DE3343456A1 - Arrangement for operating a plurality of units on a shared data line - Google Patents

Abstract

To operate a plurality of units each having a data output on a shared data line, a comparison device and a control device are provided in each unit, for control. The comparison devices of the units are connected to one another and to the control devices by organisation lines. An individual unit whose control device is activated operates as a master, while the other units operate as slaves when the control device is deactivated. A data line access request from one unit is represented by a request signal on a first organisation line, which signal starts up an address counter provided in the control device. If the address converted by the counter matches the address of the requesting unit, the latter address interrupts the counting cycle by means of a signal on a stop line. A particularly advantageous application is in a data transmitting/receiving system with a plurality of transceivers and a plurality of operating units to control the dialogue between the operating units and the transceivers via two (long-distance) data lines with bidirectional transmission.

Description

Arrangement for the operation of several devices on a common one

Datenlei device The invention relates to an arrangement for operating several Devices on a common data line in the preamble of the claim 1 specified Art.

The interconnection of several devices, each of which in irregular Intervals between data to be output on the data line requires a additional control of the access of the individual devices to the data line, there several devices are not allowed to act on the data line at the same time.

The object of the present invention is to provide an arrangement in the preamble of claim 1 described to indicate the type that is as simple as possible with control of device access to the Data line guaranteed with equal access for all devices.

The invention is described in claim 1. The subclaims contain advantageous awards and Wt

In addition to the address lines, the arrangement according to the invention requires with only two additional organizational lines, a minimum of connecting lines. The additional effort for the control device is essentially limited to an address counter which, according to a favorable embodiment, is a simple clocked binary counter.

This enables the integration of the control device in each of the Devices without any significant increase in effort.

This avoids an additional control unit and each of the connected devices can be used as a control device. For integration the control device no additional connections are required, since the Control device no separate connection lines to the individual devices is required and is therefore connected to the organization lines inside the device. The number of subscriber devices that can be operated simultaneously on the data line is limited by the number of available organization addresses. The actual The number of devices connected via the organization lines can be significantly greater be sure that the organization addresses can be alternately assigned and changed, so that devices can be switched on or off as participants as required.

The invention is used particularly advantageously in a message sending / receiving system with multiple Transmitting and / or receiving devices that belong to the first Arrangement of the type according to the invention are combined, and with several control units, which are interconnected to form a second arrangement of the type according to the invention, the two arrangements via two data lines with opposite transmission directions for the transmission of send and / or receive information and control signals, if necessary are also connected over greater distances.

The invention is based on an embodiment from the as special advantageous specified application with reference to the figures further illustrated. FIG. 1 shows the structure of a message receiving system FIG. 2 the essential equipment of the invention of a single device FIG. 3 the functional sequence in an arrangement according to the invention.

In the message receiving system in FIG. 1 are the recipients EI to E5 combined with one another via cables KE to form an arrangement of the type according to the invention. The cables KE include both the organization lines OL and the data lines DL (see FIG. 2). If necessary, the cables are at the last device in the series provided with terminating resistors W.

A cable leads from the receiver El to the receiver-side distributor VE, where the data lines DL with the long-distance line F connected and the Organizational lines are disconnected. The line F enables data traffic in both directions. Basically, their length is arbitrary. It can also be a Act radio link. Transmission techniques from the prior art are sufficient known. At the other end of the line F, the operating devices Bi, B2, B3 are the same Way as the receiver with cables KB to an arrangement of the type according to the invention combined and via the distributor VB on the control unit with the line F tied together. The send and receive lines are in one of the two distributors crossed.

The receivers are, for example, remote-commandable Automatic direction finders or telegraph view receivers with different reception frequency ranges or different orientations of the connected antenna. Ask the recipients independently or when called by one of the operating devices data telegrams, such as a determined bearing angle, a frequency, received data or the like together and then apply for access to the from the receivers to the operating devices leading data output line D1 by sending out a request signal R on the request line Ol (FIG. 2). Until access to the data line is granted the data telegrams must be buffered. The number of over the cables KE summarized receiving devices KE is in itself ~ # iany, so that the scope of the Receiving system can be changed at any time. Only the number of receiving devices which can be active at the same time as requesters for the data output line D1, is limited by the number of available organization addresses. The single Recipients can use additional input options, e.g. B. about the Data input line D2, an organization address can be assigned and taken again. It will only those devices whose current system function requires data output on the Data line D1 for transmission to one of the operating devices requires an organization address assigned, vie addressing of the receiving devices by the operating devices and vice versa takes place via the data lines DL with device addresses that are independent of the organization addresses are.

Each of the interconnected receiving devices EI to E6 contains one Device for controlling the organizational management. However, only one of these control devices is in operation. One of the receiving devices is selected as a control device via each control device has switching means M, which are either directly on or on the device can be operated remotely via the data line. The same applies to the Operating devices.

The FIG. 2 shows, for a receiving device, those for understanding the invention essential parts when using a certain interface standard, without yourself to restrict to this. Circuit details are familiar to the person skilled in the art.

The data lines, .gen DL for dialog are common to all receiving devices with the operating devices and the organization lines OL. Via the data line D2 can provide information on frequency setting and bearing reading from the operator panels etc. also telegrams for programming a specific organization address and for actuating the switching means M, by means of which the relevant device as a control device can be switched, transmitted.

For use as a control device is essentially only the clocked address counter AZ is additionally switched, so that this receiving device as the master and the other receiving devices with the address counter switched off as slaves work.

The core of the slave devices is the address comparator Komp, the a programmed address P parallel to that on the address lines 03, 04, 05, o6 compares the existing address A set by the address counter A7 and at Equality emits a corresponding signal. In binary coding, the four address lines fifteen different organization addresses available.

An address remains unoccupied as an idle address. So it can be up to up to fifteen devices can be simultaneously active as requesters for the data line.

The functional sequence results particularly clearly in connection with FIG. 3. At the beginning of the considerations, the data line is free, i. H. none the device is sending data or requesting access. In this case the request line O and the stop line 02 are without a signal, which is the case with the special The interface standard shown corresponds to the line condition; d H. the Address lines 03, 04, 05, 06 then carry the organization address of the device, that last output data on data line D1, in the example the device with the address 7t. The idle state of the counter status in the absence of a data output request has the advantage for the application described that during the rest period Disturbances of the receiving devices by the stray fields of the switching clocks can be avoided.

A change in the signal levels occurs because the device with the organization address "9" Request signal R the state of the request line 01 changes from H to L (R (9)). this causes the start of the counter clock CL. First of all, the counter emits a synchronization signal (with level L) on the stop line 021 which is the decisive for the address comparison Point in time roughly in the middle between two counting bars to avoid address misinterpretations in the edge area of the address signals on the address lines. Since that Device with address "7" does not request access to the data line, remains the address comparison without consequences. The one started by the request signal R. Counter A7 switches one address on to organization address 8. Here, too, results the address comparison at the time of the synchronization signal on the stop line no match between addressed device and requesting device, so that the counter switches to address "9". When the synchronization pulse occurs the control device of the device with the address "9" stops on the stop line the stop line at level L as long as the aniuuu. # - rungssignal R from this device is maintained. The counter AZ then does not continue to run, so that no further Device is addressed.

Prerequisite for maintaining level L on the stop line 02 is the simultaneous presence of a request signal R and an address match signal from the address comparator comp. As long as this condition is met, there is a transmit signal T the output of the data, e.g. B. a start bit StB, data bits DB and a parity bit PB include, free on the data line D1. The duration of the issue depends on the Requirement of the sending device and is therefore compared to a specified sending duration of considerable advantage, as this is not the case with short data telegrams unnecessary remains with the device for a long time and long telegrams are not divided into several parts endings have to be chopped up.

While the device is sending data with the organization address 11 "9", I also provided the device with the address "10" and sent data request the allocation via a request signal R (10) on the request line an access to the data line Di for data output. Since the request line but is already at level L, results from the new additional request signal no change. The counter AZ does not continue to run and the device mic at address "10" remains on hold while maintaining its request signal. A Transmit signal T is illl ^ device ~ 10 "not generated because there is no equality between programmed address and the address on the address lines is.

The device 119: 1 takes its request signal after sending out all data R back. As a result, the transmit signal T and the level also disappear in the device 11911 the stop line 02 changes from L to H, since it is no longer in any device at the same time a request signal R and address equality is given. The level of the request line remains at L due to the request signal R (10) from the device "10s. The combination the level states on the request line 01 (L) and the stop line (H) starts the clock CL of the address counter AZ. This then gives one again first Synchronization pulse (level L) on the stop line with the organization address still unchanged 11911. Since no address match is found for the requesting device ~ 10 ", the counter cycle is running continue and the counter sets the next organization address ~ 10 ". The device stops at the next synchronization pulse on the stop line i'10 "fixes the level L of the stop line, since there is a request signal ols as well an address match signal occur. At the same time there is a transmission signal in the device ~ 10 " T is generated and the data provided are applied to the data line D1. After the end of the data output, the request signal R is withdrawn. De of no other device has a request signal, both change the request line 01 and the stop line 02 change their level from L to H. In this case, the Counter is not restarted and remains at the last set address t'10 " stand until a new request signal occurs.

In the described access control by the inventive Arrangement, every device has the same chance of access. Time becomes the predominant Partly divided between the devices that actually require access to the data line. Simultaneous requests are served one after the other. The organization address changes, for example, with a cycle of 2 msec, so that when the data line is unoccupied the allocation takes place after a request after 30 msec at the latest, depending on the relative position of the requesting address and the address last set.

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Claims (13)

Claims arrangement for operating multiple devices, each with a data output on a common data line (D1) with a control device, the organization lines separated from the data line at the request of a or several devices each nux one of the provided with organization addresses Devices activated for outputting Uat # on the data line, characterized in that that the organization lines (OL) also connect the devices to one another, that a first organization line (01) as a request line that can be acted upon by each device, a second management line (02) as one of a requesting and of the Control device addressed device to be activated during its data output time Stop line and the other organization lines (03, 04, 05, 06) as address lines for the organization addresses are switched that the control device has a When a request signal is received on the first data line, the organization addresses from the last organization address set in cyclic Sequence calling address counter (AZ) contains its counting cycle when it occurs interrupts a signal on the stop line. 2. Arrangement according to claim 1, characterized in that the control device during the address counting cycle via the stop line synchronization pulses for address comparison gives away. 3. Arrangement according to claim 1 or claim 2, characterized in that that the address counter is a binary counter and the organization addresses in parallel encoded form on the address lines. 4. Arrangement according to one of claims 1 to 3, characterized in that that each G-erq: - one with the address lines and the device-internal address coding connected address comparator (Komp), the output of which if the addresses are the same the stop line is activated. 5. Arrangement according to one of claims 1 to 4, characterized in that that the organization address of a device over additional input options is changeable. 6. Arrangement according to claim 5, characterized in that the additional Input options include interchangeable coding plugs. 7. Arrangement according to claim 5, characterized in that the additional Input options for a data input on each device and an additional data line (D2), via which the address allocation or withdrawal takes place remotely. 8. Arrangement according to one of claims 5 to 7, characterized in that that more devices are available than organization addresses are available, and that the Devices can be assigned an available organization address as required. 9. Arrangement according to one of claims 1 to 8, characterized in that that the control device is integrated in one of the devices and is device-internal dfo organizational management is connected. 10. The arrangement according to claim 9, characterized in that each of the Devices contains such a control device that switches on via switching means (11) or can be switched off and that only one of the control devices is in operation is. 11. Arrangement according to claim 7 and claim 10, characterized in that that the switching means can be operated remotely via the further data line (D2) are. 12. Arrangement according to one of claims 1 to 11, characterized by their application in a message sending / receiving system with multiple transceivers (Ei, ... E5) and several control units (BI, B2, B3) in such a way that the transceivers among each other by means of organizational lines, the operating devices among each other by means of further organizational lines and the operating devices with the transceiver devices are connected via two data lines with opposite transmission directions. 13. Arrangement according to claim 12, characterized in that the organization addresses de transceiver devices via the from the operating devices to the transceiver devices leading data line from the control units & us can be allocated and changed.