraph and telephone traffic it was common to have one line or to allocate a channel to each connection between a transmitter and a receiver. With the need for leads high quality to transmit digital information at an extremely high digital rate, e.g. for communication between Computers or between a computer and a computer terminal, the costs for such a connection are very high compared to the density of traffic that line occupies. It will be understood that such high speed digital transmission usually takes place in the form of pulse groups with very large distances between them, so that the Line or channel is idle for a large portion of the time. To overcome this difficulty, one has the concept The packet circuit is designed to be a line or a channel to enable it to be better exploited by a number of senders and receivers as required, instead of easy to multiplex rigidly. The basic component of a packet switching system is a data packet, which consists of a block of digitally coded information, which is preceded by a head group or a preamble, which serves to identify both the original

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or starting station, as well as the destination or arrival station of the information block. Data packets from a number of originating stations sequentially arrive and open over the same line or channel the individual slots are distributed or routed through high-speed switchgear assemblies in parcel switching centers, from where they get to the respective destination. Because the line or the channel is available to be used by any number of originating stations, the capacity can with Better efficiency can be used than if the line only allows communication between a single transmitter and would be assigned to a single recipient.

Because of the complexity of a packet switching center this has so far been built using non-specialized, but very fast-working computers, but only are poorly adapted to the particular nature of the task at hand and, moreover, such computers are expensive and defective the risk of total failure if only certain parts of the computer fail.

The object of the present invention is to create an improved packet switching center in which the above disadvantages are at least partially avoided.

The solution to this problem provided according to the invention results from claim 1, the term "line" also includes, for example, individual channels of a time division multiplex system.

The control center may have an additional packet processing unit and circuitry for entrusting this additional unit with some or all of the functions of one or more of the other packet processing units in the event of a partial or total failure of this or that unit. Accordingly, this additional unit can serve as a reserve for all other packet processing units in order to keep the control center in a constant _{operational state f} as far as the data packets are concerned.

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Each packet processing unit may include buffer memory circuitry for storing data packets while they are For example, wait for the switch arrangement to set up a route for the data packets, as indicated by the relevant headers is specified.

The control center can also have a maintenance unit and an accounting unit include. The maintenance unit can be designed to carry out inspections or tests on other units the control center always executes when an error is suspected and for the storage of information, with it other units will be able to be put back into service after at least certain species errors such as deletion of the software as a result of noise have occurred when it is necessary to remove all registers to delete a processing unit and reassign it start. The accounting unit can provide details of data packets that are processed by the control center so that the sum to be debited to the subscriber is calculated can. The maintenance unit and the accounting unit can can be used together to start up the additional packet processing unit for all or part of the Control the functions of another unit. The maintenance unit and the processing unit can also be designed in this way be that they can take over the basic tasks of the other unit in the event of failure of the same, so that the two units are mutually available as a reserve.

With the provision of a reserve packet processing unit and the measure that the maintenance and accounting units can represent each other in their Orundfunktion, you only need to provide enough redundancy within the center so that it can be kept in operation after an error has occurred Duplication of the switch arrangement and its control unit as well as a multi-channel communication link which connects the main processors with one another. 809808/0869

In the embodiment of the subject invention described below, the packet processing units comprise one packet processor, one or more byte processors each and such line units as they are required to be as To be able to serve intermediate stations between the signals that are used in the control center (which can be equipped with TTL circuits, for example) and the signals on the External lines occur (e.g. V24). in which to be described Example, a byte consists of 8 bits that are transmitted within the units and processed in parallel, However, it is transmitted in serial form between the units.

Within each unit or sub-unit, depending on the case, the information can be processed by a microprocessor which can be one of type INTEL 8080, for example.

With reference to the accompanying drawings, exemplary embodiments of the subject matter of the invention are explained in more detail below.

Fig. 1 is a block diagram of a data packet

Transmission system that can be used as a packet switching center according to the invention and

Figure 2 is a diagram of an example of a packet switching center according to the invention.

The system shown in Fig. 1 comprises three packet switching centers 1, 2 and 3, which through central connection channels 4, 5 and 6 are connected to each other. The center 1 has connections to the character terminals 7A and 9A via corresponding ones Pairs of modems 7B and 7C or 9B and <JC. One or more the connections to the modems can be made through the public telephone network, provided that the data rate from the control center to the modems is low enough to allow exchange via normal telephone cables. One Parcel terminal 8 is directly connected to the center 1. the

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Center 2 is connected to a character terminal 10A via Modems HB and HC and with a computer center 12 directly. The data rates for the packet end point HA and the computer center 12 are probably too high to broadcast over the enable public telephone network. The control center 3 is connected to a terminal I] JA via modems 13B and lj3C, as well as with a computer center 14A via modems 14B and 14c in Tandem.

The character terminals 7A, 9A, IQA and I3A can each have the form of a simple keypad with printer and the information would be transmitted character by character using, for example, a 10 or 11 element character structure at speeds of 10 or 30 characters per second. This means that the data rates from the character to the terminals would be HO or 300 bps. The packet terminals 8 and HA are special units which are designed so that they can send and receive data packets, but they can otherwise be similar to the shape of a keypad / printer. The data rate _/ at which the packet terminal HA can operate is at least 2400 bps, which rate is the same as that of the computer center 12. The computer center 14A is able to transmit and receive data up to 48,000 bps, which is the usual rate is used to exchange data between control panels 1, 2 and 3 , although higher rates are possible. The packet end point HA and the computer centers 12 and 14A must be connected to the control center with direct connections because of the high data rates present here.

A brief examination of the elementary system of Figure 1 clarifies the requirements for a packet switching center which receives data packets from a number of sources and transmits them to various destinations either directly or via other centers. The changes in the data rates make buffers for the data packets an important part, so that they can be nested in one another on the connection lines of the control center or on the

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direct lines to destinations at higher speeds.

Having laid out the requirements for a parcel control center have now been an explanation that goes into detail, the structure of a control center according to an embodiment of the invention. Such a center is shown in block form in Figure 2 of the drawing and comprises sixteen packet processing units 21 to 36. The packet processing unit 36 is arranged so that it is available as a reserve for the other fifteen units, each connected to one or more lines are connected. The center comprises a switch 37 for switching through between the packet processing units according to FIG the target specification of the data packets. The switch 37 is controlled by a processor 38. Although not shown here, the Switch 37 and the processor 38 in the control center are duplicated and the switching is controlled by the processors so that in the event of a failure the faulty switch is out of order can be taken and the operational replacement switch is put into operation. The center also includes a maintenance processor 39 and an accounting processor 40. The processors 39 and 40 are associated with tape stores 41 on which the accounting information for the various data packets sent by the various participants as well as software for diagnostic and start-up routines for the processors contained in the other units.

Each of the fifteen packet processing units 21 to 35 includes the same components and those of the unit 21 will be explained below. Unit 21 contains a packet conversion unit 42, a byte processing unit 43, a switching unit 44 and Line units 45. The packet translation unit 42 includes a packet processor 46, a buffer memory 47 and a buffer access unit 48. The packet processors, the switch control processors, and the maintenance and accounting accessors become one another connected by a multiple message channel 49. The byte processing unit includes one or more byte processors of up to three different types. The three types of byte professors are nominally identical in structure, but correspondingly

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programmed to meet the different requirements of the three types of conduit to be matched. The two types of lines that come into question here are subscriber lines low speed with a processing rate of up to 96OO Bps high-speed subscriber lines with data processing rates above 9600 bps and connecting channels between the central units. The byte processing units for the various Packet processing units are arranged according to the particular combination of lines connected to the packet processing unit are connected. Each of the three processors is assigned only one type of line, which is the programming requirements simplified for the processors. Since the amount of work that can be handled by a packet processing unit, is limited by the capabilities of the packet processors, it follows that that the processing unit is lower on more subscriber lines Speed connected as connection channels between the central units can be. A packet processing unit can connect to nine to thirty-six low speed subscriber lines be connected, depending on the data rates on the lines, to two high-speed subscriber lines at 48,000 bps or to at least one connection channel between the headquarters. This means that the entire control center with I5 Processing units is capable of about 300 to 500 lines to use.

The changeover switch 44 is provided so that the line units 45, if necessary, can be connected to the reserve unit 36 can be connected in the event of a failure in the processing unit 21. The line units 45 are provided for the simple function of converting the voltage level required for the V 24 signal system that is connected to the Lines outside the control center are used in the voltages required for the TTL logic components that are inside the Find central use.

To facilitate understanding of FIG. 2, the information guides are Lines marked with single arrows and lines carrying control signals with double arrows.

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The mode of operation of the control center according to FIG. 2 is explained below. The normal idle state of the line is a continuous exchange of idle bits, i.e. groups of 8 digits which do not transmit any data, but are used to indicate that there is no signal on the relevant line in the Moment arrives. This state is also established when either the control center or the line is in operation for the first time is taken, for example after an interruption or when switching on. Each byte processor serves several lines and reports every received byte, and if only one is an idle signal, another idle signal is simply sent back at the appropriate time, whichever Signal may be the same or different from the received idle signal.

If an operating signal byte that is not idle is received, the corresponding byte processor marks the status the line over which the signal was received in its records relating to the line and transmits a signal to the packet processor 46 to indicate that the signal has been received had been. The byte processor also sends a corresponding return signal to indicate that the operating signal has been received where necessary.

A "call begins with a" call origination packet "included in its Start-up group contains among other information the identity of the destination of the call, the identity of the calling station and the type of packet it follows. ASe packets including the call origin packet begin with a "packet start" byte to which the byte processor responds to indicate that that a data packet is received. The processor detects the "packet start" byte and causes it to be placed in the buffer memory

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47 is fed into an empty buffer location by means of a small group of empty buffers stored in the Byte processor and advanced by advancing from processor 46. The byte processor then transmits an indication to the packet processor 46, the line in question, for example X over which the packet was received, ate the Buffer, for example a, into which the data was entered. The buffer table would then be advanced and subsequent bytes received from the line would be put into the buffer memory by the byte proceseor being used of the empty buffer spaces.

At this point the packet processor 46 examines the first byte and determines that this call is a new call. He checks that the line over which the byte was received is authorized to make the call, if for example some Lines are only authorized to receive calls; the apparent call can be due to interfering signals that got into the line. When the packet processor is satisfied that the byte is based on an authorized call, he assigns a call recording and a packet recording, which he interconnects and assigns a terminal record. If enough of the bytes that make up the header of the Form packet, have been received, a packet processor checks the correctness of the determination of the packet and determines the total number of bytes contained in the packet, which information is also contained in the header. if If all these tests are satisfactory, the packet processor transmits or sends this fact to the byte processor alternatively, a signal to it if for any reason the packet is incorrect.

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Now that the total length of the packet is known, the packet processor 46 allocates sufficient space in the buffer memory to hold the packet and the bytes received are transferred to the assigned addresses in the buffer memory by the byte processor. If the package is more than 64 Bytes long, the packet processor generates an address every 64 bytes into which the next received byte is written, and this is recorded in the address in the buffer memory. If the error check at the end of the packet matches the check information generated in the control center results, a confirmation is sent to the starting station, to indicate that the entire packet has been received; otherwise a negative confirmation is sent. That After the data, the packet can contain check bytes and the packet processor can perform the appropriate check on the data to ensure that it has been received correctly and an indication of whether the packet was received correctly or incorrectly is sent to the output station is.

While the bytes making up the packet are recorded in buffer memory 47 under the control of the byte processor, the packet processor 46 takes on the task of transmitting the packet from the control center to the line's buffer memory, which leads to the destination. Data that are stored in the buffer of the shift control processor 38, allow the Determination of the outgoing line or route of the busy lines that are inaccessible to the packet and which packet processor has to process the outgoing packet. details the route selected by the processor 38 and an alternative route are transmitted to the processor 46. Of the Processor 38 also transmits an advance warning to the destination packet processor, requesting buffer space for the packet, specifying its length and route

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which the packet has to transmit. The receive packet processor should respond with an acknowledgment that the Space is available and reserved for the package. If there is a negative confirmation, the maintenance processor 39 is informed and a second inquiry is made through processor 38 to the destination packet processor.

When the entire packet has been received by the buffer memory 47 and after checking that it is correct, will transmit the packet via switch 37 in the buffer of the destination packet processor. The switch control processor 38 also examines the parcel as it is heading towards its destination runs through and informs the maintenance processor 39 in the event of an error. The packet is sent out over the other switch if the test performed by the switch control processor fails and the maintenance processor fails has been reported.

When the destination packet processor's buffer has received the packet, it modifies the packet's header if necessary and informs the outbound byte processor of the line over which a packet is to be transmitted of the storage location in the buffer memory of the packet.

The outbound byte processor that received this instruction transfers the packet to the line byte by byte and generates new test digits that are placed at the end of the package. The transmission can comprise a code conversion which is carried out by means of a read-only memory, contained in the byte processor, and if this changes the length of the data field the header of the package must be modified accordingly.

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When the packet has been sent out, the outbound byte processor awaits an acknowledgment signal to indicate that the packet has been received correctly and, if so, it reports this to the assigned packet processor. If, upon receipt of the confirmation, it is indicated that an error has occurred in the packet, the packet is retransmitted over the same line and then over another line, if accessible, with the aim of achieving a satisfactory transmission. If the package is not right can be transmitted, a signal called "network information packet" is transmitted and the data packet is transmitted discarded. If the outgoing line is a connecting duct between central units, an alternative intermediate central duct will be available and an attempt will be made to do so To transmit the data packet over this channel before it is discarded. The alternative inter-central channel can be assigned to a different packet processing unit, in which case the packet must be transmitted again via the switch 37 of the corresponding packet processing unit to the alternative Route to follow. The delay introduced in this retransmission could be avoided for subsequent packets, which have the same route by transferring the information to the switch processor 38 to avoid using the unsatisfactory route.

When the parcel of origin arrives at its destination then the route that the following packets in the call are to follow has been set up and the following packets in the call take the same route. The prefixes of the following packets can be abbreviated compared to the prefixes of the is included in the call origination packet because the exact details of the origin and destination line are not required; all it is necessary to know is that the packet in question belongs to the call made by a

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correct call output packet has been established.

The maintenance processor 39 is informed of any error which occurs in the satisfactory transmission of a packet and if the results of the analysis of such errors show that a particular packet processing unit is defective, so the processor 39 could operate the switch 44 to put the reserve unit 36 into operation.

Each call continues with an exchange of packets between the lines concerned, data packets in one Direction and acknowledgment signals for each data packet in the opposite direction. The headquarters from which the Package arrives, determines the storage space of the call, the delete and reset bytes of the package, the sequence numbers of the package, the duration of the call, the statistics of the call for billing purposes and the synchronism of the lines. The control center uses this information to control and terminate the call, to trigger the recording of the information for billing purposes and to switch the lines back to the Idle state after a call has ended.

Line units are provided on a one per line basis; Its main functions are the level changes between the V24 voltages and TTL voltages, resynchronization for byte synchronism, if any Request originates from the byte processor and then the maintenance of synchronism and transformation of the data flow the serial data flow at the V24 conversion station into the 8-bit parallel flow, or vice versa.

Under the control of the maintenance and accounting processors the switch is able to transfer the control of a group to a reserve section.

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Each byte processor comprises several microprocessors. Because of the differences in the programs required, everyone is Microprocessor intended for only one type of line, i.e. high-speed subscribers, low-speed subscribers or channels between the centers. The number of Microprocessors per group depends on the let mix. The main functions of the byte processor are to set up the start-up routine that is required to run each line in the group commissioning, tftipping packets on a byte-by-byte basis from each line and channeling in the group, where they are stored in the buffer memory and information from the packet processor regarding the arrival of the data, transferring packets on a byte-by-byte basis from the buffer memory on each line and channel in the group below the monitoring by the packet processor, acknowledgment of receipt of lines and channels depending on packets that are to these have been transmitted and report on their arrival to the packet processor, transmission of acknowledgments to lines and channels under the control of the packet processor in Dependence on received packets, maintenance of a continuous flow of data on every line and every channel by transmitting idle signals when no packets or Confirmation signals are to be transmitted.

The packet processor contains a single microprocessor. Its main functions are creation and preservation of authenticity a call record for each originating call or termination call in its group, checking the headers of packets placed in the buffer memory by the byte processor, and authorizing the corresponding acknowledgments for transmission on the line, requesting the switch control processor to route the packets through the switch (if necessary) to the buffer memory ^ serving the requested line or channel in accordance

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with the Leitalgorhytmus, interaction with the byte processor for the transmission on the lines and channels those packets in its buffer that are waiting to be output, adding the main network addition in the case of inter-center packets, regulating the allocation of buffers during each call.

The buffer memory has the following defined functions: Queuing incoming packets for access to the switch, if necessary, queuing the outgoing packets for access to the corresponding outgoing route.

The multiple message channel enables fast communication between the PaJet processors, the maintenance and accounting processors and the switch control processors through direct transfer from storage to storage.

The switch, under the control of the switch control processor (translator), enables the transmission of received or generated packets in a group to aem memory a different one and a sequence for the exit, depending on the requirements by the Leitalgorhytmus of the switch-Steuar-Processor / Translator is built in.

The maintenance processor has the following main tasks: Execution of the monitoring and control point and human / Machine functions, in conjunction with the accounting processor, the initiation and monitoring of the transmission of a Control of a group to the reserve section, should a malfunction be detected in itself, execution of Diagnostic routines, where appropriate, to localize suspected faults, recording in an auxiliary memory a copy of all important programs and the semi-permanent data to enable automatic recovery

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after a processor malfunction, acting in response for error reports and recording of error records, monitoring the load on each packet processor and performing the essential functions of the accounting processor, should this fail.

The main tasks of an accounting processor are to keep accounting records for all participants, that are connected to the control center and carry out the essential functions of the maintenance processor, if this failed once.

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Claims (1)

Claims l.i) Parcel switching center with connections for a majority of lines via which the data packets enter and exit the control center, the packets each having a header with an indication of the origin and the destination of the package and a main part containing the actual information, characterized by a switch arrangement for the transmission of the data packets to the end points of the lines which ai the provisions indicated by the preamble, through a plurality of data packet processing units, each are connected to terminals for one or more lines and to the switch arrangement to receive data packets from the terminals to the switch arrangement and vice versa, and by processing circuitry included in each packet processing unit which is responsive to the headers of the packets are formed, which pass through the unit in question, in order from these the necessary for the control of the switch arrangement Le it to derive information. 2.) Package control center according to claim 1, characterized by at least one reserve packet processing unit, which is not assigned to a specific line terminal, and by a Switching arrangement for switching on the reserve unit instead a defective data packet processing unit to one of these assigned line termination point. 3.) package switching center according to claim 1 or 2, characterized by a maintenance unit which is connected to all data packet processing units for carrying out tests with regard to the functionality of the same. 4.) Parcel switching center according to claim 3, characterized in that that the maintenance unit for the deletion of the data stored in a packet processing unit and for the renewed Entry of the unit in the Faij. is designed that the at Damage found in a test suggests that there is a malfunction in the unit's software. ORIGINAL INSPECTED 809808/0869 " ² " 5.) Package switching center according to one or more of the preceding Claims, characterized by an accounting unit designed for storing details of the Centrally processed data packets and identifying them from the participants Information as well as for the calculation of the fees to be charged to this. 6.) Parcel switching center according to claim J5 and 5 or 4 and 5, characterized in that the maintenance unit and the accounting unit are designed such that they are common the connection of a reserve data packet processing unit can cause to a line termination point. 7 ·) Parcel switching center according to claims 3, 5 and 6 or 4, 5 and 6, characterized in that the maintenance unit and the accounting unit are designed such that they are at least can perform part of the functions assigned to the other unit in the event of their failure. 8.) Package switching center according to one of the preceding claims, characterized by a control unit for the switch arrangement for routing the data packets and through a reserve control unit with a reserve switch arrangement, the latter in the case of the failure of the former can be switched on. 9.) packet switching center according to one of the preceding claims, characterized in that each data packet processing unit a packet processor and a buffer memory, and that the packet processor is made responsive to the header of a packet is for allocating storage locations of the buffer memory that are adequate for receiving the packet in question. 10.) Parcel switching center according to claim 9, characterized in that that each data packet processing unit also has a byte processor which is connected to the packet processor and is connected to the buffer memory and for the input of data bytes of a received packet is formed in the buffer memory. 809808/0869 " ³ Parcel switching center according to Claim 10, characterized in that each byte processor comprises a plurality of microprocessors, each of which is designed for processing data packets, the come from lines or leave lines that have the same data rates. 12.) Parcel switching center according to claim 10 or 11, characterized in that that the byte processors for the generation and transmission of idle bytes to each other in the operational break are designed for the purpose of monitoring the central function. 13.) Parcel switching center according to one of the preceding claims, characterized by switch control circuitry for controlling the switch arrangement in dependence on routing information derived from the packet headers, which Circuits provide at least two alternative routes for the packet in question, transmission via a first route is attempted and the transfer is only attempted if the attempt is unsuccessful the second route is attempted. 809808/0869