EP0257376A1 - Electronic locking system comprising at least a lock, particularly for motor cars - Google Patents

Abstract

A control unit (237) in the receiver (2) opens the lock (3) of the locking system when the transmitter sequence (1) emits the electronic locking system (SF), which is formed by repeated operation of the transmitter (1) by the user and in a marker memory (232) of the receiver (2) is stored, matches a reference sequence (BF) within a post-synchronization area (NB) in the receiver (2). If necessary, the synchronization unit synchronizes the reference transmitter (233) to the last transmission mark (SM) of the transmission sequence (SF).

Description

The invention relates to an electronic locking system according to the preamble of claim 1 and a method for resynchronization according to the preamble of claim 10.

The basis for the operation of locking systems of this type is an initialization by means of which a sequence of reference markings is fixedly predetermined in the receiver of the receiver and a sequence of transmission markings which is identical to this in the transmitter of the transmitter. After initialization, the reference transmitter stands on a current reference marker which is identical to the current transmitter marker of the marker transmitter in the transmitter. The two sequences are determined on the basis of a stored algorithm and of start parameters, which are determined by a random process.

With each transmission process, the transmitter emits a transmission signal with a transmission marking, which is emitted, for example, by a luminescence diode in the infrared range. The transmission signal is converted in the receiver into an electrical signal from which the receiver recovers the transmission mark, which is compared in the receiver with a reference mark supplied by the reference transmitter. If the reference mark and the send mark are identical, the transmitter and receiver are synchronized and the control device initiates the opening of the lock.

If there is no identity between the reference mark and the send mark, a synchronization unit in the receiver restores the synchronization between the reference transmitter and the marker transmitter under certain conditions (post-synchronization).

A missing identity between the reference mark and the send mark can e.g. then occur when the transmitter emits a transmission signal that does not reach the receiver. In this case, the reference transmitter must be re-synchronized in the receiver in order to cause the locking system to open the lock.

In a known locking system (European patent application 84 10 61 42.7), additional information is accommodated in the transmission signal for re-synchronization, from which the receiver can see which reference mark the reference transmitter in the receiver is to be re-synchronized by the synchronization unit. The creation and evaluation of the additional information involves additional effort, without this being countered by greater security.

It is therefore an object of the present invention to carry out a resynchronization in a simple and reliable manner in the absence of synchronization between the transmitter and receiver in such a way that the electronic locking system is avoided with high probability by unauthorized persons.

According to the invention, this object is achieved by the features characterized in claims 1 and 10.

The receiver has a memory, for example a RAM, in which a section of the sequence of transmission marks - called the transmission sequence - which is formed by actuating the transmitter several times, is stored. The receiver compares this transmission sequence with a reference sequence, which consists of successive reference marks supplied by a reference transmitter, for identity. The reference sequence lies within an after Synchronization area, which extends over a section of the sequence of fiducial marks and begins with the fiducial mark that meets the first desynchronous transmission mark. If the receiver establishes identity between the transmission sequence and the reference sequence within the post-synchronization area, the synchronization unit synchronizes the reference transmitter to the last transmission marking of the transmission sequence, and the lock of the locking system is opened by the control unit.

In a catch area at the beginning of the post-synchronization area there can additionally be a relatively short sequence of reference markings - called catch sequence - within which the synchronization unit first searches for a reference mark that is identical to the received transmission mark. If an identical reference mark is found within the catch sequence, the synchronization unit synchronizes the reference transmitter to the received send markings within a very short time. Only if there is no identity between the transmission mark and the reference mark within the catch area is it examined whether a reference sequence identical to the received transmission sequence exists in the remaining part of the post-synchronization area.

The following example shows the probability that an unauthorized person can open the lock with a transmitter (probability of break-in):

If one assumes that a broadcast mark or reference mark consists of a dual word with 24 digits, there are a maximum of 2²⁴ different send markings or reference marks. The probability that an unauthorized person accidentally finds a synchronous transmission mark is only 2⁻²⁴, which is approximately equal to 5.96 x 10⁻⁸. If a catch sequence is, for example, 100 reference marks long, the value for the break-in probability is 5.96 x 10⁻⁶.
If you set the length of the post-synchronization area minus the length of the catch sequence with 1000 reference marks and if the transmission sequence is two transmission marks long, the value for the break-in probability is
(5.96 x 10⁻⁸) ² x 10³ = 5.96 x 10⁻¹³.

By varying the length of the catch area, the probability of a break-in can be further reduced. In addition to manually setting the length by the user, e.g. a random generator can be accommodated in the synchronization unit of the receiver, which redetermines the length of the capture range after each re-synchronization.

The length of the reference sequence, which the receiver checks for re-synchronization in the re-synchronization area with the received transmission sequence, can advantageously also be carried out automatically by the receiver, e.g. reset after every resynchronization.

The security of the method can be additionally increased by the length of the post-synchronization area - e.g. after each resynchronization - is automatically reset by the receiver. The variation of the post-synchronization range can either be determined via a calculation rule in the synchronization unit or e.g. are generated via a random generator in the synchronization unit.

The receiver can additionally contain a timer which blocks the receiver for a waiting time if a re-synchronization fails; During this waiting period, the recipient does not respond to any send markings. The authorized user of the locking system is thereby given the opportunity to have the locking system open after the waiting time without re-initialization by a new transmission marking.

Further advantageous variations of the invention are characterized in the subclaims.

• FIG 1 die räumliche Zuordnung von Sender und Empfänger,
• FIG 2 ein Blockschaltbild eines Ausführungsbeispiels der Er­findung,
• FIG 3 ein Flußdiagramm, das einen Algorithmus zur Erzeugung einer Bezugsmarkierung wiedergibt, und
• FIG 4 ein Flußdiagramm, das die Auswertung von Sendemarkie­rungen in Empfänger nach FIG 2 angibt.

The invention is illustrated by the figures. Show it,

• 1 shows the spatial assignment of transmitter and receiver,
• 2 shows a block diagram of an exemplary embodiment of the invention,
• 3 shows a flowchart which represents an algorithm for generating a reference mark, and
• 4 shows a flow chart which indicates the evaluation of transmit markings in the receiver according to FIG.

According to FIGS. 1 and 2, the locking system of a motor vehicle has a transmitter 1 and a receiver 2, which is connected to a lock 4 of the motor vehicle and is accommodated in the motor vehicle in the vicinity of the interior mirror.

The transmitter 1 has a trigger 12, e.g. a button which, after manual actuation, emits a trigger signal AS to a marker 11, which is connected to the trigger 12.

Excited by the trigger signal AS, the marker transmitter 11 generates an actual transmission marker SM _i per actuation by means of an algorithm (FIG. 3), which consists of a dual word with 24 digits. A low-consumption CMOS one-chip microcomputer is used as the marker 11, which outputs the transmission marker SM _i as a binary signal to a modulator 13 which has a driver transistor. This switches the current through the luminescence diode 14 in time with the binary signal, which emits a transmission signal SI - to which the transmission marking SM _{i is} modulated - as radiation in the infrared range to the receiver 2 in the motor vehicle.

The receiver 2 contains a phototransistor 21 as the receiving stage, which, when a transmission signal SI is received, forwards a signal corresponding thereto to a demodulator 22. At its output, this again delivers pulses corresponding to the transmission marking SM _i , which are further processed by a microcomputer 23 will. This essentially contains a microprocessor 230 which, through appropriate programming, acts as a synchronization unit. Four memories (RAM) 232 to 235, a timer 236, a control unit 237, a start switch 24 and an input switch 25 are connected to it via a BUS 231.

The processor 230 stores the successively incoming transmission markings SM of a transmission sequence SF in the memory 232, hereinafter referred to as the marking memory.

The memory 233 serves as a reference transmitter and contains - controlled by the processor - an old value BM _o and a new value BM _{i of} the reference mark BM alternately in succession. The new value (BM _i ) _x is generated from the old value (BM _o ) _x-1 according to an algorithm (FIG. 3) after receipt of a transmission mark. This is generated during the initialization with the aid of a random generator 2301 contained in the microprocessor, or is supplied from the memory 234 after a failed resynchronization, which is therefore referred to below as the old value memory. In synchronous normal operation and while trying to re-synchronize, the last new value (BM _i ) _x-1 serves as the old value (BM _o ) _x-1 for determining the next new value (BM _i ) _x .

The receiver 2 has an input switch 25 with three switches which are connected to the BUS 231: the length of the capture range FB can be set with a catch sequence switch, the length of a reference sequence BF with a reference sequence switch and the length of the resynchronization range NB with a range switch.

To initialize the locking system, the microcomputer 23 in the receiver 2 is connected to the transmitter 1 by means of a plug-in cable 6. Thereafter, the start switch 24 is manually operated for a random period of time which the random generator 2301 measures by counting up. After the start switch 24 has been released, the processor 230 supplies a binary random word, for example six bytes in length, the value of which depends on the actuation time of the start switch ters 24 depends. The first three bytes of this random word form an old value for the reference mark BM and are stored in the reference transmitter 233. The last three bytes form a partial word HAZ, which is stored in memory 235 - hereinafter referred to as random memory. This random word formed during the initialization (old value of the reference mark and partial word HAZ) is simultaneously loaded into the mark transmitter 11 of the transmitter 1 via the cable 6. Each transmission signal SI emitted by the transmitter 1 therefore has a transmission marking SM _i which is determined by the start parameters mentioned and an algorithm which is likewise identical for the transmitter and receiver.

In the receiver, each transmission mark SM _{i of} a transmission signal from the microcomputer is stored in the marking memory 232, the capacity of which is dimensioned to accommodate all transmission marks of a transmission sequence. Upon receipt of the first transmission mark SM _i after initialization, a new value of the reference mark is formed, based on the aforementioned start parameters and the algorithm on the basis of which the transmission mark was generated in the transmitter. Therefore, as long as each transmission mark given by the sender reaches the recipient, the transmission mark and the new value of the reference mark are identical. If the microcomputer 23 detects this, it emits an opening signal OS to the lock 3 via the control unit 237 (synchronous case).

3, an algorithm for generating the new value BM _{i of} the reference mark from the respective old value BM _{o is} explained with the aid of the computer 23.

After receiving a transmission mark SM _x , the computer 23 first checks whether the old value (BM _o ) _{x-1 of} the reference mark has the value zero or not. If this value is zero, a logical one is added to the first position of the content of the reference transmitter 233 (point G in FIG. 3).

On the other hand, if (BM _o ) _{x-1 is} not equal to zero, the computer 23 checks whether the penultimate digit NLSB and the last digit LSB of (BM _o ) _x-1 together result in the number 10 or the number 01. If one of these numbers is present, the content of the reference transmitter 233 is shifted to the right by one position and a one is added to the first position MSB (point G in FIG. 3). If the number 10 or 01 is not available, the memory content of 233 is only shifted to the right by one digit.

The partial word HAZ from the random memory 235 is now added to the content of the reference transmitter 233. The new value (BM _i ) _{x of} the reference mark is thus present in the reference transmitter 233.

4 shows the program steps for evaluating transmission marks SM _x in the receiver 2. It is assumed that a transmission sequence SF is two transmission marks SM and a reference sequence BF is two reference marks BM. The corresponding switches of the input switch 25 are therefore set to the value 2.

Upon receipt of the first transmission marking SM _x , it is stored in the marking memory 232 and the old value (BM _o ) _x-1 in the old value memory 234. The processor then causes the new value (BM _i ) _{x of} the reference mark to be generated in accordance with the algorithm according to FIG. 3 and stores it in the reference transmitter 233. The processor 230 then compares this new value with the send mark SM _x for identity.

If this identity is given, the transmitter and receiver are synchronous, the program branches to point P: The processor then sends a synchronization signal SYN to the control device 237, which then opens the lock 3 with an opening signal OS.

If the processor 230 has determined that there is no identity between the first transmission mark SM _x and the first reference mark (BM _i ) _x , it examines whether within a Catch sequence FF of m successive reference marks at the beginning of the post-synchronization area NB there is a reference mark (BM _i ) _{x + p which} is identical to the - desynchronous - transmission mark SM _x . To generate successive reference markings (BM _i ) _{x + p} according to the algorithm according to FIG. 3, the loop labeled A in FIG. 4 is run through until a reference mark identical to SM _{x is} found or the loop has been run through m times, which is equally significant with the end of the catch sequence.

If no identical reference mark was found within the catch sequence and there is already a second transmission mark SM _{x + 1} , a search is made for a reference mark that is identical to SM _x in the part of the resynchronization area NB following the catch area FB. For this purpose, the index standing on m is increased by 1 and then the reference markings (BM _i ) _{x + p} according to FIG. 3 are generated in a loop denoted by B in FIG. 4 - similar to loop A -. This loop is exited as soon as a reference mark (BM _i ) _{x + p} identical to SM _x is found or after y passes the end of the post-synchronization range is reached.

If a reference mark (BM _i ) _{x + p} identical to SM _x is found within the post-synchronization area, the processor causes the following reference mark (BM _i ) _{x + p + 1 to be} generated in accordance with the algorithm in accordance with FIF 3 and checks whether this reference mark corresponds to the Send marker SM _{x + 1 is} identical. If this is the case, the resynchronization has been successful and the steps for opening the lock already described and starting at P are carried out.

If, on the other hand, no reference marking identical to SM _x or SM _{x + 1 is} found within the resynchronization area, the resynchronization has failed. In this case, the old value (BM _o ) _{x-1 of} the reference mark saved when the first transmission mark is received in the old value memory 234 is loaded into the reference transmitter 233, so that the identity comparison upon receipt new send marks - e.g. from the authorized associated transmitter - starts from the old value (BM _o ) _x-1 . In addition, the processor issues a set signal SW to the timer 236, which emits an acknowledgment signal QW after a programmed waiting time. Only then is the receiver ready to receive again. In the meantime between the failed resynchronization and delivery of the acknowledgment signal, however, the receiver is blocked, so that incoming send marks SM are not processed.

Processor 230, random generator 2301, memories 232 to 235 and control device 237 can be in a functional unit, e.g. a one-chip microcomputer 23 with mask-programmable ROM can be combined.

Claims (10)

1. Electronic locking system with at least one lock (3), in particular for motor vehicles,
with a transmitter (1) which emits a transmission signal (SI) with each transmission process, which is modulated with a transmission marker (SM),
- With a marker (11) in the transmitter (1), which assigns a transmit marker (SM _i ) from a sequence of transmit markers (SM) to each transmit signal (SI),
- With a receiver (2), which is equipped
- With a reference transmitter (233), which delivers a current reference mark (BM _i ) from a sequence of reference markings (BM), which is identical to the sequence of transmission marks (SM) of the transmitter (1), and by each received transmission signal (SI) is steered to a new reference mark (BM _i ) of the sequence,
- And with a control unit (237) which opens the lock (3) when the transmission mark (SM _i ) and reference mark (BM _i ) (synchronization) are controlled by the synchronization unit (23),
- With a synchronization unit (23) which, after each transmission signal (SI), compares its current transmission marking (SM _i ) with the new value (BM _i ) of the reference marking supplied by the reference transmitter (233) and, if there is no identity, the synchronization of the transmitter (1) and recreating the receiver (2) (post-synchronization) if the transmission mark (SM _i ) and the new value of the reference mark lie within a post-synchronization area (NB), which extends over a section of the sequence of reference marks (BM),
characterized,
- That the synchronization unit (23) has a marker memory (232) in which a transmission sequence (SF) is stored, which consists of the transmission markings (SM) of n successive transmission signals (SI), and
- That the synchronization unit (23) the reference transmitter (233) on that reference mark (BM _i ), which is identical to the nth transmission mark (SM) of the transmission sequence (SF), then resynchronized if a reference sequence (BF.) within the resynchronization area (NB) ) consisting of n reference marks (BM) which are identical to the transmission sequence (SF). 2. Electronic locking system according to claim 1,
characterized,
that the synchronization unit (23) then synchronizes the reference transmitter (233) in the absence of synchronization to a reference mark (BM _i ) identical to the received transmission mark (SM _i ) if this transmission mark (SM _i ) within a catch sequence (FF) of reference markings (BM) is present, which extends only over a part of the post-synchronization area (NB) at the beginning. 3. Electronic locking system according to claim 2,
characterized,
that the length of the catch sequence (FF) is adjustable in the receiver (2). 4. Electronic locking system according to one of claims 1 to 3,
characterized,
that the length of the reference sequence (BF) in the receiver (2) is adjustable. 5. Electronic locking system according to one of the above claims,
characterized,
that the length of the post-synchronization area (NB) in the receiver (2) is adjustable. 6. Electronic locking system according to claim 1 or 2,
characterized,
that a timer (236) is provided in the receiver (2), the is controlled by the synchronization unit (23) and blocks the receiver (2) during a waiting period if no resynchronization is possible within the resynchronization area (NB). 7. Electronic locking system according to claim 6,
characterized,
- That an old value memory (234) is provided in which the last old value (BM _o ) of the reference mark is stored, and
- That the synchronization unit (23) sets the reference transmitter (237) to this old value after failed resynchronization. 8. transmitter for an electronic locking system for at least one lock (4), in particular for a motor vehicle,
marked by a) a trigger (12) which emits a trigger signal (AS) when actuated, b) a marker (11), which is connected to the trigger (12) and generates a transmission marker (SM) according to a predetermined algorithm when the trigger signal (AS) is received, c) a modulator (13) which modulates a control signal with the transmission marker (SM), and d) an emitter (14) for a transmission signal (SI) which is driven by the modulated control signal of the modulator (13) such that a transmission signal (SI) is emitted with each transmission process, which is modulated with a transmission marker (SM). 9. Receiver for an electronic locking system for at least one lock (4), in particular for a motor vehicle,
marked by a) a sensor (21) for receiving a transmission signal (SI), b) a reference transmitter (233) which supplies a reference mark (BM _i ) from a sequence of reference marks which result in the sequence of transmission marks (SM) of a transmitter (1) is identical, and which can be controlled by a received transmission signal (SI) to a new reference mark (BM _i ) of the sequence; c) a synchronization unit (23) which, after each transmission signal (SI), compares its transmission marking (SM) with the reference marking (BM _i ) just supplied by the reference transmitter (21) and, if there is no identity, the synchronization of transmitter (1) and receiver (2 ) restores (post-synchronization) if the transmission mark (SM _i ) and reference mark (BM _i ) lie within a post-synchronization area (NB) which extends over a section of the sequence of reference markings (BM). d) a control unit (237) which opens the lock (3) when the two markings (SM _i , BM _i ) are controlled by the synchronization unit (23); 10. Method for resynchronization of the receiver (2) and transmitter (1) of an electronic locking system with at least one lock (3), in particular for motor vehicles, wherein
- With each transmission process, the transmitter (1) emits a transmission signal (SI) which is modulated with a transmission marking (SM) from a sequence of transmission markings,
a new value (BM _i ) of the reference mark (BM _i ) from a sequence of reference markings (BM) which is identical to the sequence of transmit markings (SM) is set in the receiver (2) by each transmission signal (SM _i ),
- Each current transmission mark (SM _i ) is compared with the new value (BM _i ) of the reference mark in the receiver (2) and
- if the identity is given, the lock is opened and
- If there is no identity, this is restored by resynchronization of the transmitter if a reference mark (BM) is located within a post-psychronization area (NB) that extends over a section of the sequence of reference markings (BM), which corresponds to a current transmission marker ( SM _i ) is identical
characterized by
that a transmission sequence (SF) is stored in the receiver, which consists of the transmission markings (SM) of n successive transmission signals (SI) and,
that the post-synchronization is then carried out if there is a reference sequence (BF) of n reference markings (BM) within the post-synchronization area (NB) which is identical to the transmission sequence (SF).

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