GB2295911A - Vehicle security system - Google Patents

Abstract

A transmitter 20 is provided for transmitting a command signal, the transmitter including a rolling code generator 26 operable in response to a control logic 22 to provide a code forming at least part of said transmitted signal. The code is automatically changeable at intervals. A receiver 30 is provided which receives the transmitted signal for operating a vehicle lock. The receiver includes a rolling code generator 34 operable in response to a control logic 35 to provide a code associated with or related to the transmitted code and automatically changeable at intervals substantially in synchronism with the timing of code changes in the transmitter 20. The intervals used are communicated from one of the transmitter and receiver to the other. <IMAGE>

Description

A VEHICLE SECURITY SYSTEM The invention relates to vehicle security systems that provide for the remote operation of a vehicle security device.

The remote operation of vehicle door locks and engine immobilization systems has gained popularity over the last few years and is becoming available on an increasing number of vehicles. A typical remote control arrangement for locking and unlocking a vehicle door takes the form of a hand held transmitter which operates a receiving device in the vehicle. More recently, car thieves have been using electronic devices (known as code grabbing devices) capable of receiving a signal transmitted from a hand held transmitter and recording the signal. The recorded signal can subsequently be used to unlock the vehicle after the user leaves an area where the vehicle is parked.

A basic lock/unlock system for a vehicle utilizes a single fixed code 10 as shown in Fig.l which is transmitted both to lock and unlock the vehicle. It has been found relatively easy to receive and record such a code for subsequent unlocking of the vehicle.

In a slightly more secure system shown in Fig.2, the transmitted signal includes a fixed code 11 and portion in the form of a lock/unlock bit or bits 12. However, once the code 10 has been recorded by a code grabbing device, a thief can change the lock command bit or bits 12 to an unlock command and unlock the vehicle.

Accordingly systems have been designed in which the codes stored in the transmitter and receiver change continually, the transmitter and receiver being arranged to change at the same time and in the same way to remain in synchronism.

The present invention provides a vehicle security system comprising a security device, a transmitter for transmitting command signals, the transmitter including code generator means operable to provide a code forming at least part of said transmitted signal, the code being automatically changeable at intervals, and a receiver which receives the transmitted signal and causes operation of the security device, the receiver including code generating means operable to provide a code associated with or related to the transmitted code to facilitate operation of the security device, the code in the receiver being automatically changeable at intervals substantially in synchronism with the timing of code changes in the transmitter, wherein the transmitter and receiver are arranged such that one of them can communicate to the other the length of said intervals to be used.

The communication of the length of the intervals may, for example, take place on the first operation of the transmitter in an initial pairing procedure.

Preferably the length of said intervals varies in time.

The present invention further provides a vehicle security system including a system for remote operation according to the invention.

A system for the remote operation of a lock in accordance with the invention will now be described by way of example with reference to the remaining accompanying drawings in which:- Fig.3 shows a block diagram arrangement of a transmitter and receiver in accordance with the invention Fig.4 shows a transmitter/receiver arrangement for operating the door of a vehicle in accordance with the present invention, Fig.5 shows a modified form of transmitted signal, Fig.6 shows a time scale illustrating part of the modified transmitted signal and Fig.7.shows a signal used to communicate from the transmitter to the receiver information subsequently used for generating security codes.

A hand held transmitter 20 comprises a control logic 22 operated either by a lock button 23 or an unlock button 24.

The transmitter includes a crystal clock 25, a rolling code generator 26 and the control logic and rolling code generator provide inputs for a transmitter circuit 27.

A receiver 30 comprises a receiver circuit 32, a crystal clock 33 a rolling code generator 34 and a control logic 35.

The receiver circuit 32, the clock 33, and the rolling code generator 34 provide inputs for the control logic 35, which compares the signals received from the receiver circuit 32 and the code generator 34 and provides outputs 36 for operating vehicle door locks 37 if those signals match each other.

At intervals e.g. every 10 seconds, the code generated by the rolling code generator 26 in the transmitter 20 is changed.

Similarly, at the same intervals the code generated by the rolling code generator 34 of the receiver is changed. The clocks 25, 33, starting in synchronism, provide timing accuracy common to the transmitter 20 and receiver 30 for the transmitter and receiver code change operation. The signal transmitted by the transmitter 20 will incorporate the code generated at that time and will either match or be otherwise related to the code generated in the receiver at that time to permit the control logic 35 to produce the output signals 36.

In the simplest form of the invention the intervals are regular. The length of the intervals to be used is initially programmed into the transmitter, and communicated to the receiver when they are first used together as a pair. This allows the intervals to be of any fixed length. Alternatively the length of each interval can vary from the previous one in accordance with an algorithm, the algorithm and a 'seed' first value being held in the transmitter, and communicated to the receiver when they are first used together as a pair.

In a further alternative the length of the intervals can cycle through a sequence of different lengths, the sequence being programmed into the transmitter and communicated to the receiver in the same way. The communication from transmitter to receiver can be brought about by including in the control logic in the transmitter instructions to send the required information on the first operation of the transmitter. A signal for achieving this is shown in Figure 7. The first portion 60 of the signal is a code which would be recognized by the receiver as an instruction to pick up the following information and store it for use in generating codes. The next portion 62 of the signal includes a random sequence of interval lengths which are to be cycled through by the transmitter and receiver. The advantage of pairing up the transmitter and receiver in this way is that each pair can have different values for the seed intervals or different algorithms or sequences of intervals without the need to coordinate the manufacture and supply of the transmitters and receivers.

Because of the accuracy of the crystal clocks 25, 33 it is envisaged that they will remain in synchronism for several days. Nevertheless, each time the lock button 23 or unlock button 24 is pressed, the clocks 25, 33 in the transmitter and receiver will be re-synchronized.

If no signal is received from the transmitter 20 for a long period of time there is a risk that the clocks 25, 33 will move out of synchronism. However, if a battery 40 in the transmitter 20 fails and is removed from the transmitter, the re-closing of a battery cover 42 after replacing the battery will cause a re-synchronization signal to be generated by the control logic 22 and transmitted to the receiver 30 which will cause complete re-synchronization of the transmitter and receiver. By using the battery compartment cover 42 in that way, there is little risk that a user of the transmitter will accidentally transmit the re-synchronization signal.

As mentioned above, the rolling codes will change in response to the operation of the clocks 25, 33. An alteration in rolling code requires the processing of an algorithm but a change in code at, say, every 10 seconds can be achieved within the system. However it is envisaged that an astute thief could possibly grab the transmitted code and make use of it in the 10 second period. To reduce the risk of that, it is proposed that each signal 50 (Fig.5) includes not only a rolling code 52 (and, if desired, fixed code bits such as transmitter identification 14, a lock/unlock bit or bits 15 and even a vehicle identification 16) but also a code portion 53 which changes at intervals within the 10 second period P (Fig.6).As shown in Fig.6 the portion 50 changes eight times in the ten second period P on a regular basis (or, if desired a pseudo random basis e.g., 1, 3, 7, 2, 5 etc. within interval P) giving a thief with a grabbing device virtually no time in which to make use of the grabbed signal. This will apply both to the transmitter 20 and the receiver 30.

Such an arrangement will help when re-synchronizing the transmitter 20 and the receiver 30 as the point of resynchronization will be more accurately identified within the main code change cycle or period P. Also with such an arrangement re-synchronization could be achieved by, for example, pressing one of the transmitter buttons 23, 24 a number of times in quick succession which would be recognized by the receiver 30 as a re-synchronizing signal structure.

A further advantage of the present invention is that pressing of the transmitter buttons will have no effect on the content of the rolling code transmitted as the code is changed by operation of the clock 25 and not by the buttons 23, 24.

Therefore accidental operation of the lock/unlock buttons will not take the transmitter out of synchronism with the receiver.

Instead of using a rolling code in the transmitter and receiver, the code to be transmitted can be in the form of an encryption algorithm which effectively scrambles the content of the transmitted signal which is then unscrambled in the receiver. Information on public encryption codes is available in text books for example Cryptography; A New Dimension in Computer Data Security by Meyer, C and S. Matys 1982 New York, John Wiley & Sons, Inc.

The term "security device" used herein embraces a lock, alarm, vehicle immobilizes, latch release or similar security device.

Claims (6)

CLAINS

1. A vehicle security system comprising a security device, a transmitter for transmitting command signals, the transmitter including code generator means operable to provide a code forming at least part of said transmitted signal, the code being automatically changeable at intervals, and a receiver which receives the transmitted signal and causes operation of the security device, the receiver including code generating means operable to provide a code associated with or related to the transmitted code to facilitate operation of the security device, the code in the receiver being automatically changeable at intervals substantially in synchronism with the timing of code changes in the transmitter, wherein the transmitter and receiver are arranged such that one of them can communicate to the other the length of said intervals to be used.

2. A system according to claim 1 wherein the length of said intervals varies in time.

3. A system according to claim 2 wherein the length of the intervals is communicated in the form of a seed value and an algorithm in accordance with which each interval varies from the previous one.

4. A system according to claim 2 wherein the length of the intervals is communicated in the form of a sequence of intervals to be cycled through.

5. A system according to any foregoing claim wherein the length of the intervals is initially programmed into the transmitter for communication to the receiver.

6. A vehicle security system constructed and arranged substantially as described herein with reference to Figs.3 to 7 of the accompanying drawings.