FR2740635A1 - CODE TRANSMITTER, IN PARTICULAR FOR ANTI-THEFT SYSTEM OF A MOTOR VEHICLE - Google Patents

Abstract

This code transmitter, in particular for an anti-theft system of a motor vehicle, comprises: - an oscillating circuit (1), the resonant frequency (fR) of which is modified by an impedance (3) capable of being switched on, - a control unit, which controls an HF switch (2) by means of which, depending on a control signal, the impedance (3) is connected in the circuit of the oscillating circuit (1), and - a transmitting antenna (L1) which outputs the output signal of the oscillating circuit (1) as a code signal.

Description

The invention relates to a code transmitter, in particular for a system

  antitheft device of a motor vehicle, which sends a code signal, frequency-coded or frequency-modulated, to a receiver located in the motor vehicle. Conventional code transmitters send coded signals whose different bits differ in amplitude or frequency. In this case, the code signals are produced by means of an oscillating circuit which is detuned by a prefixed code rhythm. This is currently done at

  using still very complex means.

  The aim of the invention is to provide a code transmitter which

has a simple structure.

  According to the invention, this object is achieved by means of a code transmitter, in particular for an anti-theft system of a motor vehicle, comprising: an oscillating circuit, whose resonant frequency f R is modified by an impedance capable of to be switched on, - a control unit, which controls an RF switch by means of which, as a function of a control signal, the impedance is connected in the circuit of the oscillating circuit, and - an emitting antenna L1 which emits the signal of

  output of the oscillating circuit as a code signal.

  An exemplary implementation of the invention is described below in detail with reference to the schematic drawing. The figure shows a circuit arrangement of the transmitter

code according to the invention.

  A code transmitter for frequency modulated signals comprises an oscillating circuit or oscillator comprising a transistor T1, two resistors R5 and R6, three capacitors C2, C3 and C4 and a coil L2. The capacitors C2, C3, C4 and the coil L2 are energy accumulators between which the oscillation energy is exchanged. The transistor T1 maintains the oscillation in a manner

  permanent thanks to its amplifier properties.

  A SAW 1 resonator (Surface Acoustic Wave) imposes an oscillation on this oscillator, so that after energization, the oscillator oscillates with a frequency determined by the resonator 1 (hereinafter resonance frequency fR). To produce a frequency-coded or frequency-modulated signal (hereinafter referred to as a code signal), the resonance frequency fRz of the resonator 1 is modified. For this purpose, a switch H.F. 2 is arranged in parallel with respect to an impedance in the form of a capacitor

  3, both being connected in series with the resonator 1.

  Since the resonance frequency fR1 of the resonator 1 depends on its impedance (capacitance and inductance), the impedance of the resonator is modified, and thus the resonance frequency fR1 passes to a second resonance frequency f2, by switching on of

capacitor 3.

  After energizing the oscillator by means of an output terminal 4 of a microprocessor (not shown), the oscillator oscillates at its resonance frequency fR. By means of a second output terminal 5 of the microprocessor, the H.F. switch 2 is closed or opened according to a code stored in or produced in the microprocessor. This is done by means of the application

  voltage levels at switch H.F. 2.

  When the switch H.F. 2 is closed, it has a very small internal resistance and thus constitutes a short circuit. The capacitor 3 in parallel is thus inactive. In this case, this capacitor 3 does not affect the resonator 1. If, on the other hand, the H.F. switch 2 is open, the capacitor 3 is placed in series with the resonator 1 and consequently modifies the frequency of

resonance of this resonator 1.

  The oscillation of the oscillator, that is to say the coded signal produced by the oscillator and the resonator 1, is transmitted by means of a transmitting antenna. The L2 coil can

  to be used as a transmitting antenna.

  With this circuit arrangement, two different resonance frequencies fR, and f are generated by means of the resonator 1, which represent the "bits", i.e. the low state and the high state of the signal. of code. Depending on the code, the switch H.F. 2 is controlled via the second output terminal 5 of the microprocessor and therefore produces the code signal. In the present case, the switch H.F. 2 is in the form of a PIN diode which, in the on state, constitutes a short circuit and, in the off state, behaves like an open switch. To make the diode PIN pass, it is sufficient that it is applied to the second output terminal 5 of the microprocessor a voltage level greater than the anode of the PIN diode of + 1.5 V. For a

  about 0 V voltage, the PIN diode is blocked.

  The PIN diode can also be replaced by an H.F. transistor or a functionally equivalent H.F. 2 switch. It is essential in this case that the H.F. 2 switch has a low parasitic capacitance. The capacity of the H.F. 2 switch must be very low so that the capacity of the capacitor 3 is not changed. Thus, the capacitances of the resonator 1 and the capacitor 3 are already fixed in advance in a precise manner, and precisely defined resonance frequencies f 1 and f 2 are obtained which constitute the

logic states of the code signal.

  The H.F. 2 switch and the capacitor 3 can also be replaced by a single variable-capacity diode which in itself combines the two functions. In this case, when applying a voltage to the capacitance diode

  variable, its capacity value drops.

  Instead of the capacitor 3, it is also possible to use a coil, not shown, which is connected with the resonator 1 in a manner synchronized with the code. As a result, the impedance of the resonator 1 and thus its

  resonance frequency fR are also modified.

  A resistor R4 and a coil L1 are arranged between the second output terminal 5 of the microprocessor and the capacitor 3. The coil L1 serves as a high frequency filter which prevents the oscillator from influencing the microprocessor. The resistor R4 limits the current intended for the switch H.F. 2, so that the latter is not

subject to overload.

  The input circuit with the resistors R1 to R3 serves to adapt the voltage level and to set a working point on the transistor T1. A capacitor C1 connected to the resistors R1 to R3 serves, as the coil L1, filter

H.F. for the microprocessor.

  The resonance frequency fR1 of the resonator 1 is approximately 433 MHz. Capacitor 3 has a capacity of approximately 2.7 pF. When this capacitance acts on the resonator 1, the resonant frequency f R varies from about 34 kHz. Thus, the low state and high state differ by 34 kHz in their frequencies. It is possible to modify the resonance frequency fR1 by using other resonators. It is also possible to change the frequency difference of 34 kHz by using capacitors 3 having more capacitance values.

large or smaller.

  Instead of a SAW resonator 1, it is also possible to mount an oscillating circuit with discrete components, including capacitors, inductors and resistors or an oscillator crystal whose resonance frequency fR1 is modified, by inserting a capacitance or an inductance in the circuit, depending on the code,

  way to go to the resonance frequency fi.

  By means of the code transmitter according to the invention, it is possible to carry out what is known as a "frequency shift coding", in which a one-way and one-way switching occurs. another between two different resonance frequencies fR, and f12. In this case, one of the frequencies is considered to constitute the logic low state of the code signal and the other its state

logical high.

  The code transmitter may be integrally mounted on a door and contact key by means of which a code signal for unlocking the doors or starting the motor vehicle is produced and is transmitted to a receiver located in the motor vehicle. When the received code signal coincides with a reference code signal, the door locks are unlocked or the starting prohibition device of the motor vehicle is unlocked, so that the motor vehicle can be used. The code transmitter according to the invention can also be used for other purposes, for example for digital voice transmission in telephone systems.

Claims (7)

  A code transmitter, in particular for an anti-theft system of a motor vehicle, comprising: an oscillating circuit (1) whose resonant frequency (fR) is modified by an impedance (3) which can be switched on a control unit, which controls an RF switch (2) by means of which, as a function of a control signal, the impedance (3) is connected in the circuit of the oscillating circuit (1), and - an antenna transmitter (L :) which transmits the signal of   output of the oscillating circuit (1) as a code signal.   Code transmitter according to claim 1, characterized in that the switch H. F. (2) is a PIN diode.   Code transmitter according to claim 1, characterized in that the H.F. switch (2) is a transistor H.F ..   Code transmitter according to claim 1, characterized in that the control signal is a binary signal and the code signal is a frequency-coded signal. 5. Code transmitter according to claim 1, characterized in that the oscillating circuit (1) is a SAW resonator which imposes on an RLC oscillating circuit (Tl, R5, R6, C2, C3, C4, L2) an oscillation at its frequency of resonance (fR1, f2) -   6. Code transmitter according to claim 1, characterized in that the impedance (3) is a capacitor or a coil and is arranged in series with respect to the oscillating circuit (1) and in that the HF switch (2) is   arranged in parallel with respect to the impedance (3).   Code transmitter according to Claim 1, characterized in that the H.F. switch (2) and the impedance (3) are produced by means of a diode variable capacity.