DE3017238A1 - Station identification code generator in telephone system - uses ROM stored 0-9 codes selected by conductor pattern unique to station - Google Patents

Abstract

A microprocessor (MP) sends out the identification code group (Q) in accordance with a conductor pattern (PF) produced on, e.g. a p.c.b. between input lines (Ia,Ib, to IVa,IVb) and four output lines each of which is weighted with two alternative digits dependent on whether it is connected to an 'a' or 'b' line. The address lines (A1 .. An) of the microprocessor cause these inputs to be scanned sequentially, and to apply the corresp. output (on Xo to X4) to a storage unit (ROM) holding the binary equivalents for the numbers 0-9. The pattern for individual stations may be produced on a ceramic substrate in thick film in the form of a complete grid and the non-applicable conductor junctions erased subsequently and the entire package sealed. This gives security against tampering - important when the station identification signal is used for debiting call fees.

Description

Method and circuit arrangement for

Generating station-specific identifiers in telecommunication networks The invention relates to a method and circuit arrangement for performing the method for Generation of station-specific identifiers in remote control networks.

Thus in a station receiving a message the sending station can be determined, the message is identified by a station-specific identifier added. So from DE-AS 12 22 551 a circuit arrangement. for subscriber devices known in vehicle radio networks, which automatically before each call or during a Emergency call sends out a station-specific identifier. The identifiers exist in each case from several code numbers, each of which is assigned one of ten tone frequencies. A programming field is provided in every device, on which certain Wire jumpers the identifier assigned to the respective device can be set. The disadvantage of this circuit arrangement is that the identifiers can only be transmitted via a channel suitable for the transmission of audio frequencies can and for receiving and evaluating a specially set up for this process Device is necessary. Another disadvantage is that there are not several identical digits may follow one another directly.

It is known that the code characters necessary for the formation of identifiers Information in mask or electrically implemented as integrated semiconductor circuits programmable permanent memory to store. The disadvantage is that for programming Knowledge of the used code is necessary that the individually different Programming of hard drives is uneconomical because of the high cost of the mask or because of the time required for the electrically programmable Fes, t memories is.

The object of the invention is to provide a method and a less expensive one Specify circuit arrangement with low power requirement for the generation of station-specific identifiers in telecommunication networks in the form of z.H. in data transmission usual code characters (ASCII code, telegraph alphabet), including the immediate Sequence of sliding code characters should be possible. They are also supposed to be used for recruitment the identifiers have no knowledge of the code used to form the code characters to be required.

The object is achieved by a method and a circuit arrangement solved according to the claims.

The advantages of the invention are that the identifiers via data transmission paths can be transmitted and evaluated in data processing systems, so that no own Evaluation devices are necessary, and that when the Codes no new setting of the programming field is necessary.

The need to use the permanent memory to form the code characters Programming the code used is not a disadvantage, as these are read-only memories in all Devices are programmed in the same way and many permanent memories are programmed in the same way is economically possible. In addition, the little information to be stored can be may be stored in a permanent memory that is already available. G-opposite of the known possibility, the identifiers in mask or electrically programmable To save permanent storage, the invention has the advantage that for setting the IDs no expensive masks or programming devices are necessary.

There are also programming fields known in which by soldering of diode identifiers or other individual data can be set. the Disadvantages are the large amount of space required and the high amount of work involved in soldering the diodes.

In the development of the invention according to claim 3, any Switching means (diodes etc.) as electrically conductive connections are dispensed with, instead, galvanic connections, e.g. wire bridges, soldering points, are sufficient.

The invention is explained with reference to FIGS.

In Figure 1, the programming field 'with the inputs to I is with PF to IV and the outputs XO, X1 to -X9.

Four-digit IDs are provided, the first digit is Input I, the second position is Input II, etc.

assigned. The output XO is the number i), the output X1 is the number 1 -etc. assigned. The conductive connections are drawn with the freehand lines, with which the respective identifier, here 2905, is set. ei submission of the identifier the scanner A scans the inputs I to IV by successively selecting a specific Creates potential. This potential comes from the inserted connections the inputs of the permanent memory Sp, in which the coding of the individual digits is stored is. The coded characters are sent to the transmitter S via the outputs P1 to Pn and brought there into the form suitable for transmission.

If a microprocessor is used anyway, it can advantageously can also be used to generate the identifiers. A first example is in Figure 2 shown.

The outputs XO, X1 to X9 of the programming field PF are connected to the Data bus lines DO, D1 to D9 of the microprocessor MP connected. To the data bus lines and the read-only memory ROM is connected to the address bus lines A1 to Am, in which the coding of the individual digits is stored.

The address decoder is also attached to the address bus lines AD connected, its outputs with inputs I to IV of the programming field PF are connected.

To transmit the identifier, the microprocessor MP controls the address decoder AD so that a certain potential is applied to inputs I to IV one after the other of the programming field PF. The one appearing on the data bus lines DO, D1 to D9 Information is used by the microprocessor MP to read the to call up the associated coding and to use its output Q to le To give a signal to a data transmission device not shown here; The one in figure 2. The arrangement shown has the disadvantage that a data bus with at least 10 lines necessary is.

However, such systems are rarely used; the usual microprocessor systems have a data bus with t 8 lines.

FIG. 3 shows a circuit arrangement for a data bus with 8 lines (DO, D1 to D7). The program field PF indicates the identifier for each digit two inputs, where the first position has inputs Ia and Ib, the second Place the inputs IIa and IIb etc., the inputs Ia, IIa, IIIa and IVa the digits 0.1 to 4 and the numbers 5 to 9 are assigned to the inputs Ib, Leib, IIIb and IVb are. Two digits correspond to each of the five outputs XO, X1 to X4, namely the Output XO the digits O and 5, output X1 the digits 1. and 6, etc. As an example the connections for the identifier 2905 are drawn in the programming field PF.

The inputs Ia, Ib, IIa, IIb etc. are used to send out the identifier as in the example of Figure 2 scanned one after the other, and from the so on the data bus lines DO, D1 to D4 4 appearing information from the microprocessor MP with the im Read-only memory ROM stored coding which transmitted the code characters obtained.

The example shown in Figure 3 has the disadvantages that of the Usually existing 8 data bus lines only 5 are used and that because of The larger number of inputs in the programming field means more A-address decoders are required necessary is. These disadvantages can be avoided if the programming field for Octal numbers is set up and the microprocessor converts these octal numbers into decimal numbers revalued.

In telecommunication systems in which the device-specific identifier is used The participant in question is charged with t fees, the Risk of unauthorized change of the identifier. An implementation of the Programming field that is difficult to change at a later date or on which a subsequent one Change is easily recognizable. Such a programming field consists of an isolating one Plate that carries adjacent conductor tracks on both sides, with the Lanes on one side are assigned to the inputs, those on the other side to the outputs and the lanes on one side cross the lanes on the other side. There for Construction of telecommunication devices, preferably printed circuits are used, the programming fields can advantageously be printed as parts of these Make circuits. The connections at the crossing points are called plated through manufactured in the same operations in which the through-plating, which is necessary anyway getting produced. There are two ways of doing this. The first option is best in that only the plated-through holes are produced which are due to the identifier are necessary. With the second option, there are plated through at all intersection points attached and in a later operation the excess plating e.g. removed by drilling out. This possibility has the advantage that during manufacture of the printed circuit boards have not yet taken into account the individual identifiers must become.

The programming field can also be implemented in thick or thin film technology are also initially conductive connections at all intersections and later the superfluous ones are removed, e.g. by sandblasting.

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Claims (10)

Claims t1.J Method for generating multi-digit, station-individual 1s, Identifiers consisting of several code characters, which are created by producing certain electrically conductive connections can be set in a programming field, wherein individual parts of the programming field are scanned one after the other, characterized in that that the individual code characters by linking the from the programming field (PF) characters obtained by scanning with those stored in a read-only memory (Sp, ROM) Information can be obtained. 2. The method according to claim 1, characterized in that the link by reading out the read-only memory (Sp, ROM) under the scanning of the programming field (PF) obtained address takes place. 3. The method according to claim 2, characterized in that the output of each character from the programming field (PF) according to an n-by-1-of-m code takes place, where the product of m and n is at least equal to the number of characters and m is equal to the number of outputs of the programming field. 4. Circuit arrangement for performing the Verf'atirens according to claim 3, characterized in that the outputs of a scanner (A) with the positions the identifier assigned inputs (I to IV) of the programming field (PF) and that the outputs (XO, X1 to X9) of the programming field (PF) with the address inputs of the Fixed memory (Sp) are connected (Fig. 1). 5. Circuit arrangement for performing the method according to claim 3, characterized in that the outputs of the programming field (PF) with the data bus "lines (DO, D1, D2 etc.) of a microprocessor (MP) that are connected to the address bus lines (A1 to Am) of the microprocessor (MP) the inputs of the programming field (PF) either are connected @ directly or via an address decoder (AD) and that the data bus and address bus lines of the read-only memory (ROM) are connected. 6 ... circuit arrangement according to claim 5, characterized in that that the programming field (PF) has an input (I to IV) for each digit of the identifier and has an output (XO, X1 to X9i ati for each code character (Fig. 2). 7. Circuit arrangement according to claim 5, characterized in that the programming field (PF) two inputs (Ia, Ib to IVa, IVb) and has an output (XO, X1 to X4) for every two code characters (Fig. 3). 8., circuit arrangement according to claim 5, characterized in that the programming field has eight outputs and that is assigned by the microprocessor based on the octal number set in the programming field, the corresponding code character is calculated will. 9. Circuit arrangement according to claim 4, 5, 6, 7 or 8, characterized in that that the programming field (PF) is designed in the manner of a crossbar field, the ladder of one level being the inputs, the other level being the outputs are assigned and at each crossing point the two crossing conductors with each other are connectable. 10. The method or circuit arrangement according to one of the @ claims 1 to 3 or 4 to 9, characterized by the application on the participant side of video text systems.