FR2795574A1 - External emission radio receiver construction having command voltage functioning oscillator and detector measuring start time variation oscillator pulses. - Google Patents

Abstract

The radio frequency receiver has an oscillator (OS) which functions whilst the command voltage is applied. The receiver has a periodic voltage command generator (GE) and a detector measuring the time variation of the start of oscillator pulses.

Description

The invention relates to a radio frequency receiver comprising an oscillator and means for detecting an external emission at a frequency corresponding to the frequency of the oscillator.

Such receivers are well known in the art. These are super reaction or super heterodyne receivers including a demodulator and a low frequency amplifier. Such receivers are therefore relatively complicated and expensive. Their use in home automation, for example for remote control of doors or shutters has a significant impact on the cost of installation.

The present invention aims to provide a radio frequency receiver capable of detecting an external emission as simple as possible and a significantly lower cost than known receivers.

For this purpose, the radio frequency receiver according to the invention is characterized in that the oscillator is arranged to operate when a control voltage is applied thereto, in that the receiver comprises a generator of periodic voltage pulses. controlling the oscillator and in that the means for detecting an external transmission consist of means for detecting a variation in the starting time of the oscillator.

The invention is based on the observation that, in a receiver, the oscillator start-up time, in particular an oscillator equipped with a surface-wave resonator, is shorter when the receiver is in the d-field. a transmitter emitting on the frequency of the oscillator that in the absence of emission. This observation is used to detect, by simple means, the presence of an emission.

In the case where the transmitter transmits a recognition code or identification, in digital form, the detection of the presence of a transmission allows the receiver to generate pulses that can be used to identify this code.

If the receiver is also arranged as a transmitter, it can be added signal generating means controlled by a ULT (logic processing unit). Such a receiver-transmitter can thus equip a mobile remote control that will emit control signals only after identifying the code of a fixed transmitter associated for example with a door actuator. Thus, the mere proximity of the mobile remote control and the fixed transmitter can cause the opening of the door.

A receiver according to the invention, respectively a receiver-transmitter, can be produced in a very simple manner.

The appended drawing shows, by way of example, two embodiments of the receiver according to the invention.

Figure 1 shows the diagram of the receiver according to a first embodiment. FIG. 2 is a functional chronogram of the operating principle of the receiver represented in FIG. 1.

The receiver shown in FIG. 1 comprises a UHF oscillator OS consisting of a UHF transistor TR whose collector is connected to a DC supply source + U through an inductor L1 and whose emitter is connected to ground through a transistor. resistance R2 and a capacitor C1 connected in parallel. The terminal of the inductor L1 connected to the supply + U is connected to ground through a capacitor C2. The collector and emitter of the transistor are further connected by a capacitor C3. The collector of the transistor TR is connected to an antenna through an antenna adapter unit AA. The base of the transistor TR is connected to a pulse generator GE through a resistor R1. This same base is further connected to ground through a SAW surface wave resonator, as well as an EF shaping circuit itself connected to a TIMER chronometer. The GE generator and the TIMER chronometer are part of a ULT logical processing unit).

The control frequency of the oscillator is preferably at most 2 KHz, but with another type of oscillator, this frequency could be much higher.

The generator GE can be realized in TTL logic. It is preferably produced by means of a microcontroller. It periodically produces a pulse train that is applied across R1 to the base of transistor TR. Each pulse train has the effect of starting the oscillator OS. This start is however not instantaneous, but occurs with a certain delay essentially due to the inductive and capacitive components of the oscillator, as well as to the SAW resonator. The starting of the oscillator results in a voltage drop on the base of the transistor TR.

Under these conditions, it has been found that if the receiver is in the transmission field of a UHF transmitter emitting the same frequency as that of the oscillator <B> os, </ B> the oscillator starts up. does faster, which results in a faster drop in the voltage on the base of the transistor TR. I1 just need to detect this start to detect the presence of an external emission. This detection is characterized by a faster start and is provided by the circuit EF.

Figure 2 shows the functional timing diagram of the receiver. The signals represented at levels 1, 2, 3 and 4 are the signals measured at the corresponding points 1, 2, 3 and 4 of the diagram represented in FIG.

At level 1, there is shown schematically a pulse train generated by the generator GE. Each pulse train is for example constituted of four rectangular pulses, as shown, each pulse being of a duration greater than the start time of the oscillator.

At level 2, there are represented transmission times of the external transmitter.

At level 3, the voltage measured at the base of the transistor TR is represented. This voltage drops when the oscillator has started. It drops faster when the receiver is in the field of an external transmitter.

At level 4, rectangular pulses are shown whose length corresponds to the start time of the oscillator. These pulses are either wide or narrow, the narrow pulses corresponding to 1, and the wide pulses corresponding to 0. The duration of these pulses is measured by a timer TIMER which transforms the analog signals into digital signals which are processed by the ULT .

The external transmitter may be, for example, the transmitter of a fixed station or the transmitter of a remote control. The emitted signals are modulated in amplitude.

The receiver can also be used as a transmitter for, for example, transmitting a command signal or confirmation of reception after recognition of the external transmitter. Such a use is made without adding special means to the circuit shown: the signals to be transmitted are generated by the ULT and the generator GE.

In the embodiment shown in FIG. 1, the means for detecting the start time of the oscillator consist entirely of logic elements.

According to another embodiment, the same functions are performed by means of discrete components.

Claims (4)

<U> CLAIMS </ U> A radio frequency receiver comprising an oscillator and means for detecting an external emission at a frequency corresponding to the frequency of the oscillator, characterized in that the oscillator (OS) is arranged to operate when a voltage is reached. it is applied in that the receiver comprises a generator (GE) of periodic control voltage pulses of the oscillator and in that the means for detecting an external emission consist of detection means of a variation of the starting time of the oscillator. 2. Receiver according to claim 1, characterized in that the means for detecting an external transmission are arranged to generate a pulse train, the pulses thus generated being used to identify a recognition code. 3. Receiver according to claim 1 or 2, characterized in that the oscillator is equipped with a surface wave resonator (SAW). 4. Receiver according to claim 3, characterized in that the voltage representative of the oscillator start is measured at the terminals of the surface wave resonator and converted into a digital signal.