DE4122782C1 - Allocation recognition system for component of one group in another group - uses bidirectional data flow and codes each component of second group by formation of characteristic electrical connection between selected contacts - Google Patents

Abstract

The device described has been designed for recognising the allocation of one package (2) from a first group to one (1j) of a number m of packages (11,...1m) of a second group, where packages of the second group have a characteristic electrical coding (K1,...Km) for each package, obtainable through a number n of terminal contacts (A1,...An) by means of binary switching logic, and the packages of the first group each have an evaluating unit (3) for detecting this coding through a corresponding number of decoder lines (D1,...Dn). The codings consist of a different combination of electrical connections of the terminal contacts with one another, while the decoder lines are set out for a bidirectional information flow. The evaluating unit, for decoding purposes, detects the presence or absence of an electrical connection between each possible pair (Ai,Ak;1 less than equal to i less than k less than or equal to n) of terminal contacts. USE/ADVANTAGE - For printed circuit boards. Greatest possible number of coded components. Can be recognised using binary logic and least possible number of connecting lines.

Description

The invention relates to a device for detection the assignment of a component of a first group to one of a plurality of components of a second group according to the Preamble of claim 1 and a ver for this convertible decoding method.

Known is a generic device in the form of a slot system, in which the individual slots as parts of the second group construction have a binary coding, which groups of inserted into the slots electrical construction as components of the first group, which contain, for example, boards with printed circuits, can be decoded by means of an evaluation circuit. As a result, an assembly clearly recognizes in which of the plurality of slots it is inserted. Each slot has an equal number of n contacts and a ground connection, the electrical coding being that these n connection contacts are either short-circuited to the ground connection or are not electrically connected to it. Each module in turn has an evaluation circuit, which has a corresponding number n electrical lines to the connection contacts of the slot connection when the module is inserted into the slot. The evaluation circuit queries which of the connection contacts are short-circuited to ground and which are not. The resulting binary number enables the module to recognize the slot assigned to it. However, this known device shown in FIG. 2 requires a large number of connecting lines or connecting contacts. The number n + 1 of contacts including ground connection allows the coding of a maximum of 2 ⁿ slots. The use of multi-state logic increases the number of encodable slots for a given number of lines, but at the same time requires an increased amount of circuitry.

DE 35 06 578 C1 describes a device for detecting the Assignment of a component of a first group to one of one A plurality of components of a second group are known. It will there a plug connection with a codable free plug part used, the coding via different elec trical conductivity (resistances) or different Oscillations (resistors, capacitors or inductors) he follows.

The invention has for its object a device trained at the outset so that they while maintaining Binary circuit logic with as little connection as possible lines the clear recognition of the assignment for a the highest possible number of coded components allowed.

The object is achieved by a device with the features of claim 1. According to the invention, each connection contact is queried according to whether and to which other connection contacts there is an electrical connection. It turns out that with a larger number of components to be coded, fewer decoding lines and connecting contacts are required than in the known binary coding according to FIG. 2, since the number of different combinations of electrical connections between the connecting contacts with one another with an increasing number of connecting contacts is essential grows faster than the number of possible combinations of electrical connections of the connection contacts to a common ground connection. For decoding, the evaluation circuit detects and recognizes the presence or absence of an electrical connection between each pair of connection contacts, for which purpose the decoding lines allow a bidirectional flow of information.

The embodiment of the invention according to claim 2 allows one circuitry implementation with very little effort, because the connection contacts without the use of further electrical Components are simply short-circuited in a certain way.

In the decoding method of the invention according to claim 3 provided the connection contacts one after the other with a Apply detection signal and the reaction to the to scan other connection contacts, after which it is certain, with which other connection contacts the one with the detection signal acted upon contact is electrically connected.

With the development of the invention according to claim 4 can unnecessary generation and processing of redundant data prevent, as in a decoding process in which each other contacts with the detection signal beats and the reaction of all other connection contacts would be sampled, would necessarily arise. The Be restriction to the data required for decoding query operation according to the invention also brings a considerable time saving in decoding. So at for example the coding, in which all connection contacts are electrically connected to each other, already in the first Polling cycle detected without further polling cycles requirement.

A detection signal according to claim 5 is preferably provided, since this means secure decoding with little effort binary circuit logic enables.

Fast decoding can also be done with the advantage adhere to achieve the invention according to claim 6, because the scanning of the contacts within a cycle takes place simultaneously and thus the data obtained from it can be processed in parallel instead of in series.

A preferred embodiment of the invention as well as for the purpose better understanding the same for comparison a known one Establishment of the generic type are in the drawings are shown and are described below. It shows

Fig. 1 shows a device according to the invention for detecting the assignment of an electrical assembly to a specific slot of a slot system with a short-circuit bridge coding between the contacts and

Fig. 2 shows a device analogous to Fig. 1, but according to the prior art and with a short-circuit bridge coding between the contacts and ground.

For a better understanding of the embodiment according to the invention, the known direction is first described with reference to FIG. 2.

Fig. 2 shows schematically the assignment of an electrical assembly ( 2 ') as a component of a first group to a specific ( 1 _j ; 1jm) of a plurality m (m2) of slots ( 1 ₁' to 1 _M ') as components of a second group. The module ( 2 ') assigned slot ( 1 _j ') is one of the m slots ( 1 ₁ 'to 1 _m ') within a construction group carrier, as it is in its nature for example from DE 38 18 677 A1 is known. The boundary area between the module ( 2 ') and the slot 1 _j ' is indicated by a dashed line, a connection via a number n (n2) of contacts (A₁ ',... A _n ') of the slot 1 _j 'Takes place and the sake of clarity, the carrier as well as the other slots and the details of slot 1 _j ' and the assembly ( 2 ') which are not essential to the invention are not shown. In addition, slot 1 _j 'has a ground connection (GND).

The slot 1 _j 'is provided in the rear, the module ( 2 ') facing away from the connection contacts for coding with a short circuit bridge (K _j '), which consists in that some selected of the connection contacts (A1,' to A _n ') are short-circuited to the ground connection (GND), as indicated by the dash-dotted lines. In the example shown, the connection contacts A₁ ', A₂', A₃ 'and A _N ' are short-circuited to the ground connection (GND) and the other connection contacts A₄ ',. . ., A _n-1 'not. Accordingly, the remaining slots are provided with such short-circuit bridges as coding, the short-circuit bridges being different from one another.

In the slot 1 _j 'inserted module ( 2 '), there is an evaluation circuit, of which a first part ( 3 ') is shown schematically. The evaluation circuit ( 3 ') is in turn part of a Mikrocon trolers, not shown. From the connection contacts (A₁ 'to A _N ') lead decoding lines (D₁ 'to D _n ') to inputs of the evaluation circuit ( 3 '), via which the latter detects the voltage values present at the connection contacts (A₁' to A _n '). About an ohmic resistor (R) a higher than the ground connection (GND) higher voltage level (+ V) in the decoding lines (D₁ 'to D _n ') is fed.

As soon as the module ( 2 ') is assigned to slot 1 _j , that is, it is inserted into it, a current flows from the connection with the high voltage (+ V) through the resistors (R) through those of the connection contacts that are connected to the ground connection (GND ) are short-circuited to ground, while no current flows through the non-short-circuited connection contacts. The high voltage value (+ V) is therefore retained on those decoding lines which are linked to the connection contacts which are not short-circuited, while the voltage on the other decoding lines which are linked to the connection contacts short-circuited to the ground connection is at zero, ie ground potential, falls off.

The resulting voltage information on the decoding lines (D₁ 'to D _n ') is present at the input of the evaluation circuit ( 3 ') as a retrievable, binary information. On request via a line ( 5 a '), the evaluation circuit ( 3 ') outputs this information via a further line ( 5 b ').

Obviously, this known type of short-circuit coding of connection contacts for a given number n of decoding lines (D₁ 'to D _n ') or connection contacts (A₁ 'to A _N ') allows the unique coding of a maximum of 2 ⁿ slots, ie m2 ⁿ .

An exemplary embodiment according to the invention is described below with reference to FIG. 1.

Analogously to the case of FIG. 2, FIG. 1 shows the assignment of an electrical assembly ( 2 ) to one ( 1 _j ; 1jm) of a plurality (m2) of slots ( 1 1 ,..., 1 _m ) one not in more detail shown rack.

Just like any other slot, the slot ( 1 _j ) shown has a number n (n2) of connection contacts (A 1, _... , A _n ). A separate reference connection is not provided. Each plug contact ( 1 _j ) is provided with a short-circuit bridge (K _j ), which each produce short-circuit connections of the connection contacts (A₁ to A _n ) to one another in a clear manner, so that the short-circuit bridges (K₁ to K _m ) of the various slots ( 1 ₁ to 1 _m ) differ from each other.

The module ( 2 ) is provided with an evaluation circuit ( 3 ) to which the decoding lines (D₁ to D _n ) are routed, which, when the module ( 2 ) is assigned to one ( 1 _j ) of the slots, ie inserting the module ( 2 ) in this slot ( 1 _j ), with the connection contacts (A₁ to A _n ). The evaluation circuit ( 3 ) is part of a microcontroller, not shown. However, it can alternatively also be designed as an independent circuit unit separate from the microcontroller. Upon request by subsequent units of the microcontroller, also not shown in more detail, via a line ( 5 a), the evaluation circuit part ( 3 ) carries out a decoding process and transmits the result via a further line ( 5 b).

The decoding process consists of at least one, usually several, cycles. In a first cycle, the evaluation circuit ( 3 ) sends via a decoding line, e.g. B. D₁, a detection signal to a connection contact, for. B. A₁. At the same time, it switches the connections to the other decoding lines D₂ to D _n on reception. By applying the detection signal to the connection contact A 1, the electrical state changes to the connection contacts short-circuited with this connection contact, in the case shown these are the connection contacts A 3 and A _n , while the state of the other connection contacts does not change. The binary information obtainable for each connection contact A₂ to A _n - short circuit with connection contact A₁ or not - passes via the decoding lines D₂ to D _n to the evaluation circuit ( 3 ) which detects and evaluates them. At the end of this cycle, the evaluation circuit ( 3 ) thus knows which connection contacts are short-circuited with the connection contact A 1 and which are not. In the slot 1 _{j shown} in FIG. 1 with the short-circuit coding K _j , the evaluation circuit ( 3 ) detects z. B. in this first cycle that the connection contacts A₁, A₃ and A _n among themselves, but not with the other connection contacts are short-circuited.

In an analogous manner, the evaluation circuit ( 3 ) continues in a next cycle with the application of a next connection contact to the detection signal until it clearly identifies the coding K _j and thus has uniquely identified the assignment to slot 1 _j . To apply a next connection contact with the detection signal, the evaluation circuit ( 3 ) selects one for which no short-circuit connection to one of the other connection contacts has been detected in previous cycles. In addition, in this subsequent cycle it only evaluates the reaction at the remaining of these connection contacts for which no short-circuit connection has yet been detected. On the one hand, this is sufficient to clearly identify the respective coding K _j and, on the other hand, prevents the unnecessary processing of redundant data material. In the example shown in Fig. 1, in which a short-circuit connection of the contacts A₁, A₃ and A _{n was} detected after the first cycle, therefore omitted in the other cycles on the one hand the application of the contacts A₃ and A _n with the identification signal and He on the other hand, the evaluation of the reaction of the connection contacts A₁, A₃ and A _n to the exposure of other connection contacts with the detection signal.

The method described above generally speeds up the decoding process. So that coding, in which all connection contacts (A₁ to A _n ) are short-circuited to one another, is already clearly recognized in the first cycle, after which the interrogation process is ended immediately. In the worst case, namely that there is no short-circuit connection, n-1 interrogation cycles are required in which the connection contacts A₁ to A _n-1 are acted upon in succession with the detection signal, whereby when the connection contact A _k (1 <kn-1) is applied only the reaction of the connection contacts A _{k + 1} to A _n need to be evaluated in each case.

As a detection signal, the change in the voltage level from "LOW" to "HIGH" or vice versa is provided in a simple manner, with all connection contacts (A 1 to A _n ) being set to the same level by the evaluation circuit ( 3 ) before each cycle. After application of the one connection contact with the changed voltage level, the evaluation circuit ( 3 ) scans at which other connection contacts the voltage level changes, from which it recognizes that these are short-circuited with the connection contact to which the changed voltage has been applied.

Both the application of the detection signal and the sampling of the reaction thereon are each carried out via the same decoding lines (D 1 to D _N ) which are designed for a bidirectional flow of information, which is indicated by the double arrows.

It can be seen that the coding and decoding according to the invention with a large number of m slots to be coded a smaller number n of decoding lines and connection contacts. The following table shows the possible, different codings and their Number (S) that corresponds to the maximum number of codable slots speaks for the cases n = 2, 3 and 4.

"0" means that there is not a single short circuit ver binding, "1-2", a short-circuit connection of the contacts A₁ and A₂ etc. A "one-piece" combination means one those in which no or only a single contiguous Short circuit bridge two or more of the contacts ver binds, a "two-part" combination points accordingly two such, separate short-circuit lines. For example, "1-2 + 3-4" means that on the one hand the connection contacts A₁ and A₂, on the other hand the connection contacts A₃ and A₄ in pairs are short-circuited. For a higher number of connection con clocks (n6) are accordingly also short-circuit bridges combinations possible that consist of three or more disjoint the short-circuit lines exist, for. B. "1-2 + 3-4 + 5-6".

The number S of possible short-circuit bridge combinations exists evident from the sum of the number S 1 possible one-piece Combination, the number S₂ possible two-part combination nen, etc. These summands can be with a more precise combinatorial analysis depending on the number n of Determine connection contacts. It results in

S₁: S₁ = 2 ⁿ -n
and for
S₂: S₂ = (3 ⁿ - (n + 2) 2 ⁿ + n (n + 1) +1) / 2
From which follows:
S₁ + S₂ = (3 ⁿ -n2 ⁿ + n (n-1) +1) / 2,

which corresponds to the number S as long as n is less than 6, because only then three-piece estate nations occur.

For n = 5 this results in S = 52, which, given the same number of lines, already results in a significantly larger number of codable slots, such as the known binary coding described above by connection to ground. Because the latter allows only 2⁵ = 32 different codings with five connecting lines, whereby the additional ground connection is not yet included, which leads to an even less favorable result for the known coding. From the above equation for the sum S 1 + S 2, it is evident that the latter and thus also the number S of codable slots grows much faster than 2 ⁿ and thus faster than the number of codable slots of the known device according to FIG. 2. It should be noted that The device according to the Invention enables this much larger number of codable slots, even though it only makes use of a binary circuit logic and does not use a multi-state logic with a correspondingly higher circuit complexity.

It is clear that the device according to the invention in an analogous manner, as described for slot 1 _j , recognizes the assignment of the module ( 2 ) to any other slot.

Depending on the plurality of slots, one can A plurality of assignable modules can be provided, which functionally identical to each other only in terms of circuitry need to be as each of the assemblies over which the Coding of the assigned slot recognizing evaluations circuit including decoding lines.

Conversely, it is of course also possible to use the Codes of the modules to be inserted and the Assign evaluation circuits to the slots if this is appropriate.

The invention is particularly advantageous for use in systems bar at which the number of decoding lines while maintaining device binary circuit logic, especially due to galvanic Separation of the circuits and / or compliance with safety spacing, should be kept low, on the Side of the components containing the coding only brief terminal bridges and no more complex coding devices to Example in the form of integrated circuits.

It is clear that the invention takes place in one slot Subrack insertable electrical modules as well is well usable for other components to be assigned to each other.

Claims (6)

1. A device for detecting the assignment of a component ( 2 ) of a first group to one ( 1 _j ) of a plurality m of components ( 1 ₁,... 1 _m ) of a second group, the construction parts of the second group one for each component characteristic, electrical, via a plurality n of connection contacts (A₁,... A _n ) which can be tapped by means of binary circuit logic (K₁,... K _m ) and the components of the first group each have this coding over a corresponding number of Decoder lines (D₁,... D _n ) detecting evaluation circuit ( 3 ), characterized in that the codings consist of different combinations of electrical connections of the connection contacts with each other, that the decoding lines are designed for a bidirectional flow of information and that the evaluation circuit for decoding via these decode lines the presence or absence of an electrical connection between each m possible pair (A _i , A _k ; 1i <kn) detected by connection contacts. 2. Device according to claim 1, characterized in that the electrical connections as shorting bridges, the certain connection contacts in one for the respective coding short circuit characteristic combination, are formed. 3. A method for decoding in a device according to claim 1 or claim 2, characterized in that the evaluation circuit ( 3 ) carries out successive interrogation cycles for the detection of a coding, wherein in each interrogation cycle it acts on a single connection contact with a detection signal and other connection contacts asks for the existence of an electrical connection with this connection contact acted upon by the detection signal. 4. The method according to claim 3, characterized in that the evaluation circuit on the one hand in a next query cycle only such a connection contact with a detection signal acted upon at a previous polling cycle no electrical connection to another connection yet contact was detected, and on the other hand only the rest of these contacts, for which no electrical Ver binding with another connection contact was detected the presence of an electrical connection with this queries the detection signal applied to the contact. 5. The method according to claim 3 or 4, characterized in net that the detection signal from a change in level there is a voltage that can be changed between two values, wherein the evaluation circuit before sending the detection signals all connection contacts at the same voltage level sets. 6. The method according to any one of claims 3 to 5, characterized characterized in that the query for the existence of an electri connection with the detection signal ten connection contact for all connection contacts to be queried done simultaneously.