DD236843A1 - CIRCUIT ARRANGEMENT FOR TRANSMITTING LANGUAGE SIGNALS - Google Patents

Abstract

Circuit arrangement for the transmission of speech signals in a wired message system with multiple access and decentralized switching. The aim of the invention is to provide a circuit arrangement for the realization of a digital local communication system for low subscriber numbers with low traffic, which operates on the code division principle. The object is achieved in that the access level of the access level, which is connected to the network layer network coupler and the terminal device terminal, consists of a code multiplexer, a code demultiplexer, a control unit and a controller. According to FIG. 3, the operating unit consists of a call button, a stop button, a telephone number register, a call sign output, a keyboard and a display unit; the code divider of an AND gate, a parallel-to-serial converter, an address memory, a ringing generator and a switcher; the code multiplexer of a caller ID, a delay line, a switch network, a summer and a sampling circuit. The connection of said elements of the arrangement enable subscriber synchronous and bit synchronous operations. The invention is particularly suitable for use in local networks.

Description

For this 2 pages drawings

Field of application of the invention

The invention relates to a circuit arrangement for the transmission of speech signals in a cable-linked message system with multiple access and decentralized switching, which operates on the code division principle and is particularly suitable for use in local area networks.

Characteristics of known technical solutions

s has already been proposed an arrangement for message transmission with multiple access and decentralized switching, ei the communication network consists of defined interfaces interconnected independent levels, 'obei the terminal connection level includes various modules that provide for the connection of various terminals nd, the access level consists of access stations, on the one hand with several modules of the terminal connection level are connected and on the other hand ensures the exchange of information via network coupler network level with the transmission line and mpfangsleitung, and wherein the network level is realized as a hybrid network of lines consisting of copper and Lichtleitkabel nd passive and active Netzkopplem.

Ine high sensitivity is achievable only by a high degree of synchronization, which in turn can only be lipped consuming. In the realization of telecommunications networks with low subscriber numbers and low revenue offer, which are provided primarily for voice signal transmission, there is the disadvantage of the arrangement according to the eitmultiplexprinzip in the high circuit complexity, which is caused in particular by the high necessary synchronicity / ird.

iel the invention

JeI the invention is to provide a circuit arrangement for the realization of a digital local communication system for low subscriber numbers with low traffic, which is preferably suitable for voice transmission.

Explanation of the essence of the invention

) the invention has for its object to provide a working according to the code division multiplexing circuit for 'detection and transmission of preferably speech signals, in which the access station of the [communication system for signal transmission bit synchronism and to establish a connection' silessersynchronismus requires a high insensitivity to interference has and is realized by low ichaltungsaufwand. According to the invention the object is achieved in that the access station consists of a ^ demultiplexer, a controller, a code demultiplexer and a control unit. The operator unit is connected to the controller, the code multiplexer and the code demultiplexer and the controller establishes connections to the following: the demultiplexer, the source encoder and the regenerator of the transmission line. Furthermore, the code multiplexer with the luellencodierer and the regenerator of the transmission line and the code demultiplexer with the regenerator of the receive line and the source encoder are interconnected.

) The operating unit consists of a call button, stop button, a phone number register, a call sign output, a keyboard md a display unit. The call button and the stop button are connected to the controller and the caller ID to the iufnummerregister and Rufzeichenausgabe. The code multiplexer consists of an idler, an analog-to-serial converter, an address memory, a ring generator, and a switcher. The member is connected to the parallel aerienverter, the switch and the regenerator of the transmission line and the parallel-to-serial converter, the address memory, ier call generator and the switch are connected to the controller. Furthermore, the call generator with the switch, Jer address memory with the parallel-to-serial converter and the switch with the source coder are interconnected.

The code demultiplexer consists of a caller ID, a delay line, a switch network, a summer and a sampling circuit. Here, call recognition is connected to the receive line regenerator, the delay line, the summer, the sampling circuit, and the source decoder. The delay line st is connected to the switch network and the regenerator of the receiving line. Furthermore, connections exist between the switch network and the summer, between the summer and sampling circuit, and the envelope decoder.

On the premise that the caller identifier is interconnected only with the receive line regenerator, the delay line, each summer, sampling circuit, source decoder, and ring output, and that the envelope coder is a delta modulator and the source decoder is a delta demodulator, a: slave-asynchronous Circuit arrangement realized.

The switch network in the code demultiplexer can be omitted here, if according to the codeword combination only the high- ³ otential leading outputs of the delay line are directly connected to a corresponding number of inputs of the summer.

Another possibility is that to the outputs of the delay line one, the code word length corresponding number of switches are connected, which are connected to the inputs of the summer and that only the necessary for decoding the codeword outputs of the delay line and the other switches open

In principle, a connection is set up by multiplying the digitally coded source signals by the codeword of the receiver. In this case, the access station, the four operating states can take call, readiness for call reception, call recognition and bidirectional information exchange.

When connecting a station A to another station B, the subscriber A first scans the call number B. The selected number B appears on its display. Then the call button is pressed. This will send a header.

This head block consists of two parts. The first part is for the synchronization of the receiver B and contains a certain number of synchronization symbols. The second part contains the BCD coded address of subscriber A.

If station B is ready to receive at this time, i.e. Station B is not in a dialogue with another station and is trying to establish no connection, its receiver synchronizes with the first part of the call

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Headers and reads in the address part. The station B display shows the number A, a call sign is triggered via the call sign output. Subscriber B, in turn, presses the call button, and the sender B synchronization process to receiver A starts. From this moment the connection is established and subscribers A and B can exchange information in duplex mode. The connection is terminated by pressing the stop button.

embodiment

The invention will be explained below using an exemplary embodiment. In the accompanying drawings shows

Fig. 1: Line network

Fig. 2: basic structure of a subscriber station

3: assemblies of an access station

Message systems with multiple access and distributed switching use primarily line-saving network structures, such. B. Line and ring networks. Fig. 1 shows a network execution in line form with activated subscriber stations T, which operate on the code division principle.

The subscriber stations T are connected to each other via a common transmission line SL and receiving line EL, which are short-circuited at the end of the transmission line SL.

Each subscriber station T consists of the network coupler NK, the access station ZS and the actual terminal EG. Defined interfaces exchange the signals between the mentioned modules. Code multiplexing and multiple access are digital, with only binary signals being transmitted. To realize a simple digital superimposition of the signals, bit sync is required. For bit clock synchronization, therefore, a clock generator TG is required at the beginning of the transmission line SL.

In principle, a connection is set up by multiplying and transmitting the digitally coded source signals of the source coder QC with the codeword of the receiver. In order to establish and maintain a connection, subscriber sync is still required, i. two interlocutors synchronize their information exchange.

2 shows the basic components of the terminal EG, the access station ZS and the network coupler NK. The terminal EG consists of the actual speech source SQ and the speech sink SS, as well as the source coder QC and the source decoder QD. The source encoder QC converts the analog voice signal into a digital source signal and transmits this as a data signal DQC to the access station ZS, the source encoder QC being synchronized and clocked by the control part ST of the access station ZS via the signal TQC. In addition to a plus code modulator, the source encoder QC may also be used e.g. be executed as a delta modulator. Accordingly, the source decoder QD receiving its signal DQD from the access station ZS is realized by a pulse code demodulator and by a delta demodulator, respectively. Synchronization and clocking of the source decoder is also done with the signal TQD from the controller ST of the access station ZS. The access station ZS consists of the function modules code multiplexer CMU, control ST, operating unit BE and code divider CDE.

The code multiplexer CMU transfers the transmission signal of the subscriber station T to the regenerator of the transmission line RSL, which, like the regenerator of the reception line REL, regenerates the incoming line signals, extracts the access station ZS as a data signal DSL, or provides data signals DEL and clock signals TSL and TEL and resend. In the regenerator of the transmission line RSL, the bit synchronous superposition of the various transmission data signals is also realized.

About the code multiplexer CMU also the signals of the control unit BE, such. As the signals to the subscriber synchronism, passed, the code multiplexer CMU is synchronized and controlled by the controller ST.

The code divider CDE receives all the transmitted signals via the regenerator of the receiving line REL and transfers the recognized call signals of the operating unit BE or data signals to the source decoder QD.

The realization of an access station ZS shows the illustration in FIG. 3. The operating unit BE contains the call button S1, the stop button S2, the keyboard TA, the display unit AE, the telephone number register RR and the call sign output RZ. The code multiplexer CMU consists of a parallel-to-serial converter PS, an address memory AS, a call generator RG, an AND gate UG and a switch S3.

The code divider CDE contains the modules Call Recognition RE, Delay Line VL, Switch Network VR, Summer SU and Sample AB.

The access station ZS can assume many different states. In addition to call, readiness for call reception and call recognition, the exchange of information can be implemented bidirectionally or in duplex mode. The operation of the circuit arrangement will be explained using the example of the source coding and decoding by delta modulation method. If a subscriber A has a send request to another subscriber B, he first of all scans his call number into the keyboard TA. The dialed number is BCD coded and stored in the call number register RR. Thus, the address memory AS is addressed and at its outputs the first part of the code word, which is assigned to the called subscriber B appears. At the same time, the display unit AE displays the telephone number stored in the telephone number register RR.

After pressing the call button S1, the controller supplies the corresponding clocks to the address memory AS and the parallel-to-serial converter PS and turns on the call generator RG. The call generator RG first transmits a sequence of synchronization symbols and then the BCD-coded telephone number of the subscriber A.

 Thereafter, the call generator RG is turned off by the controller ST and the delta modulator is switched on.

e from the parallel-serial converter PS incoming code words are ND-linked to the output of the delta modulator in the AND UG and reach the network coupler NK. The right phase of information and code word is ensured by the: ST circuit.

At the time of the call, the subscriber B should be in the ready state. The entire multiplex signal on the npfangsleitung EL passes through the delay line VL and is checked bit by bit for coincidence. The errors cause formation bits to be recognized incorrectly, but the caller ID does not respond. A call is recognized only when all chronological symbols arrive consecutively in the system time frame. The caller ID triggers on the call sign output Z the call signal and passes the following signal to the telephone number register RR. As a result, the register of the subscriber B is loaded with the number of the subscriber A. This number is displayed and the address memory AS trained accordingly.

amit are the conditions for a conversation between participants A and B created. Upon completion of the call, the stop key S2 blocks the control ST and sets the code demultiplexer CDE back to standby condition that the source encoder QC consists of a delta modulator and the source decoder QD is an eldademodulator, the synchronization of the circuitry to the bit synchronous transmission limited earth and the subscriber synchronism deleted. According to Fig. 3, this is done by dispensing with the connection of the uferkennung RE of the code demultiplexer CDE to the number register RR.

The delay line VL in the code demultiplexer CDE can be implemented very simply by an actuated shift chain because of the digital signal transmission, at whose parallel outputs only the high-speed expected summer SU according to the code word instruction are directly supplied. The summer simply represents a narrow gate with a number of inputs corresponding to the high level. Only when the own code word is detected, the summer SU outputs a pulse. If the codeword has e.g. 12 bit length with 5 high symbols and 7 low symbols on, so a nand gate lit 5 inputs is needed. Since, in this case, the delay line VL and the summer SU are connected directly, the switch network VR is omitted.

[For a more universal use, the switch network VR can be switched between the outputs of the delay network VL and the inputs of the summer SU by interposing a number of signal switches corresponding to the code word length. This switch network is programmed so that only the high-level ends their points of the outputs of the delay line are switched through, all other inputs of the summer SU 'grounded by the switch to a fixed high reference potential. In this case, the summer SU requires a Nandlatter with a number of inputs corresponding to the code word length.

Claims (7)

Invention claim: 1. A circuit arrangement for transmitting voice signals, consisting of a transmission line and a receiving line, which are connected together at one end and open at the other end and a communication network, which is formed of three levels, so that in the terminal connection level of the connection to a Implemented terminal with a voice source, the access level belonging access station via defined interfaces to a terminal of the terminal connection level and the other via network coupler network level with the transmission line and the receiving line is connected, and that the network coupler regeneration of the line signals of the transmission line and realize the receiving line, characterized in that the access station (ZS) consists of a code multiplexer (CMU), a code demultiplexer (CDE), a controller (ST) and a control unit (BE), the operating unit (BE) is connected to the controller (ST), to the code multiplexer (CMU) and to the code demultiplexer (CDE), in that the controller (ST) is equipped with the code multiplexer (CMU), with the source coder (QC) and with the regenerator of the transmission line (RSL), in that the code division multiplexer (CMU) is connected to the source coder (QC) and to the regenerator of the transmission line (RSL), and in that the code division multiplexer (CDE) is connected to the regenerator of the reception line (REL) and to the source decoder (QD) 2. A circuit arrangement according to item 1, characterized in that the operating unit (BE) from a call button (S1) a stop button (S2), a telephone number register (RR), a call sign output (RZ), a keyboard (TA) and a display unit (AZ ) consists. in that the call button (S1) and the stop button (S2) are connected to the control (ST), the call number register (RR) is connected to the caller ID (RE), and the call sign output (RZ) is connected to the caller ID (RE). 3. Circuit arrangement according to points 1 and 2, characterized in that the code multiplexer (CMU) of an AND gate (UG), a parallel-to-serial converter (PS), an address memory (AS), a call generator (RG) and a switch (S3) the undulator (UG) is connected to the parallel-to-serial converter (PS), the changeover switch (S3) and the regenerator of the transmission line (RSL), in that the parallel-to-serial converter (PS), the address memory (AS), the ringing generator (RG) and the changeover switch (S3) are connected to the controller (ST), that the call generator (RG) with the switch (S3), that the address memory (AS) with the Parailel series converter (PS), and the switch (S3) is connected to the source coder (QC). 4. Circuit arrangement according to the items 1, and 2, characterized in that the code demultiplexer (CDE) from a call identifier (RE), a delay line (VL), a switch network (VR), a summer (SU) and a sampling circuit (AB ) consists, that the caller identification (RE) with the regenerator of the receiving line (REL), with the delay line (VL), the summer (SU), the sampling circuit (AB) and the source decoder (QD) that the delay line (VL) with the regenerator of the Receive line (REL) and the switch network (VR), that the switch network (VR) to the summer (SU), that the summer (SU) to the sampling circuit (AB) and that the sampling circuit to the source decoder (QD) is connected. 5. Circuit arrangement according to the points 1, 2 and 4, characterized in that the call recognition (RE) of the code division multiplexer (CDE) only with the regenerator of the receiving line (REL), with the delay line (VL), the summer (SU), the Scanning circuit (AB), the source decoder (QD) and the call sign output (RZ), and that the source encoder (QC) is known to consist of a delta modulator and the source decoder (QD) of a delta demodulator. 6. Circuit arrangement according to points 1 and 4, characterized in that according to the code word of the subscriber station (T) only the high-potential leading outputs of the delay line (VL) with a corresponding number of inputs of the summer (SU) are directly connected. 7. Circuit arrangement according to points 1 and 4, characterized in that to the outputs of the delay line (VL) one, the code word length corresponding number of switches are connected, which are connected to the inputs of the summer (SU) and that only the decoding de? Codewordes necessary outputs of the delay line (VL) are switched through and the other switches are open.