DE2428127C2 - Circuit arrangement for a telecommunications system controlled using stored control functions - Google Patents

Description

The invention relates to a circuit arrangement for using stored control functions Controlled telecommunications system, in which Tesi points, control points and via a data busbar interconnected registers that store data are controlled with the aid of access signals, generated on the basis of control instructions identified by means of instruction address numbers being carried out a control function consisting of a number of consecutively processed Control instructions exists, with the help of a start instruction address number is set in motion, which is assigned to the first control instruction of the control function and which is stored in one of the data-storing registers of the telecommunications system.

Known telephone systems that are centrally controlled using a stored program exist, as /. B. in the journal »Japan Telecommunications Review-Vol. 13: No. 3 and 4 and Vol. 14: No. 1 «is published under the heading» D-10 Electronic Switching System «, from the actual telephone system and from a data processing system. The data processing system is formed from a memory part and a processor. The memory part comprises a program memory, a data memory and registers which form a switching unit which stores control instructions generated by the data processing system and transmits them to the telecommunications system or stores operating status information generated in the telecommunications system and sends them to the data processing system. The processor comprises a number of registers storing data, an arithmetic unit and a control unit which contains a microinstruction generalor with a microprogram memory and controls the processing of the instructions stored in the program memory.

However, in such a data transfer

telecommunication system encompassing work system not only so-called effective instructions that the Control of the functional units of the telecommunications system serve, but also very many so-called ineffective ones Instructions used to control the data processing system. Furthermore if the data processing system requires the use of its own programming language, in which a normal telephone technician can hardly use the original telecommunications control functions can recognize. The result will eventually be quite a mess and Very complex system received, its commissioning, maintenance and expansion at great expense connected is.

The proposed invention is based on a conventional self-dial telephone system, which are controlled with the help of control devices such as identification seekers, signal distributors or markers is, and it is the object of the invention to provide a using stored control instructions managed system that does not require the use of a programming language requires and in which the mentioned ineffective control instructions are largely avoided. This is made more simple by the introduction of data processing technology Aids in the functional units of the telecommunications system achieved without it the conventional tried and tested control principles as a result of a concentration of the system control by means of a data processing system must be changed. The resources mentioned include Register for storing data and logic arrangements controlled with the help of time-phase signals, which access signals for accessing the said via a data bus with each other connected register and the control and test points of the telecommunications system.

The main characteristics of the invention are that in the mentioned data storing Register a number of instruction registers each containing a control instruction and at least one Instruction address register for storing the above instruction address numbers are received, which instruction address register is provided with an incremental input, its activation brings about an increase in the stored address numbers by one unit, and that the telecommunications system at least one time phase generator for generating time phase signals representing the processing period of each control instruction into time phases, and an access signal generator which of the time phase signals, the instruction address numbers and the control instructions are controlled, at the outputs of which said access signals are generated and the first one Logic arrangement which contains the contents of the instruction address register during a time phase at the beginning decoded in each processing period and which are stored in the instruction register assigned to the respective address number accesses a second logic array during the remaining time phases of the processing period Activation of the mentioned step-up input during a time phase in the middle of each Processing period, a third logic arrangement that controls the transfer of data from one of the aforementioned registers to the instruction address register only during a time period at the end of the corresponding processing periods allows, and contains a fourth logic arrangement with an AND function, whose inputs during the time phase at the end of such Processing period which results in an access signal for accessing one of the test points mentioned, and are activated by a binary state of this test point and their output with the aforementioned incremental input of the instruction address register is connected.

Advantageous further developments of the invention are described in the subclaims. In order to make such processing periods, which result in an access signal for accessing one of the control points mentioned, independent of the time phase signals of the time phase generator with regard to their duration, one of the test points is accessed together with the control point, the time phase generator is provided with a signal extension input, the activation of which is an extension the straight ausgesen ^ao Deten time phase signal causes, and the telecommunications system includes a fifth logic means having inputs results during such a processing period, the access signals for accessing one of said control points UNII one of said test ^a 5 dots, of at least one of these access signals to and from a binary state of this test point are activated and the output of which is connected to the aforementioned signal extension input of the time phase generator.

When the instruction register mentioned in the main claim is configured as one with an address decoder and a memory provided with a read register, the read register is used for decoding respectively for transferring the instruction stored in it with the access signal generator or connected to the data bus and said first logic arrangement of the access signal generator is designed as a gate arrangement that the instruction address register only during which connects the time phases at the beginning of the processing periods with the address decoder of the memory. The invention is described in more detail below with reference to the drawings. Fig. 1 shows a basic diagram one controlled according to the invention using stored control functions Telecommunication system and Fig. 2 shows the implementation of a control function using the example of a route selection Marker of a telecommunications system according to the invention.

In Fig. 1, a telephone system EX is by means of its control points OP, test pointers. TP and data storing registers REG indicated. One end of a relay winding is mentioned as an example of a control point. When a voltage is supplied to this end of the winding, the relay picks up, which is equivalent to a control process in the telecommunications system. To adapt the telephone system to the high data processing speeds, for example, a bistable multivibrator can be used, the output of which is connected to the end of the winding and the input of which in this case represents the control point. An example of a test point is a subscriber line whose loop resistance can be either high or low resistance. When using bistable multivibrators, their output sides are suitable as test points. The inclusion of registers that store data in the functional units of the telephone system enables in many cases

The saving of relay sets. For example, the operating status of a group selector in the telephone system can be displayed very advantageously by means of a register R1, the binary content of each bit position of the register indicating the occupied or free status of an associated selector position. The introduction of further registers R2, for example to feed the mentioned operating status of the group selector to another functional unit of the telecommunications system, for example a marker, for further evaluation, will not cause any difficulties for a normal telephone technician, even if he is not a data processing specialist. In Fig. 1 a data busbar DB is shown, which connects all registers with each other, however, the connections of the individual bit positions in the status registers Ri or the connections of the control and test points OP, TP to the actual telephone system of the system are not shown because these connections are conditioned by the individual embodiment of the telephone system and are not needed for an understanding of the present invention.

A prerequisite for controlling the system using stored control functions is that each of the named control and test points and each of the named registers can be accessed by means of an assigned access signal which is fed to an associated access gate. These access signals are sent out according to FIG. 1 by an access signal generator ASG , it being assumed that the control points are supplied with a positive voltage necessary for control with the aid of the access gates, that the respective binary state of the accessed test point is fed to a common output O of the telecommunications system and that a distinction is made with regard to the access signals for the registers whether the access signal controls the data reception or the data transmission of the accessed register.

The aforementioned control using stored control functions is also achieved through the use of a number of instruction registers IR and at least one instruction address register IAR with associated access gates. Each instruction register contains a control instruction in binary coded form, whereby in principle three different types of instructions, test instructions, control instructions and transport instructions are sufficient to control systems of any complexity.

The purpose of a test instruction is to access a test point in order to carry out the above-mentioned transfer of the binary state to the common output O. This means that a test instruction contains the address of the test point whose state is to be tested.

The purpose of a control instruction is to access a control point or to control a control point, from which it follows that such an instruction contains at least the address of the relevant control point. In a modification of the control instructions described below, these also contain the address of a test point. The modification consists in applying voltage to the relevant control point until the relevant test point has a certain binary state.

The purpose of a transport instruction is to transport data from one register to another via the data bus and via the associated access gate, from which it follows that a transport instruction normally contains the address of the sending S and the address of the receiving register. There are registers R2, which are accessed on the basis of one instruction for receiving and on the basis of another instruction for sending data. If, however, a transport instruction addresses one of the registers Rl / ur storage of the operating states, this register is only ever accessed for sending data to the data bus. Receipt of data from the data bus is also impossible with the instruction registers because the instructions stored there are fixed values. For a data transport from one of the instruction registers IR to one of the registers REG of the telecommunications system or to the instruction address register IAR, as a result of the circumstance. that the Instruktionsregiao ster is itself the sending register, uses a transport instruction which contains both the data to be transported d and the address a of the receiving register. The fact that we are dealing with data transports means that the instruction registers and the instruction address register with the associated access gates are also connected to the aforementioned data busbar.

Said access signal generator 4SG be α occurring in the various types of instructions addresses referred supplied rather wel the addresses decoded, and generates the above-mentioned Zugriffsignalc as. In addition to the instruction registers, the instruction address register also differs from the other F registers of the telecommunications system in that its contents are not only fed to the data bus for the purpose of transport to another register, but above all to the access signal generator. The instruction address register is used exclusively for storing an instruction address number which is assigned to one of the instruction registers. The access signal generator decodes the instruction address numbers and thereby generates access signals asi for the address parts a stored in the instruction registers . Furthermore, the instruction address register differs from all other registers in that it is provided with an incremental input ST , the activation of which has the effect that the stored address number is increased by a binary counter.

Each instruction is processed step by step, the division of a processing period into at least three time phases, a start, a middle and an end phase, is controlled by means of a phase generator PC SS, which sends corresponding time phase signals ΦΙ, Φ2, Φ3 to the access signal generator - The Access signal generator contains a first logic arrangement Ll which decodes the content of the instruction address register during the initial phases and sends out the access signal asi for the instruction register assigned to the respective instruction address number during the rest of the time phase. In this way, the address content α of the accessed Ir stniktionsregisters for ZugriffsignalgeneraU • 3 during this remaining time phases of the corresponding processing period available.

The access signals as for the activation of the control and test points: e and for the connection all

Register including the induction register and of the instruction address register to the data bus, are of further logic arrangements of the access signal generator during suitable time phases generated. Since transient processes are to be expected, it is advantageous to access the data receiving register only to be accessed in the final phases. On the other hand, registers that are accessed via the data busbar c Send data and access control and control points as soon as possible.

The mode of operation of the access signal generator will be described further below with reference to the embodiment shown in FIG will be described in more detail.

In the schematic diagram of Hg. 1, the conversion of the addresses α received from the instruction registers into the access signals as is only indicated by a dashed line for the sake of clarity. In the above-mentioned first logic arrangement IA , the time phase control is indicated with the aid of a gate G1 activated during the initial phases, via which the instruction address numbers are written to an intermediate register /? 3, the output of which is connected to an address decoder DEC1. Representative for all other registers, the time phase control with the help of a logic arrangement Li is indicated for the instruction address register, which is activated for sending data to the busbar during the middle and end phases and for receiving data from the busbar during the end phases.

The execution of a control function, which consists of a number of control instructions, takes place in Principle as follows:

If nothing has to be changed on the operating state of the telecommunications system, the phase generator PG sends no time phase signals and the Instruktionsadreßregister IAR includes the address number of a transport instruction, a so-called Einleitungsinslruktion that as a transmitter address, the address of a specific register of the telecommunication system, the so-called start register SR, and as a receiver address, the Contains instruction address register address. To understand the present invention, it is not necessary to go into greater detail on how an instruction address number is written to the start register with which the first control instruction of the control function now to be performed is to be accessed. You can provide several phase generators with associated instruction registers, instruction address registers and access signal generators if all control functions occurring in a telecommunications system are processed according to the invention . Each phase generator is then assigned the processing of certain control functions, which relate to a defined number of control and test points, although a suitable use of registers enables the phase generators to work together. In such cases, the start register that cooperates with a first phase generator also belongs to the registers that cooperate with a second phase generator. When the second phase generator has completed a control function, for example with a data transport to this start register, a control function is requested in this way, the processing of which is controlled by the first phase generator. On the other hand, there is in every telecommunications system, regardless of whether all control functions or only some of them are processed using data processing tools, at least one control function, the processing of which is requested by the change in an operating state of the telecommunications system. If, for example, a telephone subscriber changes the loop status of his connection line, an instruction address number is written into a start register with which the first Stev.crinstruction in the control function for searching all connection lines is to be accessed.

An address number stored in the start register SR triggers the start of the phase generator PG .

• 5 During the initial phase of the first processing period, reference is made to the introductory instruction mentioned above accessed, whereby a transport of the address number stored in the start register via the Data bus to the instruction address register

^ao IAR is triggered, where it is written during the final phase of this first processing period. This means that the first control instruction of the control function to be carried out is accessed at the beginning of the next processing period

«5 will. It is assumed that this first control instruction applies to the control of a control point which is accordingly accessed and activated by the access signal generator as described above. The access of the second control instruction in the control function initiated in this way is obtained with the aid of the above-mentioned incremental input ST at the instruction address register IAR , which is activated by means of an OR gate L1 during the middle phase of each processing period. In this way, instruction address numbers increased by one counting unit and thus access signals asi for control instructions to be processed one after the other are obtained in successive processing periods. Even during the middle phase in the machining

«° period for the mentioned introductory instruction such an increase in the address number occurred, but it was canceled when the first control instruction was received assigned instruction address number during the relevant end phase.

«5 ben. In principle, the Adreßnummererhöhung is canceled when accessed as a result of a transport instruction to the Instruktionsadreßregister as a receiving register.

This property comes into play when

5 »in connection with a test instruction, the further execution of the control function depends on the binary state of the accessed test point. The above-mentioned output O of the Ferameldcantagt common for all test points is fet with a -

SS connected to an AND gate LA , which is activated during the final phases and whose output is connected to the stepping input ST of the instruction address register via the OR gate Ll. In this way it depends on the binary state of the test point

tes whether the content of the instruction address register is received during the relevant processing period or is increased by one counting unit twice. The address number, increased by one counter compared to the AdrcB number of a test instruction, is often a

fc assigned to a transport instruction, on the basis of which a new instruction address number via the Data busbar to the instrukrJonsadreBreefter is transported. One achieves that after a test

609627/321

9 10

Instructions are available with one of two possible instructing instruction address numbers

is continued. stands.

If the actual control function of the communications standards The Zugriflsignalgenerator .4.SO umlaßt dean position to Ut is performed. with the help of the normal coding of the code numbers, an increase in the operational deck address number during the middle phases 5 of the DECl. which has access to a transport instruction at the operational part of the reading room, is connected to (»round sters RR . and for decoding dr which the instruction address register receives an instruction address number during the addresses of the register, test and control points of the end phase, telecommunication system has a transmitter and a receiver - which is one counting unit smaller than that of the above-mentioned one control and one test decoder DEC'S bis called introductory ^{instruction assigned address 10} D £ ('6. which is numbered via associated activation gates and that of a control instruction called the time phase generator PCi Operation deco stop instruction. By means of the slope indexer and instructions to the variable part of the read register, a control lock is accessed during the end phase the one with the address number phase generator PG stops ¹ S 22 in the read-only memory ROM is a η bit positions during the middle phase in the Insiruktionsadreßicgi- comprehensive variable part half of the send addresses au ster the address number assigned to the introductory instruction and the other address number also containing // positions. Half assigned to the reception addresses ra. With the help of FIG. 2, the example of the introduction of the code number 5 means that both the marker M of a self-dial telephone system * ° the instruction address register and the routing register carried out below include some modi-ter 2 / i bit positions and that it is possible fications or further developments dtr bis- is, control functions with a total of 2 ^: "Control instructors explained in principle the control. When using a sufficiently large fixed marker part, two registers / 74 and K5, an im value memory and a data transpulse generator CL, a computer C, some gate and ^a 5 porte shown sieuern the cooperation between 2 "registers of the telecommunications system to shift register SHR. The variable parts of test instructions are explained below. The control register SR, which has the code number .V, for example the one with the address instruction address register IAR and the phase number 23 in the read-only memory, contains only the rator FG are already described with reference to FIG. Test point addresses ta, so that the existing Bitpo-An which 3o are instead of the data bus in Figure 2 sitions in and of itself from accessing. ^2: allow th compounds for the occurring DA "Testpunkeinzelnen If it is assumed that no shown tentransporte because it is thus easier., the control point is longer than clarify up /.um end of diesbezügli-carrying activated the routing control function to ER- chen processing period. In place of the Instruktionsregistcr is a need with the variable parts of the Steuerinstrukeinem address decoder decl and are Read regions with the code number 2. For example, the read-only memory ROM equipped with the most RR requires address number 25 in the read-only memory only for the control point addresses <> a and it can also be used Access to 2 'control points depends on the form of coding that is used for the fixed value case shown in Fa 2 In the th embodiment, it is possible to store stored and immediately / intangible 4o, the storage periods of the Stcu control instructions is selected. The instructions, independent of the time phases, consist of an operation signal and a variable signal of the phase in question. This becomes part of op and να. The variable part contains the addresses achieved by the phase generator PG ^with the register to be controlled. Test and control points are given away to a signal requesting input / s' /: / .. or the data which are to be transported to one of the 45 and that one variable part of such control registers. As constructions already made with the code 2 ζ Β that of the basic description is clear, comes with the address number "> (in read-only memory, the ven the introduction declared difference between more effective control point address na by the control decoder and ineffective instructions mainly w decoded DEC'S _u d., and the other variable half through the various transport instructions for the address of ta a eeeieneten test point contains expression. Those instructions which tionsadreßregister either the Instruk- which address decoding of f test decoder 'DECB to the data receiving and which test point Toggle its binary or data ends access, are ineffective because they change when the control process is finished. An active right to actually control the fourth of said signal extension input. Telecommunication system assign the operating parts 55 which an extension of the! m phase generator, this ineffective transp Local instructions are in the straight line aiiso <»<: _P n, i _e r -7 ·. u · .r 1 Fnlec embodiment shown inFig 2 special OPE L ^ ^ irdmfne XZL f _L l wä2 raüonskodenummern supplied arrange. In addition to the code, the middle phase of the relevant control structure numbers 1, 2 or 3 for the effective transport, initiated " _n H ™ 1, ^DLirenenaen ^ yourin. Control and test instructions are the code numbers 60 BinfrSSSl "κ ^g ff, ^uhechter f ^tcn -J ^ mer4 or 5 for the data transfer _SP location from the start register S? N has We ^ H ^fa " ^S ™ ^g "f ^ne ^ ^T % SR or from the variable part of the read register RR for ££ _e L λi ^3rt ' ^{g modlh7icrtc} , ^S instruction address register IAR used. This be Sn5 · £ ΐ ^ "^ T- Τ *? -" T indicates that together with code number 4 no wS? I r- * ™ ° ^Τ , ^To 8 ^nffsi 8 ⁿ f ^{le for n} "variable part is required because the sending and the 6 ₅ iJSoT * J? . Z T " ^Te , ^{st points} _K ^er f" receiving registers are denoted by means of the code number defigis ^ R4 5 ^M ^ «« erte.le, and that the entire variable part of an IngaSähtron IV ^{daS C1} " ^e " ¹ ^ * instruction with code number 5 for the " transpor- Su ^ ^^^ TVSE

pen, VG are involved in the establishment of a new telephone connection within a number of similar groups. It is assumed that both the input side and the output side have already been investigated. which paths in a group of e.g. B. 1 2 ways for the new connection in the voter groups may be coupled without disrupting existing connections. All possible routes between the participating input and output selector groups, which include a number of route groups, are defined by fixed intermediate lines. The examination results relating to a specific route group are for each of the associated intermediate lines to which one of the intermediate line numbers 0 to 11 is assigned. stored both on the input side and on the output side in a bit position of the aforementioned registers R4 and RS. According to the bit positions in register R4 , it is assumed that the intermediate lines with the numbers 0, 5, 8 and 11 on the input side, or it is assumed that the intermediate lines with the numbers 2.4, 5, fi and <S be eligible for the new connection. Di ·: The route selection function of the marker Λ / consists in determining a route, ie an intermediate line, via which the new connection is to be coupled.

The read lines of the two registers mentioned are connected to the write line of the shift register SHR via an AND gate arrangement G'3, an AND function being carried out for each bit position, so that only positions are activated in the shift register if both registers R4 and / ? 5 corresponding positions are activated. According to the example assumed, the ^{bit positions assigned to the intermediate lines 1} with the numbers 5 and 8 are activated in the shift register. The computer C, softer with a Nuil input 0, is to be understood to set the computer content to zero. counts the shift pulses applied to the shift input of the shift register. The zero input of the computer forms a control point OPl. A first test point 7 ″ P1 uses an OR gate (74 connected to the bit positions of the shift register) to indicate whether at least one of the bit positions is activated.

If the binary state of the first test point TP \ indicates that no intermediate line within the route group used for route selection is suitable for the new connection, the route selection control function is aborted and, with the help of other control functions, the input and output selector positions for another Group of trails investigated.

A second test point TP1 is formed from that bit position of the shift register to which the contents of the other positions are shifted one after the other in the cycle of the pulse generator CL and shift pulses received at the shift input. With the help of an AND gate G5 activated during a corresponding control instruction, shift pulses are sent to control point OP3, ie to computer C and to shift register SHR, until said second test point TP2 is activated, for which five shift pulses are necessary according to the example assumed. At the end of the route selection, the computer C contains the number of that intermediate line via which the new connection is to be established.

Starting from a stopped phase generator P (I and an inactive in all bit positions Instruktionsadreßregister IAR the implementation of Wegewahlfunktior is introduced according to the example shown in Fig. 2 by entering the lnstruktionsadreßnummer 22 in the provided with an OR gate G6 start register. It is believed that the data transports both to the start register SR

ίο as well as to the two registers R4 and R5 that work together with the voter groups originate from control functions that belong to the voter groups SC. The OR gate dft is connected to a start input on the phase via a blocking gate G7

'5 sengenerators /' G connected, which is provided with an output iv, which is activated as long as time phase signals are sent out, and which is connected to an inverting input of the blocking gate. In this way, the phase generator only receives a brief start pulse and it is impossible to initiate a new control function before a control function that has just been processed has been completed. For a better understanding, the outputs of the operation decoder DECl and the operational parts of the accessed control instructions are labeled with the corresponding operation code numbers 1 to 5 and the outputs of the address decoder DECA with the instruction address numbers 0, 22 to 27, λ to max used in the example.

Using the time phase signals sent from the phase generator PG ΦΙ, ΦΙ. Φ 3 the route selection is carried out step-by-step. The following list of steps uses two-digit list numbers, in which the tens digit denotes the current processing period number and the units digits 1, 2 and 3 denote the start, middle and end phases. The following steps are obtained:

11. To the instruction assigned to the address number U, which has the operation code number 4.

is grilled and stored in the read register RR.

12: The content of the instruction address register JAR

is brought to 1 by activating the incremental input Sl and the code number 4 is decoded by the operation decoder DECl.

13; The content of the start register SR, ie the address number 22, is transported to the instruction address register.

21: To the instruction assigned to address number 22, which has the code number 1 is quickly accessed and stored in the reading register.

22: The content of the instruction address register win is brought to 23, the code number 1 is decoded and the register R4 in the marker M is changed with the help of the value stored in the variable part of the read register!

and decoded from the transmission decoder DECH transmitting address SA for transmitting the binary contents looool 001001 activated.

23: The shift register SHR in the marker M wiri using the vomit cherten in the variable part of the read register and all official from the receiver decoder DEC4 deco receiving address ra for receiving the Bi närinhaltes 000,001,001,000 activated.

31: To the Ir assigned to AJreßnummer 23 instruction, which has the code number 3, is picked up and stored in the read register.

32: The content of the instruction address register is brought to 24, the code number 3 is decoded and on the first test point TPl in the marker we

accessed with the help of the test point address tal stored in the variable part of the read register and decoded by the test decoder DEC6.

33: The content of the instruction address register is brought to 25 by activating the increment input, because the accessed test point TPX is activated.

41: The instruction assigned to address number 25 and having code number 2 is accessed and stored in the read register.

42 and 43: The contents of the Instruktionsadreßregisters is brought to 26, the code 2 is decoded and the zero-input 0 of the computer C is oal activated as a control point OP2 of the marker with the aid of the data stored in the variable part of the read register and decoded by the control decoder DECS control point address, ie the computer content is set to NuH.

51: To the instruction assigned to address number 26, which has the code number 2 is accessed and stored in the read register.

52: Content of Instruktionsadreßregisters is brought to 27, the code 2 is decoded, the shift input of the shift register as the control point OP of the marker by means of the variable part of the l ^ eseregistcrs stored and decoded by the control decoder DECS control point address OA3 for receiving from the pulse CL Schicbeimpulse transmitted activated, on the second test point TP2 of the marker, with the aid of the data stored in the variable part of the read register and decoded by the test decoder DEC6 test point address accessed valley, the center phase of this processing period is lengthened as a result of activation of the signal extension input SEL of the phase generator, because the second test point is inactive , and on the basis of the shift pulses, the content of the shift register is shifted until the binary state of the second test point changes at the content 100 H) OOOOOOO, with the computer C counting five shift pulses.

61: On the instruction assigned to address number 27, which has the code number 5 is accessed and stored in the read register.

62: The content of the instruction address register is brought to 28 and the code number 5 is decoded.

63: The variable part of the read register, ie the instruction address number max, which has binary "1" in all bit positions, is transported to the instruction address register.

71: To the one consisting exclusively of binary "1" Instruction assigned to the address number.

which has the code number 2 is accessed and stored in the read register.

72: The content of the instruction address register, which consists exclusively of binary "1", is extended by a Unit increases, which equates to zeroing,

ίο the code 2 is decoded, and a control point OPL to zeros of the start register CME and for stopping of the phase generator PG stored in the variable part of the read register and decoded by the control decoder DECS control point address oa \ accessed using.

73: The aforementioned control point OP1 is activated.

If all bit positions of the shift register SHR

would have remained inactive in step 23, ie. if no path of the examined path group for the new one

* o connection would have come into question, the continuation input ST of the instruction address register is not activated in step 33 and the result is:

41: On du instruction assigned to address number 24, which has the code number 5, will .zug

»5 reached and saved in the read register.

42: The content of the instruction address register is brought to 25 and the code number 5 is decoded.

43: The variable part of the read register, ie the address number χ of an instruction which initiates a new instruction sequence, which is not described here, is transported to the instruction address register.

In order to differentiate the routing function from other control functions as far as possible, it is appropriate Assume the example that the contents of the computer C before the investigation of each route group is set to zero. By means of another, not described Control function, the address of the selected link is calculated in that the Link number 711 obtained in the computer is added to an address number that corresponds to the link is assigned with the link number zero. In a variant not shown is the This addition is included in the route selection.

♦ 5 fen, that e.g. the voter groups SG the computer with the address of the intermediate line; with the number zero, with the computer at the end of the route selection contains the address of the link via which the new connection is to be connected.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Circuit arrangement for a telecommunications system controlled using stored control functions, in which test points, control points and data-storing registers connected to one another via a data busbar are controlled with the aid of access signals that are generated on the basis of control instructions identified by means of instruction address numbers, with the implementation of a Control function, which consists of a number of consecutively processed control instructions, is set in motion with the aid of a start instruction address number which is assigned to the first control instruction of the control function and which is stored in one of the data-storing registers of the telecommunications system, characterized in that in the registers (REG) storing said data, a number of instruction registers (IR) each containing a control instruction and at least one instruction address register (IAR) for storing the abovementioned instruction address numbers e in, which instruction address register is provided with an incremental input (ST) , the activation of which causes the stored address number to be increased by one unit, and that the telecommunications system has at least one time phase generator 3 »(PG) for generating time phase signals (Φ ί Φ2, Φ3), which subdivide the processing period of each control instruction into time phases, and an access signal generator (ASG) , which is controlled by the time phase signals, the instruction address numbers and the control instructions, at the outputs of which said access signals (as) are generated and which has a first logic arrangement (Ll), which decodes the content of the instruction address register during a ♦ <> time phase at the beginning of each processing period and softly accesses the instruction register assigned to the respective address number during the remaining time phases of the processing period, a second logic arrangement (Ll) for activating said increment Initially during a time phase in the middle of each processing period, a third logic arrangement (L3) which allows data transfer from one of the aforementioned registers to the instruction address register only during a time phase at the end of the corresponding processing periods, and a fourth logic arrangement (L4) with an AND function contains whose input «: during the time phase at the end of such a processing period, which results in an access signal for accessing one of the test points mentioned (TP) , and activated by a binary state of this test point and the output with the said incremental input (ST) of the instruction address register (LAR) is connected. 2. Circuit arrangement according to claim 1, characterized in that said time phase generator is provided with a signal extension input (SEL) , the activation of which causes an extension of the time phase signal just sent, and that the telecommunications system contains a fifth logic arrangement ( LS) , the inputs of which during such Processing period which results in access signals for accessing one of said control points and one of said test points, are activated by at least one of these access signals and a binary state of this test point and the output of which is connected to said signal extension input of the time phase generator. 3. Circuit arrangement according to one of claims 1 and 2, characterized in that said instruction registers are designed as at least one with an address decoder (DECl) and a read register ( RR) provided memory (ROM) and that said first logic arrangement of the access signal generator as a Gate arrangement (Gl) is formed which read register for decoding or transporting the instructions stored in it is connected to the access signal generator or to the data busbar (DB) and which gate arrangement prevents the instruction address register only during the time phases at the beginning of the processing periods with the address decoder of the memory