HU180142B - Arrangement for high speed transmitting digital information on the limited distance - Google Patents

Abstract

The apparatus according to the invention transmits more than 1 million bit / seo speeds digital information, phase modulated, in a synchronous form at a limited distance / 100 m - 1000 m / intelligent equipment / computer microprocessor / between.

Description

With the rapid increase in the number of intelligent devices, there is a need, among other things, for computers and microcomputers of different performance operating within one administration system to exchange information.

In order to meet the demand, so-called communication oscillators are built between the devices, the design and transmission speed of which depend greatly on the target to be achieved and the distance to be bridged. In recent years, there has been a significant increase in the number of cases where several intelligent equipment, mainly mini and microcomputers, operate at the same site. At the same time, different principles for organizing equipment into a common system have developed. One of these basic principles is the capacity allocation or resouroe sharing principle, based on the well-known fact that peripherals / storage, hardoepers / units are cheaper the more powerful they are. Effective implementation of the principle requires high-speed information transfer, especially when allocating high-capacity storage.

Outstanding ezámítógépgyárak such as Digital Equipment Corporation / PDP-11 Peripheral Handbook, 1976, p 4-150. / _R or Hewlett-Paokard Journal, March 1978 / products have been sold from the units for years to two or

-1180.142 allow multiple computers to transfer high speed information over a limited distance. A common feature of these units is that they can be used within a given engine family. Developed by Digital Equipment Corporation and controlled by a KMC-11 or DMC-11 microprogrammable controller, the transmission unit, connected to the PDP-11 family, is a so-called transmission unit. The 1 Mb local line unit has a full storage medium for storing a message / information volume transmitted during the transmission process, so its use has limitations on the load on the computer. The constraints ensure that synchronization. transmission transmission equipment at the appropriate rate. be able to access the computer's memory.

The object of the present invention is to provide a transmission device which is widely applicable, but does not impose any particular conditions on the speed and load of the intelligent device,

The block diagram of the invention is shown in FIG. 1, and a block diagram of an embodiment is shown in FIG. 2, which is an arrangement that stores the message to be transmitted both before and after transmission in the transmission apparatus while automatically performing information transfer between stores. integrity check.

There is no time-limited, asynchronous transfer between pre-transfer and post-transfer intermediate storage and intelligent devices. This solution relieves smart equipment of the constraints of high-speed synchronous transmission.

The arrangement according to the invention is illustrated in Figure 1. It consists of a first intermediate storage 21 directly connected to the first intelligent device / computer, a microprocessor / microprocessor 21 and a first automatic transmission unit 31, a second intermediate storage 22 and a second automatic transmission unit 32 directly connected to the second intelligent device / computer, microprocessor 12 and Of 4 transmission cables (s) connecting 31 first automatic transmission units and 32 second automatic transmission units,

The information exchange between the first intelligent device 11 and the first intermediate storage 21 and the second intelligent device 12 and the second intermediate storage 22 is asynchronous.

On the other hand, between the first intermediate storage 21 and the second intermediate storage 22, the first automatic transmission unit 31 and the second automatic transmission unit 32 carry out synchronous information transmission via the transmission cable (s).

An arrangement of a possible embodiment of the transmission device according to the invention is shown in Figure 2. One characteristic of the implemented transmission device is that it consists of two completely symmetrical parts, so-called stations. One, the first station consisting of units denoted by numbers containing 1 as the second digit, and the second, the second station consisting of units denoted by numbers having 2 as the second digit.

Another feature of the transmission device is that it is also divided into two fully symmetrical parts, so-called transmission channels. One channel transmits information from the first intelligent device 11 to the second intelligent device 12 and from the first transmitter 311, the first preset 211, the first broadcast controller 312, the first master clock 313, the first transmission cable 4l.

-2180.142 • 324 second receivers, 222 second post-storage, 325 second receivers, 326 second slaves · clock. The second oschannel transmits information from the second intelligent device 12 to the first intelligent device 11 from the second transmitter 321, the second preset 221, the second broadcast controller 322, the second master clock 323, the second transmission cable 42, the first receiver 314, consisting of first post storage 212, first reception controller 315, first slave clock 316,

The structure and operation symmetry allow one of its transmission oscillators to be written, because the descriptions will be valid for the other channel with the following substitution: for the first word, second for the unit identifier numbers in the second, instead of 1. We write.

Information transmission can take place simultaneously between the two transmission channels, between the local and remote stations, that is, the connection is full-duplex.

Operation of the transmission device according to Figure 2.

The first transmitter 311, the second receiver 324, the second transmitter 321, and the first receiver 314 autonomously build and then control the two-way transmission channel before transmission. The transmission process from the first intelligent device 11 to the second intelligent device 12 is initiated by the first intelligent device 11 by sending an instruction to the first broadcast controller 312. In the transmission process, the message to be transmitted is first transmitted from the first intelligent device 11 to the first pre-storage 211. The input of the first pre-memory 211 to the instruction of the first intelligent device 11, with the permission of the first broadcast controller 312, goes in assimilated units corresponding to the word length of the first intelligent device 11. The message length is active within the capacity of the first storage 211.

As the next phase of the transmission process, the first broadcast controller 312 directs the message entered into the first preset 211 in an asynchronous manner with additional information required for transmission / message start, message closing, CRC character error checking / to the first transmitter 311. The information is transmitted synchronously between the first preset 211 and the first transmitter 311 using the signals of the master clock 313. The first transmitter 311 also encodes the message using the signals of the first master clock 313 and then transmits it to the first transmission cable 4l as a bit-phase, phase-modulated signal,

Receiver 324 regenerates and decodes the signal coming from the first transmission cable 4l. The receiver extracts from the incoming signal the phase reference signal needed for decoding and thereby the incoming message. The phase reference signal controls the second slave clock 326, using the signals of the second receiver 324 and the second reception controller 325 to synchronize reception and writing of the message. utótárolóba. If no signal is received on the transmission cable, the second slave clock 326 receives a control signal from the second master clock 323 so that the sequential circuits using the Signals of the second slave clock 326 operate at the appropriate frequency.

As a third phase of the transmission process, the second intelligent device 12 reads the received message from the second post storage 222 to signal to the second reception controller 325. There is asynchronous transmission between the second post storage 222 and the second intelligent device 12 in the equivalent units of 3180.142.

The units that build and control the transmission channels will produce selective fault signals if the channels are not built or if transmission is interrupted for any reason on the built-in sub-channels.

A selective error message is generated by the first broadcast controller 312 and the second broadcast controller 322, respectively, when the composed message is formally incorrect or if the external station detects an atomic error while preparing the message.

The first reception controller 315 and the second reception controller 325 also generate a selective error message if the received message is defective or the receiving station detects a channel error while processing the message,

In addition to the fault indications, the transmission device automatically rebuilds the faulty channel,

At the physical level, the digital modulated synchronous signal transmission is widely used for the transmission of digital information, where, as already mentioned, the decoding of the transmitted encoded signal utilizes the phase reference / clock signal obtained from the signal itself. With phase reference, a slave clock generator runs synchronously on the receiver side and its incoming signals are synchronously processed with its phase splitting signals,

In order to be able to transmit the physical level, the slave clock generator of both receivers must be synchronized with the master clock generator of the transmitter connected to the transmission cable at the time of transmission.

The transmission channels must be set up before each message, or maintained between messages, so that the receiver can detect the start of non-perlodic incoming messages.

The transmission device described is advantageously applicable to information systems between intelligent devices of different types and capacities, since the information to be transmitted is fully stored by the device both before and after transmission, so that the requirements of synchronous transmission technology are not transferred to intelligent devices. . The transmission device is easily adaptable to modern computing devices such as microprocessors, making it well suited for distributing centralized computing capacities in low-performance, light-weight systems.

The transmission device automatically senses and checks the transmission channels between the two intelligent devices. If an error is detected, it will rebuild them and at the same time indicate a malfunction to both devices.

Claims (2)

Patent claims 1, / Arrangement for high speed, high speed transmission of digital information including a first intermediate storage / 21 /, a second intermediate storage / 22 /, a first automatic transmission unit / 31 /, and a second automatic transmission unit / 32 /, and transmission cable / plow / t / 4 / characterized in that the first intermediate storage / 21 / first output and input is connected to the first intelligent device / 11 /, the first intermediate storage / 21 / second output and input-4180.142 you are the first automatic connected to the first input and output of the transmission unit / 31 /, the first automatic transmission unit / 31 / the second output and input to the first intelligent device / 11 / connected to the first automatic transmission unit / 31 / the third output and input to the transmission cable / s / / 4 / connects to one end of the transmission cable / s / / 4 / to the other end of the second automatic transmission unit / 32 / and connected to its output, the second automatic transmission unit / 32 / second output and input to the second intelligent device / 12 / connected to the second automatic transmission unit / 32 / first output and input to the second intermediate storage / 22 / second input and output, the second output / input 22 of the second intermediate storage / 22 / connects to the second intelligent unit / 12 /. Embodiment of arrangement according to claim 1, characterized in that the first intermediate storage (21) is preferably from a first pre-storage (221) and a first post-storage (212), the second intermediate storage (22) from a second pre-storage (221) and a second post-storage / 222 /, a first auto-transmission unit / 31 / a first transmitter / 311 /, a first broadcast controller / 312 /, a first master clock / 313 /, a first receiver / 314 /, a first reception controller / 315 / and a first slave clock / 316 /, a second automatic transmission unit / 32 / a second transmitter / 321 /, and a second broadcast controller / 322 /. a second master clock / 323 /, a second receiver / 324 /, a second reception controller / 325 /, and a second slave clock / 326 /, the transmission cable / s / / 4 / a first transmission cable / 41 / and a second consisting of a transmission cable / 42 / and a first output and input of the first pre-storage / 211 /, a first output and input of the first post-storage / 212 /, a third transmission and input of the first broadcast controller / 312 / a first output and input of a first reception controller. it connects to the first intelligent device / 11 /, the fourth output of the first broadcast controller / 312 / connects to the second input of the first preset / 211 /, the second input and output of the first post storage / 212 / connects to the second input and output of the first reception controller / 315 / first master clock / 313 / first output and input connected to first transmitter / 312 / first input and output, first master clock / 313 / third output to first slave clock is connected to the first input of / 316 /, the second output and input of the first transmitter / 311 / is connected to the second input and output of the first transmitter / 312 /, the first master clock / 313 / second output is connected to the third input of the first transmitter / 311 / first output / 211 / second output connects to first transmitter / 311 / fourth input, first receiver / 314 / fourth output connects to first transmitter / 311 / first output / first receiver / 314 / first output to first post-storage / 212 / third connects to the input of the first receiver / 314 / the third output and input of the first receiver / 315 / the third input and output of the first receiver / slave / 316 / the first output connects to the fourth input of the first receiver / 315 / slave / 316 / second output and input connects to first receiver / 314 / second input and output, first transmitter / 311 / first output to first transmission cable / 41 / one end connected to the first transmission cable / 41 / Osato other end connected to the second receiving / 324 / to the first input, the second transmitter / 321 / first output of the second transmission -5180.112 connected to one end of cable / 42 /, second end of transmission cable / 42 / connected to first input of first receiver / 314 /, second output and input of second slave clock / 326 / to second input / output of second receiver / 324 / is connected, the first output of the second slave clock / 320 / is connected to the fourth input of the second receiver / 325 /, the third output and input of the second receiver / 324 / is connected to the third input and output of the second receiver / 325 /, the second receiver / 324 / first its output is connected to the third input of the second post-storage / 222 /, the fourth output of the second receiver / 324 / is connected to the first input of the second transmitter / 321 /, the second output and input of the second transmitter / 321 / is connected to the second input and output , the first output and input of the second master clock / 323 / is connected to the first input and output of the second broadcast controller / 322 /, the second output of the master clock / 323 / odik is connected to the third input of the second transmitter / 321 /, the third output of the second master clock / 323 / is connected to the first input of the second slave clock / 326 /, the second output and input of the second receiver / 325 / connected to the second input and output of the post-storage / 222 /, the fourth output of the second broadcast controller / 322 / connected to the second input of the second pre-storage / 221 /, the second output of the second storage / 221 / connected to the fourth input of the second transmitter / 321 / 325 / first output and input, second post storage / 222 / first output and input, second pre-storage / 221 / first output and input, second broadcast controller / 322 / third output and input are connected to second intelligent device / 12 /.