DE2645196C2 - Concentrator for time multiple operation - Google Patents

Description

The invention relates to a concentrator for time multiple operation according to the preamble of the main claim.

Such a concentrator is cited in DE-OS 22 798 as prior art. The writing itself deals with questions of timing adjustment.

Within the concentrator, a connection is established from subscribers connected to η to the m channels, where n> m . The connection from the exchange to the concentrator can be wireless over long distances; digital radio transmission has advantages with regard to the signal-to-noise ratio and the use of secure coding phenomena occur and the connections are briefly interrupted as a result. The existing connections are lost and have to be re-established. This means loss of time and a nuisance for the participants.

It is the object of the invention to provide a remote-controlled To create concentrator which avoids this disadvantage and is also so flexible that it can be used in future Systems and connection conditions can be adapted without difficulty.

According to the invention, this is achieved by the teaching of the Hauptanspnichs-

Refinements of the invention can be found in the subclaims.

The invention will now be explained with reference to figures. It shows

Fig. 1 is a block diagram of the concentrator according to the invention ^,

F i g. FIG. 2 shows the composition of three types of instructions which are carried out in the concentrator according to FIG. 1 can be used,

F i g. 3 is a timing diagram showing the timings of a multiple time frame and FIG

FIGS. 4a-4c show the composition of a message the exchange and the reply message.

The block diagram according to FIG. 1 shows the structure of the concentrator according to the invention. An important part is a micro-programmable control unit for carrying out various operations required by the exchange and for checking its own circuits. The control unit contains a computing unit 10, a read-only memory U for storing the microprograms, an instruction counter 12, an instruction register 13, a working memory 14, which consists of sixteen registers A 0 ... A 15, two registers 15 and 16, a logic circuit 17 for control of the command counter 12 and several NAN D circuits 18. Further components of the concentrator are connected to the control unit via data lines, in particular a memory 33 and an associated register 331, a subscriber memory 35, another memory 36 with registers 371 and 372, registers 361 and 351, a multiplexer 34 and subscriber circuits 40.

Each of these circuits is connected to the control unit via a data bus D for receiving commands and data and via a data bus A for sending data. A synchronization circuit 20 is also connected to the data bus A ; it receives data from the exchange via an input / output unit 32. Another input / output unit 31 is connected to the data bus D. All of these various circuits are peripheral units to a control unit, they receive instructions with an address code from it. Each unit can recognize its own address in a message and sends data back if necessary. This achieves great flexibility, the concentrator works independently of the exchange, and different units can be connected to the data lines A and D for different requirements. Suitable programs for these units can also be stored in the read-only memory of the control unit. The design and layout of such units is known; examples can be found in French patent 13 28 952.

The way in which the concentrator works with the exchange is described below.

A time multiple frame consists of 24 channels VO

... V 23; one channel is used for signaling, one channel for synchronization (FIG. 3). Each channel is subdivided into 6 bit times AfO ... M 5 and lasts 5.208us- The bit times are in turn divided into eight base times a ... h Coded information, consisting of six bits, is transmitted on a channel, which has a bit rate of 1.152 megabits / s corresponds to The channels V2 ... V 23 are used to transmit the conversation information of the participants. All data are converted into serial form. The synchronization unit 20 checks the synchronization code arriving on the channel VO; If this code is received correctly, the concentrator is ready to receive signaling information on channel VI.A microprogram in program memory 11 corresponds to each signaling information item. There are three different types of commands / 1, / 2 and / 3 (Fig. 2). every command! consists of 16 bits 00 ... 15 and contains an operafh> nscode codop 0 ... codop 3 of 4 bits. The eleventh bit of the command / 1 is zero, an address part A is represented by the bits 05 ... 09, a destination address part B by the bits 00 ... 04. The command / 2 consists of the eleventh bit with the value 1 and Address bits 00 ... 10. The command / 3 is a jump command with an operation code (bits 12 ... 15) and the address of the next command (bits 00 ... 09). Hatched parts (bits 10 to / 1 and bits 10 and 11 for / 3) show that these bits are not evaluated.

The address part A of each command arrives at the processing unit 10, which emits the necessary signals for its execution. If the eleventh bit is zero, the bits 05 ... 09 represent the address of the operand A (ADROR in FIG Has a value of one, bits 05 ... 10 represent the value of the operand (VALOR) , which is then transferred to data bus A via gate circuits 18. Bits 00 ... 04 of commands / 1 or / 2 indicate the number address of the relevant command (ADRDS). If there is a jump instruction (/ 3) in the instruction register 13, the bits 00 ... 09 represent the address of the next instruction and are transferred to the instruction counter 12 together with a jump instruction which is obtained by decoding the operation code.

The F i g. 4a and 4b show the composition of a message from the exchange and the response message. This message relates to the scan of the subscriber memory. Each message consists of six words I to VI, each with six bits 00 ... 05, each word being transmitted on channel VI of a frame. The first word is the same for all messages and consists of bits with the value 1. The second word represents the code of the message, in this example the code relating to the scanning of the subscriber memory and of two bits 00 and 01 with the Value 1 exists The response is the same as the message from the exchange. The third word Hl of the exchange denotes the number of a subscriber device and consists of bits NEQ 2 ... bo NEQ 5 and two bits with the value zero. The concentrator then delivers the requested data with regard to this subscriber device and with regard to the next three subscribers. these are the ones for which the last two bits of the following values HA bb ben: NEQi = O. NEQQ = ',; NEQ i = \. NEQO = O and NEQ 1 = 1. NEQO = 1. This saves the central control system and time. The bits of the fourth word IV and the fifth word V of the message from the exchange all have the value 0. The words IV and V of the response are each divided into two half-words, each half-word is assigned to one of the four subscribers. The relevant data for these four participants (£ (? 00 ... £ (? Ll)) are (Fig. 4c):

- Subscriber is already connected ( CONN bit).

- loop of the subscriber line not closed (bit EBE),

- Participant is noted in the memory (bit FA).

The last word VI of each message is a parity word; each bit represents the parity of one of the five words I —V. The parity word is used to check the transmission of both the messages from the exchange to the concentrator and vice versa.

There are 3 types on the signaling channel V1 Transfer of messages: messages from the exchange to the concentrator, feedback to the central office from the concentrator and error messages to the exchange, which are sent instead of the acknowledgment when a command from the exchange cannot be carried out or an incorrect transmission due to the parity check was established.

A possible report and feedback was given under the F i g. 4a-4c. Other possible messages the exchange are z. E.g. whether a participant is connected to a certain channel, whether a specific participant is connected to a channel. that in the memory new data relating to a subscriber should be enrolled, etc.

These are only examples, a corresponding design of the peripheral units of the control unit allows all requirements to be met, a special program can be provided for each message from the exchange, the peripheral units work largely independently of one another. Thus' -Λ an extension or modification of the concentrator possible without difficulty. Different types of subscriber devices that work with different bit rates can also be served.

In the event of incorrect transmission of messages from the exchange to the concentrator, e.g. B. in the event of failure or interruption of the radio connection, the control unit reports this to the exchange and waits until new faultless messages arrive.

For this purpose 2 sheets of drawings

Claims (4)

Patent claims: 1. Concentrator for time division, which is remotely controlled via a multiplex connection from a switching center, a multiplex frame containing a synchronization channel, a signaling channel and m information channels for the subscribers, with a speech path network from the subscriber connections to the multiplex line, characterized in that a stored-program control unit (10 —18) the messages from the exchange on the Signalisieningskanal is provided receives feedback emits the messages from the exchange and evaluates the necessary logical links in the concentrator by passing on corresponding program commands via data lines (A, D) a \ c to several peripheral units (31-40) which, based on address codes, recognize and execute the program commands intended for them. 2. Concentrator according to claim I, characterized in that the messages of the exchange consist of N words, that each word contains P bits, one word being transmitted in a multiplex frame, and that the N words are an identical start word for all messages and the code of the The second word indicating the required operation and an iVth word whose bits indicate the parity of corresponding bits in the N-1 preceding words. 3. Concentrator according to claim 1 and 2, characterized characterized in that the control unit after receiving a message in front of the exchange a The Either the requested data is identical to the received message or contains a confirmation of receipt or serves as an error message if the message from the exchange cannot be processed or due to a parity test was recognized as faulty by the control unit. 4. Concentrator according to claim 3, characterized in that when the content of a subscriber memory is requested by a message from the exchange, the corresponding feedback contains not only the requested data relating to the one subscriber, but also the data of the next M subscribers, where M is a selectable number.