DE19827692C2 - Coding circuit and use of the same in an actuating or control device for a signal-actuated locking system - Google Patents

Abstract

The invention relates to a coding circuit (1) providing an electronic code that can be easily, manually and randomly adjusted in addition to being easily and manually duplicated and reproduced. Preferably, the circuit has a non-volatile memory device (5) for storing said code (13), a programming device (21) for manually inputting said code (13) by means of first actuating devices (6) and a display device (9) which displays the code (13) to a user. The programming and preferably the display of said code are performed successively for each n position of the code. The invention is provided with m first actuating devices (6), whereby m corresponds to the number of possible states for each position of the code (12), preferably in addition to a display element (15) that can deliver m signals that can be recognized and differentiated by the user. The inventive coding circuit is particularly suitable for components of a closing system, e.g. for a manual radio transmitter or a radio receiver in a radio-controlled garage door system, as a replacement for mechanical circuits.

Description

The invention relates to a coding circuit according to the preamble of the attached claim 1, as is known from the pre-used hand-held transmitters shown in FIG. 6 for the remote control of gate drives, and their use according to the appended claims 11 and 13.

In general, the invention relates to a coding circuit for supplying one for free re produce readable and manually adjustable codes from n digits, each with ma can be assigned arbitrarily with one of m possible states, for a security relevant multi-component system - in particular a signal-operated locking system tem -, whose components work together in a code-protected manner.

Locking systems are known from EP 0 497 040 A1 and WO 94/17268 A1, in which authorized persons must enter a personal code (PIN). Have these systems the disadvantage that the person has to keep the code in mind and that too Persons who should only have temporary access have access to the personal code must have, which is why this must be changed after the authorization expires.

In contrast, the invention is concerned with, for example, from DE 42 33 130 A7 known coding circuits that are used in such a multi-component system (for example remote-controlled or remote-controlled systems with transmitters and receivers as a comm components) are used in which two or more components under Ver communicate using a code, the codes only for easy Extension of the system by one component or to replace a component freely and easy to change, but also to be duplicable. The code is in the here coding circuits of interest not like a PIN in an automated teller machine or when starting up a cell phone or in the systems according to EP 0 497 040 A1 or WO 94/17268 A1 from the user's memory  entered out. Rather, the code is in the components components and is automatically activated by the components exchanged in cooperation to determine whether the components are authorized to work together. The So the operator only comes into contact with the code, if this should be changed or re-entered.

An example of such a multi-component system is a radio-controlled garage door for closing a garage entrance. A handheld radio transmitter is normally available for each authorized person, by means of which the door can be opened remotely by sending a code signal to a radio receiver connected to a door operator. The code contained in the handheld radio transmitter is then, so to speak, the key with which the authorization to open the garage door is verified. In order to be able to guarantee mass production and simple subsequent delivery of hand-held radio transmitters with later adaptation options to existing codes, coding circuits of the type mentioned at the outset, so-called coding switches, have been used with such hand-held radio transmitters and radio receivers. An example of a hand-held radio transmitter provided with such a coding switch is shown in the attached FIG. 6.

Such coding switches (sometimes referred to in the vernacular as "mouse piano") consist of n individual switches, which can be combined into several in a switch strip or other switch housing. The switches usually have two switch positions, corresponding to two possible states (m = 2), which are often referred to as "OFF / ON", "OPEN / CLOSED" or "0" and "1". With such coding switches m ⁿ ver different codes can be set manually. B. n = 10 switches with two possible switching positions (m = 2) 2 ¹⁰ = 1024 different, arbitrarily adjustable codes.

For example, in order to enter the bit sequence "0100000010" as a code, the second and penultimate switch is set to the "1" position, as shown in FIG. 6, while all other switches remain in the "0" position. The coding is fail-safe, ie even if the voltage or other energy supply is interrupted, the coding is retained, since the switches are mechanically fixed. The greatest advantage of the known coding circuits is that the set code is visible when you look at the coding circuit (see Fig. 6) and is therefore very easy to duplicate. If the multi-component system is to be expanded by one component, for example, a new radio transmitter is added to an existing garage door system, only the corresponding code needs to be set on the new component by duplicating the switch setting of an existing component.

However, the price and the sometimes fili are disadvantageous grane usability of the often tiny switches. The known coding circuits also ensure little security. Although the coding scarf mostly hidden, so z. B. inside the housing the handheld radio transmitter and the radio receiver, arranged so that the set code only when this com components can be duplicated. However, the  due to the number of switches only a limited number of available code options Possibility that the code by trying or by chance from a non-calc person with a comparable manually adjustable component.

Despite these disadvantages, there will be a demand for such coding in the future Circuits exist because existing systems will probably be in operation for a long time which and for such systems components for retrofitting are desired. Except multi-component systems with such coding switches offer that for everyone Users the ability to create a desired code with little effort and no hassle set operation on the corresponding component.

DE 42 33 130 A1, already mentioned above, describes a coding circuit in a learning remote control is known, which should also be relatively easy to program, compared to conventional coding circuits with mechanical coding switches (here DIP switch) but should offer greater security. To this end, this includes be knew coding circuit in addition to a number of mechanical coding switches Programming device and a two-position programming operation switch, being in its first position on the series of mechanical coding scarf the first half of the code and when the programming code is in the second position the second half of the code is entered.

DE 42 42 231 C3 describes a multi-component system in the form of a remote control direction with a coding circuit for changing the code by means of which the individual Components - remote control and receiver - communicate with each other, known. With this known coding circuit, the disadvantages of mechanical coding switches are avoided, but in particular the free duplicability of the code should be prevented. To do this, one of the components becomes independent of the others Components manufactured and in the course of the functional test at the manufacturer with an ID identification code. Regardless of this, the other receiver becomes code neutral delivered and only for use on the codes of the specifically available additional compo be programmed. So here one of the components is automatically learnable. With this known solution, the main disadvantages of mechanical Coding circuits avoided, but this at the expense of the possibility of free change and duplicating the code.  

In addition, this coding circuit cannot be used with existing coding circuits use mechanical coding switches, be made fully compatible.

A locking system, the components of which communicate with each other with code protection, is also known from DE 94 19 635 U1. The code used is also changed bar, but this is done automatically with the various components in synchronism running clock counter. An expansion of this locking system with additional components or integration of components of this locking system into existing systems therefore hardly possible or at most very difficult.

The object of the invention is to provide a coding circuit in the preamble of the attached Claim 1 mentioned type to create the mechanical coding circuit is cheaper and a greater variety of adjustable code options offers and especially for retrofitting existing multi-component systems suitable is.

To solve this problem is a coding circuit in the preamble of claim 1 mentioned type further developed according to its characteristic features.

The coding circuit according to the invention comprises a signal-operated memory device device for storing the code, a programming device for entering or changing of the code in or in the memory device, operated with at least m manually baren first actuators, by means of which during a programming process the n digits of the code to be stored in the memory device in succession one of the m possible states can be assigned signal-controlled, and one signal-controlled Display device,  with the memory device for reading out the code stored therein is connected and suitable for displaying the stored code to an operator is not.

The operator can in the coding circuit according to the invention as in the known mechanical coding switches a code arbitrarily via the programming device device that has buttons or the like as the first actuators. The code entered is stored in the memory device. In addition, the Operator read the stored code on the display device so that it can easily duplicate the stored code on other components. The code circuit according to the invention thus fulfills the most important functions of be knew mechanical coding switch, but is not like this in the number n of digits of the code limited by mechanical components. The circuit could also be wide res can also be realized with the help of software. Then the manufacturer needs to manufacture only one component with appropriate hardware. About customizing the Software is an adaptation of the number n of codes to ver from existing systems applied codes easily possible.

Advantageous uses of the coding circuit according to the invention are in the claims Chen 11 and 13 specified. Advantageous embodiments of the invention are the subject of subclaims.

Thus the coding circuit according to the invention even in the event of a power supply failure works just like the mechanical coding switch and the stored code maintains, it is preferred that the storage device is independent of the energy supply ges memory element, in particular a non-volatile semiconductor memory element has.  

It is further preferred if the programming device a manually operated programming mode initiator device for initiating the programming process. This has the advantage that an inadvertent reprogramming is difficult. In addition, with such training the first actuators in a standard operation with other functions.

Accidental initiation of an is even more difficult Programming process when the programming mode is on control device via actuation of a second actuator equipment that is more difficult to access than that Most actuators, or via a certain Combination or sequence of operations of the first actuation supply devices can be actuated.

It is also conceivable that the display device possibly has a hidden display that permanently displays the set code. An un desired recognizability of the stored code can but instead of a hidden arrangement of an ad be prevented by the display a manually operable display mode guide device for initiating a display mode and a Display element that is activated after operating the display mode the operator displays the code on has. This is preferred because then the display element arranged on the one hand without further ado in an exposed location can become visible, for example on a housing, which makes reading easier, but on the other hand also perform other functions in a normal mode  can, for example, to display for the operation of the Component in which the coding circuit is used becomes, required or desired parameter or Si gnale can serve.

The display element could also be a display on which the code completely (i.e. every n digits at once) is showable. As mentioned, codes should also be generated cash where the number n of digits is large and which is naturally limited in its expansion Displays only incomplete or one after the other anyway could be shown. Very inexpensive, but still it is entirely sufficient if the display element only indicates the status of a single location. The ad the n digits can then take place one after the other. Therefore is provided in a further preferred embodiment that the display element in display mode one by one for each some of the n positions perceived by the operator bares and that of the m possible states with which the corresponding position of the code is currently occupied, assignable signal.

An unwanted initiation of the display mode with possibly Unwanted disclosure of the code will be difficult if the Display mode initiator via actuation of a third actuator that is more difficult to access is as the first actuators, or about a certain combination or sequence of operations first actuators or the first and the second actuators can be actuated.  

The invention is also readily applicable to systems bar, where previously switches with more than two switching positions have been used. It is also conceivable, Dezi enter and change malcodes arbitrarily. Costs cheaper and considering that a change Setting or entering the codes for those discussed here systems is extremely rare, however a particularly advantageous embodiment of the invention, where the code allows an n-digit bit sequence with m = 2 states ("0" or "1" or "H" or "L") per position, d. H. Bit, is where the programmer device preferably two buttons as the first actuation has directions, each one of the two possible Chen states are assigned.

Furthermore, a signal generator can (but does not have to) be provided be the operations or functions of the coding scarf quit by sending signals to the operator animals.

As a signal generator and as a display element is advantageous a signal lamp, especially a light emitting di ode used.

The invention can be used particularly advantageously Coding circuit in an actuator for a Code-protected signal-operated locking system, for remote ben a code signal to operate the locking system, which has a control device which the code signal receives from the actuator, with a pre given signal code compares and after finding one Match the locking system for opening or closing  controls, wherein the actuating device with a code signal setting device for ver at least partially manually arbitrarily setting the code signal to be delivered see is. An example of such an actuating device is a hand-held radio transmitter for a radio-controlled garage door. Such a handheld radio transmitter can be used instead existing radio transmitters with known mechanical coding switches be set. Instead of a mechanical setting of the switches, the input is made the code by programming the same into the memory device by means of the Pro gramming device. Such a program operation is advantageously carried out via a the housing arranged push button initiated as a second actuator. Wuh rend the programming process to the transmitter of the code signals in Normalbe drove certain keys as the first actuators for entering the states of the individual digits of the code can be used one after the other. As a display element can be used in many radio transmitters anyway to display the transmission function in normal operation existing light emitting diode can be used, the button without subsequent Actuation of the first actuation elements (signal buttons) as the third actuation element can be used to initiate the display mode.

Furthermore, the further use according to the invention of the co Dierschalt a control device for a code-protected signal-actuated locking system for receiving a code signal sent by an actuator, Comparing the code signal with a predetermined signal code and controlling the Locking system after a match between the signal code and Code signal, with a signal code setting device  at least partially manually arbitrarily Setting the predefined signal code, realizable, which instead of a control device with mechanical Code switches can be used. This is the signal code setting device with the coding according to the invention circuit provided. An example of such a tax direction is a radio receiver for a radio remote control garage door.

The invention makes it possible for existing Locking systems such as the garage door mentioned, with a multitude of users and accordingly a lot number of components, i.e. hand transmitters or the like, can be gradually modernized by the Com components are gradually replaced. Once everyone is Components with the coding circuits according to the invention instead of the mechanical coding switch previously used provided that the inventor according coding circuit - for example by ange matched software - a code with a larger number n of Codes used as before, d. H. re-entered become. The individual authorized persons only need by a message, for example in letter form, which the new code and possibly an instruction manual for Setting the new code contains, be informed. The invention makes it possible for the justified Individuals based on this message alone their code without to be able to re-set external help.

Embodiments of the invention are set out below hand explained in more detail in the accompanying drawing. In this shows:  

Fig. 1 shows a basic diagram of an encoding circuit in a first embodiment;

Fig. 2 is a block diagram of the encoding circuit of FIG. 1,

Fig. 3 is a schematic diagram of an encoding circuit in a second embodiment,

Fig. 4 is a block diagram of the encoding circuit of Fig. 3,

Fig. 5 is a front view of a handheld radio transmitter for a radio signal actuated remotely controlled garage door system,

Fig. 6 is a rear view of a known handheld transmitter with the battery compartment open and

Fig. 7 is a rear view of a novel handheld radio transmitter with the battery compartment open

In Fig. 1 a for providing a code, by means of which a component of a system is justified sammenwirken TO can prove with other system components, suitable coding circuit 1 shown in a first approximate shape exporting.

The coding circuit 1 has an input 2 and an output 3 , which are connected to a processor P acting as a control unit 4 . In addition, the coding circuit 1 for power supply has a current or voltage supply connection V and a Massean circuit M.

A memory device 5 for storing a bit sequence 13 as code is connected to the control unit 4 . The memory device 5 has a programmable non-volatile semiconductor memory S, which holds stored values even in the event of a power failure.

In addition, two first actuating devices 6 operable by an operator, a display device 9 , a signal generator 11 , a second actuating device 12 operable by the operator and a third actuating device 14 operable by the operator are connected to the control unit 4 .

The two first actuating devices 6 are essentially formed by a first easily accessible button 7 and a second easily accessible button 8 .

The display device 9 comprises a display element 15 which can emit at least two signals which are perceptible and distinguishable by the operator. In the exporting approximately example of FIG. 1, the display element 15 is suitable for displaying numerals.

The signal generator 11 comprises an LED as a signal lamp 10 for emitting optical signals. The second actuation device 12 comprises a first button 16 , and the third actuator comprises a second button 17th The buttons 16 , 17 are more difficult to access than the buttons 7 and 8 .

As shown in FIG. 2, a Normal Operation controller 18 for controlling a normal operation, a Pro programming mode controller 19 process for controlling a program in a programming mode and a Anzeigemo dus controller 20 for controlling a display operation in a display mode in the processor P implemented in the form of software.

The normal operation controller 18 is connected to the input 2 and the output 3 and to the storage device 5 . The programming mode controller 19 is with the two first actuating devices 6 , the second actuating device 12 , the signal generator 11 and the storage device 5 for forming a programming device 21 for entering or changing the code (the bit sequence 13 ) in or in the storage device 5 connected. The display mode controller 20 is connected to the third actuation device 14 and the display element 15 and forms together with these the display device 9 , which is used to display the code stored in the memory device 5 to the operator. For this purpose, the display device 9 is connected to the memory device 5 via the display mode controller 20 .

In the following the function of the coding circuit 1 will be described.

In normal operation, the coding circuit 1 serves to provide an n-digit bit sequence 13 , ie a binary number with n digits, each with one of two possible states, "0" and "1" (or "H" and "L" ), are to be issued on request. For this purpose, the normal operation control of the control unit 4, after receiving a request signal via the input 2, reads out the bit sequence 13 stored in the storage device 5 and outputs it as an electrical signal to the output 3 .

The programming device 21 is active in a programming mode. The programming mode is initiated by actuating the second actuating device 12 . The programming mode controller 19 , which acts together with the second actuating device 12 as a programming mode initiating device, activates the first actuating devices 6 in the programming mode and controls the programming process. The operator can then select the desired state or value, "0" or "1", for each of the n positions, one after the other, by actuating the corresponding one of the first actuating devices 6 . If states have been selected for all n positions, the programming mode controller 19 supplies the bit sequence thus entered in the form of electrical signals as a new code to the memory device 5 , where a possibly existing bit sequence is deleted and the new bit to be used as the new code follow 13 is saved. Thereafter, the programming mode controller 19 automatically ends the programming mode. On the other hand, the programming mode can also be canceled at any time by actuating the second actuation device 12 again, possibly followed incomplete entries are then disregarded, the old code remains stored. Normal mode is resumed when the programming mode is ended or canceled.

For example, the system specifies that the code to be supplied must be a sequence of 10 bits, ie n = 10. If, for example, the bit sequence "0100000010" is to be re-entered as a code, the operator first actuates the second actuation device in order initiate the programming mode. Then she first presses the first key 7 to assign the status or value "0" to the first digit, then the second key 8 to assign the status or value "1" to the second digit, then the first six times in succession , once the second and once the first button.

All inputs or operations on the actuation devices 6 and 12 are acknowledged by signals from the signal generator 11 . The signal lamp 10 of the signal generator 11 emits, for example, a long signal when the first button 7 is pressed and two short signals with a defined pause in between when the second button 8 is pressed. The successful initiation of the programming mode is also indicated, for example by a rapidly flashing signal. Successful storage of the new code is also acknowledged by the signal generator 11 .

To check the stored code or copy the same to other components of the system, the coding circuit 1 can be brought into a display mode. In the display mode, the operator's code is displayed by the display device 9 . As Anzeigemoduseinleiteinrichtung for initiating the display mode acts as in the third actuation device 14 together with the display mode controller 20, the 14 starts the display mode upon actuation of the third actuator. The display mode controller 20 then reads the stored bit sequence 13 from the memory device 5 and controls the display element 15 in such a way that the individual states "0" or "1" (or "H" or "L") of the n digits one after the other. After all n bits have been displayed, the coding circuit 1 automatically returns from the display mode to normal operation.

If, for example, the bit sequence "0100000010" is stored as a code in the storage device 5 , the display element 15 successively shows a "0" (or alternatively, for example, an "H") at a pace which allows the individual states to be read. , a "1" (or alternatively eg an "L"), six times a "0"("H"), a "1"("L") and again a "0"("H") . There is a pause between the individual displays, indicating that a new position is now being displayed.

In Fig. 3 is a coding circuit is shown in a second embodiment 30 of. It has a timer 31 and, in contrast to the coding circuit 1, has only a single button 32 instead of the first and second buttons 16 and 17 . Furthermore, the display functions of the signal sensor 11 and the display device 9 are taken over by a single display element 34 in the form of a signal lamp designed as an LED instead of by two separately designed elements 10 and 15 . The buttons 6 and 8 forming the first actuating devices 6 are arranged together with the display element 34 on an easily accessible loading control panel 33 . Other elements of the coding circuit 30 , such as the control unit 4 , the Speicherein device 5 , the timer 31 and the button 32 are arranged on a circuit board 36 , which is located inside a housing 35 .

As shown in FIG. 4, the display mode controller 20 in the coding circuit 30 is connected to the programming mode controller 19 and to the display element 34 in addition to the storage device 5 . The programming mode controller 19 is connected to the display mode control 20 also with the memory device 5 , with the display element 34 , the button 32 , the first actuation elements 6 and the timer 31 . The display mode controller 20 is also connected to the button 32 via the programming mode controller 19 .

The function of the coding circuit 30 is the same as that of the coding circuit 1 in normal operation. However, the button 32 acts on the one hand together with the buttons 7 and 8 as a second actuating device 12 for initiating the programming mode and on the other hand together with the timer 31 as a third actuating device 14 for initiating the display mode. To press the button 32 , the operator must have access to the inside of the housing 35 , that is to say open the housing. If the button 32 is actuated, the programming mode controller 19 starts the timer 31 . If programming is started within a certain period of time, for example 4 seconds, by actuating one of the first actuating devices 6 , for example the first key 7 , the actuation is interpreted as input for the first bit of the code, and the programming process becomes As described above for the coding circuit 1 , the signal lamp used as the display element 34 fulfills the function of the signal lamp 10 , ie the display element 34 acts as a signal generator 11 in programming mode. It acknowledges every entry, e.g. B. by emitting a long signal for a "0" and emitting two short signals for a "1". If all n bits are input, the input bit sequence is sent in the form of electrical signals to the memory device 5 , stored there in a voltage-fail-safe manner, and the successful input process is likewise acknowledged by the display element 34 as a signal generator 11 in the form of a longer flashing sequence. Then after it is switched back to normal operation.

However, takes place after pressing the pushbutton 32 within the PRE-by timer 31 given time period no actuation of the first actuator means 6, as are the programming mode control 19 outputs a signal to the display mode controller 20 from which then starts the display mode for performing the display operation. The display process is carried out essentially analogously to that of the coding circuit 1 , but here the display element 34 is used to display the individual binary states, "0" or "1", the n digits of the code. The display is the same as when confirming inputs, ie the signal lamp used as display element 34 gives a long signal for a state "0" (this state is assigned to key 7 in the example shown) and a state for "1""two short signals with a defined pause in between, which is shorter than the pause between the display of individual binary digits or bits.

In a special embodiment of the coding circuit 30 , the timer 31 becomes active after each input in the programming mode. In this embodiment, between two inputs, a certain period of time, e.g. B. as by 4 seconds, the programming process is canceled and the coding circuit 30 returns to normal operation without the coding having been changed.

The coding circuits described are particularly suitable net for actuating or control devices from Mehr component systems, in particular locking systems, um to leave a code there as an "electronic key" remote, which entitles the components to interact. For example, they can be used to deliver codes by radio receivers and / or handheld radio transmitters Garage door systems are used.

In Fig. 5, a radio transmitter 38 of such a garage door system is shown in front view. The Handfunksen of 38 is provided with the housing 35 , which contains the devices necessary for Sen the signals and on the front, visible in Fig. 5, the operating panel neel 33 with the buttons 7 and 8 and the display element 34 is formed. In normal operation, a transmission of code signals is initiated by actuation of the buttons 7 and 8 , for example to open a garage door (for example by pressing the button 7 ) or to switch garage lights or the like on or off (for example by actuation) button 8 ). The display element 34 is used in normal operation to acknowledge transmission of the code signals. There may also be additional buttons 36 for additional functions.

In known hand-held radio transmitters, such as the hand-held radio transmitter 39 shown in FIG. 6 in a rear view with the battery compartment 40 open, there is, in addition to a battery 41 , a set of individual small mechanical switches 43 with a coding switch for setting the code signal to be transmitted within the battery compartment 40 42 , by means of which a bit sequence can be set as a code in a recognizable manner by setting the switch 43 .

The hand-held radio transmitter 38 , which is shown in FIG. 5 in a front view and in FIG. 7 in a rear view with the battery compartment 40 open, has the coding circuit 30 as a code signal setting device for arbitrary, readable and thereby controllable and reproducible setting of the code signal. Instead of the coding switch 42 , the coding circuit 30 is therefore provided, of which part of the circuit board 36 can be seen in FIG. 7 with a component (IC) having the control unit 4 and the memory device 5 . On the part of the board 36 accessible from the battery compartment 40 , the button 32 is attached so that it can be actuated after opening the battery compartment 40 , but is normally protected against unintentional actuation.

Just like the hand-held radio transmitter 38 shown in FIGS. 5 and 7, a corresponding (not shown) radio receiver of the radio-controlled garage door system can be provided with the coding circuit 30 (or the coding circuit 1 or a comparable coding circuit). In the radio receiver, the code is required as a signal code for comparison with the code signal received by the handheld radio transmitter. If the code signal and signal code match, the radio receiver emits a control signal for actuating a door operator, a light switch or the like. Through the coding circuit 30 (or 1) of the radio receiver, the signal code can be set arbitrarily and the stored signal code can be read by the display device 9 . With the help of the coding circuit 1 , 30 , the codes can be easily transferred between hand-held radio transmitters and radio receivers.

The number n of digits need not necessarily be a fixed size. If desired, a much longer code (e.g. with 20, 25, 30,... Digits) can be programmed if the software of the controls 18 , 19 and 20 is designed accordingly.

Coding circuits are also conceivable that are not limited to the input and display of binary codes. The codes will usually be stored as bit sequences and will preferably also be passed on as such in a digital electronic manner. For the user, however, the use of number systems other than the binary system, for example the common decimal system, may be more pleasant. In such a case, m = 2 states (or values) instead of m = 2 as with the bit sequence 13 are possible per digit of the code to be entered. Accordingly, in an embodiment that supports a decimal system, ten first actuating devices, for example in the form of a numeric keypad, will also be present. Then there is a conversion device which converts the decimal inputs into a bit sequence (binary number) in the programming mode and the bit sequence (binary number) into a decimal number in the display mode.

In still further embodiments (not shown), the signal generator 11 is omitted as a part that is actually unnecessary. With such coding circuits, the operator must do without acknowledgment of inputs.

Embodiments are also conceivable which do not require any buttons 16 , 17 , 32 and which have only the first actuation devices 6 as actuatable devices. The functions of the buttons 16 , 17 and 32 are exercised in such embodiments by certain operating sequences or combinations of actuations of the first actuating devices 6 . For example, in one embodiment, the programming mode can be initiated by pressing keys 7 and 8 together and then actuating one of these keys to enter the state of the first bit. If no further input is made after the joint actuation within the time specified by the pointer, the display mode is started. In a further embodiment, the programming and / or the display mode is initiated by double-clicking one or both of the buttons 7 and 8 .

The controls 18 , 19 and 20 can also be in the form of hardware. In addition, the coding circuits described here can be used instead of a garage door system also in other remotely controllable systems for coding the communication between transmitters and receivers, for example for remotely controlling electrical or electronic devices, industrial and power plants or alarm systems or the like.

There are also various combinations of the Features of the coding circuits described here and the System components described here possible.

Essential aspects of the signal-actuated locking system described here are summarized again below with reference to the representation in FIG. 2:

To provide a simply manually arbitrarily adjustable and manually simply duplicable or reproducible electronic code, a coding circuit ( 1 ) is proposed which has a preferably non-volatile memory device ( 5 ) for storing the code ( 13 ), a programming device ( 21 ) for manual Entering the code ( 13 ) via first actuating devices ( 6 ) and a display device for ( 9 ) for displaying the code ( 13 ) to an operator. The programming and preferably also the display of the code takes place in succession for each of n positions of the code. For this purpose, m first actuating devices ( 6 ) are provided, m corresponding to the number of states possible for each position of the code ( 13 ) and preferably a display element ( 15 ) which can provide m signals which are recognizable and distinguishable by the operator. The coding circuit according to the invention is particularly suitable for components of a locking system, for example for hand-held radio transmitters or radio receivers of a radio-controllable garage door system, where it replaces mechanical coding switches.

Reference list

1

Coding circuit

2nd

entrance

3rd

output

4

Control unit

5

Storage device

6

first actuating device

7

first button

8th

second button

9

Display device

10th

Signal lamp

11

Signal generator

12th

second actuating device

13

Bit sequence (code)

14

third actuating device

15

Display element

16

first button

17th

second button

18th

Normal operation control

19th

Programming mode control

20th

Display mode control

21

Programming device

30th

Coding circuit

31

Timer

32

Button

33

Control panel

34

Display element (signal lamp)

35

casing

36

circuit board

37

another button

38

Radio transmitter

39

known handheld radio transmitter

40

Battery compartment

41

battery

42

Coding switch

43

switch
P processor
T timer
S non-volatile semiconductor memory

Claims (13)

1.Coding circuit in a component ( 38 ) of a security-relevant multicomponent system - in particular a signal-actuated locking system - for delivering a code ( 13 ) by means of which the component ( 38 ) communicates with one or more other components of the multicomponent system in a code-protected manner Communication of the component serving code ( 13 ) for freely reproducing the same on another component provided with the coding circuit - in particular on a component ( 38 ) to be retrofitted or to be replaced provided with the coding circuit - is readable and manually adjustable, the code ( 13 ) being off n digits exist, each of which can be arbitrarily assigned to one of m possible states, characterized by
a signal-operated storage device ( 5 ) for storing the code ( 13 ),
a programming device ( 21 ) for entering or changing the code ( 13 ) in or in the memory device ( 5 ), with at least m manually actuable first actuating devices ( 6 ), by means of which during a programming operation the n digits in the memory device ( 5 ) codes ( 13 ) to be stored can be sequentially assigned in a signal-controlled manner with one of the m possible states, and
a signal-controlled display device ( 9 ) which is connected to the memory device ( 5 ) for reading out the code ( 13 ) stored therein and is suitable for displaying the stored code ( 13 ) to an operator. 2. Coding circuit according to claim 1, characterized in that the memory device ( 5 ) has an energy supply-independent memory element, in particular a non-volatile semiconductor memory (S). 3. Coding circuit according to one of claims 1 or 2, characterized in that the programming device ( 21 ) has a manually operable programming mode initiating device ( 12 , 19 ) for initiating the programming process. 4. Coding circuit according to claim 3, characterized in that the programming mode initiating device ( 12 , 19 ) via actuation of a second actuating device ( 12 ) which is more difficult to access than the first actuating devices ( 6 ), or via a specific combination or actuation sequence of the first actuating devices ( 6 ) can be actuated. 5. Coding circuit according to one of claims 1 to 4, characterized in that the display device ( 9 ) a manually operable display mode initiating device ( 14 , 20 ) for initiating egg nes display mode and a display element ( 15 , 34 ) which after actuation of the display mode initiating device ( 14 , 20 ) the operator displays the code ( 13 ). 6. Coding circuit according to claim 5, characterized in that the display element ( 15 , 34 ) one after the other in the display mode for each of the n positions perceptible by the operator and that of the m possible states with which the corresponding position of the code ( 13 ) is currently occupied, assignable signal. 7. Coding circuit according to claim 5 or 6, characterized in that the display mode initiating device ( 14 , 20 ) by actuating a third actuating device ( 14 ) which is more difficult to access than the first actuating devices ( 6 ), or by a specific combination or actuation sequence the first actuating devices ( 6 ) or the first ( 6 ) and the second actuating devices ( 12 ) can be actuated. 8. Coding circuit according to one of claims 1 to 7, characterized in that the code is an n-digit bit sequence ( 13 ) with m = 2 possible states per digit or bit, the programming device ( 21 ) preferably having two keys ( 7 , 8 ) for forming the first actuating devices ( 6 ), which are each assigned to one of the two possible states. 9. Coding circuit according to one of claims 1 to 8, characterized by a signal generator ( 11 ), the operations and / or functions of the coding circuit ( 1 , 30 ) acknowledged by emitting signals to the operator. 10. Coding circuit according to claim 6 and claim 9, characterized by a signal lamp ( 34 ), in particular a light-emitting diode, which serves as a signal generator ( 11 ) and as a display element. 11. Use of a coding circuit according to one of claims 1 to 10 in an actuating device for a code-protected signal-actuated locking system, in particular in a hand-held radio transmitter ( 38 ) for a radio-controlled gate, which actuating device is used to emit a code signal for actuating the locking system, which has a control device, which receives the code signal from the actuating device, compares it with a predetermined signal code and controls the locking system for opening or closing after determining a match, the actuating device providing a code signal setting device comprising the coding circuit ( 1 , 30 ) for at least partially manually arbitrarily setting the code signal to be emitted is. 12. Use according to claim 11 of the coding circuit ( 1 , 30 ) according to claim 8, wherein at least one of the two keys ( 7 , 8 ) can be actuated in normal operation, in which no programming can be carried out, to emit the signal code. 13. Use of a coding circuit according to one of claims 1 to 10 in a control device for a code-protected signal-actuated locking system, in particular in a radio receiver of a radio-controlled gate, which control device for receiving a code signal sent by an actuating device ( 38 ), comparing the code signal with a predetermined signal code and controlling the locking system after determining a correspondence between the signal code and the code signal, and is provided with a signal code setting device comprising the coding circuit ( 1 , 30 ) for at least partially manually arbitrarily setting the predetermined signal code.