HU181819B - Central control unit for several perifery - Google Patents

Abstract

The system has two identical computers each having a central processing unit, memory unit and input-output unit the last being connected optionally to the homogenous unit of the adjacent computer and to the users. The central processing unit has a control unit, time base unit, surveillance unit, actuation and synchronising unit and consol unit. The last four units are connected to the control unit by two channels, respectively for transmitting input and output information of the control unit as well as by two other channels shared by commands from the control unit and by requests for interruption of processing directed and memorised in the control unit. The control unit is connected to the actuation and synchronising unit across a corresponding channel, the actuation and synchronising unit controlling the synchronising of the two computers.

Description

The present invention relates to a central control unit for a plurality of peripherals comprising two equal central units. In particular, the control unit of the present invention is advantageously used as a component of equipment serving peripherals (e.g., telephone terminals) used in many PCM-type plants by buffer exchange using a buffer network and central control.

SUMMARY OF THE INVENTION The present invention relates to a central control unit having two peer-to-peer central units capable of serving multiple peripherals while being highly functional, high throughput, providing information to or through the peripherals without interruption of traffic. one or more components of one central unit of the central control unit, whether hardware or software, fail, and at the same time disconnects the central unit displaying the failure from the other central unit and peripherals.

Another object of the present invention is to provide a central control unit in which a lack of synchronization between the two central units is detected and, once the synchronization is lost, they can be mutually separated so that the necessary intervention can be performed by a suitable diagnostic program.

The object of the present invention is achieved by providing a central control unit for serving multiple peripherals, connected external units, comprising two 181819 peer central processing units, each central processing unit comprising a central processing unit, a central storage unit and an on / off unit. wherein the on / off unit ₅ is connected to a peripheral at the same element of the other central unit, the central processing unit, the central storage unit and the on / off unit being interconnected with each other, the central processing unit 10 being connected to the central storage unit, and connected to the on / off unit by a first or second channel for transmitting control commands, and a central processing unit for central control switching, time-based generator, monitoring unit, comprising a switching and synchronizing unit and a console, wherein the central control circuit is connected to the other units of the central processing unit by a third or fourth channel for transmitting and receiving input information thereto, and a fifth channel for transmitting control commands therefrom and a central channel for transmitting the control circuit is also bidirectionally connected to the update and synchronization unit via a seventh channel.

Preferably, malfunctioning states in the hardware and software of each central unit are detected by a monitoring unit that emits an outage error message following a program limit and a maximum processing time, connected to the third and fourth channels 30, when processing is interrupted. provided with a monitoring circuit that stores information and transmits to the seventh channel by identifying the time intervals and time classes defined by the interrupt; alarm monitor connected to the monitoring circuit via an eighteenth channel, monitoring and displaying instructions to the third and fourth channels and receiving instructions from the central control circuit by detecting logic-electrical errors of processing, monitoring the status of the central unit according to priority classes depending on said errors equipped with a unit; a control unit connected by a central control circuit connected to the alarm monitoring unit by means of a switch channel, a similar unit of the second central unit and a console, controlled via a switch channel and a synchronization channel to any of the central units comprising the central control unit, depending on the control used in the alarm monitoring unit, either in the central control unit or in the console, it can be connected to the corresponding unit of the other central unit, and is connected to the interface unit in a control circuit for connecting peripherals to the adjacent central unit.

Preferably, an update and synchronization unit is provided for controlling the synchronization of the two central units (and for detecting the lack of synchronization), which is a microprogrammed control unit controlled by the central control circuit, connected to the third channel and the fourth channel. a microprogrammed control unit-controlled storage unit for storing input and output information and control commands, a microprogrammed control unit-controlled storage unit connected to the storage unit and its control unit by means of an additional channel; maintains an interface circuit connected to the control unit, the comparator and the storage unit wherein the microprogrammed control unit, the comparator, the storage unit, and the interface circuitry, by means of their respective central control units, for monitoring interruptions, controlling the flow of information with the update and synchronization unit in the adjacent central unit, and controlling the central control circuit trained to monitor synchronization.

The present invention will now be described in more detail with reference to the accompanying drawing, with reference to the accompanying drawings. In the drawing it is

Figure 1 is a block diagram of a central control unit according to the invention, a

Fig. 2 is a block diagram of the central control circuit of the central control unit according to the invention, a

Fig. 3 is a block diagram of one of the modules forming the on / off unit of the central control unit according to the invention, a

Figure 4 is a block diagram of one of the storage modules forming the central storage unit of the control unit according to the invention,

Figure 5 is a block diagram of the monitoring and alarm monitoring sub-assembly of the central control unit of the present invention, a

Figure 6 is a block diagram of the update and synchronization unit of the central control unit according to the invention,

Figure 7 is a block diagram of a time base generator of the central control unit of the present invention.

The central control unit according to the invention (Fig. 1) consists of central units A and B. The two equal A and B central units are the most important part of the present invention. Each A or B central unit comprises a central processing unit 2, a central storage unit 1 consisting of storage modules la and an on / off unit 3 consisting of modules 3a. These units are interconnected by means of an electrical coupler 4. The function of the electrical interface 4 is to carry information to be exchanged between the units. The instructions exchanged between the central storage unit and the central processing unit 2 are transmitted on the first channel, while the instructions exchanged between the central processing unit 2 and the on / off unit 3 on the second channel 5b.

The central processing unit 2 comprises a central control circuit 7, a time base generator 8, a monitoring unit 9, an update and synchronization unit 10, and a console 11, wherein the central control circuit 7 is connected to said further units via a third channel 12 and a fourth channel 13. The third channel 12 is responsible for transmitting outgoing information from the central control circuit 7, while the fourth channel 13 transmits the information to the input of the central control circuit 7. A fifth channel 21 and a sixth channel 22 are provided between the central control circuit 7 and the other elements of the central processing unit for transmitting control commands from the central control circuit 7 and similar instructions stored therein. As shown in FIG. 1, the update and synchronization unit 10 is also led by a seventh channel 14 to the central control unit 7. It is also apparent from Figure 1 that the time base generator 8, the monitoring unit 9, and the update and synchronization unit 10 are connected to similar parts of the adjacent central unit via channels 8a, 9a, 10a.

Peripherals 6 (e.g., a buffer network) can be connected to the on / off unit 3 in any central unit. When the operation of the central units A and B is normal, they operate synchronously in the central control unit according to the invention, i.e. they perform the same operations at the same time. What is more, the two A and B CPUs send signals to the different peripherals 6, so it is possible for the two A and B CPUs to choose between the two A and B CPUs

-2181819. In this case, the selected A or B central unit will be "subordinate" and the other B or A central unit will be "subordinate".

The individual core units A or B 3 in / out 170 additional units of the central unit 160 are guided bekap- _5-switched switch unit. The functions of the auxiliary central unit 170 are not described herein, since its presence and operation are not the subject of the present invention.

7. The central control circuit arrangement shown in Figure 2 in way of example _1C. This unit comprises interface interfaces 15, 16 microprogrammed control circuits, 17 timing circuits, 18 offset-rotation units, 19 interface interfaces and 20 logic-arithmetic circuits performing interface functions. ₁₅ The unit of one central storage unit, and three on / off assembly in the 16 micro-programmed control circuit, 17 timer switch, 18 shift-rotating unit, the 11 stack and the logical arithmetic circuit 20 ensures proper contact. The fourth channel 13 establishes the connection between the inter- ₂ θ face switch 15, the microprogrammed control circuit 16, the offset-rotary unit 18, the interface switch 19 and the logic-arithmetic circuit 20, while the microprogrammed control circuit 16 With 25 winters, the third channel 12 connects them.

The central control circuit 7 executes the instructions stored in the central storage unit 1 (or in the program stored in the ROM storage of the microprogrammed control circuit 16) in the order determined by the instructions. The central control circuit 7 can change this order according to instructions from the external units. 35

The operation is controlled by the microprogrammed control circuit 16 by sequencing the instructions in a sequence of micro instructions, each of which is via the fifth channel 21 to the functional units forming the central control circuit 7 and the first and second channels 5a and 5b. Contains a series of control signals sent to 1 central storage unit and 3 on / off units. Such microcontrollers are executed simultaneously by said components 45 and circuits.

The microprogrammed control circuit 16 is also capable of reading interruptions and access requests to the central storage unit, taking into account appropriate priorities. For this purpose, for example, a register 50 is provided which can be accessed via the fifth channel 21, the first channel 5a and the second channel 55b respectively by the central control circuit components 7 and other components of the central control unit according to the invention.

The function of the logic-arithmetic coupling 20 is to integrate the contents of the registers therein with the results of the operations 60 according to the micro instructions received, according to the purpose and function of the logical and arithmetic operations.

18 shifts rotating unit, taking into account the corresponding external registers, the contents of the 20 logic-arithmetic circuit registers shifted (indexed) to ⁶⁵ or as needed to rotate left and right, and a function by which, in accordance with the micro instructions from the results into the same registers.

The interface switch 15 for the central storage unit 1 and the on / off unit 3 and the interface switch 19 for the console 11 are responsible for exchanging data and instructions with the external units, taking into account the timing requirements for these units and the micro instructions received.

The function of the timer switching 17 is to schedule the other functional units forming the central control switching 7 through the appropriate eighth channel 23 as needed. The timing may be interrupted by a suitable micro-instruction (frozen cycle) in order to synchronize the central control circuit 7 with other components of the central control unit according to the invention. The eighth channel 23 feeds the other units in addition to the central control circuit components 7 such that the timing signals can be recorded as reference signals.

The on / off unit 3 comprises four modules 3a in the exemplary embodiment shown in FIG. Figure 3 is a block diagram of the on / off unit 3.

Referring to Figure 3, each module 3a contains the following functional units ·. Microprogrammed control circuit 26, channel unit 29 providing direct access to central storage unit 1, interrupt 27! priority switching, priority switching 28, interface switches 25 adapted to said channels, central control switch 7 and central storage unit 1, channel breaker 30, locking unit 32 and interface interfaces 31 (e.g., fifteen).

The interface circuit 25, the microprogrammed control circuit 26, the channel unit 29 and the circuit breaker 30 are interconnected via ninth and tenth channels 33 and 34, respectively. These channels provide unidirectional information transport, the ninth channel 33 from the interface switch 25 and the tenth channel 34 for this switching. A first unidirectional channel 35 establishes a connection between the microprogrammed control switch 26 and the interrupt priority 27, and the second unidirectional channel 36 between the priority switch 28 and the interrupt priority 27. Interconnection between the channel breaker 30, the interface circuits 31 and the closing unit 32 is provided by a bidirectional channel 37.

Modules 3a of the on / off unit 3 provide execution of the input-output instructions, the codes of which are received from the central control circuit 7 and the contents of the registers, status and control registers forming the channel storage units depending on (these are formed in the terminal unit 32 and the interface circuits 31) they exchange data with the peripherals 6, check their correctness, indicate the data exchange3

-3181819

traffic and possible malfunction of the central control switch 7.

In addition, the on / off unit 3 also provides interrupt request requests and direct access to the central repository for so-called DMA operations (first on the second channel 5b and then on the eighth channel 23) for so-called DMA operations already prioritized and coded with the type of operation to be performed. also transmits signaling requests to the central storage unit 1 and to the central control circuit 7.

There are three main ways to transmit information: program control, interrupt, and direct storage access (DMA).

The microprogrammed control circuit 26 provides the execution of input-output operations encoded by the central control circuit 7 through output channels 122, organized into micro instructions, or containing a series of micro instructions that are parallel (via transport channels 38) to and between the output and input modules they enter the functional components that make up the microprogrammed control circuit 26.

The function of the microprogrammed control circuit 26 is to generate a series of micro-instruction sets that are required to transmit the information described above. The microprogrammed control circuit 26 also transmits information (via the second channel 5b) during execution to the central control control unit 7 via the control register and using the status register formed in the module to the necessary locations.

The channel unit 29 provides direct access through the repository and includes two internal storage units, one containing control words for different channels and the other containing a table of mapping between each channel and the peripherals 6. Such an arrangement makes it possible to assign a greater number of peripherals of the same type to the same channel (in this case, the larger number of peripherals of the same type contains a common data buffer which allows the data to be processed in a homogeneous manner).

The channel unit 29 controls the transmission of data to and from the peripherals 6 such that once the transmission has begun, the central control switching operation time will not be consumed by this process.

The interrupt priority setting circuit 27 and the priority setting circuit 28 assigned to the channels perform priority control in the event of concurrent events in the on / off unit 3 due to module 3a. The respective control signals reach the two aforementioned circuits via twelfth and 39th channels, respectively.

In addition to providing a fork junction between one of the ninth and 34th tenths of a one-way channel 33 and one of two-way channels 37, the circuit breaker 30 provides control and regeneration of parity of data passing through it, thereby enabling the lowest level of hierarchical operation to be selected. does not extend to the higher levels.

The locking unit 32 not only provides electrical closure of the bidirectional channel 37, but also controls and regenerates the data transmitted from the interface circuits 31 and the interface circuits 31, thereby ensuring that any malfunction can be isolated at the level of the interface circuits 31 itself. .

The bidirectional interface interfaces 31, together with their respective peripherals 6, are capable of achieving a maximum of fifteen such switches in each module 3a, at least in the embodiment shown herein, and are generally arbitrary in the module 27, In the switch, the priorities assigned to the interruptions received through the 40th and 39th channels or the DMA requirements.

From the update and synchronization unit 10, described below, the signals are received through control channel 51, the switch channel 61a and the synchronization channel 61b provide switching and non-switching information between the parent and slave central units, which will be described on the interface 100. ; 62 channels are provided for transmitting synchronization signals, while a peripheral channel 6a is led to the peripherals 6.

As mentioned above, the central storage unit 1 consists of a storage module 1a (for example, sixteen as in an embodiment of the central control unit according to the invention). Each of the storage modules la is characterized by the block diagram of Figure 4.

The storage module la (Fig. 4) includes interface connections 41, timing units 42, selectors 43, storage units 44, delay units 45 and readout units 46, which are adapted to the central control circuit 7.

The interface circuits 41, the delay unit 45 and the scan unit 46 are interconnected by a thirteen channel 47 which is responsible for transmitting the input data required in the current storage module. The interface circuits 41 and the selection unit 43 are interconnected by a fourteenth channel 48 which is responsible for transmitting the input addresses to the current storage module. Further, between the interface connections 41 and the read-out unit 46, a fifteenth channel 49 is arranged for the purpose of deriving corresponding data from the current storage module la.

Each storage module 1 is capable, in addition to the addressable memory arrangement, of entering information from the central control switch 7 or the on / off unit 3 and returning this information as needed. All these operations are performed by command of the central control switch 7 when the appropriate controls are transmitted by the first channel 5 and the data and the corresponding addresses are received from the on / off unit. The timer unit 42 converts the controls from the central control circuit 7 via the first channel 5a into timer control signals which pass through the transmission channel 50 to other functional units forming the storage module la.

The selection unit 43 converts the address of the memory arrangement created by the transmission operation into an appropriate signal pair (referred to in the literature as Lx and Ly) and this pair is placed in the appropriate area or level of the central storage unit 1 to select the cores. In addition, the selector 43 is capable of determining and comparing an address based on such signals. If no identity is found, the selection unit 43 announces an interrupt request in the form of an appropriate signal (external event), which is received through channel 121 of the twenty-fourth.

The storage element 44 comprises magnetic cores and decoding circuits which form storage cores.

The delay unit 45 and the scan unit 46 control the delay coils 44a and the scan coils 44b according to the transmitted address and data.

The interface switch 41 is adapted to the central control switch 7 and the on / off unit 3 to decode the address of the central storage unit 1 for transmission. Such a central storage unit 1 is determined by the transmission operation, checks the parity of the addresses and the parity of the data, and then processes the controls replaced by the central control switch 7 using the first channel 5a. If improper phenomena are detected, the interface switch 41 generates interrupts in the form of external events, which are transmitted to the central control switch 7 via appropriate signals transmitted through the first channel 5a.

The monitoring and alarm monitoring unit 9 (Fig. 5) comprises 54 alarm monitoring units, 65 monitoring circuits, control switches 66 and switching units 67, wherein the control circuit 66 interconnecting the upper A or B and the subordinate B or A and the adjacent A or B The switching unit 67, which establishes an interface connection with the corresponding elements of the monitoring unit 9 in the central unit, forms 150 parts. The alarm monitoring unit 64 and the monitoring circuit 65 are connected to the fourth channel 13 and, together with the control circuit 66, are connected to the third channel 12 as well. The alarm monitoring unit 64 is controlled by the monitoring circuit 65 and the control circuit 66 via the microprogrammed control circuit 16 via the fifth channel 21, while the alarm monitoring unit 64 and the monitoring circuit 65 is also provided by the timing signals transmitted through the sixth channel 22.

The monitoring circuit 65 is responsible for following program limits and processing maximum time limits and generating an output error signal (70 in eighteenth channels) if it is unable to observe these limits. If the program has to be interrupted spontaneously, for the purpose of executing a subroutine, or for other reasons, the time counting is interrupted by the monitoring switch 65 and the time elapsed is recorded in the central storage unit 1 and is ready to be restarted.

The alarm monitoring unit 64 is connected to the eighteenth channel 70 and the 63 monitoring units. The function of the latter is to detect logic-electric anomalies in the work of the central unit 1 and to write instructions from the central control switching 7 via the third channel 12, to indicate logic-electrical-functional anomalies of the central unit 1 and to execute diagnostic programs according to the priority classes depending on the anomalies mentioned. The output signals from the alarm monitoring unit 64 are transmitted as an external event through the eighth channel 23 to the central control circuit 7.

The control signals from the central control circuit 7 (forcing the parent A or B to replace by substitution) and the demand signal from the alarm monitoring unit 64 for forcing the sub B or A to be transmitted through the switch channel 81 (and these signals through the eighteenth due to software errors reported by channel 150 or hardware failures detected by control units 63), and controls from 9 monitoring units (and 69 through 17th channel) of the other 150 units, where 68th 16th channels are present in adjacent A or B for receiving similar requests transmitted by the monitoring unit 9 of the central unit, the control circuit 66 coupling the parent unit A or B to the slave generates the corresponding override signals or their negatives using ramkörök. Said signals pass through the switching channel 61a and the synchronization channel 61b and are distributed by the on / off unit 3 to the respective peripherals 6 and at the same time provide the latter with the possibility to select the subordinate units 150. This selection is provided by the non-coupling elements of the coupling unit 100, which is not within the scope of the present invention as it is known per se.

In the monitoring unit 9, the switching unit 67 is an interface switching arrangement which is matched to the unit of the adjacent central unit A or B which performs the same function. The two switching units 67 are connected to each other by a coupling channel 9a. The switching unit 67 is responsible for exchanging controls and information between the parent and subordinate units with a similar switching unit 67 in the adjacent central unit A or B, both of which perform interface functions.

The update and synchronization unit 10 (FIG. 6) includes 52 microprogrammed control units, 53 comparators, 54 storage units and 55 interface circuits. The latter is responsible for providing the matching 10 update and synchronization units in the adjacent central unit A or B. The storage unit 54 stores the input and output information and controls for the update and synchronization unit 10.

The function of the microprogrammed control unit 52 is to generate control signals (microcontrollers) transmitted through the control channel 51 which, on the one hand, are connected to the comparator 53, the storage unit 54, the interfa5

-511 ce switching, on the other hand, to the on / off unit 3 (Fig. 3), the monitoring unit 9 (Fig. 5) and the time base generator 8 (described below), and to the central control circuit 7 (Fig. 2). come. ⁵

The microprogrammed control unit 52 is controlled via the fifth channel 21 from the central control circuit 7 and via the 20th channel 59 from the update and synchronization units 10 of the adjacent central unit A or B. 52 micro ¹⁰ programmed controller general micro-instructions which are applied to the A or B to CPU hereinafter units over the control channel 51, to which the ten updating and synchronization unit belongs, and supplied to the neighbors ¹⁵ DOS or B central unit 10 update and synchronization units. These micro instructions serve as synchronizing signals.

Interruption is another function of the microprogrammed control unit 52! generating requests (23 eighth channel in the form of external events transmitted over ²⁰ nonane), which then become the seven central control unit and each of the connectors 10 updating and synchronization unit, and the comparison to malfunction, as well as the operations at accompanying ²⁵ it is not appropriate indicates synchronization.

In the illustrated circuit of the update and synchronization unit 10 (Fig. 6), the microprogrammed control unit 52 and the storage unit 54 are connected to the third channel 12, while the storage ³ θ unit is connected to the fourth channel 13. the interface link 55 is interconnected by a nineteenth channel 57 which also transmits the outgoing data and addresses 35 of the update and synchronization unit 10. The nineteenth channel 57 is further connected to the inlet interface 55 with the coupling channel 10a through which the controls and data may be exchanged with the update and synchronization units 10 in the adjacent central unit A or B. The input addresses and data of the update and synchronization unit 10 pass through the coupling channel 10a to the interface circuit 55 which feeds the comparator 53 and the storage unit 45 via the seventh channel 14.

Under synchronized operating conditions, the comparator 53 is arranged to check whether there is an equal relationship between the central units A and B constituting the control unit according to the invention. The data to be exchanged between the central control circuit 7 between the on / off unit 3 and the central storage unit 1 and address traffic. If equivalence does not exist (referred to in the literature as mismatching), the inter-55 face-switching error 55 generates, via the microprogrammed control unit 52, as an external event, as mentioned above, the central control unit via the eighth channel 23. The storage unit 54 serves to store input and output information sent to the update and synchronization unit 60 and can generate states to be sent to the central control circuit 7. This unit can store the control signals 65 from the central control circuit 7, as well as the data and addresses exchanged between the on / off unit 3 and the central storage unit 211, and is capable of storing these data via the 10 centralization and synchronization units. In addition, the data and addresses are sent to a comparator 53 in the A or B central unit, where they can be compared with the data and addresses from the neighboring A or B central unit.

The interface circuit 55, which is associated with the update and synchronization units 10 of the adjacent central unit A or B, serves to send data and control addresses of the same update and synchronization unit 10 to the adjacent central unit A or B and the resulting can accommodate data and control addresses.

Accordingly, the update and synchronization unit 10 cooperates with a similar subset of the adjacent central unit A or B.

Synchronization between the two central units A and B is ensured and controlled by said units. In addition, they allow the non-functioning A or B central units to be updated and reset synchronization, and to verify the parallel operation of the two A and B central units in synchronized state. The latter is provided by the control addresses and data passing through the central storage unit 1, the central control circuit Ί and the on / off unit 3. The synchronization of the two central units A and B according to the invention is carried out as follows.

Suppose that Central Unit A provides the elementary step (address generation, data generation). When the central control switch 7 receives the address, it transmits it via the third channel 12 to the storage unit 54 and simultaneously informs the microprogrammed control unit 52 of the transmission of the address via the fifth channel 21. The microprogrammed control unit 52 controls the storage unit 54 via the control channel 51, which transmits the address to the nineteenth channel 57 (consequently, the address is also transmitted to the updating and synchronizing units 10 of the adjacent central unit B) and the address accordingly to the comparator 53. into their respective registers.

The microprogrammed control unit 52 informs the adjacent update and synchronization unit 10 via the control channel 51 that it has sent the address. In parallel, though not necessarily at the same time, before or after the address is transmitted to the adjacent central unit B, the same central unit A will provide this address (provided that the operation of the current channel 10 is correct). sends it to the update and synchronization unit. The input address is updated to the comparator 53. The arrival of the address to the microprogrammed control unit 52 is provided by the neighboring central unit B via micro instructions transmitted through the 20th channel 59. This allows the microprogramme of the microprogrammed control unit 52 to be executed, resulting in a

The -613 comparator develops an area that is capable of performing the comparison operation.

In other words, comparator 53 checks whether the address generated by the central unit A matches that generated by the central unit B. If the result of the comparison indicates an error, a separate procedure is initiated (due to the misalignment, both A and B central units request interruption by starting a special diagnostic program). In the case of a positive result of the comparison, the microprogram of the microprogrammed control unit 52 can be executed and thus the central control circuit 7 may send appropriate data to said address. The central control circuit Ί can then move to a new step if the comparison with the data in the previous step gives a positive result (this comparison is made by comparator 53). Accordingly, even if the execution of a single step in the A and B CPUs takes different time, the start of the new step is the same for the two A and B CPUs, since these two A and B CPUs perform comparisons simultaneously in 53 comparators. depends on operations.

The output information of the central control unit 7 is transmitted through the fourth channel 13 and stored in a suitable register formed in the storage unit 54. In addition, the seventh channel 14 serves to perform update operations on the central unit A by the neighboring central unit B.

As mentioned above, the output and input addresses and data transmitted on the respective nineteenth channel 57 and channel 56 provide control of the exchange between identical update and synchronization units 10 of the central units A and B via channel 24. The channel 56, the nineteenth channel 57 and the 28th channel 58 are coupled to the interface channel 10a between the two update and synchronization units 10.

The time base generating unit 8 (FIG. 7) comprises a control unit 71, a clock signal generator 72, a time base generating unit 73 and an interface circuit 74 which interfaces with the time base generator 8 of the adjacent central unit A or B.

The beat generator 72 (Fig. 7) is directed to the third channel 12, while the control unit 71 is directed to the fourth channel 13. The control unit 71 is connected to the fifth channel 21, the sixth channel 22 and the control channel 51, while its output is directed to the eighth channel 23. The output control signals of the control unit 71 are transmitted to the interface circuit 74 via the twenty-third channel 77b, while the input control signals from the interface circuit 74 are transmitted by the twenty-second channel 77a. The purpose of the time base generator 8 is to generate the most important time units required in the operating system providing the telecommunication and charging functions provided by the central control circuitry of the present invention.

The control unit 71 operates on the basis of information received from the beat generator 72 and the same unit formed in the adjacent central unit A or B via the interface switch 74. It generates interrupt requests, which are transmitted to the central control circuit 7 in the form of external events. The demands generated by the control unit 71 appear synchronously in the two central units A and B of the central control unit 7 when there is mutual synchronization between the latter.

The clock signal generator 72 (to which the sixth channels 22 and the eighth channels 23 are connected) provides time counting based on the control signals received from the central control circuit 7 and informs the control circuit 71 of the completion of the corresponding periods. In addition, the time counting is performed in such a way that it is independent of the time used by the central control switch 7 and allows the interruption requests to be received in the form of external events.

The time base generating unit 73 generates the time units according to the required times. This is provided by a separately controlled high-stability oscillator.

The interface circuit 74, together with the time base generator 8 in the adjacent central unit A or B, exchanges controls via channel 8a with an identical unit of the adjacent central unit A or B. Accordingly, the central control unit according to the invention is structured in such a way that the exchange of information between the peripherals 6, e.g.

Under normal operating conditions, the two control units A and B operate synchronously and perform the same operations in parallel. The two central units A and B send signals to the various peripherals 6 which allow the users to override a specific part.

In the event of a malfunction, where one of the A or B central units is malfunctioning, the two A and B central units operate independently of each other, whereupon the properly functioning A or B central unit performs the function of the parent unit, checking the peripherals 6 a malfunctioning (subordinate) B or A central unit runs diagnostic programs and interventions to repair it. This is very important even if one of the peripheral units A or B that monitors the peripherals 6 fails.

The exemplary embodiment of the central control unit according to the invention described herein is only one embodiment, and the block diagrams described above represent a possible embodiment of the essence of the invention as claimed.

Patent claims:

Claims (7)

Patent claims: A central control unit for a plurality of peripherals comprising two equal central units, characterized in that each central unit (A and B) is provided with a central processing unit (2), a central storage unit (1) and an on / off unit (3). comprising, where the on / off unit (3) can be connected to a peripheral (6) in place of the same element of the other central unit (A or B), the central processing unit (2), the central storage unit (1) and the on / off unit ( 3) with an electrical interface (4) which transmits information between them -7181819 15 connected, the central processing unit (2) is connected to the central storage unit (1) and the on / off unit (3) via first and second channels (5a, 5b) for transmitting control instructions, and the central processing unit (2) comprising a control circuit (7), a time base generator (8), a monitoring unit (9), an update and synchronization unit (10) and a console (11), wherein the central control circuit (7) is third to the other units of the central processing unit (2); connected to a fourth channel (12, 13) and a fifth channel (21) and a sixth channel (22) for transmitting interrupt requests, and the central control circuit (7) is bidirectionally connected via the seventh channel (14) to the update and synchronization unit (10). An embodiment of the central control unit according to claim 1, characterized in that each monitoring unit (9) is provided with a monitoring circuit (65) connected to the third and fourth channels (12, 13) and connected to the seventh channel (14); an alarm monitoring unit (64) connected to the monitoring circuit (65) via an eighteenth channel (70), to which control units (63) are connected; a component (150) connected to the central control circuit (7) connected to the alarm monitoring unit (64) by means of a switch channel (81), a similar unit of the second central unit (A or B) and a console (11); 61a) and via a synchronization channel (61b) to any of the central units (A, B) forming the central control unit via the interface unit (100) connecting the peripherals (6), wherein the component (150) in the alarm monitoring unit (64) depending on the control used in the control unit (7) or the console (11), it is connected to the corresponding unit of the other central unit (A or B). The central control unit according to claim 1, characterized in that each update and synchronization unit (10) is a microprogrammed control unit (52) connected to the central control circuit (7), both for the third channel (12) and the fourth channel (12). 13) a connected comparator (53) connected to the microprogrammed control unit (52), the comparator (53) connected to the microprogrammed control unit (52) and the storage unit (54) or its control element, the adjacent central unit The A / B includes an interface circuit (55) adapted to the same circuit in the update and synchronization unit (10), the microprogrammed control unit (52), the comparator line (53) and the storage unit (54). 4. The central control unit according to any one of claims 1 to 3, characterized in that the central control circuit (7) is connected to an output eighth channel (23) by a microprogrammed control circuit (16), the microprogrammed control circuit (16) on the sixth channel (22) and the fifth channel (21). a timing circuit (17) coupled to the third and fourth channels (12, 13) and a logic-arithmetic circuit (20) connected to the fifth and sixth channels (21, 22), to the third and fourth channels (12, 13) and a shifting unit (18) connected to the fifth and sixth channels (22, 23), to the third and fourth channels (12, 13) and to the fifth and sixth channels (22, 23), and on two separate channels an interface switch (19) connected to a console (11) and an electrical interface to the central storage unit (1) and the on / off unit (3) (4) connected to the first, second, third, fourth, fifth, sixth, seventh and eighth channels (5a, 5b, 12, 13, 22, 23, 14) and control channel (51) includes an interface circuit (15). 5. The central control unit according to any one of claims 1 to 3, characterized in that the central storage unit (1) comprises a plurality of storage modules (1a), each of which is connected to the central control circuit (7) and the on / off unit (3) by an electrical coupler (4). an interface circuit (41) coupled to the central control circuit (7), also via a first channel (5a), a timing unit (42) controlled by the central control circuit (7) and connected via a transmission channel (50), and a selection unit (43) connected to a storage element (44) by at least two connection lines (43a) connected to the interface circuit (41) via a fourteenth channel (48), connected to the storage element (44) by the transmission channel (50) and ) via a delay coil (44a) for interface switching (41) to the current storage module (la) a connector connected via a fifteenth channel (49) and a thirteenth channel (47), a delay unit (45) and a timing unit (42) connected via a transmission channel (50), a reading coil (44b) and an interface circuit (41). ) comprises a reading unit (46) coupled to the fifteenth channel (49). An embodiment of the central control unit according to any one of claims 1-5, characterized in that the on / off unit (3) consists of modules (3a) and each module (3a) for the central storage unit (1) and the central control circuit. (7) a one-way ninth and tenth channels (33, 34), a transport channel (38) connected to the electrical coupler (4) and the first channel (5b), and a sixth output channel (23), a control channel (51), a switch channel ( 61a) and an interface circuit (25) connected to the synchronization channel (61b) and an output channel (122), a microprogrammed control circuit (26) connected to the tenth channel (34) and a transport channel, and a priority setting circuit 27 connected to the twelfth channel (40). , connected to the ninth and tenth channels (33, 34), the transport channel (38) and the second one-way channel (36) a node unit (29), a priority setting circuit (28) for controlling the access priorities of the channels to the central storage unit (1), and the ninth and second events connected to the transport channel (38) identified by the signals received from the eleventh channel (39) in the modules (3a); bidirectional connected to the tenth channel (33, 34) and the transport channel (38) A channel breaker (30) connected to channel (8181819), a bidirectional channel (37) and a conveyor channel (38) connected to its respective peripherals (6), and a control channel (51) and a switch channel (shoulder), the synchronizer - output channels (6a) led to 5 channels (61b) and output peripheral channels (6a), respectively, connected to the respective peripherals (6), and to the coupling unit (100) via the synchronization channel (61b) and the switch channel (39b). ) Comprising 10 connected interface circuits (31) and a locking unit (32), wherein the microprogrammed control circuit (26) is connected to the interface circuit (25) via an inlet conveyor and to an output of the interrupt priority setting circuit (27) 15, the link unit (29) is connected to the prioritization switch (28) by the second unidirectional channel (36) and the channel breaker (30) is connected to the closing unit (32) via the bidirectional channel (37). 7. Central control unit according to any one of claims 1 to 3, characterized in that the time base generator (8) is a time base generator (73), preferably an oscillator, with this channel (75) and the third, fifth and sixth channels (12, 21, 22). an interconnected beat generator (72), an interface switch (74) coupled to the same type of units in the neighbor processor time base generator, the fourth, fifth, sixth, eighth channels (13, 21, 22, 23) and the control channel (51). and a control unit (71) coupled to the interface switching (74) for the twenty-second (77a) and the twenty-third (77b) channels connected to the interface signal generator (72). Figure 3, Figure 7 Responsible for publishing: Director of Economic and Legal Publishing 84.4447 - Zrínyi Printing House, Budapest