EP0891606A1

EP0891606A1 - Method and device for assigning an authorization device to a base station

Info

Publication number: EP0891606A1
Application number: EP98907879A
Authority: EP
Inventors: Heidrun Hacker; Stephan Schmitz
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 1997-02-04
Filing date: 1998-01-30
Publication date: 1999-01-20
Also published as: AU6608998A; JP2000509863A; DE19703999A1; WO1998034200A1; BR9805968A; AU729223B2; US6304968B1

Abstract

The invention relates to a method and a device for assigning an authorization device (20) to a base station (10). The base station (10) transmits a search signal which is received by the authorization device (20) and compared with a previously stored reference signal that has been assigned to a base station (10). If the search signal matches the reference signal, the authorization device (20) emits a response signal. If they do not match, the authorization device (20) verifies whether the search signal corresponds to another previously stored reference signal assigned to a different base station (10).

Description

Method and device for assigning an authorization device to a base station

State of the art

The invention is based on a method according to the type of the main claim, as it is the German patent application,

Case number 196 45 769.6, can be removed. The assignment of an authorization device designed as a remote control to a base station belonging in particular to a motor vehicle is then carried out in a two-stage process, the base station sending out a search signal in the first assignment step in order to determine authorization devices present in the signal range area. Authorization devices present receive the search signal, compare it with a reference signal stored in a memory, and, if the search signal and reference signal match, respond by returning a presence signal. The return is carried out at a point in time related to the receipt of the call signal and characteristic for the respective returning authorization device, on the basis of which the base station presently identifies the authorization elements present. She then selects one of the attendees and subjects it to an assignment correctness check in the second assignment step. The method makes it possible to assign several authorization devices to a base station and to ensure that the assignment is carried out quickly. The object of the invention is to provide, based on this known method, a possibility which allows an authorization device to be assigned to a plurality of base stations.

Advantages of the invention

The object is achieved by a method having the features of the main claim and an authorization device designed to carry it out in accordance with the subclaims. The method according to the invention permits the assignment of an authorization device to several base stations, for example the assignment of a remote control to several motor vehicles, to different buildings or simultaneously to buildings and vehicles, without any special user

Must take action. Since only one authorization device to be assigned after unilateral signal transmission is initially recognized directly on the basis of a search signal emitted by the base station, and only then is the accuracy of the assignment checked, the method works very quickly. It is also advantageous to limit the number of base stations that can be assigned to an authorization device to a value adapted to the intended use.

An embodiment of the invention is explained below with reference to the drawing.

drawing

FIG. 1 shows a block diagram of an allocation device, FIG. 2 shows a flow diagram to illustrate its operation.

description

In FIG. 1, reference number 10 denotes a base station which is permanently assigned to part of a device or an object or such. For example, the base station can be part of the access device to a building or a motor vehicle. The reference number 20 denotes an authorization device, referred to in the following as a remote control, which is functionally assigned to the base station 10 in a contactless manner via a signal transmission path 30. A remote control 20 can be assigned to several base stations 10, whereby the base stations 10 can belong to different technical devices. For example, a remote control can be assigned to a vehicle and a building at the same time. The remote control 20 can be a transponder, for example. Base station 10 and remote control 20 together form an overall system referred to here as a remote control device.

The core of the base station 10 is formed by a microprocessor 13 which, in particular, causes and monitors the output of signals by the base station 10 and evaluates incoming signals. It has a memory 15 in which a program for executing an assignment check dialog is stored. Connected to the microprocessor 13 is a transmitting / receiving device 11 for delivering or receiving Signals to or from a remote control 20. Signals to be emitted or received via the transceiver 11 are or are partially encrypted. A encoder 14 is therefore connected between the microprocessor 13 and the transceiver 11 for encrypting outgoing signals, and a decoder 12 for decrypting incoming signals. Encoder 14 and decoder 12 each access a memory 31 to carry out the encryption or decryption. in which a cryptographic key code characteristic of the base station 10 is stored. Another memory 15 is also assigned to the microprocessor 13. This includes, among other things, a serial number 16, a manufacturer code 17, and a directory 18 with the group numbers 181G, 182G, ..., 18iG with i = 1,2, ..., M of the remote controls 20 assigned to the base station 10 and the Manufacturer codes belonging to the group numbers 181H, 182H, ..., 18iH with i = 1,2, ..., M of the remote controls. The serial number 16 is a code which is characteristic of a base station 10 and all assigned remote controls 20. The manufacturer code 17 is assigned by the manufacturer of the base station 10 and uniquely identifies it, the group numbers 181G, 182G, ..., 18iG are used to differentiate from remote controls 20 assigned to a common base station 10 with the same serial numbers 16. Furthermore, they are connected to the microprocessor 13 Actuating means 19, which allow a user to influence the function of the microprocessor 13 manually and, for example, as indicated in FIG. 1, are designed as a keypad; any other configuration, for example as a voice input system, is also possible.

The remote control 20 has a transceiver 21 corresponding to the base station-side transceiver 11 for receiving signals emitted by the base station 10 or for emitting signals the base station 10. Analogously to the base station 10, the transceiver 21 is followed by a decoder 22 for decoding coded signals. Connected to these is a microprocessor 24, which processes signals received via transceiver 21 and decoder 22 and initiates follow-up measures depending on the result. In particular, the microprocessor 24 controls the delivery of signals to the base station 10 via the transceiver 21. It is done in an encrypted form, in order to prevent eavesdropping or imitation. An encoder 23 is therefore connected between the microprocessor 24 and the transceiver 21, analogously to the base station 10.

A memory 25 is assigned to the decoder 22, encoder 23 and microprocessor 24 in order to carry out the signal processing in the remote control 20, ie the decoding of incoming and the coding of outgoing signals, and to control the operation of the microprocessor 24. It is divided into several areas 251, 252, 253, ..., 25n with n = 1,2,3, ..., L, three of which are indicated for the sake of clarity. Each memory area 251,..., 25n each contains a memory location 26 for storing a serial number, a memory location 27 for storing a group number and a memory location 31 for storing a cryptographic key code. The function of the codes stored in the memory locations 26, 27 31 corresponds to that of the identically named codes stored in the memory 15 of the base station 10. Thus the serial number 26 is a code characteristic of a telecontrol device consisting of base station 10 and assigned authorization devices 20, which code is expediently determined by the manufacturer or by the user of the overall device and is identical to the serial number 16 present in base station 10. Group number 27 - this corresponds to a group number entry 18iG in the directory 18 in the memory 15 of the base station 10 - is used to distinguish between a number of remote controls 20 having the same serial number. It is assigned to the remote control 20 by the base station 10 in a special teaching mode. The cryptographic key code stored in the memory 31 is used by decoders 22 and encoders 23 for decrypting incoming or outgoing signals. Depending on the communication method used, it is identical to the key code stored in the memory 31 of the base station or is related to it. Each memory area 251,..., 25n also has a space for storing usage information relating to the functional scope of a base station 10. For example, when used in a motor vehicle, the usage radius 28 can restrict the action radius for the validity of a base station 20 to a specific value . In the memory 25 there is also a manufacturer code 29 assigned to the remote control 20 by the manufacturer.

Serial numbers, cryptographic key codes and usage information stored in a memory area 251,..., 25n are assigned to a single base station 10. A remote control 20 can thus correspond to the number of memory areas 251,..., 25n several base stations

10 assigned. The number L is expediently set to a value oriented towards the intended use. In the case of remote controls for motor vehicles and buildings, this value can be, for example, four for facilities intended for private individuals and, for example, 500 for facilities intended for vehicle rentals.

There is a radio link 30 between base station 10 and remote control 20 for the transmission of signals which can be transmitted without contact between the device-side transmitter de / receiving device 11 and the transmitting / receiving device 21 on the side of the remote control 20. Infrared signals or high-frequency signals are expediently used as signal carriers.

The mode of operation of the device shown in FIG. 1 is explained below on the basis of the flow chart in FIG. The sequence steps are preceded by a letter B or F, which indicates whether the relevant sequence step takes place in the base station 10: B or in the remote control 30: F. The assignment process is usually initiated by the actuation of a mechanical, electrical or electro-optical trigger mechanism, for example, by a user, step 100. In the case of use in the door of a motor vehicle, the trigger mechanism can e.g. insist on operating the door handle. As a result, the microprocessor 13 of the base station 10 initiates the transmission of a search signal by the transmitting / receiving device 11, step 102. The search signal essentially contains one, preferably in the form of a

Start bits realized, start sequence for activating the remote controls 20 and the serial number 16 stored in the memory 15. It is expediently unencrypted. The search signal is received by all remote controls 20 located within the range of the radio link 30 via its transceiver 21, step 104. All remote controls 20 that have been activated are then activated, step 106, and check whether they are assigned to the base station 10 emitting the search signal. To do this, you set a running index n to the value 1, step 108 and then load the serial number 26 from the memory 25 into the microprocessor 24 from the memory 25. The transmitted start bit is used to synchronize the microprocessor 24 with the received search signal. The microprocessor 24 now checks whether those from the first memory area 251 read serial number matches the serial number transmitted in the search signal, step 112. If the test reveals a mismatch, the microprocessor 24 determines whether the checked serial number comes from the last memory area 25L, step 114. If this is not the case, it increases the run index n by 1, step 116, and repeats steps 110 and 112. If all memory areas 251,

252 ... 25L is checked and a match regarding the serial number transmitted with the received search signal is not found, the assignment is terminated, step 115.

If a check in step 112 shows a match of the received serial number with a stored one, the microprocessor 24 activates the associated memory area 25n and initiates the delivery of a response signal to the base station 10, step 120. The response signal is expediently a short, simple signal, for example the group number 26 from the activated memory area 25n. The received serial number, for example, can also be sent back to the sending base station 10 as a response signal, the return being carried out in a predetermined time window from the receipt of the search signal. The base station 10 is also informed of the group number in this way. The latter method is explained in more detail in the German application, file number 196 45 769.6, to which reference is made.

After receiving the response signal from the remote control 20, the base station-side microprocessor 13 initiates an accuracy check. It is expediently carried out using the known challenge-response method. The base station 10 uses its transceiver 11 to set an encrypted challenge Signal which is received by the remote control 20, decoded, recoded with the aid of the manufacturer code and the cryptographic key code from the activated memory area 25n, re-encoded in the encoder 23 and sent back to the base station 10 as a response signal via the transceiver 21 . In the meantime, the microprocessor 13 of the base station 10 determines a target response signal from the previously sent challenge signal. The calculation is carried out from the challenge signal according to a predetermined algorithm using the cryptographic key code stored in the memory 31 and the manufacturer code 181H, 182H,..., 18iH of the remote control, which code is present in the memory 15. The microprocessor 13 compares the target response signal with the response signal received by the remote control 20. If the two do not match, base station 10 and remote control 20 are not associated with one another. The microprocessor 13 then initiates follow-up measures provided for this case, for example it blocks the device assigned to the base station 10 against use. In this case, the user is advised, for example by visual or acoustic display, that an assignment has not been made. Further follow-up measures can also be provided, for example a repetition of the assignment process starting with step 102. If the assignment correctness check shows a match between the response signal and the target response signal determined in the microprocessor 13, a confirmation is given that the assignment is correct. It expediently takes place in a form that is perceptible to the user optically or acoustically and leads, for example, to the release of the device assigned to the base station 10.

Claims

Expectations

1. A method for assigning an authorization device to a base station with the steps

Delivery of a search signal by the base station, reception of the search signal by the authorization device, comparison of the search signal with a previously stored reference signal assigned to a base station, delivery of a response signal by the authorization device if the search signal matches a reference signal,

characterized in that

in the authorization device (20) a received search signal is compared with a further pre-stored reference signal assigned to another base station (10) if it does not match the first one.

2. The method according to claim 1, characterized in that upon receipt of a response signal in the base station (10) initiates an assignment correctness check in which the presence of a matching cryptographic code key in the base station (10) and authorization device (20) is checked.

3. The method according to claim 1, characterized in that an unencrypted signal is used as the search signal, and the same search signal is stored as a reference signal in several authorization devices (20).

4. The method according to claim 1, characterized in that the authorization device (20) activates further pre-stored information (28) when a search signal matches a reference signal, which information is at least partially transmitted to the base station (10) in a subsequent signal exchange.

5. Authorization device for carrying out a method according to claim 1, characterized by a memory (25) for storing several reference signals assigned to different base stations (10), a receiving device (21) for receiving search signals emitted by a base station (10). a processing device (22, 23, 24) which contains means for comparing a search signal with all stored reference signals, and a transmission device (21) for emitting a response signal when a received search signal matches one of the stored reference signals

(26).

6. Authorization device according to claim 5, characterized in that the processing device (22, 23, 24) compares a received search signal in succession with all stored reference signals.

7. Authorization device according to claim 5, characterized in that the processing device (22, 23, 24), if a received search signal matches a stored reference signal, activates further information stored in the memory (25), which is used to check the

The correctness of the assignment to a base station (10) characterized by the search signal is used.

8. Authorization device according to claim 5, characterized in that the number (L) of memory locations (251, 252,

..., 25n) for storing reference signals and thus the number of possible assignments to different base stations (10) is limited to a value based on the intended use.