HU193088B - Equipment for time shared digital interconnecting sources of information, in particular to the central exchanges - Google Patents

Abstract

A switching device for the time-division digital interconnection of information sources 2, consists of a control circuit block and a connection circuit block, wherein said control circuit block /1/ consists of a control unit provided with a memory block /3/, a transient storage unit provided with speed-matching device /4/, a control-matching circuit /5/, a transient storage unit /6/, a distributed patch panel instruction storage unit /7/, a generator of patch panel addresses /8/, a change in state sensing circuit /9/, a storage unit containing states and/or changes in state /10/,a generator of scanning addresses /11/, an intervention control circuit /12/, an instruction converter /13/, an address decoder /14/, a decoder of state addresses /15/, and an address decoder of intervention point /16/ respectively. <IMAGE>

Description

BACKGROUND OF THE INVENTION The present invention relates to an apparatus for time-divisional digital switching of information sources, in particular telephone switchboards, which, by advantageously grouping switching functions, implementing digital time-sharing, provide flexible use of switching devices of various applications and capacities.

Devices based on time division digital (PCM) switching generally employ a combination of time (T) and space division (S). A typical example of such a solution is a digital PBX known as the DBX-1200. This switchboard, like other companies' first-generation digital switchgear, which is already being deployed in digital networks, switches with pulse code modulated (PCM) signals inside the switchboard. The A / D-D / A conversion is carried out by a common encoder / decoder circuit, transmitted from so-called primary PCM multiplex equipment, which has been used for a long time in telecommunications. Eight of these common encoder / decoder circuits are present in the apparatus, each forming a PCM bus. An analog channel is fixedly assigned to a bus and its time slot. The connection between the analog channels is done by appropriately mapping the time slots such that the eight-serial PCM signal is fed to a separate switching circuit by means of a serial / parallel converter, which performs the slots. The switching stage also transmits the call tones that play a role in the call setup to the caller and the caller, as the call tones are connected to a separate 32-channel A / D D / A converter array.

The DBX-1200 PBX described above has several disadvantages.

Because of the 32-channel common A / D to D / A converters, the system capacity can only be increased or decreased in 32 steps. Fixed time slot selection allows you to connect as many information sources as there are time slots. This unnecessarily increases the number of time slots and, with it, the A / D to D / A converters. The disadvantage of fixed time slot assignment is that switching information sources require a switching stage even with minimal deployment. Because voice dialing is handled through a separate 32-channel port, and the tones required for different call setups are connected to a so-called service port, the minimal setup requires three ports and a switch box.

Our aim was to eliminate the above-mentioned disadvantages by providing a more economical, flexible design with a small scale expandable switching device such that the cost of the exchange would increase proportionally with the expansion of the 2 available information sources and thus be as low as possible per line.

Our object was achieved by employing A / D to D / A converters per channel and a distributed switching field per channel in contrast to the 32 channel A / D to D / A converters. This made it possible to connect more than one source of information to a primary PCM bus, but of course only one source of information identical to the number of slots was activated. In the present invention, the transition from the transmission bus to the receiving bus does not require a separate time switching step, so the 32-channel D / A is not required for generating choice tones and implementing operator functions, particularly the three-way control. — Apply the A / D module.

The invention will now be described in more detail with reference to the exemplary embodiments shown in the accompanying drawings, which illustrate further features and advantages of the invention. In the drawing:

Fig. 1 is a circuit diagram of an apparatus according to the invention with four different information sources connected to a circuit board with a PCM bus; Fig. 2 is an embodiment of an apparatus according to the invention with three PCM buses; FIG. 4 is a centralized version of the connector circuit information source interface circuit of FIG. 1, and FIG. 5 is a front view of the interface device of FIG. 1, FIG. Fig. 7 is a state change detection circuit of the control circuit array of Fig. 1, Figure 8 is a detailed diagram of a single-bus switch of the control circuit array of Figure 1.

Figures 1 and 2 illustrate an embodiment of the switching device according to the invention; Fig. 4A shows a portion of the circuit arrangement. The drawings illustrate exemplary embodiments of a switching device according to the invention as a PBX, but the invention is not limited thereto. The

-2193083 With the appropriate design of some modules, any other type of digital (PCM) switching equipment (rural end center, office network transit center, office network data switching center, etc.) can be configured.

The embodiment of the switchgear according to the invention shown in Fig. 1 is made up of two types of arrays, the control circuit 1 and the connector 2 arrays. The most important part of the control circuit array 1 is the central controller 3, in which the microprocessor 3a is connected to the RAM 3b and the PROM 3b by a bidirectional data bus and a unidirectional address and control bus and connected to the same circuits as the control panel information and instructions are transmitted to the remainder of the control circuit 1.

The connecting circuits 2 fit the information source to the switchgear. Due to differences in the source of information, the connection circuits 2 may also be different, but each includes a distributed switching field 18, an intervention receiving circuit 19, a scanned signal transmission circuit 20, and an information source interface circuit 23. Since the connector circuit 2 of the present invention may differ depending on the type of information source, the four most common forms of the information source interface circuit 23 will now be described in detail.

To pair the S analog phone, proceed as follows:

The structure of the connector circuit 2 in this case is the same as that shown in FIG. The structure of the information source interface circuit 23 for this case is shown in Figure 3. The dual-wire analogue telephone device is connected to the stapler 23b via signal transducer 23a. In the simplest case, the transducer 23a is a relay contact through which the speech information between the switching device and the telephone device passes through its resting contact and the call signal (ringing) is transmitted to the telephone device. The actuator 23c may in this case be a relay coil actuated by the actuation receiving circuit 19 via the actuation summary circuit 22. If necessary, the actuator 23c may incorporate damping or amplification into the four-wire speech path, also upon initiation of the intervening receiving circuit 19. The function of the level adapter 23b is to provide the microphone power supply to the telephone device, to connect the two-way information transmission of the telephone device dual-wired to the information source adapter 23 to the A / D-D / A converter 21, to close the telephone and fitting these signals through the signaling level adapter 23d to the electronic circuits of the switching device and transmitting these signals to the scanned signal transmitting circuit 20.

The analog T main panel is fitted as follows. The structure of the connector circuit 2 is the same as that shown in FIG. The structure of the adapter 23 for this case is shown in Figure 4. In this case, the level adapter 23b only performs a 2/4 wire conversion. On the one hand, the transponder 23a provides call, status monitoring, toll counter signals, etc., from the main exchange. which are sent to the circuit for transmitting the scanned signals through signaling level adapter 23d. The signal transducer 23a also includes a circuit for closing the loop or possibly reversing the center, which receives actuator information from the intervening circuit 19 via the actuator 23c.

The analog keypad 0 is matched as follows:

The structure of the connector circuit 2 is the same as that shown in FIG. The configuration of the information source 23 for this case is shown in Figure 5. The two-wire or four-wire line of the O keypad is connected to the level adapter 23b. In the case of a two-wire line, the level adapter 23b also performs 2/4-wire conversion, while in the case of a four-wire operator line, it only performs level alignment via the speech signal. Its output is connected in a quad-wire manner to the signal aggregator input 23e. The two quad-wire outputs of the signal generator 23e are connected to the two A / D-D / A converters 21 in the connector circuit 2, thus allowing the operator to establish a speech connection with another information source or to connect to an existing speech connection between two . The signals from the keypad keypad are fed to the signal transmitting circuit 20 via the signaling interface adapter 23d, and the actuator 23c controls the keypad display organs through signals from the intervention receiving circuit 19.

The digital subscriber D is fitted as follows: The connection circuit 2 has the same structure as shown in FIG. The structure of the information source interface circuit 23 for this case is shown in Figure 6. In this case, the transmission of information between the digital subscriber D and the switching equipment is in some way done by digitally encoded line signals in a dual-wire or quad-wire manner at a rate depending on the information to be transmitted and the transmission method. The digital stream between digital subscriber D and level interface 23b may carry, in addition to speech information, signaling information as well as data transmission information. These signaling and data information is fed to the line digital signal stream via the actuator 23c and the level adapter 23b to receive the intervention 19

-3193088 at the pace defined by the circle. Signals or data sent from digital subscriber D are retrieved from the line stream via the level adapter 23b and the signal transducer 23d, which are received by the scanned signal transmitting circuit 20. The digital speech information extracted from the line digital stream on the level adapter 23b is matched by the rate adapter 23f to the distributed switching field 18 of the switching device at the bit rate required by the system.

Regardless of variants, the control circuit 1 and the connection circuit 2 are connected by three operations: scanning, intervention, and control of the distributed switching field. The three operations are described separately below.

Information on the state of the information sources connected to the 2-circuit array - which may be analogue telephone S, main switch T, digital subscriber D, etc. (two wires for telephone: lift, ground button; often four wires for main switch: call monitoring, call monitoring, charge counter signal monitoring, loop state monitoring), the control circuit 1 learns by cyclic scanning. Scanning is done in such a way that the generator of the scan addresses 11, which in a simpler case can be a n-bit counter, generates the addresses of the scans, which are decoded by the state address decoder 15 to individual enable signals which are transmitted to the scanned signals. In this way, they enter an active state and transmit the status of the scanning point connected to the inputs to the control circuit array 1. The circuit 20 for transmitting the scanned signals can be implemented with an AND gate for transmitting a bit of information, and preferably with a parallel converter for multiple bits. The serial information received in the control circuit array 1 is preprocessed. preferably a RAM - and at the same time it is compared with the state obtained from the same location in the previous scan cycle, which is also stored in the state library 10. The state library also contains the -information that the state information taken during the two scan cycles preceding the current cycle was identical- So, an embodiment of the state change detector circuit 9 will be described below - taking into account the status of the current and previous scan cycles, as well as the state before the current cycle. t is the relative value of states taken in a scan cycle.

If there was a change in state between the two preceding cycles and both the instantaneous and the preceding cycle, this is not considered by the circuit as an interference pulse that is not suitable for further processing. If the states in the two preceding cycles were the same, but the current state shows a change in state relative to the previous one, then it is still not a state change for the operation of the equipment. Then, the state change detection circuit 9 merely assumes the state change and stores it in the state memory 10. The hypothetical state change is not yet transmitted to the central controller 3. This shall be determined on the basis of an evaluation of the status of the next scan cycle. An actual state change occurs only when the states acquired during the two scan cycles preceding the current scan cycle show a change relative to one another, but the states of the current and preceding cycle are the same. In this case, the change of state detection circuit 9 is via the control interface circuit 5 - which preferably sends a parallel peripheral signal to the central controller 3. As a result, the central controller 3 reads the status change address, i.e. the status of the generator of the scan addresses 11, which at the same time gives the address of the respective terminal block as well as the characteristic wire of which terminal block. Based on the stored program, the central controller 3 sends out the instructions which are necessary due to the state change. (These can be eg intervention information, instructions linking information sources, etc.)

An embodiment of the state change detection circuit 9 is shown in FIG. 7 with respect to the state memory 10. After the power is turned on, the reset circuit 9g resets the memory area containing the state of the scanned points through one of the OR gates 9b and the memory area of the preset state changes through the other OR gate 9b. The serial scan information is fed to the signal generator 9a where the actual value of the information is determined by sampling the pulse edge. The regenerated signal, with the exception of the reset time after turning on the storage voltage, passes unchanged through the OR gate 9b, and is thus transmitted to the one-bit comparator 9d and the state memory 10. The one-bit comparator 9d compares the regenerated signal and the status information read from the state memory 10, that is, received from the same scan location in the previous scan cycle and stored by the 9-bit temporary buffer for the time of evaluation. The output of the one-bit comparator 9d and the assumed state change information read from the state memory 10 and stored in the other one-bit cache 9c is transmitted to the positive AND gate 9e and the negative AND gate 9f. The positive AND gate 9e determines the assumed state change and

-4193088 is written back to state space 10 via OR gate 9b. The negative AND 9f detects the actual state change and then sends an output signal to the control interface 5.

Intervention is specifically referred to when the command of the central controller 3 changes the state of the actuator (e.g., bell relay, damping switch, on, etc.) in the connection circuit 2. The intervention proceeds as follows: the central controller 3 transmits to the temporary storage 6 information about the new state of the actuator and the address of the actuator, which corresponds to the address of the circuit receiving the actuation 19. After the data and address are transmitted, the cache 6 sends a signal to the intervention control circuit 12 which generates a short-term enable signal. The intervention address decoder 16 performs the decoding on the basis of the received address bits and sends an enable signal to the intervention intervention receiving circuit 19 for a period of time determined by the intervention control circuit 12, in which information about the new status of the intervention body is written. The intervention receiving circuit 19 may conveniently be implemented with a bit addressable storage.

Transmit and receive time slots of the distributed switching field 18 must be mapped to connect the information sources. The control is performed by the central controller 3 issuing instructions for the mode of the distributed switching field 18, together with the address of the respective switching field 18. The command word and address are received by caches with speed adapters 4. The speed adapter is required so that the temporary storage with the speed adapter 4 cannot receive any further instruction from the central controller 3 until the previous instruction has been written to the distributed switch field instruction storage (RAM).

The distributed switching field instruction store 7 serves to store instructions for all the distributed switching fields 18 of the apparatus so that these instructions can be read at intervals and transmitted to all distributed switching fields 18 for updating. According to the task, the capacity of the distributed switching field instruction storage 7 must be in accordance with the number of distributed switching fields 18 in the apparatus. Distributed switching fields 18 are controlled and updated by generating the switching field addresses by generating the switching field addresses generator 8, which may actually be a binary counter, to address the switching field instruction library 7 and read out the word for that distributed switching field 18. or words. The instruction word, read in parallel from the distributed switch field instruction store 7, is transmitted to the instruction converter 13 for parallel / serial conversion, which output, at the same time as the enable signal of the address decoder 14 linked to the switch field address generator 8,

The distributed switching field 18 acts in response to the serial control word as follows: it stores separately transmission and reception time slot information. The received transmit or receive timing signal operates two internal counters which compare their status with the stored time slot data for transmission and reception.

If the comparison shows identity, the circuit permits the transmission or reception of the distributed switching field 18, or both at the same time, depending on which stored time slots the internal counters show. Authorization in both modes (transmit and receive) lasts only one slot at each frame time, until another instruction from the central controller 3 changes the contents of the internal instruction library in the distributed switching field 18. Commercially available integrated circuits which perform the functions of a distributed switching field 18 are known. (PL: Intel 2911, Motorola MC 14416)

The operation of the exemplary embodiment of the apparatus of the invention illustrated in Figure 1 is as follows for a call: The operation is described for a signal connection between two information sources, where both information sources are telephones.

To indicate the need to establish a connection, lift the handset of the calling device. This results in a change in one of the information source states. This new state is transferred from the circuits transmitting the scan signals 20 to the state change detection circuit 9 via the scan address generator 11 and the status address decoder 15 during the cyclic scan. The state change detection circuit 9 detects the state of change by means of the state library 10 and sends a signal to the central controller 3 via the control interface 5. The central controller 3 interrupts the currently running program as a result of the signaling and reads through the control interface 5 the status change address, i.e. the current status of the generator of the scan addresses 11. From the scanned address, the central controller 3 determines the address of the initiating device and its associated distributed switching field 18. Thereafter, assuming there is a free time slot for linking the information sources, the central controller 3 transmits a selection tone to the call originator by switching the receive switch input of the distributed switching field 18 to a time slot containing PCM words corresponding to digital samples of the selection tone. These words

-5193088 is transmitted to the receiving bus by cyclically reading 26 digital audio generators, preferably one PROM. This control process is performed by sending the address of the distributed switching field 18 and the code corresponding to the receive mode and the receive time slot to the central controller 3 for the temporary storage with the speed adapter 4. From the cache with speed adapter 4, the codes corresponding to the mode and time slot - i.e., the instruction word - are written to the line of the distributed switching field instruction library 7 which belongs to the distributed switching field 18. From the Distributed Switch Field Command 7, the address generator of the switch field addresses 8 transmits the command word so that the output of the generator of the switch field 8 addresses the distributed switch field 18 via the address decoder 14, which is read from the can receive a command word. Thereafter, the reception input of the distributed switching field 18 is opened in the time slot corresponding to the selection tone and transmits the information in that time slot to the A / D-D / A converter 21. The dial tone will be heard in the caller. This is the starting point for the selection process (eg dialing). Each pulse of the pulse sequence sent to enter the number of the called information source is transmitted to the central controller 3 as a change of status. The central controller 3 determines the address of the called information source based on the usual state changes. If the called information source is free, the central controller 3 sends to the temporary storage 6 the address of the actuator (ringing relay) associated with the called information source and the status information required to pull the relay. The intervention site address decoder 16 addresses the intervention receiving circuit 19 and stores in itself information corresponding to the new state of the intervention means in the information source interface circuitry 23. The output of the intervention receiving circuit 19 actuates the bell relay via the intervention summarizing circuit 22, since the intervention summarizing circuit 22 does not change this state in this case. The ringing is interrupted by releasing or re-engaging the ringing relay so that the intervention receiving circuit 19 receives various information from the central controller 3. If the device of the called information source is lifted during the ringing time, the intervention summing circuit 22 changes the state of the intervening place based on the signal received from the information source matching circuit 23 independently of the central controller 3, i.e. releases the ringing relay. The addition of the called information source occurs as a state change at the central controller 3, whereby the central controller 3 assigns a free time slot 6 to the two information sources. The distributed switching fields 18 are controlled such that in one free time slot the call transmitting side is active and the called receive input is open and the other in the free time slot vice versa. The transmission outputs of the distributed switching fields 18 are connected to a single wire, the X transmission bus. The PCM signals are transmitted through the X transmission bus to the one-bus switch 24, which establishes a connection between an X transmission— and a R receive bus, in this case a short circuit. The circuitry of the connector 2 of the O keypad has the ability to be third connected to an already established connection without the need for changing the time slots of the calling and called information sources involved in the original connection or for additional time slots. This is done by inserting one of the distributed switch field 18 of the O keypad into one information signal path (e.g., the call-to-call direction) and the other 18 distributed switch field 18 of the O keypad into the other information path. . This entanglement implies that the information transmitted by the information sources is received by the fields of the two distributed switches 18 of the O keypad and transmitted to the A / DD / A converter 21 attached thereto. To the analog signal thus obtained, the information source interface circuit 23 adds the analog signal from the operator O and returns it to the A / D-D / A converter 21. With the aid of the two distributed switching fields 18 and the single-bus switch 24, the summed analog information in the form of PCM words is placed in the same time slots from which the exception was previously made. This is done so that the transmitter outputs of the two distributed switching fields 18 of the keypad O are not connected to the transmit bus X but to the enable circuit 24b of the single bus switch 24 shown in FIG. The X transmission bus is connected to the blocking circuit 24a. 24a prohibiting circuit and 24b enable circuit also connects to the operator T _x transmission time slot line which is connected to two 18 distributed switching system for the O manager and active in time slots when the corresponding two distributed patch panel 18 the transmission output is active. The operator's transmission time slot T _x signal via the disabling circuit 24a clears the information entered by the caller and the receiver, and using the same time slots 24b permitting circuit permits the PCM signals corresponding to the O manager. The blocking circuit 24a and the enabling circuit 24b are implemented with three-state gates, so that the output bus R is connected by connecting the outputs. In this way, the caller can receive information from both the caller and the O operator, and the caller, both the called and the O operator, in its own time slot. The single-bus switch 24 is also adapted to establish a connection between any information source and the O operator in a single time slot. In this case, only one of the 18 switch switches 6193088 belonging to the O keypad is deleted, so that the one-bus switch 24 is erased in a single time slot, the transmitter information source associated with the O keypad, and replaced by the O keypad transmitter information.

Another embodiment of the switching device according to the invention is shown in Fig. 2, which shows a larger number of switching devices formed by a plurality of connection circuits 2, whereby a group of the connection circuits 2 are connected to the drive 17. The control of the distributed switching field 18 and the interference receiving circuit 19 in the connection circuit 2 and the interrogation of the scanned signals 20 is carried out in the same manner as in the embodiment shown in FIG. The only difference is that the PCM outputs of the distributed switching fields 18 are not connected to a common broadcast bus, but to one broadcast bus per group. The transmission thus formed bus connected 17 to a driver circuit which by distributed patch panels 18 in the group, T _x transmission time slots produced in the active transmission time slot signal latch qualify the signal transmission bus, i.e. only T _x transmission time slot is active in 25 multi-bus switches. This gating allows for the connection of two groups of connecting circuits, which are geometrically spaced apart, to an X transmission bus. The multi-bus switch 25, thus moving the time slots, switches between the X transmission buses R and the reception buses R thus formed. Ready-made circuits are now commercially available to provide 25 multi-bus switches. (e.g. SGS MO88)

Claims (5)

Apparatus for time-divisional digital switching of information sources comprising a control circuit array and a plurality of connecting circuits, characterized in that the control circuit block (1) comprises a control unit (3), a speed adapter with temporary storage (4), a control interface circuit (5). ), a temporary storage (6), a distributed switch field instruction store (7), a switch field address generator (8)., a state change detection circuit (9), a state store (10), a scan address generator (11), an intervention control circuit (12). ), an instruction from a converter (13), an address decoder (14), a status address decoder (15) and an intervention address decoder (16); the connector circuit (2), a distributed switch field (18), an intervention receiving circuit (19), a scanned signal transmitting circuit (20) and an information source interface circuit (23), wherein the control unit (3) is provided with a speed adapter. storage (4), the control interface 12 (5) and the temporary storage to (6); a distributed switch field instruction store (7) for a temporary storage device (4) having a speed adapter, a switch field address generator (8) and an instruction converter (13); a switch field address generator (8) for the address decoder (14); the control interface circuit (5> to the state change detection circuit (9), the state library (10) and the scan address generator (11); the state change detection circuit (9) to the state memory (10); the scan address generator (11)) a state address decoder (15), a temporary storage (6) for an intervention site address encoder (16), an intervention control circuit (12) and an intervention receiving circuit (19), an intervention control circuit (12) for an intervention site address encoder (15); 16); an instruction converter (13) for the distributed switching fields (18); the address decoder (14) for the distributed switching fields (18); the state change detection circuit (9) with another wire to the state store (10) and the scanned signal transmission circuits. (20); status address address decoder (15) for scanned signal transmitting circuits (20); intervention site address decoder (20); 16) an intervention receiving circuit (19), an information source interface circuit (23) to a scanned signal transmitting circuit (20); and the distributed switching field (18) is connected to the other distributed switching fields (18) by two independent wires. Apparatus according to claim 1, characterized in that the connecting circuit array (2) comprises an A / D-D / A converter (21) and an intervention summing circuit (22), wherein the A / D-D / A a converter (21) coupled to the distributed switching field (18) and the information source interface circuit (23), and the intervention summary circuit (22) to the intervention receiving circuit (19) and two additional wires to the information source interface circuit (23). Apparatus according to claim 1, characterized in that the apparatus comprises a single bus switch (24), which comprises a single bus switch (24) prohibiting circuit (24a) and an enabling circuit (24b), wherein the transmission bus (X) the blocking circuit (24a), the operator transmit bus (Xo), the enable circuit (24b), the operator transmit time slot (Txo), the blocking circuit (24a) and the enable circuit (24b), and the blocking circuit (24a) and the outputs of the enable circuit (24b) are connected to the receive bus (R). Device according to Claim 1, characterized in that the device is more than 7 -7193088 comprising a bus switch (25) and drives (17), wherein the connecting circuits (2) are connected to the drives (17) by means of two information wires and a transmission time slot (Tx) wire, respectively, and the drives (17). transmit buses (X) and receive buses (R) are connected to the multi-bus switch (25). 1 ( Apparatus according to claim 1, characterized in that the state change detection circuit (9) comprises a signal regenerator (9a), an OR gate (9b), a one-bit temporary storage (9c), a one-bit comparator (9d), positive AND consisting of a gate (9e), a negative AND gate (9f) and a reset current (14g), wherein one of the OR gates (9b) for the signal regenerator (9a), the negative AAND gate (9f) for the one-bit comparator (9d) and a magazine (10), while the other OR gate (9b) is connected to the negative AND gate (9f), to the positive AND gate (9e) and to the status store (10); a status store (10) with a single wire to the one-bit temporary storage (9c), one of which is a one-bit temporary storage (9c) connected to the one-bit comparator (9d); and the reset circuit (9g) is connected to a common point of the one-bit comparator (9d) and the positive AND gate (9e) and to the common point of the positive AND gate (9e) and the other one-bit temporary storage (9c).