DE4111097A1 - RECEIVER CIRCUIT FOR A MODULATED RADIOELECTRICAL SIGNAL FOR AN INDEPENDENT ELECTRONIC DEVICE - Google Patents

Description

The present invention relates generally Remote interrogation and response devices elektroma gnetic construction, in particular for the purpose of Identification of people and objects, e.g. B. as part of dialog remote control systems for Motor vehicles or similar applications. In particular it concerns a new reception circuit for a portable element which, for example, in is able to receive certain Signa len to respond and then a response signal itself, e.g. B. to generate an identification signal.

For dialog remote control units that are are true, the remote recognition approach one ensure the vehicle by the driver sends an electronic integrated in the vehicle cal board module a query signal to an "electronic cal label ", which is generally in the form of a Stamp or flat card of small dimensions has sung by the driver z. B. in a pocket will be carried. The card receives the query egg gnal, analyzes this with the help of a Card built-in microprocessor and processed or reads one encoded according to the card Identification signal into a memory, wherein this signal in turn from this card towards of the on-board module is sent. This can then be a  carry out a certain number of measures and in particular re enable the outputs or automa a regulation of certain organs like the Make mirrors and the seats to them the Stature and the driving habits of the cardholder adapt.

One of the main problems you face facing such a type of remote control, is that the card carried by the driver small dimensions and light weight must (typically the dimensions of a Credit card) while maintaining a substantial Independence on the order of a year or more must be ensured so that the current consumption of the circuits contained therein for is the design of determining parameters.

From US-A-35 85 511 is a demodulation scarf tion known that a two-pole transistor contains a corresponding temperature DC transistor is assigned, the receiver ger transmitter voltage partly as a basic polarization voltage is used.

Such a circuit only works if the two transistors are thermally coupled, e.g. B. as part of an integrated circuit.

In addition, it is not described or featured suggest that such a demodulation circuit is connected directly to the receiving antenna, d. H. before each amplification of the signals.

The present invention has the purpose within of the context described above, a receive scarf propose that use extremely little electricity needs and is still able to to cause reliable demodulation and at the end  gang signals with an amplitude of considerable size to deliver; in particular, the invention has the Purpose, in the context of discrete components to propose such a circuit that directly to a Receiving coil antenna can be connected and their temperature compensation without thermal coupling is achieved.

For this purpose it concerns a receiving circuit for an independent electronic device that battery powered and for receiving an RF signal which is determined by the "all-or nothing "amplitude modulation of a carrier wave is formed by a modulating signal which in a certain low frequency range, characterized in that they follow one another of which contains:

• - a coil antenna (L 0 ), tuned to the frequency of the carrier wave by a capacitor (C 3 ),
• - A demodulation stage (T 1 , R 1 , R 4 , R 3 , R 5 ), which is driven directly by the antenna and contains a two-pole transistor (T 1 ), which is connected as a common transmitter, and a polarization branch for the base of said transistor with two series-connected polarization resistors (R 1 , R 4 ) and a thermally uncoupled semiconductor temperature compensation means (T 3 ) with said bipolar transistor, the non-linearity of the transition base / transmitter of said transistor generates a signal at the frequency of the modulating signal by distortion, and the limited pass band switches the carrier wave frequency off,
• - A voltage amplifier stage (T 6 , R 36 , R 34 , R 10 , R 9 ) and
• - A shaping stage (S 1 ) for the signals supplied by the amplifier stage.

Other aspects, purposes and advantages of present invention will be more apparent in Reading through the detailed description below exercise of a preferred embodiment of the Invention by way of example without limitation Character is described and attached to the Reference drawing, which represents the following:

Fig. 1 is a schematic diagram of a receiving circuit according to the invention.

Figure 2 is a detailed schematic of the circuit according to the invention, and

Fig. 3 shows the waveform at various points of the circuit of Fig. 2..

First of all, it must be pointed out that same or similar elements or parts of one Figure to another by the same reference numbers Marked are.

Referring first to FIG 1, which is tuned signal to be received by a capacitor C 3 to the carrier wave is made to FIG. Wherein a receiving antenna of a current loop L 0 is formed.

Two diodes D 1 and D 2, which are arranged in opposite directions to one another, are connected in parallel to the antenna, which drives a receiving circuit R, which is capable of delivering square-wave signals representative of the received information at the output.

Referring to FIG. 2, the image captured by the antenna signal controls via a decoupling capacitor C 2, the base of a first bipolar NPN transistor T, which is polarized by resistors R 1 and R 4 to 1. The resistor R 4 is connected in series with a transistor T 3 , the base and the receiver of which are connected to one another and the transmitter of which is connected to ground.

R5 and C1 are transmit resistors or capacitors of T1, with R3 being the receive resistor. The said receiver directly controls the base of an NPN transistor T 4 , which was provided with a receiving resistor R 7 and whose transmitter is connected to ground.

The receiver of T 4 is connected to the base of an NPN transistor T 6 via a decoupling capacitor C 17 . The base of T 6 is also connected to the receiver and the base of T 3 via a resistor R 34 . A resistor R 36 is otherwise connected between the base of T 6 and the positive supply line.

T 6 has a receiving resistor R 10 and a resistor R 9 and a transmitting capacitor C 6 . The receiver of T 6 is connected directly to the base of a transistor T 8 , which has a transmitting resistor R 12 and a receiving resistor R 11 . The receiver mentioned is also connected to the two inputs of a NAND connection with known hysteresis S 1 .

The circuit is supplied by two series-connected batteries B 1 and B 2 so that a continuous voltage of the order of 5.5 volts is supplied. The batteries are a diode D 4 and a capacitor C 4 net assigned. D4 protects the circuits against possible pole reversal; C 4 is a supply voltage decoupling capacitor.

The loop antenna L 0- C 3 is constructed in the present example so that it can detect radioelectric radiation whose carrier wave frequency is of the order of 120 kHz. In order to limit the space requirement of the coil L 0 and to simplify its installation in a card in credit card format or a similar size, for example a rectangular winding of 100 turns is produced with a wire of 0.1 mm. The thickness of the winding thus obtained is of the order of 3 to 3.5 mm and this value is compatible with the thickness that one wants to give the card.

The value of C3 is chosen according to the frequency to be received and the value of L 0 .

The two diodes D 1 and D 2 allow the voltage generated at the terminals of the frame to be limited in order to avoid saturation of the subsequent circuit if, for one reason or another, the card comes into the immediate vicinity of the transmitting antenna.

In the present example it is the Coding of the numeric to be sent to the card Signals around two-phase NRZ coding, i. H. it becomes a carrier wave, in the present example Sinusoidal signal of 120 kHz, "all-or-nothing" ampli modulated by a modulation signal in square wave form, the frequency of which is from can take two discrete values, e.g. B. either 500 Hz, or 1 kHz, depending on the logic to be transmitted level. An advantage of this choice is that such coding is neither a direction nor a direction has continuous component.

The transistor T 1 is the heart of the demodulation stage of the circuit. In particular, the non-linearity of the transmitter-base transition of such a two-pole transistor is used to cause distortion of the carrier wave signal and thus to generate a signal with the frequency of the modulating signal. Appropriate selective filtering within the demodulation stage itself allows this signal to be recovered while at the same time switching off the frequency of the carrier wave.

T 3 has the purpose to effect a temperature compensation of the base transmitter voltage fluctuations of T 1 . In this way it is avoided that the polarization point of T 1 and thus the gain of the stage does not change with temperature fluctuations. Thanks to the circuit described, this compensation can be achieved without the need for thermal coupling of T 1 and T 3 .

Taking into account the power consumption requirements Generally, transistors are also selected high β current gain (preferably 100 or more) for low current levels in the micro-lamp re-order of magnitude.

The values of the polarization resistors R 1 and R 4 are chosen as high as possible to minimize the bridge current. In addition, since R 5 is determined by calculation, R 3 is chosen to be quite high in order to achieve a limited dynamic range, without this having disadvantages, but rather causing a high voltage gain.

The values of the resistors are also chosen so that the stage arranged around T 1 forms a filter whose cut-off frequency corresponds to a few kilohertz, for example, and this value is compatible with the modulation signals of 500 Hz and 1 kHz of the received signal.

The gain of the amplifier stage arranged below T 1 is selected on the one hand according to the amplitude of the signals supplied by T 1 and on the other hand ge according to the voltage excursion required at the output in order to bring the terminal S 1 to a tilt. A gain in the order of a few hundred is particularly suitable.

The stage switched as a common receiver around T 4 forms a buffer stage, which is necessary to take into account the very strong output impedance of the demodulation stage and in particular to avoid any attenuation between the two stages. R 7 is chosen so that a receiver current of a few microampere fractions is achieved.

It should be noted that for this intermediate stage does not provide temperature compensation as this Unity gain level against fluctuations the polarization point has very little sensitivity shows. The space saved in this way can be significant.

The actual amplification stage is arranged around T 6 , T 3 , as in the demodulation stage, taking on the function of temperature compensation.

In one variant, two different tempera compensation transistors for the demodulation and gain stages are provided.

For example, R 36 and R 34 have the same values as R 1 and R 4 . R 9 is chosen with a view to achieving a receiver current in the order of a few microamps. R 10 is chosen so that a considerable gain is achieved and at the same time sufficient dynamics is guaranteed.

The stage arranged around T 8 forms an interface stage between the output of T 6 and the NAND connection, T 8 being connected as a changeover switch. The values of R 11 and R 12 are chosen so that when T 8 is saturated, the output voltage is lower than the low threshold voltage of the terminal, e.g. B. 1 volt.

The NAND terminal S 1 is designed to shape the signals coming from the amplifier. A CMOS type connector is preferably chosen for limited power consumption. The hysteresis allows the immunity of the circuit to be increased.

In Fig. 3 the course of the signals at the input of the circuit (voltage V 1 ), at the output of the demodulation stage (voltage V 2 ) or at the output of the terminal S 1 (voltage V 3 ) is shown.

A major advantage of the present invention is achieving a reliable and effective Demodulation with limited power consumption. In particular allows an essential feature of the Invention, according to which demodulation and filtering of signals above any significant voltage reinforcement takes place, the achievement of a extremely low average power consumption need. In particular, tests have the execution a receiving circuit according to the present Invention with a power consumption of the order of magnitude voltage of 4 µA with a supply voltage in the Order of magnitude of 5.5 volts. By ent speaking dimensioning of the battery You can rien the receiving circuit constantly leave on what is the use of a allows the first part of the messages, which as Wake-up signals from a subsequent circuit come in.  

The receiving circuit according to the present invention Any suitable decoding device can be added be switched, for example, in a micro processor is installed.

Of course, the present invention is limited in no way to the above and in the embodiment shown in the drawings, but the expert will make any change or make modifications that make sense corresponds to the invention.

Claims (7)

1. receiving circuit for an independent electronic device, which is powered by a battery and is intended to receive an RF signal which is modulated by the "all-or-nothing" amplitude of a carrier wave by a modulation signal located in a specific NF band is formed, characterized in that it contains the following in succession:

• - a coil antenna (L 0 ), tuned to the frequency of the carrier wave by a capacitor (C 3 ),
• - A demodulation stage (T 1 , R 1 , R 4 , R 3 , R 5 ), which is driven directly by the antenna and contains a two-pole transistor (T 1 ), which is connected as a common transmitter, and a polarization branch for the base of said transistor with two series-connected polarization resistors (R 1 , R 4 ) and a thermally uncoupled semiconductor temperature compensation means (T 3 ) with said bipolar transistor, the non-linearity of the transition base / transmitter of said transistor generates a signal at the frequency of the modulating signal by distortion, and the limited pass band switches the carrier wave frequency off,
• - A voltage amplifier stage (T 6 , R 36 , R 34 , R 10 , R 9 ) and
• - A shaping stage (S 1 ) for the signals supplied by the amplifier stage.

2. receiving circuit according to claim 1, characterized in that the demodulation stage also contains receiving resistors (R 3 ) and transmitting resistors (R 5 ), and that the Basispo larisations-, receiving and transmitting resistors have high values, so that in the said stage low cut-off frequency is achieved and at the same time power consumption is limited. 3. Circuit according to claim 1 and 2, characterized in that the temperature compensation means (T 3 ) for the demodulation and amplification stage works together. 4. Circuit according to one of claims 1 to 3, characterized in that it also contains an impedance converter stage (T 4 , R 7 ) between the demodulation stage and the amplifier stage, which includes a two-pole transistor (T 4 ) connected as a common receiver . 5. Circuit according to one of claims 1 to 4, characterized in that it also contains an interface stage (T 8 , R 11 , R 12 ) between the amplifier stage and the shaping stage, which includes a switched transistor (T 8 ). 6. Circuit according to one of claims 1 to 5, characterized in that the shaping stage contains a NAND-connection (S 1 ), the two inputs of which are connected to one another. 7. Circuit according to one of claims 1 to 6, characterized in that two voltage limiter diodes (D 1 , D 2 ) are also provided, which are connected to one another in a complementary manner between the input of the demodulation stage and ground.