DE4243510A1 - Ascertaining presence and position of module for telecommunications appts. - Google Patents

Abstract

The method is applied to indicate the presence of a module with each insertion position for the latter provided by a carrier board (2) identified by two respective frequencies denoting the position location relative to the carrier board and denoting the specific carrier board.Each module has an evaluation circuit for these two frequencies for generating a corresponding position code transferred to a central point. Pref. each carrier board is fitted with a supply group (7) including a frequency generator.

Description

The present invention relates to a method and means for determining presence and the position of installed in a unit Assemblies according to the preamble of claim 1 or of claim 14.

Such a method for a telecontrol system is over DE-PS 32 36 812 known. There is a headquarters there via data transmission devices with several Connected substations. Each substation contains one control unit equipped with a microprocessor and can be equipped with pluggable interface modules become. Addressing of the Substations are made and by querying the Slots the assignment or non-assignment of the same be determined and registered. For this, from a presence signal for a newly plugged-in module issued as soon as the assembly its required  Operating voltage and a defined state reached Has. The data are transmitted via clock pulses and the codes are generated and output as pulse diagrams.

An interface module is addressed via its slots. So z. B. with five individual contacts of a slot encode 30 different addresses. The number of addresses therefore depends on the number of individual contacts.

The object of the present invention is to be achieved be a variety of addresses with a very to be able to code a small number of individual contacts. In particular, this should be done with only two individual contacts and without additional measures necessary when inserting to be possible.

This task is solved by the in the license plate of the Claim 1 and 14 specified features. Through this Allocation of two frequencies per slot to Position detection, both of the slot the assembly in the rack as well as the Subrack in the assembly, can be a very large number of addresses are encoded because of the number the frequencies are almost unlimited. The different frequencies are also easier in Way z. B. by dividing or multiplying one Basic frequency can be generated with suitable factors.

Further advantageous details of the invention are in specified in the subclaims and subsequently based on that illustrated in the drawing Exemplary embodiments described. Show it:  

Fig. 1 is a flowchart of the process sequence of the position detection,

Fig. 2 shows the basic structure of a unit in a front view,

Fig. 3 is a circuit principle of a supply module,

Fig. 4 is the view of the slot side of a rack and

Fig. 5 shows a rack in a side view.

With monitoring, control and regulation systems or other telecontrol systems etc., in which one Central from a data exchange with decentralized Units takes place, the central and expansion of the units to be known and monitored become.

A unit 1 consists, for example, of a frame in which several subracks 2 can be installed in succession. Each rack 2 has a number of slots 3 or 3.1 to 3. n. In each slot 3 , a module 4 can be inserted and connected via the associated connector 5 . The assemblies can be of the same type and the same or different adjustability or different types. In the case of the structural unit 1 shown in FIG. 2, modules 4 inserted into the slots 3.4 , 3.5 , 3.6 and 3.9 are indicated by the dash-dotted lines in the uppermost subrack 2.1 .

In order to determine whether, and are installed at which position in a rack 2 modules 4, according to the invention for each slot 3, two frequencies fs and f z. 5. B. provided at a respective male terminal 5. i.1 and 5 .i.2 of the mating plug i. The respective subrack 2 is defined by the frequency fB. This is at each slot 3 of the rack 2 on the same connector, z. B. 5 .i.1, on and for each rack 2. i a different frequency fBi is used. Likewise, each slot 3 is assigned a different slot characteristic frequency fs and to the same connector, for. B. 5 .i.2, the respective connector 5 out. When an assembly 4 is plugged in, a position code is generated from the frequencies fsi and fBi present at the plug 5 of the slot 3 via an evaluation unit 6 provided on it or to be installed, in particular designed as a processor, indicated by a dotted line in an assembly 4 in FIG. 2, the z. B. is provided to the control center and is pending, for example, at least one plug connection 5. i. From here it is via a suitable data bus, e.g. B. an electrical and / or optical bus, forwarded to the central office. This gives z. B. the position in alphanumeric and / or numerical form and / or represents it on a display, if necessary, additionally graphically as a real replica of the assembly, rack and assemblies.

Fig. 1 shows a possible procedure of a flowchart. After the start, e.g. B. switching on the entire system or inserting the module 4 or the at least partially populated module rack 2 is from the evaluation unit 6 z. B. measured via the timer of the processor, the frequency or the period of the slot characteristic frequency fs and determined whether this is in a valid range. If this is the case, e.g. B. generated by conversion, a slot code corresponding to the occupied slot. The period of the subrack identification frequency fB is then measured and a subrack code corresponding to its position in the assembly 1 is generated therefrom and this and the slot code are sent to the control center via a data bus. Each module 4 thus represents a bus node.

All modules 4 are preferably provided with means which can generate a type code corresponding to the type of module 4 and can provide it for output to the control center. This is done e.g. B. by appropriate programming of the processor if the evaluation circuit 6 is realized by a processor. In this way, not only the position of an inserted or removed module 4 but also the type etc. of the module 4 can be determined from a control center.

Furthermore, each assembly 4 can have means for recognizing internal and / or external errors of the assembly or other system units, which outputs or provides an error-specific signal in the event of an identified error. In the multiplex operation, the control center can query whether the assignment has changed and whether and which errors have occurred at which point. Based on the information received, a display of the same z. B. on a screen and / or preprogrammed measures can be taken.

According to an advantageous development of the invention, each module rack 2 used is equipped with a supply module 7 , which is provided with a frequency generator 8 each, as shown with reference to FIG. 3. This shows the circuit components of a supply module 7 necessary for understanding the invention. This can generate a fundamental frequency fG, which is divided by first means for frequency conversion 9 into such a number of mutually different frequencies that a separate frequency is available for each of the remaining slots 3 .

In the embodiment eleven slots 3 are provided, of which in all racks 2, the same slot, z. B. 3.o, is used to connect the supply module 7 . As a means for frequency conversion 9 , nine 1: 2 dividers 10. I are provided, the output of each being connected to the input of the following 1: 2 divider 10 and each output also being separately connected to a connection element 11. I, z . B. a socket 11.9 to 11.1 is performed. The fundamental frequency fB is directly present at the socket 11.10 . Each socket 11. i is contacted with a separate line 12.10 to 12.1 , each with a defined plug connection, for. B. 5 .i.2, the connector 5 one of the slots 3.10 to 3.1 is connected (see. Fig. 4).

Each supply module 7 has an input 13 , an output 14 and a mains connection 15 and second means for frequency conversion 16 . Furthermore, a control element 17 with three inputs a, b, c and an output d is provided. Input 13 and output 14 are expediently arranged such that when the subracks 2 are arranged in succession in a column or row, the supply modules 7 are also in a column or row and the output 14 of the one supply module 7 is above or next to that Input 13 subsequent supply module 7 is. This enables a relatively short connecting line or a bus cable 18 between the two ( FIG. 2).

The input a of the control element 17 is connected to the output 8 A of the frequency generator 8 , so that the fundamental frequency fG is applied to it. The output 16 A of the second means for frequency conversion 16 is connected to the second input b. To the frequency input 16 e is connected at the output 14 of the previous rack 2 pending subrack characteristic frequency fB via a bus cable 18 or connected.

A control voltage U.St can be connected to the third input c via the input 13 or a bus cable 18 .

About the control unit 17 , when one of the supply modules 7 forms the first unit, the control voltage U.St z. B. handed over by the dashed short-circuit bridge 19 from the bus control. This has the effect that the fundamental frequency fG present at input a is switched through to output d and input b is blocked. The through-connected fundamental frequency fG passes through a hole formed as a divider stage decoupling means 20 as subrack characteristic frequency fB to all slots 3. i common line 21 which is 5 connected to each similar male terminal 5. i.1 a plug i of the slots 3. i . Thus, the same assigned characteristic frequency fB = fG is on each connector 5. i of this subrack

In one of the first racks mentioned, for. B. 2.1, the following subrack, z. B. 2.2, the output frequency output dB = fG is output via a second decoupling means 22 at the output 14 of the former and applied via the connected bus cable 18 via the input 13 of the following subrack 2.2 to its second means for frequency conversion 16 and in use a 1: 2 divider with half frequency is output to the input b of the control element 17 . No control voltage is applied to input c, which means that input a is blocked and input b is switched through. The second subrack 2.2 thus has a characteristic frequency fB with a halved frequency, which is also output on the following subrack 2.3 . The frequency divided down from the previous one is available on each subsequent rack as the basis for generating its own characteristic frequency.

It can be seen that, by installing such subracks 2.1, any number of subassemblies 4 of the most varied types can be positioned at any slot, and the associated subrack 2. i and the slot 3. I occupied there automatically in the form of position and occupancy data are available and can be displayed graphically and / or numerically at the control center. In particular, an exact image of the modules with module type and slot can be displayed on a graphic terminal.

The separate lines 12. I shown in FIG. 4 and the common line 21 and a data bus to be connected to the control center are expedient on the side 22 of the bottom 23 of the base 23 of the rack 2 opposite the plug connections 5. i of the slots 3. i in printed circuit technology provided in single or preferably multi-layer technology. The circuit carrier used can also be provided with a metal core for better heat dissipation. In addition, a heat sink 24 is expediently connected to the circuit carrier in a thermally conductive manner.

Instead of generating the basic frequency fG by a frequency generator 8 of the supply module 7 , it can also be generated externally and fed via the input 13 to the unit used as the first subrack 2 .

As can be seen from the exemplary embodiment described, the frequencies for the position of the subracks 4. I are set automatically by the bus cables 18 which are necessary anyway in connection with the subracks 2 , since the subsequent subracks 2 change the frequency obtained from the previous one by a factor K. . The subrack number n therefore generally results from the equation

This results in a correspondingly simple manner Subrack number for each halving the Frequency, i.e. with the factor K = accordingly the equation

The number n can be used in a program for one Processor in a program loop with a division determine by 2 or by bit shift.

The inventive method and the device are particularly suitable for a surveillance system, at those with the assemblies u. a. Cascades more optical Amplifiers can be realized with high optical Output powers work. For this it is necessary that the modules can exchange data and the Positions of assemblies etc. are known exactly, too if freely selectable and assemblies without special Measures can be used, exchanged or removed.

Claims (19)

1. A method for determining the presence and position of modules installed in a unit for systems of telecommunications technology, each unit consisting of a plurality of subracks and each subrack having a plurality of slots for inserting the modules, characterized in that for each slot ( 3. i) two frequencies (fs, fB) are provided, one (fs) of the position of the respective slot ( 3. i) on the rack ( 2. i) and the other (fB) of the associated rack ( 2. i) defines that each module ( 4. i) is or is equipped with an evaluation unit ( 6 ), which consists of the frequencies (fs ,; fB) available at the slot ( 3. i) for this slot ( 3. i) with respect to the position of the module ( 4. i) on the subrack ( 2. i) and the position of the subrack ( 2. i) in the structural unit ( 1 ), and a position code is generated provides a central office. 2. The method according to claim 1, characterized in that (2. i) a slot (3) is equipped with a supply assembly (7, i) in each rack, which includes a frequency generator (8), which generates a fundamental frequency (fG) , from the first means for frequency conversion ( 9 ) one of the remaining number of slots ( 3. i.1) of the respective associated rack ( 2 ) corresponding number of frequencies (fs) for detecting the position of the modules ( 4. i) the subrack ( 2 ) are generated and one of these frequencies (fs) is output to each of the slots ( 3. i) of this subrack ( 2 ) as a slot frequency (fs) and made available there for evaluation. 3. The method according to claim 1 or 2, characterized in that supply modules ( 7. i) are used, each having at least one input ( 13 ) and one output ( 14 ) and each with second means for frequency conversion ( 16 ) or is, 'one from these differing output frequency (fB is consisting of an input at the input (13) input frequency (fB)'') produces, on the one hand all the slots (3 i) of the respective mounting rack (2) as the subrack characteristic frequency (fB) supplied and on the other hand provided at the output ( 14 ) and there as the input frequency (fB ') the input ( 13 ) of the supply module ( 7 ) of a subsequent rack ( 2 ) is fed in such a way that several racks ( 2 ) on their Ein - And outputs ( 13 , 14 ) are connected to each other in series and the supply module ( 7 ) of the first subrack ( 2 ) has the basic frequency (fG) or a second basic frequency uenz either in a converted form or directly or via its second frequency conversion means ( 16 ). 4. The method according to any one of claims 1 to 3, characterized in that each assembly ( 4 ) has means by which a code corresponding to the type of assembly ( 4 ) is generated and made available for further processing. 5. The method according to any one of claims 1 to 4, characterized in that each module ( 4 ) is connected via a data bus to a center in which data for the position for the rack ( 2 ) and the slot ( 3 ) and data for the type of assembly ( 4 ) is evaluated and made available for further processing and / or displayed. 6. The method according to any one of claims 1 to 5, characterized in that each assembly ( 4 ) has means for error detection internal and / or external and / or system errors and an error-specific signal is provided when an error is detected. 7. The method according to claim 5 or 6, characterized characterized in that at least the position and Error data from the control center in multiplex mode, in particular via a serial data bus become. 8. The method according to any one of claims 1 to 7, characterized in that after inserting an assembly ( 2 ) into a slot ( 3 ), the evaluation unit ( 6 ) of the assembly ( 2 ) in one process step, the period of time on a pin ( 5.2 ) of the slot ( 3 ) measuring a frequency (fs) and, if it determines that the measured period falls within a predetermined time range, converts the value obtained into a slot number and converts it into a signal that can be evaluated by the control center, and that it is converted into another process step measures the period of the frequency (fB) present at another pin ( 5.1 ) of the slot ( 3 ) and, if it determines that the measured period time falls within a predetermined time range, converts the value obtained into a rack number and into one converts the signal that can be evaluated by the control center and the position signals received at the slot ( 3 ), in particular a data bus g. 9. The method according to any one of claims 1 to 8, characterized in that a processor is used as the evaluation unit ( 6 ) of the assembly. 10. The method according to claim 9, characterized in that the processor corresponds to each Module type is programmed and programming involves the generation and output of a type code. 11. The method according to claim 9 or 10, characterized characterized in that the timer of the processor Period time counting or frequency measurement carried out becomes. 12. The method according to any one of claims 1 to 11, characterized in that input ( 13 ) and output ( 14 ) of a supply module ( 7 ) side by side and the supply modules ( 7 ) in a column or row of the unit ( 1 ) attached Subracks ( 2 ) can be arranged in a column or row. 13. The method according to claim 12, characterized in that the inputs and outputs ( 13 , 14 ) are arranged such that an output ( 14 ) of an upper supply module ( 7 ) above the input ( 13 ) of a lower supply module ( 7 ) lies. 14. Device for carrying out the method according to claim 1 or the following, consisting of a structural unit in the form of a cabinet frame open at the front, in which a plurality of subracks are arranged one above the other and / or next to one another, which in turn have a number of slots for a pluggable assembly, characterized in that the subracks ( 2 ) are mounted in succession, in that a subassembly ( 7 ) with at least one frequency generator ( 8 ) and two frequency converters ( 9 ; 16 ) is provided in each subrack ( 2 ), one of which ( 9 ) one of the number of slots ( 3 ) for the modules ( 4 ) corresponding number of frequencies (fs) can generate and the other ( 16 ) can perform a simple frequency conversion that each frequency (fs) generated by the first frequency converter ( 9 ) a separate line ( 12. i) to a defined plug connection ( 5. i.2) each one of the slots ( 3. i) and that the frequency (fB) output by the second frequency converter ( 16 ) is routed via a common line ( 21 ) to a defined plug connection ( 5. i.1) of each slot ( 3 ) and also via a connecting line ( 18 ) is connected to the input of the second frequency converter ( 16 ) of the subsequent subracks ( 2 ), and that all slots can be connected to a control center via a data bus. 15. The device according to claim 14, characterized in that the frequency converter ( 9 , 16 ) of the supply module (s) ( 7 ) are designed as dividers and the first frequency converter ( 9 ) consists of several dividers ( 10. i), the output a divider (10 i) except with the associated plug-in connection (5 i.2) to the input of the subsequent divider (10 i) is connected. 16. Device according to one of claims 14 or 15, characterized in that each supply module ( 7 ) has a control element ( 17 ) with at least three inputs (a, b, c), a first input (a) having the output ( 8 A) of the frequency generator ( 8 ), a second input (b) is connected to the output ( 16 A) of the second frequency converter ( 16 ) and a control voltage (U.St) can be applied to the third input (c) with which either the frequency at the first (a) or at the second input (b) can be switched through to the output (d) of the control element ( 17 ). 17. The device according to claim 16, characterized in that the output (d) of the control member ( 17 ) with the common line ( 21 ) and a connection of the output ( 14 ) of the supply module ( 7 ) is connected. 18. Device according to claim 17, characterized in that between the output (d) of the control element ( 17 ) and the common line ( 21 ) and between the output (d) and the connection of the output ( 14 ) each have a decoupling means ( 20 ; 22nd ) is provided. 19. Device according to one of claims 14 to 18, characterized in that the common line ( 21 ), the separate lines ( 12. i) and the data bus on the plug connections ( 5. i) of the slots ( 3 ) opposite the outside of the Bottom ( 23 ) of the subrack ( 2 ) are arranged in printed single or multi-layer circuit technology.