FI66994B - ANORDNING FOER SELECTIVELY UTBYTE AV INFORMATIONER - Google Patents

Description

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^ ^ 1) UTLÄCCNINGSSKRIFT 6 6 994 ^ ^ (51) Kv.lk?/l reducedta3 G 06 F 3/04 FINLAND — FINLAND (H) PK «KmMaii« g 753578 (22) HtktmtafiM — Anattkningadag 1 8.12.75 (23) AlkupAivi — GIMgh «Ctd * g 18.12.75 (41) Τ · Ημ {ulkiMfcsJ - Khrtt 30.07.76

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Patent · och reyj star ityrel sen '' AwnHaw nthgd od> utLnmftn fitiawd ji.uo.oh (32) (33) (31) Pyritty «χ>» ηη i * »wprtocmt 29.01.75

France-France (FR) 7502801 (71) Compagnie Internationale pour 11Informatique C11-Honeywel1 Bull, 94, Avenue Gambetta, 75960 Paris Cedex 20, France-France (FR) (72) Claude Jean-Baptiste Bouvier, Nogent / Marne, David John Smithson,

Buc, Jean-Paul Luais, Fontenay sous Boife, France-France (FR) (74) Oy Borenius 6 Co Ab (54) Device for the selective exchange of information -Anordning för selective utbyte av informationer (61) Supplement to the patent 64473 - Tillägg till patent 64473 This invention is an appendix to Finnish patent application 3415/74, entitled "Device for the selective exchange of information", and this appendix relates to the improvement of the control modules described in the main patent (patent no. 64473).

According to the main object of the invention, a device comprising a n-position combination for selectively exchanging information between transmitting and receiving means is known, the combination having a communication channel between different stations and information transmission means between said transmitting means and said receiving means, said control devices being formed of a combination of there are n station control modules connected between the link and the respective stations, these modules each being formed of a processing unit and an associated memory for processing information at the level of each station. Thus, an information processing system implemented at the level of each station processes information that is exchanged between members of a particular station and members of other stations.

The connection channel thus described in the main patent application is a standard device connecting the modules, which is not controlled by a special module, but which receives the control of each module in turn. This method of communication between the modules 2 66994 makes it possible to achieve high data rates, while the use of two-way receivers on the connection channel allows data to be transmitted over long distances. Based on Figure 2 of the main patent application, the information is transmitted as a message from the matching circuit ABj, which adapts a certain module MOj to the connecting channel, towards the second matching circuit ABj, which adapts the second module MOj to the connecting channel. Messages sent and received by the station are monitored by the logical devices of the gateway monitoring device, represented by Gj in Figure 2 of the main patent application. Data transmission can only be undertaken by a station that acts as an independent or dominant gateway station. Two types of transfer are possible: 1. Transfer of data from an independent or dominant main station to a subordinate position.

2. The transfer of data from a subordinate position to an independent or dominant master station.

Two transfer methods are allowed: 1. The normal way to transfer data from one drive to another.

2. "Shuffle mode" based on mixing data from a specified station with a combination of other stations.

The management of the access channel is mandatory from one station to another. An independent station has the ability to initiate the transmission of a message to or from another station or stations. If the transfer is not required, or if the transfer is completed, the control of the connecting channel must be handed over to the next station.

The system described in the main patent application satisfactorily meets the above requirements and is ideally suited for transmitting data between remote stations. Instead, this solution becomes expensive in the event that the stations are located close to each other. The matching circuit ABj of the device described in the main patent application is repeated as many times as there are stations located close to each other. It is therefore an object of this further application to patent a device in which a single link channel matching circuit ABj is used for a combination of stations located close to each other, which contains the characteristics of the module of each station and which enables connections between all stations with the same characteristics. The use of a single matching circuit ABj becomes possible in the case of developing a local connecting channel, 3 66994, which connects the control devices Gj of each station to the matching circuit ABj.

In order for the system described in the main patent application to remain unchanged, the local connection channel must have the following characteristics.

The local connection channel must allow data transfer between both nearby and remote stations.

The local link must provide the same transmission rate as the link connecting the combinations of remote stations.

The local access channel must be completely independent of the logic of each station, and the interoperability between the modules of the stations must always be the same regardless of the station.

The local connection channel must be completely controlled by the matching circuit ABj and in no case must it be at the control level of the modules.

No local connection channel with the characteristics listed above is already known. The originality of the device according to the invention will be better understood from the following description, which is presented on the basis of the accompanying drawings.

Figure 1 shows a data processing apparatus according to the description of the main patent application, which is distributed.

Figure 2 shows the same distributed data processing apparatus including the devices which are the subject of this further application.

Fig. 3 shows an embodiment of a logic matching circuit ABj, which is the subject of this further application, which is connected on the one hand to a local connection channel and on the other hand to a connection channel of a combination formed by remote stations. To avoid confusion with the main patent application, the circuit ABj is hereinafter denoted by the symbol PEL.

Figure 4 shows the type of message sent by each DPC.

Figure 5 shows an embodiment of the PEL receiving circuits of the logic matching circuit which is the subject of this further patent application.

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Figures 6a and 6b show an embodiment of the PEL transmission circuits of the logic matching circuit which is the subject of this further patent application.

The data processing apparatus shown in Figure 1 is the same as that shown in Figure 2 of the main patent application. The link channel 120 connects several stations to each other, e.g., STj. Thus, the number of connected stations is arbitrary. According to the figure, the station STj is connected to the connection channel by means of the connection module 100, and the station STj + n is connected to the connection channel 120 via the connection module 110. Each module connected to the station has the same structure as shown in Figure 1. Station STj 107 is connected to processing element Pj 106, station STj + n 117 is connected to processing element Pj + n 116. Processing elements 106 and 116 are connected to fast memories Mj 105 and Mj + n 115, respectively, in which the micrograms required for inter-station storage are stored. data transfer. The processing means of the station STj comprises: a control circuit Cj 102 containing all necessary logical devices for processing the micrograms in the memory Mj 105 and transferring data between the station STj 107 and the link 120, a further matching circuit ABj 101 connecting the link 120 to the control circuit Gj 102 and the circuit AMj 104, which is connected to the memory Mj 105 and opens access to this.

Figure 2 shows the same distributed data processing apparatus incorporating the devices which are the subject of this supplementary patent application. The two distant station groups, each of which forms close stations in the group, each have ST1 217 stations ...

ST n 219 group for the first station group, and stations ST 220 ...

A group ST 222 for a second group of stations communicating with each other via a link 200 common to all other groups of stations not shown shown close to each other. Each station in a group of nearby stations can connect to any station in that group through its associated local access channel and the associated matching circuit PEL. Each station in a group of nearby stations can connect to any station in the second group separate from the previous stations through a local access channel and an associated matching circuit PEL that connects the station to a connection channel common to all groups of nearby stations.

According to Figure 2, the stations ST 217, ST 2 218, ST n 219 communicate with each other via the local connection channel 201, and the stations ST1 220, 5 66994 ST2 221, STK 222 communicate with each other via the local connection channel 202. Instead, any of the stations ST 217, ST 2 218, ST n 219 can communicate with any of the stations ST1 220, ST2 221, ST n 222 via the local link channels 201 and 202 and the link channel 200. Circuit FEL 203 provides matching between local link 201 and link 200. Circuit PEL 204 provides matching between local link 202 and link 200. Each station is associated with a link channel monitoring device DPC, which has all the logical devices necessary for processing the micro-programs in the corresponding memory M. According to Figure 2, combinations can be checked (ST 217, DPC1 205, M 211); (ST2 218, DPC2 206, M2 212); (ST n 219, DPCn 207, M3 213); (ST 220, DPC, 208, M, 214); (ST2 221, DPC2 209, M2 215); (STK 222, DPCK 210, MK 216).

Figure 3 shows the connection point between the matching circuit PEL 300 and the control monitoring device DPC 301, both of which are connected to the local link 305. The circuit PEL 300 has control logic 306 and circuits for serializing and parallel communication of messages on the serial link 304 or local link 305. Circuit ST1 307 receives messages from its local link 305 at its parallel inputs and retransmits them to link 304 using serial forwarding. Circuit SR2 308 receives messages from its serial link 304 at its only input as serial forwarding and retransmits them to the local link using parallel forwarding. The control monitoring device DPC 301 receives or retransmits messages from the local connection channel 305. The reception of messages from the circuit PEL 300 via the control-monitoring device DPC 301 takes place in the shift register PIPO 309, which operates according to the rule "from first input to first output". The register FIPO 309 retransmits the messages to the microprocessor C315 and the memory adapter MDI 313, which forwards the information in the message to the main memory MMU 303. The microprocessor 315 is connected to a message length calculator DL 310 and an address calculator CA 312. The length calculator and address counter are used to obtain an address directly from memory MMU 303. without recourse to microprocessor C 315. This microprocessor C315 and the memory RDM 311, which contains the micrograms required to control all types of messages, recognize the messages and process them. The messages in the local communication channel between the circuit PEL 300 and the DPC 301 are synchronized by the control logic 306 of the circuit PEL, which generates the signals VALA, KAP and EK on the three conductors of the local control channel. When the transmitting DPC 6 66994 manages the serial gateway and the local gateway, it transmits a signal EO to the local gateway, which after receiving this signal by the circuit PEL 300 causes the control logic 306 to send the signal VALA on the one hand and the message start signal on the serial gateway to signal all devices . The circuit PEL then sends a signal UK to the local connection channel, which is taken into account by the controlling DPC device and which requests this DPC device to send a signal. The DPC sends a signal to the local access channel, which the circuit PEL retransmits to the receiving device DPC by sending a signal KAP, which opens access to the data in each register PIPO 309 of each DPC, which DPC is connected to the local connection channel. Figure 4 shows the message format type. The first byte of the message represents a block. It is formed from digital series 01111110 and recognizes the beginning and end of the message. The second byte gives the address of the drive. The address consists of 8 bits.

It specifies the position of the local gateway or serial gateway that needs to send the message. This address value can indicate a specific station or all other stations at the same time.

The third byte identifies the type of message. The 4-bit code specifies the message type for microprocessor C315. Other 4-bit groups may have different meanings. The definition of the fourth byte and subsequent bits depends on the type of message. The logic does not generate a fourth byte, which is, in other words, a sign of "address," i.e., the address of the transmitting module necessary for the receiver to obtain an address for response. Both bits of CRC are control bits.

The byte n indicates the end of the message and its code is the same as the message start code.

The logic PEL recognizes the beginning and end of the message and generates the signal VALA. When it comes to the start of a message, the signal VALA becomes dominant and allows the message to access each FIP0 connected to the local link channel circuit PEL. The message bits following this character are transmitted one after the other at the rate of the signal KAP, which transfers each received 1-aid circuit to the PIPO 309 registers. The PIPO is dynamic and the output is independent of the input. The DPC reads the PIPO from the time the first byte occurs at the output without waiting for the entire message to be registered to the PIP0. Each DPC has read the station number in the first byte of the message and which leaves it first. Station number identification 7 66994 is performed by a microprogram at the level of each DPC. When one of the DPCs recognizes the station number included in the message, the microprocessor C315 reads the next byte contained in the circuit PIPO 309 and transmits the contents of the byte within the circuit PIPO 309 by means of the signal SO. The next byte contains the message type. The message type can have different meanings. It can be an information transfer message or ITM. The microprocessor C315 reads the third byte of the message, which contains the index number, and starts retrieving the length and address from the buffer in the main memory MMU 303 on the basis of this number. The address of the buffer is placed in the address counter 312 and the length of the buffer is placed in the length counter 310. The address counter ensures the propagation of the address necessary to write data to the selected buffer of the memory MMU 303. The length calculator informs the logic of any exceedances of the length. When the entire message has passed to the buffer MMU 303, the DPC sends a response message to the transmitting station and enters the waiting state to wait for the next reception. The message type may be a message to read the BRC buffer, and is used by the master station to request another selected slave station to transmit information contained in a particular buffer in its main memory. The address of the buffer is specified in the second half of the third byte of the message, and this byte also contains the Index Number. From this index number, the receiving DPC calculates the address of the buffer that contains the data to be transmitted to the main memory. The address of the buffer is entered into the address calculator and the length of the buffer is entered into the length calculator by the microprocessor. The address counter ensures that the address propagates when the data contained in the selected buffer is read into main memory. When the entire message has been transmitted, the receiving DPC sends a response signal and moves to wait for the next reception after transferring control to the next module.

The message type may be a message "POLL" for the purpose of transmitting serial link channel management from one station to another station, the address of this second station being included in the second byte of the message. When a station recognizes the number in the second byte of a message and when it recognizes the message "POLL", it asks the logic to know if it has a message to send.If the answer is no, move the station to the next station in serial channel management, subtracting its actual address by one unit and forwarding serial connection message "POLL ·. If the answer is yes, the station logically retrieves the buffer included in the main memory where the data to be transmitted is located and sends a message to the serial communication channel ITM.

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Finally, the message type may be a response message from the receiver to the sender and may be an ACK acknowledgment or an indication that the station is busy, in which case the message type is a "BUSY" message.

The communication between the stations is the transmission of the messages defined above to the serial communication channel, and this is done under the control of the micro-programs in the RDM of each DPG. The dormant station continuously monitors and checks the signals coming from the local access channel to the input of its DPC, at which point this station retrieves the message with the address of this station. The station can exit its sleep mode in the event of three different possibilities: 1. The received message is the message "POLL".

2. The received message is the message "ITM".

3. The received message is the message "BRC".

When the station receives the message "POLL", the station becomes the dominant station, in both other cases it becomes the slave station, in all three cases the station DPC only considers the arrival of the message if it has the correct format and the correct bits CRC.

When the message "UM" arrives, the called station sends a reply message to the station that sent it, whose address is located in the fourth byte of the message ITM. If the buffer indicates that the space in the second part of the third byte is available and in the correct format, the response of the called station will be ACK. If the selected buffer is not available, the response will be the message “BUSY”. If the received message is incorrect (incorrect CRC), there is no response.

The sending station logically notifies the destination of the successful arrival of the message ITM when the station receives the ACK message from the station receiving the message ITM, and then returns to its sleep state after transferring control to the next station.

When a station is assigned the message "POLL", it becomes the dominant station for both the local access channel and the serial connection channel and takes one of the following three actions, depending on the station logic, which can be: 1. The "POLL" sequence, if the logic has nothing to do.

2. Series "ITM" if the logic requests this.

3. Series "BRC" if the logic requests this.

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The master, i.e. the master station, which no longer needs the serial connection channel or its local access channel, sends the message "POLI" to the address of the next station, which is obtained by subtracting one from the address of the master station.

If the address of the main station is 0, the address of the next station will be the station with the highest number. The main station continues to monitor the operation of the line after sending the message "POLI". After the operation is detected, the main station returns to sleep mode. If after a certain time no line operation is detected, the time is defined at subsystem level, the main station starts a new series "POLL" to the new address, obtained by subtracting one from the previous address.If the previous address is zero, the address with the highest number must be used.

Fig. 5 shows, as an exemplary embodiment, a matching circuit for a serial communication channel and relates in particular to its receiving part. Messages from the serial communication channel are received at the input SO of the amplifier 501, the output of which is connected to the his inputs J and K of the lever JK 501. Since the first byte of the message block is zero, the lever JK 501 has its logic "1" of its input J, and its output Q is set to 1 and generates a signal ACT indicating that the serial communication channel is operational. The signal ACT opens the inputs SO and R 1 of the AND gate 502, the SO 1 receives the serial channel signals and the R 1 is a clock signal. The output of the AND gate 502 is branched to the input of a four-lever calculator 504, which calculator advances the unit each time the input SO of the AND gate 502 is in logic state 1. The calculator 504 receives logical 0 and these parallel inputs 10 to 13 of its parallel inputs. the inputs are opened by an AND gate 509, which receives a clock signal R 1 at its second input and a clock signal opening signal S 1 from the output of the NAND circuit 501 at its second input, so that when 0 is detected in the serial channel, the signal S1 has a value of 1, and the counter inputs 504 ... 13 open under the influence of the PE input of this calculator and return the four levers forming this calculator to zero. The outputs Q0 ... Q2 of the calculator 504 are connected to the inputs 10 ... 12 of the binary-decimal decoder 505, the only outputs 05 *, Q6 * and Q7 * of the decoder being used to output the signals CRU5 *, CRU6 *, CRU7 *. Input 13 * receives a signal ACT which is zero when the serial link is in operation, and thus opens the outputs 00 * ... Q7 * of decoder 505. The signal CRU5 * is a logic zero when the counter 504 has counted 5 consecutive bits 1 from the input SO, and in countries cases this signal is one. This signal CRU5 * goes to the input of the AND gate 506, which port receives at both of its other inputs the signal VAOT coming from the output Q of the lever VACT510 and the output of the clock signal R1 · the AND gate 506 going to the input of the inverter 507 in bits to generate a reception control signal CP *. The signal CRU6 * goes to the input of an inverter 508, the output of which is connected to one input of the AND gate 509, and the other two inputs of this port receive a signal S1 from the inverter 501 and a clock signal R1. The output of the AND gate 509 goes to the clock input CP of the lever JK 510, whose input J of the lever J is always 1 and the input K is always 0. When the counter 504 has thus counted 6 bits in a row 'M ", the output CRU6 * of the decoder 505 is logical zero, and opens the input of the AND gate 509 when a zero appears in the input SO, which controls the input CP of the lever 510, which lever enters state 1. The signal VAOT generated by the output Q of the lever 510 goes to state 1 and opens the input of the AND gate 506 and allows clock signals R1 to generate a signal CP * that controls the receive bits at the output of inverter 507. The AND gate 530 sends a signal VAIiA to the local link and repeats the VACT state of the lever. to the local link, which leaves the DPC transmitter and enters the input of the AND gate 530. The signal CRU7 * generated by the output Q7 * of the decoder 505 is repeated through two inverters 511 and 512 and is fed preferred input to reset MR lever 510 to zero. Thus, when the counter 504 has detected 7 consecutive bits 1, the lever 510 again generates a signal VACT which cancels the reception of the byte CP * reception. The recovery of Vipan VACT 510 due to the signal CRU7 * is random, and it occurs, for example, when a line break occurs in the middle of a message. Lever VACT 510 normally returns to zero when its input CP has received a byte indicating the end of the message, with inputs J and K being in states 1 and 0, respectively. When signal VACT is 1, it opens clock signal RO input and OFF gate 517 input CRU5 *, the gate output of which is connected to the input CI of the calculator 515. The output of the calculator 515 is connected to the inputs of a binary-decimal decoder 516, the outputs of the decoder of which are connected to inverters 518 ... 525, which successively generate signals CBR1 ... CBR8 controlling the reception of bits in the rhythm of the clock RO. When the decoder 516 detects the eighth position of the counter 515, the signal CBR8 goes to the input of the AND gate 514 and resets to zero this counter 515, which is again ready to count 8 bits. Circuits 526 and 527 are shift registers, the clock circuit input CP * receives the output of inverter 507, and this inverter reproduces clock signals R.j when signal VACT is present, with signal SO received at input SO 116 being transferred in series to shift registers 526 ... 527. Each register has 4 byte positions, and a fourth byte position corresponding to the output T3 of the register 526 is connected to the inputs Jk of the second register 527, while the 8 hit bytes received in series SO are sequentially transferred to the transfer registers 526 and 527, and the byte becomes i bytes T01 to T03, where the less significant portion that has been received at the end of the link is located at location T3 of register 527, while the more significant portion at the end is located at location TO of register 526. Circuits 528 and 529 are interface circuits for the outputs of shift registers 526 and 527 to the local link. The inputs 10 ... 13 of both of these circuits are connected to the outputs T0 ... T3 of shift registers 526 and 527, respectively. The connection to the local connection channel takes place at the moment when the eighth position of the counter 515 is detected when the signal CBR8 changes to zero.

Based on the above explanation, the processing of signals entering the serial link can be summarized as follows:

The arrival of zero on the serial communication channel is indicated in the logic circuit FE1 by a lever 501 bis which supplies the operating byte ACT of the line. This signal ACT then opens the input of a counter 504 which counts all consecutive ones transmitted on the serial link channel. It has been mentioned above that the preamble of the message comprises six consecutive bits 1 with two bits 0 on each side. The decoder 505 detects this word, and the decoder output CRU6 * enters state 0 when the sixth consecutive one byte enters, whereby this detector sets lever 510, which provides a signal VACT, and which results in bits from the serial link channel being taken into shift registers 528 and 529 and shifted in parallel to the local link channel by the signal CBR8 of decoder 525. The transition of the signal VACT to one is transmitted by the local link signal VALA to all circuits DPC, which receive a notification that the preamble of the message has become meaningful. The DPC circuits then analyze the next byte to read the station number. Precautions have been taken, especially with regard to the following rules.

When the receiving circuit indicates 5 bits as consecutive ones in the next bits following the word, the signal CRU5X at the output of the counter 504 goes to zero and opens the bit reception control CP *, and 12 6 6 9 9 4 if the next byte is zero, it returns the counter 504 to zero NO- Via the input of AND gate 509, and this byte is taken into account in shift registers 526 and 527, and if the next byte is 1, signal CRU6 * receives a value of 0 to indicate that it is the end word of the message, and returns lever VAOT 510 to zero, this byte is also taken into account in shift registers 526 and 527. If the next byte is still one, the signal CRU7 * is set to 0 and the lever ACT501 bis switches the line on. The signal CBR8 does not occur in this case, and the message is not forwarded to the local link.

Figs. 6A and 6B show an embodiment of the transmission portion of the serial link matching circuit. The transmitted signal BO is received at the control module and sets the lever JK 601, which at its output Q outputs a signal E 1 which, when applied to the input J of the lever JK 602, sets this lever to state 1 to generate a signal MIS. When the signal E. is present before the signal MIS, switching these signals E1 and EMIS * to the input of the AND gate 605 causes the parallel inputs of the calculator 604 to open, the four inputs of the calculator of which are forced to zero, so that the calculator 604 thus returns to zero at the time the combination of circuits shown in Figures 6A and 6B will transmit. In the presence of the signal MIS, the input PE of the counter 604 no longer opens these parallel inputs. The calculator 604 then proceeds with its input C1, which is connected to the output of the AND gate, which has 3 inputs 612. The outputs QO, Q1, Q2, Q3 of the calculator 604 are connected to the inputs of the binary-decimal decoder 605, which outputs the states CYO *, *, CY3 *, CY4 *, which receive the value 0 in turn in the order of 0, 1, 2, 3, 4 each time the counter 604 advances by one. The outputs CY * 0 and CY * 4 are connected to the inputs of the inverters 605 and 606, respectively, to generate complement signals. The signals CYO are applied to the input of the AND gate 609, which receives the input opening signal PC. The signal CY1 is applied to the input of the AND gate 610, which also receives the opening signal PC at its input. The AND gate 611 receives an opening signal PC at its second input and a signal VCRC at its second input from the output of the AND gate 616, which port receives a signal CY2 * at its second input and a signal CY3 * at its second input. The outputs of the three AND gates 609, 610 and 611 connect the input of the AND gate 612. When the counter 604 is at zero, the output CYO * is at zero and opens the input of the AND AND gate 612, when the signal PC arrives, the decoder 605 interprets the state 1 of the calculator 604, the CY * changes to zero and opens the input of the AND AND Gate 610. When the signal E0 at the input of the lever JK 601 ends, the signal E1 * of the output <£ of the lever JK 601 changes to state 1 and then opens the input E1 * of the AND gate 610, which in the presence of the signal PC causes the counter 604 to advance a step, and the decoder 605 interprets state CY2 *, which changes to zero. The signal VCRC * generated by the AND gate 616 is 1 when CY2 or CY3 is present, i.e. at positions 2 and 3 of the counter 604, starting at position 0. When either of these two conditions holds, the calculator proceeds step by step under the influence of the signal PC.

The counter 627 preceding the hammer-decimal counter 628 counts the bits transmitted within each byte. Decoder 628 interprets 9 locations CBE0 ... CBE8 of calculator 627. The counter 627 proceeds to its input CL

the effect of an incoming signal from an AND gate 622 which receives at its inputs a clock signal from the EMIS lever JK 602 and a signal BS * changed by the AND gate 621, both inputs of which receive one of the 0 and the other of the counter 620 the same counter location 2. The counter 620 propagates under the influence of the signal coming to its input C1 and coming from the AND gate 618. This AND gate 618 receives at its second input the signal VBS from the output of the AND gate 613 to its second input converted bit 1 from the output of the AND gate 621 and a clock signal to its third input. The signal PC is obtained from an inverter 632, the input of which receives the output of the AND gate 631, which port receives at its inputs a signal BS * from the output of the AND gate 621 and a signal CBE8 from the output of the amplifier converter 630 and a clock signal R 1. The signal BIT 1 changes at the output of the AND gate 625, which receives the output of the AND gate 624 at its second input and the output of the AND gate 625 at its second input. The AND gate 624 receives the cyclic redundancy bits of the circuit CRC 623 at its second input and the signal VCRC converted to the AND gate 616 at its second input. The NO gate 625 receives a signal VCRC * from the inverter 627 at its second input and a DSO bit sequence at its second input, which transmits the word and data. The bit sequence is transmitted to the serial link channel from the output of the AND gate 629, which receives the signal BS * from its output from bit 1 and the output of the AND gate 621. The signal ZR is used to reset the counter 620 to zero via the AND gate 619. The input DSO of the AND gate 625 receives a series of bits from the shift registers 637 and 638, the contents of which are cleared in series via the output T3 of the shift register 638 H 66994. The output T3 of the shift register 637 is connected to the inputs J and K of the shift register 638. The inputs 10 ... 03 of each register receive the data to be transmitted Ό0 ... B7. This information D0 ... D7 is taken into account by the signal CP * from the output of the inverter 640, the inverter input of which is connected to the output of a three-input NO gate 639 controlled by signals CBEO * from the output CBEO * of the binary-decoder 628, two a signal BS * from the outputs of the AND gate 621 having an input and a clock signal Rq. Buffer registers 635 and 636 transmit a word when the signal EMDR * from inverter 615 has opened these registers, inputs 10 ... 13 of buffer register 635 receive polarities corresponding to code 0111, inputs 10 ... 13 of buffer register 636 receive polarities corresponding to code 1110. The outputs D0 ... D3 of the buffer register 635 are connected to the inputs of the shift register 638, and the outputs D4 ... D7 of the buffer register 635 are connected to the inputs of the shift register 637.

The inputs 10 ... 13 of the buffer registers 633 and 634 are connected on the one hand to the local link data lines DAT0 ... DAT3 at the buffer register 633 and on the other hand to the local link data lines DAT4 ... DAT7 at the buffer register 634. The information on the local link is passed to the inputs of shift registers 637 and 638 when accepted by the signal CY1 * and CBE8 *, which signals come from the respective decoders 605 and 628. The EEL circuit sends a signal EK to the local link channel for the AND gate 643, which receives at its inputs the signal E1 from the lever 601, the signal CDEO from the decoder 628 and the clock signal TO. The signal "signal to be received" KAP is transmitted from the output of an inverter 647, the inverter input of which is connected to an AND gate 646, one input of which is connected to the output of an AND gate 645, the latter port receiving a signal CYO * on the one hand and signal CY1 *. The other two inputs of the AND gate 646 receive the clock signal T5 on the one hand and the signal CBE8 on the other hand from the inverter output 630.

According to the above, data from the local gateway is sent to the serial gateway as follows. When the module wants to transmit, it first transmits the signal EO, which is received by the lever JK601 and generates the signal E1, after which, after the clock 602, it transmits the signal EMIS. The signal E1 resets the counter 604 to zero via the AND gate 603, and the decoder 605 interprets the state CYO * and generates the signal MDR * through the inverter 615 and controls the opening of the buffer registers 635 and 630 to transfer the word to the input of the shift registers 637 and 638. Signal E1 also causes a signal VALA to the local link channel by the AND gate 530 of Figure 5 to all DPC circuits connected to this channel. The signal CBE8 * has reset the counter 627 to zero after the previous message has ended, and at the start of the new message, the decoder 628 interprets the location CBEO *. The counter 620 is also zero at the start of the new cycle, and the output BS * of the AND gate 621 is 1, and the counter 627 proceeds in the rhythm of the clock R1, whereby the states of the counter appear as a signal sequence CBEO * ... CBE8 *. At time RO and for states CBEO * and BS, the signals CP * appearing at the output of inverter 640 open the parallel inputs of shift registers 637 and 638 and the word is passed to these registers 637 and 638. At the next time R1 NO-AND-641 port output P * opens the clock input CP of shift registers 637 and 638, and the word in registers 637 and 638 moves one step, leaving the first byte corresponding to the least relevant signal from the output DSO of register 638 opened by the signal VCRC at the input of the AND gate 625, and terminates at the ZRC of the serial link. The next 7 hits of the word follow in turn at the rate of the clock signal RO. When the eighth byte is transmitted, that is, at the moment when the signal CBE8 appears at the output of the inverter 630 at time R7, the signal PC appears, and the output of the AND gate 609 controlled by the signals CYO and PC causes the counter 604 to advance one step, and the decoder 605 interprets , which causes the signal VBS to appear at the output of the AND gate 613 and to open the input of the AND gate 618. The presence of signals 0Y1 * and CBE8 allows the second byte of information in the local link to be transmitted to the conductors DAT0 ... DAT7 of buffers 633 and 634. The contents of buffers 633 and 634 are cleared by registers 637 and 638, respectively, by the effect of the CBEO * signal, which returns to zero at the moment, whereby the counter 627 returns to zero by the CBE8 * signal from the output of the AND gate 631 to the internal PE of this counter 627. At the following locations CBEO1 ... CBE08 of the decoder 628, the 8 hits in the shift registers 637 and 638 are transmitted byte by byte (one byte in each position) to the output DSO of the shift register 638. The sequence of serial bytes is transmitted through the AND AND gates 625, 626, and 629 to the serial link channel. The input C1 of the counter 620 controlled by the AND gate 618 causes this counter to advance 16 6 6 99 4 units each time the byte is one at the output DSO of the shift register 638. When the counter 620 has counted a total of 5 bits in consecutive ones, the signal BS * at the output of the AND gate 621 returns to zero and stops the progress of the counter 627 for the clock period and forces zero to the serial communication channel, the signal ZCR, which is 1, returns the counter 620 to zero 1, the reset of the counter 620 to zero generates a signal BS1 * one, and the period continues until the signal CBE8 * appears. The placement of byte 0, i.e. the return byte, after 5 bits as consecutive ones can only occur at the times when the signal VB3 appears at the input of the AND gate 618, i.e. in periods CY1, CY2 and CY3. The end of the cycle CY1 is controlled by the UPC, which returns the signal EO to zero, which causes the lever 601 to return to zero and the signal E1 to disappear again. The input of the AND gate 610 then becomes open when the signal E1 is lost, and its output causes the counter 604 to advance one step, causing a state CY2 at the output of the decoder 605. This causes the signal VCRC to settle at one and open the input of port 624 and send the first byte CRC redundancy to the serial communication channel under the influence of the control signal generator CRC 623. The signal PC following the transmission of the first byte CRC causes the counter 604 to advance the step interpreted by the decoder 604 in the period CY3 *, and the second CRC byte is now sent to the serial link channel. This is only possible if the VCRC remains in logical one during two consecutive states CY2 * and CY3 *. After the input of the AND gate 611 is received, the PC signal 604 following the next signal proceeds again, and the decoder 605 then interprets the location CY4. Shifting the signal CY4 to zero at the input of the AND gate 614 results in the signal MDR * settling at one at the output of the inverter 614 and opening buffers 635 and 636, which then transmit the final word transfer to registers 637 and 638, where they are retransmitted on the beat.

The above description describes only one possible embodiment, so that one skilled in the art can obviously implement other devices without departing from the scope of the invention.

Claims (4)

66994 1. Anordning för selective informationsbyte enligt krav 1 i huvud-patent nr. 64473, kännetecknad därav, att olika grupper (217-219, 220-222) av stationer (217 ... 222, 302) at the beginning of the communication between the communication genome and the channel (200, 304) of the same station as the station group (217-219), 220-222) with the station, and with the station (217, 218, 219, 302) and in the group (217-219, 220-222) with the station (217, 218, 219) at the end of the station to the communicator communication with the station (217, 218, 219) and the station group (217-219) via the local channel (201), with the station (217, 218, 219) and the group (217-219) of the station head to the station of the station, and to the side of the station to the station (217 ... 222, 302) and to the group (220-222) to the station (220, 221, 222) to the station of the station (220, 221, 222) föregäende, genom en förbindelsekanal (200, 304), som förenar nämnda stationsgrupper (217-219, 220-222), och genom varje lokal förbindelsekanal (201, 202, 305) som förbinder stationerna (217 ... 219, 220 .. .222) and a group of stationers (217 ... 219 and 220 ... 222)) at the time of communication with the station (217 ... 222, 302). 1. The main patent no. Device for exchanging selective information according to claim 1, characterized in that the separate station groups (217-219, 220-222) formed by the short-spaced stations (217-222, 302) are connected to each other via a connecting channel (200, 304), connecting these station groups (217-219, 220-222) to each other, and that each station (217, 218, 219, 302) in the station group (217-219) of the short-spaced stations (217, 218, 219) may be connected on the other hand, to another station (217, 218, 219) of the same station group (217-219) via a local connecting channel (201) connecting all stations (217, 218, 219) of the same station group (217-219) of the short-distance stations to each other , and on the other hand, to any other station (217 ... 222, 302) of the second station group (220-222) formed by the short-spaced stations (220, 221, 222) and spaced apart from the previous station group (217-219). via an (200, 304) connecting these station groups (217-219, 220-222) and through each local link (201, 202, 305) connecting a short distance between stations (217-219 and 220). ... 222) stations of the station group (217-219, 220-222) to each interconnected station (217 ... 222, 302). 2. An order according to claim 1, which is intended to apply to a group of stationary channels (200, 304) for a stationary station (217-219, 220-222) on a card in accordance with 20 66994 of the first and last 20 years, 305) in the case of an account with its own station group (217-219) of the station (217, 218, 219, 302) at the same time as the first step of the logic communication (203, 204, 300) with the same information information. , which has a rum main channel (200, 304) and a local channel (201, 202, 305), and has an internal logic (306), which is connected to the local channel (201, 202). and the second account (307, 308) is provided with information on the second channel (200, 304) or on the local channel (201, 202, 305). Device according to claim 1 of said main patent, characterized in that the transmitter is arranged in the connecting channel (200) of the station groups (217-219, 220-222) formed by the short-spaced stations (217-219 and 220-222). 304) and the local link (201, 202, 305) with respect to a single short distance station group (217-219, 220-222) is provided by a logic relay (203, 204, 300) which takes care of all information exchanges on said actual link (200, 304) and local link (201, 202, 305), comprising control logic (306) connected to the local link (201, 202, 305) and the circuits (307) , 308) that transmit data to or receive data from said link (200, 304) or local link (201, 202, 305). 18 66994 3. An arrangement according to claim 1, which is intended to cover a station (217 ... 222, 302) and is connected to a local transmission channel (201, 202, 305) with a stationary station module (205 ... 210, 301), wherein the information (309) is provided with information from a local processing channel (201, 202, 305), connected to a microprocessor (315), and under the control of a micro-program that is included and connected (211. ..216, 311), which includes nitrogen and communication information on the local communication channels (201, 202, 305) and communication channels (200, 304) with the group (217-219, 220-222) of the station head. korta inbördes avständ. Device according to claim 1 of the main patent, characterized in that each station (217 ... 222, 302) is connected to its local connection channel (201, 202, 305) via a station control module (205 ... 210, 301) with means (309 ) for receiving information from the gateway (200, 304), the means (309) being connected to a microprocessor (315) which interprets the type of information received based on the microprograms written in the associated memory (211 ... 216, 311) and ensures connection to the local gateway (201, 202, 305) and a short channel spacing (200, 304) of station groups (217-219, 220-222). Device according to Claim 2 of the main patent, characterized in that the logic transmitter (203, 204, 300) has circuits (307) which receive information from the connection channel (217-219, 220-222) of the short-distance stations (217-219, 220-222). 200, 304), and wherein the circuits (307) have a first means for detecting the presence of information in the link channel (200, 304) combined with a second means for detecting the preamble of the information, which, if the word is correct, opens circuits that take into account short distance information supporting the groups of stations (217-219, 220-222) along the link (200, 304), for retransmission to the local link (201, 202, 305), and a third means connected to said first means for indicating the presence of the final word of the information, which instrument closes those circuits that take the information into account. Device according to Claims 2 and 3 of the main patent, characterized in that the logic transmitter (203, 204, 300) has circuits (307) which transmit data to the connecting channel (200) of the station groups (217-219, 220-222) formed by the short-distance stations. 304), wherein the circuits (307) have a first means coupled to the microprocessor (315) of each station control module (205 ... 210, 301) via a local link (200, 304) to account for a signal transmitted by the microprocessor (315). 315) is connected to the device combination to generate a preamble of a message 1966994 (200, 304) to the link channel 1966994 (200, 304) of the station groups (217-219, 220-222) formed by the spaced stations, a second means connected to the first means for generating a signal requesting a local in the connecting channel (201, 202, 305) the nature of this message, a third means connected to the first means to take into account those messages t transmitted by the station control module (205 ... 210, 301) to the local link (201, 202, 305) and retransmit them to the link (200, 304) connecting the groups of stations formed by the short-distance stations (217). -219, 220-222), and a combination of a fourth means combined with the first and third means for generating the final word of the messages. 4. A method according to claim 2 and a patent, according to which a logical application (203, 204, 300) is provided (307) for generating information on the channel (200, 304) of the group (217-219), 217-219, the station is connected to the source of the data exchange, the same data is used to detect the information on the channel (200, 304), the account is to be used to detect the data in the information channel (200, 304), and the information is stored correctly. the screen (308) is provided with information from a group of channels (200, 304) for the group (217-219, 220-222) of the station on the main channel, for which the account is located on the local channel (201, 202, 305). ), and on the other hand, an account may be drawn up on the basis of the information provided by the Member State in which the information is provided.