NO159822B - METHOD AND APPLICATION FOR TRANSMISSION CONTROL IN ONE-DIGITAL TELECOMMUNICATION NETWORK. - Google Patents

Description

The invention relates to a method and apparatus in a telecommunications system for using so-called pass-through control to control the setup and existence of a duplex connection for the transmission of digital information in a time-shared multiplexed bus network, to which subscribers are connected via line terminals.

In Swedish patent 7410475-3, for example, a method is described for pass-through control in a digital exchange in a telecommunications system. The method is characterized by incorrect parity which is deliberately introduced into the digital character stream of an input on a switchboard, after measures have been taken to establish a connection between the input and a specific output on the switchboard, after which said output is scanned for incorrect parity, and that information regarding the result of said scan, which indicates a wrongly or correctly established connection, is transferred to a central control unit.

The problem with the known method is that it completely

is under the control of a central control unit which manages all activity regarding the pass-through control, which results in significant time delay and complicated hardware. The method is also not applicable in a larger connection network with a larger number of exchanges or terminals. Control is limited exclusively to the central office. The procedure is based on parity being checked on the receiving side under the control of the central processor and created on the sending side also under the control of the central processor. It is thus necessary to take active measures on both the sending and receiving side of a connection.

The method and apparatus according to the invention, which solves the aforementioned problems, are defined in the patent claims and are usable in a multiprocessor system, and are not under the control of any central processor. The pass-through control according to the invention is based on monitoring to ensure that a connection has been established and exists, controlled from one and the same terminal, i.e. the terminal that sends the pass-through control also has the task of detecting it. This means that all other terminals along the connecting road, e.g. processors and PCM line terminals, only forward the control message without taking any further action. The embodiment according to this invention is also based on the fact that an incorrect parity

bit is added to the data samples. It is of course possible to use other control signals than incorrect parity, e.g. a special control word or a special control bit. The invention thus allows monitoring that a correct connection has been established in a duplex connection in a digital bus system. The pass-through check (TCT) for both halves of a duplex connection is implemented, and the result is checked at the same point (terminal) of the connection. A parity bit of intentionally incorrect polarity is sent along with the speech sample and, as mentioned, the generation of the parity bit and the checking of its polarity are performed in the same terminal (processor). In a multiprocessor system, implementation and control can thus be added to one and the same processor, which is not possible in the known technique.

The apparatus according to the invention is described in detail below by means of an embodiment, and with reference to the attached drawings on which

figure 1 is a traffic road core showing the creation of a connection where the device according to the invention is included,

figure 2 shows a terminal in the connection network with the apparatus according to the invention drawn up as a block diagram, and figure 3 is a block diagram of a terminal for carrying out the pass-through control.

As will be seen from Figure 1, a digital switching network of the aforementioned type contains a number of terminals T, which are digital, processor-controlled exchanges, of which one of said terminals, denoted TCT, is assigned to carry out the pass-through control in the network. The terminals T are connected to each other via time-multiplexed buses TB

(Time Switch Bus). Subscriber-connected PCM line terminals PCM 1 and PCM 2 are also connected to terminals T. In the line terminals, e.g. respectively analogue/digital conversion and digital/analogue conversion from and to the line outside the digital network structure.

A duplex connection can be thought of as arranged between

two subscribers in the directions A to B and B to A. The actual connection of the connection in the time multiplexed step is not explained, as this is known within the art. A normal parity check is carried out in a manner known per se in the TCT station to ensure that a connection path has been created at all.

If any link point is incorrect, incorrect parity is achieved, indicating e.g. non-operated exchange points, i.e. exchangers that have not been connected. The converter causes false parity when not enabled.

When correct parity has been established, i.e. a correct connection has been established through the network, the pass-through check is performed with the intention of generating incorrect (inverted) parity from the terminal (selector point) TCT which has been assigned by a central processor CP (not shown) at the time of connection to perform the pass-through check. For the aforementioned check, it is only in the TCT terminal that correct parity is awaited. All other connection points in the established connection are connected through, whether the parity is correct or incorrect, i.e. the outgoing parity is the same as the incoming parity. The intentionally generated erroneous parity bit is taken around the entire connection path and returns as input data to the TCT station, where it is detected. Once it has been detected, the correct parity is sent to the network. Correct parity is then awaited, to ensure that all registers along the link path are cleared of incorrect parity. The central processor is then informed that the link has been set up correctly. A micro-processor MP in the TCT station can decide whether correct or incorrect parity should be sent. Odd parity is considered correct parity. For detected incorrect parity (not generated on purpose), correct parity is sent. For an unacknowledged pass-through check, the central processor makes another connection attempt. An alarm is given for repeated unsuccessful connection attempts. The TCT station is usually the station closest to the A subscriber.

The intentionally imposed incorrect parity is constantly tied to specific channels through the various stations along the link path. The advantage of this is that no switches can be operated incorrectly without this being detected by the switching control.

Fig. 2 shows the parts relevant to the invention which are part of a line terminal, e.g. PCM 2.

When transferring a call in one direction from the subscriber

A to the subscriber B, binary information is received in serial form from the switching terminals on an input to a series/parallel converter SP2. of the type.74LS395 in the line terminal PCM 2. As it is a question of a time-divided system, the voice information is transmitted in the form of samples, each of which consists of 8 bits and a parity bit. After the transformation into parallel form, the speech samples and the parity bit are applied to the inputs of a parallel/series converter PS 2 of the type 74LS395 for further transmission on a line Li, e.g. to the subscriber B. Said signals from the output of the converter SP 2 are also applied to the inputs of a modulo-2 adder M2 of the type 74LS280, in which a parity check is carried out in a known way, i.e. a check of whether the parity is. odd or even, and accordingly a parity bit is sent to the input of a modulo-2 adder M3 of type 74LS280. The voice samples from subscriber B are fed to the input of a series/parallel converter SP3

in the line terminal PCMr-2. After conversion, the signals are supplied

in parallel form to the inputs of a parallel/serial converter PS3 for transmission on the time bus TB, and also

to additional inputs on said modulo-2 adder M3,

on the output of which a parity bit is sent in response to the parity bit and speech sample from subscriber B that is supplied to the inputs. The speech samples from the subscriber B thus deviate from the converter PS3 with a parity bit introduced in the line circuit, said parity bit being achieved without information exchange with, and control from, a common central processor, but only by means of a single loop connection process. Outgoing parity has the same polarity as incoming parity.

In fig. 3 shows the circuits required for the implementation of the pass-through control which are included in the TCT terminal, as said terminal is selected to control said control when the connection is connected. Such circuits are also included

in the other terminals T, as all terminals are the same.

A series/parallel converter SP1 of the 74LS395 type receives

on its input the speech sample with the parity bit from the time bus TB. The binary speech samples are forwarded to a parallel/series converter PSI of type 74LS395 for output to the line in series form. The speech samples from the output of the converter SPl are also fed to the inputs of a modulo-2 adder Ml of the type 74LS280, while the parity bit from the bus is fed to a first data input of a data selector DS of the type 74LS15 3.

A signal of a constant level, e.g. corresponding to a logical one, an input is supplied to the modulo-2 adder. The parity signal formed by the addition is sent from a first output of the modulo-2 adder Ml to a second input of the data selector DS. The inverted parity bit is sent from a second output of the adder to a third input of the data selector. The signal from said first parity output on the adder Ml is compared in an exclusive-OR gate, denoted OR, of the type 74LS882 with the parity bit obtained from the converter SPl. If necessary, the result of the comparison can be read into a local processor MP, this being a microprocessor made by MOTOROLA with the number M6801. At the start of a pass-through check, the microprocessor MP is given an order from the not-shown central processor CP to carry out said pass-through check, the microprocessor then writes into a control memory CM, of the type 214 8 made by Intel, that a correct parity is to be sent, i.e. .the value 01 corresponding to odd parity. A status counter TR of the type 74LS161 is simultaneously set to zero by the microprocessor. The status counter's task is to control the micropro-. the sessor's reaction to incoming parities. Control signals are sent from two outputs on the control memory to corresponding control inputs PCO and PCI on the data selector DS. For PC0=0 and PC1=1, odd parity is sent via the data selector's input 5 output 1 to the input of the parallel/series converter PSI. This parity signal is sent through the network and received at the TCT station's input.

In case of equality between the compared parity signals, the circuit OR sends a logical zero signal which means correct parity and, provided that the state counter TR is at zero, means that the microprocessor steps the counter TR et. step and changes the control word in the memory CM, thereby intentionally sending incorrect parity (even parity) corresponding to the logic signal 10. When the control inputs are activated by the signal 10, even parityfc is sent via input 6 to the converter PSI from the data selector.

In the event of a difference between the compared paxity sigmals, the circuit OR sends a logic 1 signal which causes, provided that the condition counter TR is at one, the microprocessor MP tfshifts the counter by one step and changes the control word in the memory CM: to correct parity, i.e. odd (01 ), which is broadcast on the bus via the data selector. When this correct parity is detected again, and assuming that the state counter TR is in position 2, the microprocessor steps the counter a further step (3) and sends a control signal to the central processor as a message that the fence switching check has ended. The value 3 on the state counter means that incoming parities would no longer be taken into account.

In a terminal T, which is not designated as a control terminal for the pass-through control, the state counter TR is set to position 3 at the moment of connection and the control memory CM is loaded with the value 00, with incoming parity thus being fed via the data selector DS input 4-output 1 to the parallel/series input the converter PSI and to the line.

Claims (5)

1. Procedure for, in the duplex transmission of digital information between subscribers connected to terminals which are connected to each other via a telecommunications network of the time multiplex type, in which the information is transmitted in the form of binary words in specially allocated time slots, to perform through-link control, during ongoing traffic, by means of a parity check to check that a correct connection has been established after a connection path has been established, characterized in that the pass-through check is started and detected in one and the same station (TCT), a control bit of incorrect parity being arranged to be sent with the intention , after detected correct parity, together with each of a number of word samples from a specific station (TCT) in the connection network, the said station being selected when the connection is established, and that the said control bit when passing through other stations is carried unchanged to the next connection point in the network, and that a parity check of said control bit is carried out in said specific station (TCT), from which correct parity is generated and sent after approved parity check, i.e. for received intentional incorrect parity. 2. Apparatus for carrying out the method as stated in claim 1, for, in duplex transmission of digital information between subscribers connected to terminals connected to each other via a telecommunications network of the time multiplex type, in which information is transmitted in the form of binary words in specially allocated time slots, to - perform pass-through control, during ongoing traffic, with the help of a parity check to check that the correct connection has been established after a connection path has been established, characterized in that a station (TCT), in the established link path, for sending and receiving pass-through control information, contains a first parity control means (Ml), provided with inputs and outputs for parity checking of binary information coming from a line (TB), a non-inverted and an inverted output for the resulting control signal being connected respectively to a second and a third data input of a data selector (DS), if first input, the parity information is supplied directly from said line (TB) via a series/parallel converter (SPl), a local processor (MP) which via a control memory (CM) controls the selection of output information from the data selector so that the latter depending on the value on signals from the control memory connected to control inputs (PCO, PCI), sends signals on an output corresponding to one of said three inputs, a comparison circuit (OR) for comparison between incoming parity from the line and calculated, non-inverted parity from said first parity control means ( Ml), as the comparison result is supplied to the input of said local processor, a status counter (TR) which is connected to the local processor (MP) and is advanced by said processor in dependence on signals from the comparator (OR), the status signal from the counter and the result from the comparison circuit (OR) constitute control information for selection of information in the control memory (CM),- and that a second parity control means (M2) in a line terminal (PCM2) checks incoming information in one direction of the duplex connection to form a parity bit which is supplied to a third parity control means (M3), which also receives binary word from the other direction of the duplex connection and feeds the parity bit generated after the parity check on to the next connection point in a direction towards the TCT station. 3. Apparatus as specified in claim 2, characterized in that the data selector (DS) is connected so that it sends correct (odd) parity when receiving the control signals PC0=0 and PC1=1, inverted (even) parity when receiving the signals 10 , and on receiving the control signals 00 transmits incoming parity from the line without change to the next connection point. 4. Apparatus as specified in claim 2, characterized in that said parity control means (Ml, M2, M3) comprise modulo-2 adders. 5. Apparatus as stated in claim 2, characterized in that said comparator circuit (OR) is an exclusive-or circuit.