EP0891607B1 - Method for operating a remote-control device and a remote-control device - Google Patents

Description

State of the art

The invention relates to a method and a device according to the preamble of the independent claims 1 and 11. A generic device is as an access control system of the EP-A-285 419 known. The system described therein allows a question unit arranged in a device by stepwise scanning of the transponder codes for the unambiguous recognition of an assigned transponder from a group of several transponders located simultaneously in the access area of the question unit. A change in the existing code in the transponder codes by the questioner is not described.

From the EP-A-427 342 a transmission system is known, which consists of an interrogation unit and a number of transponders. The transponders communicate with the interrogator via an individual addressing unit to read and / or write certain information even when multiple transponders are within the interrogation zone. In response to a start code sent by the interrogation unit, the transponders respond with a characteristic time delay, which ensures the addressing of the different transponders.

From the GB-A-2 192 665 For example, a control device is known which comprises a key which communicates with a base station including a transceiver. The signal transmitted by the key evaluates the base station and only returns a response signal if it matches.

A generic method is shown in the German application number 196 45 769.6 removable. Thereafter allows a consisting of a base station and an associated actuator remote control device teaching a further actuating element by transmitting code information from a main operating element in the newly to be taught actuator. A re-learning is only possible if the main operating element and learning actuator to be brought in a predetermined manner in the range of the base station. Shown is only the teaching not yet assigned Betätigungselemen te. An influence on already assigned actuators or on the nature of the assignment is not disclosed. It is an object of the invention to extend the assignment function in the remote control device described above and to provide options for their design.

The object is achieved by a method or an arrangement having the features of the independent claims 1 and 14. The method according to the invention allows an intervention in the configuration of the assignment between the actuator and base station depending solely on the presence of the main operating element, regardless of the assignment state of an actuating element , Advantageously, in addition to the reassignment of an actuator, the base station allows the restriction of an assignment, the conditional provisional cancellation, the agreement of an auxiliary key code for facilitating the assignment, as well as the selective or general deletion of assignments. Which change is made is determined by means of a keyboard or advantageously over the duration of the presence of the main operating element in the range of the base station. It is expedient to intervene in the assignment in each case only with one actuating element at the same time. The actuator is preferably adapted to be independently assigned to a plurality of base stations.

An embodiment of the invention will be explained in more detail with reference to the drawing.

drawing

1 shows a block diagram of a remote control device, FIG. 2 shows a flow chart for illustrating its operation, FIG. 3 shows a flow chart of the operating mode learning, and FIG. 4 shows the structure of a search signal.

description

In FIG. 1, the reference numeral 10 designates a base station which is assigned to a technical device and controls its startup or access thereto. For example, a base station 10 may be part of the access control device to a motor vehicle or a building, or may belong to a computer or other consumer good. Denoted by the reference numeral 20 is a device here called actuator, which is assigned to the base station 10 functionally and acts without contact on them. An actuator 20 may be, for example, a transponder.

In the base station 10 is a transmitting / receiving device 11 for dispensing or receiving over a radio link 30 contactless transferable signals. Connected to its output is a decoder 12 which receives encoded signals received by the transceiver 11 for decoding. To carry out the decryption, the decoder 12 is assigned a memory 31 with necessary information, in particular in the form of a cryptographic key code. The decrypted signals are fed to a downstream microprocessor 13, which evaluates them and in dependence on Result of the evaluation initiates follow-up. In particular, it controls the delivery of signals via the transceiver 11. The microprocessor 13 is also assigned a memory 15. This includes, inter alia, a serial number 16, a manufacturer code 17, and a directory 18, 18H with the group numbers of the base station 10 associated with actuators 20 and the group numbers corresponding manufacturer code 27. In memory location 18H, the main actuator 20H is registered. The manufacturer code 17 is assigned by the manufacturer of the base station and designates it clearly. The serial number 16 is characteristic of mutually associated base stations 10 and actuators 20, the group numbers are used to distinguish from a common base station 10 associated actuators 20 with the same serial numbers. The memory 15 further has a slot 32 for storing an auxiliary key code. Signals to be output via the transceiver 11 are generally encrypted. For this purpose, an encoder 14 is connected between the microprocessor 13 and the transmitting / receiving device and is likewise connected to the memory 31 in order to carry out the coding. Furthermore, the base station 10 has an input device 19 to allow a user access to the microprocessor 13. The input device 19 may, for example, as shown in Figure 1, be designed as a keypad; Any other embodiments are also possible.

The actuating element 20 has a transmitting / receiving device 21 corresponding to the base station side transmitting / receiving device for receiving signals transmitted by the base station 10 or for delivering non-contact signals to the base station 10. Analogous to the base station 10, the transmitting / receiving device 21 is a decoder 22 downstream of the decoding of coded signals. To carry out the decoding, the decoder 22 is connected to a memory 31 whose content corresponds to that of the base-station-side memory 31, and in which, in particular, the cryptographic key code used in the signal encryption in the base station 10 is stored. Connected further to the decoder 22 is a microprocessor 24, which processes received signals via transceiver 21 and encoder 22 and initiates follow-up measures depending on the result. The microprocessor 24 controls, in particular, the signal output to the base station 10 via the transceiver 21. It is done to exclude interception or mimicking, usually in encrypted form. For this purpose, an encoder 23 is connected between microprocessor 24 and transmitting / receiving device 21 - analogous to the base station - which is likewise connected to memory 31 for carrying out the coding function. The microprocessor 24 is further associated with a memory device 25. In particular, it comprises a memory location 16 for storing a serial number, a memory location 26 for storing a group number, and a memory location 27 for storing a manufacturer code. The latter is awarded by the manufacturer of the actuator 20 and denotes that clearly. The serial number is a code characteristic of the overall apparatus consisting of base station 10 and actuators 20. It is expediently determined by the manufacturer or, where appropriate, the user of the overall device and is identical to the present in the base station 10 serial number 16. The group number is used to distinguish several same serial number exhibiting actuators 20. It is in the use of the device by the user of the base station 10th established. In the memory 25 are still usage information 28 to define the functional scope of the respective actuator 20. These include in particular use restrictions, with which is about the range of action for the validity of an actuator 20 is limited to a certain value, the maximum speed is limited, or the actuator is temporarily locked. The usage information 28 may alternatively also be stored in the base station in its memory 15. The base station 10 calls them from there after assigning the actuating element 20. Furthermore, a reference signal 34 is expediently filed in the memory 25 to a zero search signal, with the help of a re-learning of the Betätigungseleemntes 20 is possible.

Between base station 10 and actuator 20 there is a radio link 30 for transmitting contactless transmissible signals between the base station side and the actuating element side transmitting / receiving device 11 and 21 from the base station side transmitting / receiving device 11 outgoing signals simultaneously reach all located within their reach actuators 20. Als Signals are useful infrared signals or high frequency signals used.

A base station 10 may be associated with a plurality of actuators 20, each allowing an authorized user to start up or access the base station 10 zugeordnete technical device.

One of the actuators 20 is designed as a main actuator 20H and serves only to manage the other actuators 20. Its function as the main actuator 20H can be set, for example, via a special manufacturer-assigned, other actuators 20 not available group number 16. The structural configuration of the main operating element 20H corresponds to the actuating element 20 shown in FIG. 1. A start-up or access to the base station However, 10 associated technical device does not allow a corresponding use restriction is permanently stored as usage information 28 in the memory 25 of the main operating element 20H. It is like the cryptographic key code 31 as well as stored in the memory 25, the association information, ie the manufacturer code 27 and the serial number 16, not changeable by a user. The main actuating element also differs from the other actuating elements by a region 33 present in the memory 25, wherein information about the number of valid operating elements 20 assigned to a base station 10 and their manufacturer codes 17 are stored.

The mode of operation of the device shown in FIG. 1 is explained below with the aid of the flowchart of FIG.

The assignment process is usually initiated by the operation of a mechanical, electrical or electro-optical release mechanism, not shown, by a user, step 40. In the case of use in conjunction with the door of a motor vehicle, the trigger mechanism may be, for example, operating the door handle. On the basis of a release signal issued thereafter, the microprocessor 13 initiates the delivery of a search signal by the transmitting / receiving device 11, step 42. The search signal, as indicated in FIG. 4, essentially comprises a start sequence 35, preferably realized as a start bit, as well as the Memory 15 stored serial number 16. It is expediently unencrypted. The search signal is received by everyone within the range of the radio link 30 located actuators 20 via the transmitting / receiving means 21 received. After passing through the decoder 22, it is then checked by the microprocessor 24 of all achieved actuators 20, whether the serial number transmitted with the search signal coincides with the stored in the memory 25, serving as a reference signal serial number 16, step 43. The co-transmitted start bit 35 is used for Synchronization of the microprocessor 24 to the received search signal. If the check reveals that the reference serial number 16 present in the memory 25 does not match the serial number transmitted with the search signal, the actuating element 20 switches to a sleep state, step 41. It no longer participates therein in the subsequent communication with the base station 10 ,

If the test in step 43 shows a match of the received with the stored serial number 16, the microprocessor 24 causes a response in the form of a contact signal, step 44. The contact signal is a short simple signal, suitably the group number 26 of the associated actuator 20 in bit-coded form. Like the search signal, it is unencrypted. Within the reach range of the base station there may be several associated actuation elements which all respond to a search signal by returning a contact signal. In order to always ensure unambiguous communication, the base station 10 determines from the received contact signals which of the possible authorized actuators 20 are present and notes the present ones by corresponding entries in the memory 15. A method of distinguishing a plurality of simultaneously present actuators 20 is in German Registration, file number 196 45 769.6 disclosed to which reference is made in this regard. Will not be present Actuator 20 detects an outgoing signal, step 70.

After determining the presence of actuators 20, the determination of the mode is carried out; In particular, the operating modes are possible: assignment, training, deferrals, auxiliary key assignment, deletion. For selection, the microprocessor 13 first checks to see if the actuator 20 configured as the main actuator 20H is present, step 46. If not, an association correctness check follows, step 60, with the goal of the operating release of the base station 10, step 62.

If the microprocessor 13 detects the presence of the main operating element 20H, it determines the duration of its presence and derives therefrom the subsequently activated operating mode. For example, it first checks whether the presence duration corresponds to a time span associated with the learning mode of operation, step 48. For example, the learning mode of operation can be assigned a zero to 30 second presence duration of the actuating element. If appropriate, it executes the trainee mode explained later, step 80. If the main actuator 20H is present for longer than the occupancy associated with the mode of learning, the microprocessor 13 subsequently checks whether the occupancy time corresponds to a period associated with the mode of use, for example a residence time of 30 to 120 seconds be provided. If appropriate, it proceeds to the operating conditions operating mode, step 64. If the test in step 50 reveals that the main operating element has not yet been removed from the range of coverage of the base station 10 in the period of use allocated to the operating conditions, the microprocessor 13 checks whether the presence period of the actuating element corresponds to a period of time associated with the auxiliary key assignment mode, such as by checking whether the main operating member 20H is present for up to 240 seconds. If appropriate, it proceeds with the execution of the auxiliary key assignment operating mode, step 66. Analogously, if necessary, then a check is made on the operating mode clear, step 54.

By examining further presence periods, further operating modes can subsequently be selected, step 56. If, in addition to the modes of operation shown in FIG. 2, assigning, learning conditions, auxiliary key assignment and deletion, another operating mode is not provided, step 54 can be omitted. The delete mode is set when the check in step 52 results in a presence duration exceeding the time period for the usage conditions mode.

In each case before execution of the function determined by the selected operating mode, the microprocessor 13 determines to which of the present actuating elements 20 the function relates, step 58. The basis for the determination can be, for example, a predetermined graduation of the actuating elements 20, in which approximately first the actuator 20 with the lowest group number is selected.

The selected actuator informs the microprocessor 13 by sending its group number. Any additional actuators with other group numbers that may be present no longer participate in the subsequent communication. For this purpose, it may be provided that the microprocessor 13 outputs a command to the non-participating actuators 20, whereby they are brought into a sleep mode.

The base station 10 then subjects the selected actuator 20 to an assignment correctness check, step 60. In the example, this is done by way of the known challenge-response method. In this case, the base station 10 sends a challenge signal via its transmitting / receiving device 11, which is determined only for the selected actuating element 20 and is only executed by it. At the same time, the base station side microprocessor 13 determines a desired response signal. The calculation is carried out from the challenge signal according to a predetermined algorithm using the cryptographic key stored in the memory 31 as well as the manufacturer code 17 of the actuating element 20 to be assigned in the memory 15. The challenge signal is meanwhile received by the transmitting / receiving device 21 in the actuating element 20 , decoded in the decoder 22 and supplied to the microprocessor 24. The latter derives a response signal from the received challenge signal in the same way as the base station-side microprocessor 13 with the aid of the cryptographic key 31 and its manufacturer code 27 and sends it back to the base station 10. There it is received by the transmitting / receiving device 11, decoded again in the decoder 12 and supplied to the microprocessor 13. The latter compares it with the previously determined desired response signal. If both do not match, base station 10 and actuator 20 are not related to each other. The processor 13 then initiates appropriate follow-up action, for example blocking the base station 10 against use. In addition, it follows suitably an indication to the user that an assignment has not been made, for example by visual or audible indication. Also, further connection measures may be provided, for example, a repetition of the assignment process. If the test results in a match of the response signal returned by the actuating element 20 with the previously determined desired response signal, a confirmation is made that the assignment is correct. It expediently takes place in a form visually or acoustically perceptible to the user and leads, for example, to the release of the base station 10.

If the teaching mode is selected, the microprocessor 13 first subjects the main operating element 20H to an assignment correctness test, analogous to the assignment correctness check when an actuating element 20 is assigned according to step 60. If a correct assignment of the main operating element 20H and base station 10 is established, the microprocessor 13 checks on the basis of the directory 18 whether there are still free group numbers still assigned to any actuator, and an assignment of further actuators 20 to the base station 10 is possible at all, step 81. In the case of a negative determination, the training mode is aborted, step 70. In the case of a positive determination follows a Checking whether not yet trained actuators 20 are within range of the base station. For this purpose, the microprocessor 13 causes the transmission of a zero search signal, step 83, which has, for example, the shape of a special, for brand new actuators 20 characteristic and directly executable for this serial number. It is useful as a fixed reference signal 34 in the memory 25 of each actuator available. Whose respective microprocessors 24 cause upon receipt of a zero search signal each time the output of a first randomly formed contact signal. Its input checks the base station 10, step 84. Then, if at least one contact signal is received from a brand new actuator 20, it performs a routine to ensure that the subsequent communication is done with only one actuator 20 to be relocated, Step 85. Such a singulation routine is file number in the said German application 196 45 769.6 described to the referenced. If no contact signal is received, the teaching is aborted, step 70.

After a single active, learning actuator 20 has been separated in the range of the radio link 30, the microprocessor 13 causes the transmission of the serial number 16, the cryptographic code key 31, and one of the actuator 20 in the future associated, characteristic group number 26. The transmitted code information 16, 26th , 31 accepts the actuator 20 in the space previously provided in the memory 25. After successful transmission and storage of the code information 16, 26, 31, the actuator 20 sends an acknowledgment signal to the base station 10, step 87. It is useful in this case, the manufacturer code 27, which the base station-side microprocessor 13 stores in the memory 15 at the previously assigned group number. Then, the microprocessor 13 issues a lock command to the newly assigned actuator 20, step 88, which causes the serial number 16 previously written in the memory 25 and the cryptographic code information stored in the memory 31 to be protected against writing and reading. The actuating element 20 is then associated with the base station 10.

The teaching of a new actuator 20 also registers the main actuator 20H, such as due to the inhibit command previously issued by the microprocessor, and requests the base station 10 to transmit the manufacturer code 17 of the new actuator 20. Upon receipt, the main actuator 20H determines its location in memory 25 existing information 33 on the number of the base station 10 associated with actuators 20 and their Hrstellercodes the present after the learning of the new actuator total number of associated actuators 20 and transmits the number of Bassisstation 10, step 90. Their microprocessor 13 checks to see whether it coincides with the number of registered in the directory 18 actuators 20, step 92. If yes It confirms the new total number to the main operating element 20H, expediently by returning the registered number. The main actuator 20H then adopts the manufacturer code 27 of the newly arrived actuator 20 as well as the new total number in its memory 25. If the number determined by the main actuator 20H and the number determined by the microprocessor 13 do not match, no registration takes place.

In the subsequent step 94, the base station 10 sets off a wake-up command, by means of which the optionally present further, in the sleep state actuators 20 are switched active again. It can now follow the training of further to be reassigned actuators 20 by repeating the steps 83 follow.

In the same way as brand-new actuators can be taught also actuators that have already been trained, ie in the memory 25 already a series and a group number are available. Upon receipt of a signal from a base station, these firstly check whether it matches the serial number 16 stored in the memory 25. If this is not the case, they check whether the received signal is a zero search signal and coincides with the reference signal stored on the memory location 34. If a pre-harvested actuator 20 is then present, it responds like a brand-new actuator with the transmission of a random contact signal, and is then trained analogous to brand new actuators according to steps 85 to 88.

In use conditions mode, upon selection of an actuator 20, the base station 10 first performs an assignment correctness check for the main actuator 20H, step 60, then an association correctness check for the selected actuator 20 to be locked. If both tests are successful, the base station 10 transmits an additional association setting to the selected one Actuator 20, which takes them as usage information 28 in its memory 25. The additional allocation setting can be a usage restriction, for example. For example, the operational enabling effect of an actuator 20 may be limited to a predetermined range of action. Likewise, the actuating element 20, for example, temporarily out of force or the presence of a certain further actuating element 20 in the range of the base station 10 for an unlimited operating release of the base station 10 can be made a condition. For each additional setting, there is also an inverse function which, for example, freely releases an actuating element which is restricted with regard to its range of action or a period of time. Also handling conditions, such as the presence of a certain further actuator can be canceled. The definition of each additional settings to be made or their withdrawal takes place with the aid of the input device 19, preferably by pressing keys.

Alternatively to the deposit of usage information in the memory 25 of the actuating elements 20, this can also be done in the memory 15 of the base station 10, expediently as a supplement to the corresponding entry in the directory 18, from where they are read out if necessary.

In the auxiliary key allocation operating mode, an assignment correctness check according to step 60 for the main actuating element 20H, and then for the selected actuating element 20 is also initially carried out. Then the user sets an auxiliary key in the form of a secret code via the input device 19. The auxiliary key 32 is stored in the memory 15 of the base station 10 and transmitted to the present actuating elements 20, which also store it each in their memory 25. By means of the auxiliary key 32, actuating elements 20 equipped therewith can subsequently be influenced in their functionality solely by means of the input device 19; a simultaneous or preceding presence of the main actuating element 20H is not necessary. The user must do this via the input device 19 enter the auxiliary key. He is forwarded by the base station 10 to a present actuator 20, which is then ready to receive additional agreements. For example, when used in automobiles, it may be determined that an actuator 20 may allow the engine to be started but not the opening of the glove box, or a change in stored vehicle settings such as mirror or seat adjustment. Additional agreements also place the actuators 20 in their memory 25. Each time they perform the assignment correctness check, they transmit the memory contents with the additional agreements to the base station 10, which then takes it into account.

In the delete mode, an assignment correctness check, step 60, for the main actuation element 20H, takes place analogously to the blocking mode for the selected actuator 20. Thereafter, the base station 10 deletes in its memory 15 belonging to the selected actuator 20 entries in the directory 18, ie in particular its group number and the associated manufacturer code.

The deletion command is expediently also triggered by means of the input device 19. It may be provided that in the mode delete one after the other or at the same time the directory entries 18 all located in the coverage area of the base station 10 actuators 10 are deleted. It is also expedient to be able to delete the entire directory 18 independently of the presence of the actuation elements 20 concerned. The complete deletion of all actuators is suitably triggered by a special, to be entered via the input device 19 command. In step 60, in this case, the assignment correctness check is made only for the main operating member 20H, not for a selected operating member 20 and. The directory entry 18 of the main operating element 20H can not be deleted.

Instead of the presence of the main operating element 20H in the range of the base station 10, the selection of the operating mode can also take place with the aid of the input device 19. Upon receipt of a contact signal from an actuator 20, step 44, in this case, a routine is performed by the base station to determine which mode of operation has been selected. For example, instead of checking in step 46 whether the main operator 20H is present, a check is made as to whether the associate mode is selected, optionally branching to step 62 via step 58. In steps 48, 50, 52, 54 instead of the presence duration inputs via the input device 19 queried.

The above-described method or the above-described arrangement can be configured and modified in many ways while retaining the basic idea of being able to influence the allocation of components forming part of a remote-control device in the presence of a main operating element 20H in a number of ways. This is especially true for the internal structure of base station and actuators, as well as for the design and sequence of process steps, such as the timing of performing the accessibility check or the handling of brand new or pretanning actuators during teach-in.

Claims (21)

1. Method for operating a telecontrol device having

   - a base station (10) which is available only to an authorised user,

   - an operating element (20) for controlling the base station (10),

   - memory means (15, 25), produced in the operating element (20) and in the base station (10), which store a piece of information associating the operating element (20) with the base station (10), and also having

   - a wireless signal transmission link, produced between the base station (10) and the operating element (20), for contactlessly performing the telecontrol, having the following steps:

   - a piece of authorization information (16, 26, 31) is stored in the memory (25) of an operating element (20) which is in the form of a primary operating element (20H),

   - the primary operating element (20H) is brought into the range of the wireless signal transmission link (30),

   - the presence of the primary operating element (20H) is established by the base station (10),

   characterized by the following further steps:

   - the base station (10) is made ready to change the association information (18) stored in the memory means (15, 25) when the presence of the primary operating element (20H) has been established.
2. Method according to Claim 1, characterized by the base station (10) being made ready to change the content of the memory (25) in another operating element (20) via the wireless signal transmission link (30).
3. Method according to Claim 1, characterized in that a secret auxiliary key code (32) is created in the base station (10) and in an operating element (20) in the presence of the primary operating element (20H), said secret auxiliary key code subsequently rendering the base station (10) able to change the memory content of the operating element (20) even when the primary operating element (20H) is not present.
4. Method according to Claim 1, characterized in that the number of operating elements (20) associated with a base station (10) is stored in the primary operating element (20H).
5. Base station for carrying out the method according to Claim 1, having a transmission/reception device (11) for sending/receiving signals to/from an associated operating element (20), and also means (13) for establishing the presence of a primary operating element (20H) in the range of the transmission/reception device (11), characterized in that it has an alterable memory (15) which records all existing associations between the operating elements (20, 20H) in the form of respective characteristic information (18) for the associations, where the base station (10) is made ready to change the association information (18) stored in the memory means (15, 25) when the presence of the primary operating element (20H) has been established.
6. The base station as claimed in Claim 5, characterized in that when a primary operating element (20H) is present it is ready to use the transmission/reception device (11) to send signals which change the content of the memory (25) in another operating element (20).
7. Base station according to Claim 5, characterized in that it is designed to associate an operating element (20) with the base station (10).
8. Base station according to Claim 5, characterized in that it is designed to conditionally cancel the association between an operating element (20) and the base station (10).
9. Base station according to Claim 5, characterized in that it is designed to delete the association between an operating element (20) and the base station (10).
10. Base station according to Claim 5, characterized in that the memory (25) can store a secret auxiliary key code (32) which can be used to make the base station (10) ready to subsequently send signals which change the content of the memory (25) in another operating element (20) even when the primary operating element (20H) is not present.
11. Base station according to Claim 5, characterized in that it only ever sends signals prompting a change in the memory (25) in an operating element (20) to one operating element (20) at the same time.
12. Base station according to Claim 5, characterized in that after identifying the presence of a primary operating element (20H) it puts it into a sleep mode.
13. Base station according to Claim 5, characterized in that it derives the type of changes which can be made in the memory (25) of an operating element (20) from the length of time for which the primary operating element (20H) is present.
14. Operating element for carrying out the method according to Claim 1, having a transmission/reception device (21) for receiving/sending contactlessly transmitted signals from/to a base station (10) and also a memory (25) for storing a piece of authorization information (16, 26, 31) for an associated base station (10), where
    the memory (25) contains an invariable piece of information (27) which explicitly denotes the operating element (20), characterized in that the memory contains a variable piece of information (16, 26) which associates the operating element (20) with a base station (10).
15. Operating element according to Claim 14, characterized in that the associating piece of information (16, 16) has a predetermined form in the new state.
16. Telecontrol device having a base station (10) which is available only to an authorized user and also an operating element (20), associated with the base station (10), for contactlessly controlling the base station (10), where
    the base station (10) has an alterable memory (15) which records all existing associations between operating elements (20, 20H) in the form of respective characteristic information for the associations, characterized in that the number and/or the type of the associations can be altered by a user.
17. Telecontrol device according to Claim 16, characterized in that the operating element (20) has a memory (25) for a piece of association information (16, 26, 31), and in that the base station (10) is designed to control the memory (25) in order to alter the association information (16, 26, 31).
18. Telecontrol device according to Claim 16, characterized in that the base station (10) has a plurality of associated operating elements (20), one of which is in the form of a primary operating element (20H) whose memory (25) is unalterable.
19. Telecontrol device according to Claim 16, characterized in that the base station (10) is associated with a technical facility in order to enable startup thereof, startup not being possible with the primary operating element (20H).
20. Telecontrol device according to Claim 16 characterized in that the base station (10) is associated with a technical facility in order to enable startup thereof, and the memory means (15, 25) are able to store information (28) which allow only limited startup of the technical facility.
21. Telecontrol device according to Claim 16, characterized by a base station (10) according to Claim 5 and also an operating element (20) according to Claim 14.

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