FR2662876A1 - Receiver for radio frequency waves with an induction loop having extremely low consumption, in particular for remote control - Google Patents

Abstract

This receiver is characterised in that it essentially includes, as a component of at least one amplifier stage, a CMOS-technology inverter I, I', with a threshold voltage Vt less than 1 volt, the consumption of which is limited by a resistor R1 of high ohmic value, arranged between a battery E and its power supply input Vcc, the signal input Ve of the said inverter I, I' being biased to its transition threshold by a high loop resistor r, r' connected between this input Ve and its output Vs. Application to badges for long-range identification.

Description

Radio wave receiver with induction loop and extremely low consumption, especially for remote control.

 The present invention relates to a radio wave receiver with induction loop and extremely low consumption, in particular for remote control and more particularly, although not exclusively, a receiver that can be incorporated into an identification badge worn by a person and being intended to operate permanently so as to be able to detect if necessary the reception of a remote control radio signal emitted by an emitting source from which said badge may be at a relatively large distance, being in principle a badge said "hands free" that it should not be necessary to grasp in the hand to approach said source emitter, said receiver must therefore operate on battery and consuming only an extremely low current.

 Currently known remote control systems for remote identification generally operate by ultrasonic wave modulation, or infrared electromagnetic waves. These systems have the disadvantage of operating "on sight": the remote control member must be out of storage and "pointed" with more or less precision to the device to remote control. In addition, these systems can not operate through a wall; they can not operate in "hands free", that is to say without being out of their storage by the wearer of the identification badge.

 The invention relates essentially to a radio wave receiver that can be incorporated into an identification badge deserving the name "hands-free".

 It may be for example an identification badge reduced dimensions and standardized-advantageously those of a magnetic stripe card, bank or the like- worn in a pocket of clothing by a person subject to some control, for allow access only to authorized areas, which are located in the issuing field of a reader-recorder (including cardholder identification code or other control or monitoring data ).

 The principle of these installations is that the reader-recorder, namely the emitting source mentioned above, periodically transmits an activation signal of the badge, which must be received by the receiver, which is permanently powered and must then, by the intermediate an appropriate logic and a transmitter also contained in said badge, issue the carrier code or other data to said reader-recorder.

 What has been called above "a relatively large distance" may be of the order of a few meters for the badge to deserve the name "hands-free", and its autonomy will in practice be greater than a year, with a diet by a single battery, at least 3 volts, therefore reduced Ah capacity.

 The current consumption of the receiver will therefore be extremely low, and preferably not more than ten microamperes.

 It goes without saying that the badge must be able to emit and receive radio signals through a certain thickness of material, without appreciable attenuation, which is why we will use low frequency radio signals, of the order of a hundred kHz. Such waves are slightly attenuated by a thin conductive layer, and pass through substantially non-attenuating non-conductive and non-magnetic materials (walls, partitions, wooden doors, openwork grids).

 The receiver of these radio waves according to the invention will also be able to transform into a logic signal 0 volts, + volts V modulation in all or nothing of a low frequency radio wave emitted by the aforementioned source of the recorder player, distant a few meters.

To solve these various problems, a receiver according to the present invention, of the general type defined at the beginning, will be characterized in that it comprises essentially, as a component of at least one amplifier stage, a CMOS technology inverter and threshold voltage less than 1
Volt, the consumption of which is limited by a resistance of high ohmic value, arranged between said battery and its supply input, the signal input of said inverter being biased at its transition threshold by a high loopback resistance connected between this input and his exit.

 It will be understood that this inverter is thus made to work as a high voltage gain amplifier, this looping bringing its operating point to the middle of the steep transition curve between its two states. With such a threshold voltage lower than 1 V, the consumption of the inverter can be extremely reduced, since a high ohmic resistance connected between the battery and its supply input, will greatly limit the current of the inverter. consumed power, while lowering just a little more than twice the value of this threshold the voltage actually supplying the inverter.

These and other features of the invention will be better understood in the following description, made with reference to the figures of the attached drawing in which
FIG. 1 schematically represents the mounting of a CMOS technology inverter operating as a voltage amplifier, in accordance with what has just been explained.
FIG. 2 shows the operating diagram of this inverter; and
- Figure 3 shows the circuit diagram of a radio receiver according to the invention, using an amplifier stage having two inverters of this type and a transistor demodulation stage and RC circuit.

 In FIG. 1, Ve and Vs represent the DC input and output voltages of a CMOS technology inverter referenced at I, Vcc representing the voltage of its power supply.

The conventional operation of such an inverter is represented by the curve B of FIG. 2: when the input is at O, the output is at Vcc and, conversely, when the input is at Vcc, the output is at 0, the switching takes place for an input voltage
Ve + Vcc / 2.

 With the abscissa and the ordinate the same scale, the diagram B thus fits in the square K.

If now the output Vs of the inverter is connected to its input Ve by a resistor r, the input impedance of the inverter being practically infinite, the current flowing through this resistor is practically zero and consequently: Vs = Ve . The operating point P of the inverter is then at the intersection of the curve B and the first bisector S of the diagram, namely in the middle of the steep part of the curve B. This explains why that a voltage amplifier is thus realized, since a small variation of the voltage Ve around Vcc / 2 will result in a strong variation of
Vs.

 For there to be amplification in a MOS transistor, it is also appropriate that there passes current, and therefore that Ve> Vt, Vt is the threshold voltage of the transistor.

 As Ve = Vcc / 2 at the operating point, we see that the amplifier operating condition is: Vcc> 2 Vt.

With a 3 V lithium battery, we see that this condition prohibits the use of inverters such as those of the series known in the trade under the name CD 4000, which have a threshold voltage
Vt s 1.6 V, especially since these cells have a plateau voltage close to 2.9 V. This is why, in accordance with the invention, the threshold voltage Vt of the inverter has been set to value less than 1 Volt.

For this purpose, it will be preferable to choose CMOS technology inverters of the series known in the trade under the name 74 HC-U04, for which
Vt s 0.7 V.

 On these bases, and whereas Vcc should be only slightly greater than 2 Vt so that the current i supplying the inverter is very small, it will be easy to calculate the resistance value R1 to be inserted between the voltage stack E = 3 Volts and inverter I.

We will indeed have R1 = E - Vcc. E - 2 Vt
ii
By fixing for example i to 5zA, we will have R1 s 3 - 1.4. 320 kO.

5.10-6
In the general diagram of the receiver shown in FIG. 3, there is shown an amplifier stage with two inverters of CMOS technology, referenced I and I ', with their respective feedback resistors r and r', the role of which has been explained above. .

 The radio control waves emitted by the fixed reader-recorder are received by an air antenna represented by a coil L1. This coil is part of a parallel resonance circuit tuned to the frequency of the emitted wave (for example 125 kHz) by a capacitor C1. The resistor R2 and the diodes mounted in the head-to-tail CR1 and CR2 constitute a clipping network of the signal induced in the coil, with an impedance sufficiently high not to damp the resonant circuit LlCl, and sufficiently low in front of the impedance of input of the first amplifier I, so as not to weaken the signal at the input of the latter.

 This signal is transmitted to the amplifier I-I '(CMOS series 74 HC-U04 inverters with 0.7 V threshold voltage) by a capacitor C2. It should be noted that preferably the inverters do not have an output buffer stage, which could amplify the signal excessively in power and could radiate on the antenna. C3 represents a decoupling capacitor of the resistor R1 of the supply circuit mentioned above and connected to the battery E.

The signal thus amplified from the inverter I 'drives a demodulator constituted by a resistor divider bridge R5 and R6 lowering the DC component of the output voltage of the preceding amplifier below the conduction threshold of a bipolar transistor Qi of way that without signal received, this transistor does not lead. The capacitor C4 makes it possible to present, without attenuation, the amplified signal at the base of the transistor, which functions as amplifier, rectifier and integrator thanks to the network time constant.
R7-C5 constituting its collector circuit.

 In other words, the transistor Qi plays both the role of envelope detector of the amplified signal by the two inverters I-I 'and low frequency amplifier.

 It takes advantage of the fact that the DC output voltage of the inverters is Vt, ie 0.7 V, which voltage is almost equal to the threshold voltage of the NPN bipolar transistor Q1. It is to be sure that the transistor 91 is blocked at rest that this voltage is lowered slightly by the above-mentioned divider R5-R6.

 As soon as a wave is amplified by the two inverters I and I 'in the vicinity of the conduction threshold of this transistor Q1, the voltage across capacitor C5 drops to 0, whereas normally it is at +3 volts. the battery. This voltage, after a lowering of impedance due to the two inverters of the integrated circuit, thus constitutes a logical signal DL of the output of the receiver, significant of the state of modulation in all or nothing of the radio wave used for the emission of the command by the reader-recorder.

Claims (4)

 1. Extremely low-power radio wave receiver, in particular for a remote control, this receiver being able in particular to be incorporated into an identification badge carried by a person and intended to operate permanently so as to be able to detect reception if necessary a remote control radio signal emitted by an emitting source from which said badge may be at a relatively large distance, being in principle a so-called "hands-free" badge that it should not be necessary to enter in the hand to approach it of said transmitting source, said receiver therefore having to operate on a battery and having to consume only an extremely weak current, characterized in that it essentially comprises, as a component of at least one amplifier stage , a CMOS technology inverter (I, I ') with a threshold voltage (Vt) of less than 1 volt, the consumption of which is limited by a resistor e (R1) having a high resistance value arranged between said battery (E) and its supply input (Vcc), the signal input (Ve) of said inverter (I, I ') being biased at its transition threshold by a high loopback resistance (r, r ') connected between this input (Ve) and its output (Vs).  2. Receiver according to claim 1, characterized in that said inverter (I, I ') belongs to the series 74 HC-U04 or the like, having a threshold voltage of about 0.7 V, the battery (E) having a voltage of the order of 3 V.  3. Receiver according to claim 1 or 2, characterized in that said inverters (I, I ') are devoid of output buffer stages.  4. Receiver according to any one of the preceding claims, characterized in that said amplifier stage (I, I ') is followed by a bipolar transistor demodulator (Q1), a resistance divider bridge (R5-R6) lowering the voltage output of said amplifier under the conduction threshold of said transistor (au), the latter operating as amplifier, rectifier and integrator (R7-C5) as soon as a wave is amplified by the preceding circuit (I, I ') in the vicinity of said threshold of conduction.