DE10056877B4 - receiver sensitivity - Google Patents

Abstract

One Access system for a vehicle with a receiver circuit (1) transmitted for reception RF signals, the receiver circuit (1) an amplifier (20) for reinforcement the signals and a controller (30) for generating a sensitivity control signal for Adjusting the sensitivity of the receiver circuit (1), wherein a supply circuit (24, 26, 28, 29) for the amplifier (20) is provided for the sensitivity control signal for setting a power supply (32) for the amplifier (20) and thereby the sensitivity of the receiver circuit (1) responsive wherein the supply circuit (24, 26, 28, 29) is parallel circuit branches, including a first, high-impedance branch and a second, low-resistance Turn off between the amplifier (20) and the power supply (32), including a switch (28) in the low impedance branch for switching the low resistance circuit tap in response to the sensitivity control signal and wherein the sensitivity is changed such that during a learning procedure the controller (30) turns off the switch (28) and after the learning procedure the controller (30) the switch (28) ...

Description

The The present invention relates to receiver sensitivity, and more particularly to a circuit for controlling the sensitivity of a communication signal receiver.

Keyless Access systems for Vehicles use radio frequency (RF) signals, which are hand-held Sender of an electronic key to operate the interlocks in a vehicle become. These access systems use a combination of static and dynamic data for validating the transmitter in a receiver circuit inside the vehicle. The dynamic data components within the sender and receiver are updated after each successful validation to the Improve system security. During production becomes uses a learning procedure to register an RF key code that from a special transmitter with the receiver circuitry of a special one Transfer vehicle and the dynamic data components of the two circuits to synchronize. The sensitivity of the receiver to RF signals must be carefully determined during the Key learning process be controlled: if the receiver too sensitive, it becomes the key code of other vehicles learn on the production line; if the sensitivity is too low, he becomes the key code at all not learning. A similar restriction encounters a transceiver resynchronization procedure too, which must be obeyed if the dynamic data in one of the two devices due lost total power failure of the corresponding memory. So that the keyless Access system is working properly, must the Sensitivity of the receiver circuit within the motor vehicle a low sensitivity mode in order to Learn and sync and a high sensitivity mode for normal Have operation. For practical purposes the change in the sensitivity about 30 dB.

At present, the sensitivity of receiver circuits by a circuit as in 1 shown, set. Incoming RF signals are downconverted to intermediate frequency (ff) and from an ff amplifier 2 strengthened. The signal continues from a peak detector 4 and a pass filter 6 processed for low frequencies before sending it to a comparator 8th is transmitted. The comparator 8th has two inputs: a positive input 9 and a negative input 11 , The comparator 8th subtracts one at the negative input 11 existing base voltage from that at the positive input 9 existing data signal. The resulting output 12 is transmitted to an external microprocessor for further processing. The passage filter 6 for low frequencies has a shorter time constant than a pass filter, that of an input resistor 10 and a capacitor 14 is formed. The input resistance 10 is between the two inputs of the comparator 8th connected. The capacitor 14 is between the negative input 11 of the comparator 8th and ground switched. During normal operation, the voltage sets across the capacitor 14 the long-term conduction noise level, which is therefore from the comparator 8th from the at the positive entrance 9 existing signal is subtracted.

When the system needs to be resynchronized, the microprocessor is instructed by an external computer system connected to the access system to enter a resynchronization mode. The microprocessor reduces the sensitivity of the receiver circuit by applying a potential to the gate of an extension mode field effect transistor (FET). 16 , and thereby displaces the FET 16 from a non-conductive to a conductive state.

When the FET 16 between the SV supply rail 32 and a charging resistance 15 is switched, it follows that the supply voltage at one end of the charging resistor 15 is created. The other end of the charging resistor 15 is with a plate of the capacitor 14 connected. When the FET 16 is turned on by the microprocessor, current flows through the charging resistor 15 and charge the capacitor 14 , After a predetermined amount of time, the microprocessor removes the gate bias from the FET 16 , The FET 16 is switched off, no significant current flows through it and the capacitor 14 stop loading. Because the charged plate of the capacitor 14 also with the negative input 11 of the comparator 8th is connected, the capacitor voltage. through the comparator 8th from the signal at the positive input 9 subtracted. Therefore, the sensitivity of the receiver is reduced. The value of the charging resistor 15 is high (typically 4.7 MΩ) to the charging current of the capacitor 14 to reduce and thereby allow the voltage across the capacitor 14 and as a result, to precisely control the receiver sensitivity. The on the capacitor 14 Stored charge drains slowly, but there is enough time to complete the resynchronization procedure. While on the capacitor 14 stored charge drains, so also reduces the negative input 11 of the comparator 8th supplied voltage. As a result, the sensitivity of the receiver eventually returns to its normal high value.

The performance of this circuit suffers from variations in the resistance of the resistive element 15 , As the nominal value of the resistive element 15 is high (4.7 MΩ), the actual value is extremely sensitive to environmental conditions, especially in the automotive sector. These fluctuations cause the capacitor 14 charging too fast, so that the sensitivity decreases rapidly and the synchronization process fails because the RF signal is not detected at all. Therefore, the circuits must be tuned by hand to achieve the required performance; which is impractical.

From the DE 198 32 285 A1 An access control device for a vehicle is known in which the reception sensitivity of a code transmitter of the access control device is variable in order to reduce the influence of interference signals on a question-answer dialog. For this purpose, in order to increase the reception sensitivity, a second preamplifier is additionally connected in front of an evaluation unit of the code transmitter in addition to a first preamplifier by means of a bypass switch or a variable gain of the preamplifier is set.

Furthermore, from the DE 39 42 936 A1 a broadband amplifier stage with field effect transistors as a reinforcing element whose gain is varied by means of the drain current at a fixed drain-source voltage, known. Since the DC gain of the amplifying element is generally insufficient to keep the drain-source voltage constant at small currents, a large gain operational amplifier is turned on in the feedback branch to stabilize the drain-source voltage. In order to keep the drain-source voltage of a field effect transistor used as a reinforcing element constant, the drain current flowing through it is controlled by means of a control transistor.

It is the object of the invention, a cost-effective circuit for regulation the sensitivity of a communication signal receiver or at least one convenient alternative provide.

The present invention relates to an access system for a vehicle having a receiver circuit ( 1 ) for receiving transmitted RF signals, the receiver circuit ( 1 ) an amplifier ( 20 ) to amplify the signals and a controller ( 30 ) for generating a sensitivity control signal for adjusting the sensitivity of the receiver circuit ( 1 ), wherein a supply circuit ( 24 . 26 . 28 . 29 ) for the amplifier ( 20 ) is provided for the sensitivity control signal for adjusting a power supply ( 32 ) for the amplifier ( 20 ) and thereby the sensitivity of the receiver circuit ( 1 ), the supply circuit ( 24 . 26 . 28 . 29 ) parallel circuit branches, including a first, high-impedance branch and a second, low-resistance branch between the amplifier ( 20 ) and the power supply ( 32 ), including a switch ( 28 in the low-impedance branch for switching the low-resistance circuit branch in response to the sensitivity control signal, and wherein the sensitivity is changed such that during a learning procedure the controller ( 30 ) the switch ( 28 ) and after the learning procedure of the controller ( 30 ) the switch ( 28 ).

A preferred embodiment The present invention will be described, by way of example only, with reference to the accompanying drawings Drawings are described, wherein:

1 Fig. 10 is a block diagram of a known RF receiver circuit; and 2 a block diagram of a preferred embodiment of a RF 10 Receiver circuit is.

An RF receiver circuit 1 a keyless entry system for a vehicle, as in 2 shown includes a low noise amplifier (LNA) 20 for amplifying radio frequency (RF) signals received from an electronic key and an RF integrated circuit (RF IC) 22 for processing the amplified signals for a microprocessor 30 , The LNA 20 is a standard two transistor cascode amplifier known to those skilled in the art.

The LNA 20 is powered by a 5V power supply 32 energized, but is in the 20 circuit 1 with the feeder 32 connected via two parallel circuit branches, including a first branch with a high resistance 24 (27 kΩ) and a second branch with a low resistance 26 (47Ω) and a pnp bipolar transistor 28 (BC856) connected in series. The base of the transistor is controlled by a signal from a microprocessor 30 over a third 25 resistance 29 (22kΩ) controlled.

As described above, after a new keyless entry system has been installed in a motor vehicle, the system must learn the binary code transmitted by a particular hand-held RF transmitter which subsequently to 30 Operation of the door locks is used. To ensure that the received code is free of interference from other sources, the sensitivity of the RF receiver during the learning procedure is reduced and the transmitter is operated from within the car. The sensitivity of the system is controlled by the microprocessor. During the learning procedure, the microprocessor turns off 30 the transistor 28 off and the low resistance 26 is effectively disconnected. The resistance between the power supply 32 and the LNA 20 5 is practically equal to the resistance of the high resistance element 24 , or 27 kΩ. This resistance is much greater than the effective resistance of the LNA 20 , and as a result, most of the power supply voltage goes through the high-impedance resistor 24 and the LNA 20 receives only a small portion of it, 1.76V in the circuit 1 , The reinforcement of the LNA 20 is therefore strong 10 reduced. In the circuit 1 is the DC collector current of the LNA 20 only 120 μA, and the LNA 20 weakens its input signal under these conditions and provides a -20dB attenuation.

After the learning procedure is completed, the microprocessor turns on the transistor 28 at. Current flows through the transistor 28 , and the low resistance 26 is effectively connected in parallel with the high-impedance resistor 24 ,

The total resistance of the two circuit branches is therefore slightly less than the resistance of the low resistance 26 , in this example 46.9Ω. This is significantly less than the effective resistance of the LNA 20 , and as a result becomes 20 Almost the entire supply voltage supplied to this. In the circuit 1 4.7V of the SV supply voltage will be the LNA 20 fed, which decreases 3.56mA. The resulting amplification of the LNA 20 is 15 dB.

Under the control of the microprocessor ( 30 ), the sensitivity of the circuit 1 25 can be changed by a nominal value of 35 dB. Measurements on a number of actual circuits indicate an average change of 30 dB with a spread of 5 dB. This satisfies the requirement of adequate sensitivity during normal operation and greatly reduces the sensitivity during the learning mode, where only the strong one, from a key in the obvious 30 Area transmitted signal is detected.

A Variety of modifications will be present to the expert, without departing from the scope of the above with reference to the accompanying drawings to deviate described invention.

Claims (3)

An access system for a vehicle having a receiver circuit ( 1 ) for receiving transmitted RF signals, the receiver circuit ( 1 ) an amplifier ( 20 ) to amplify the signals and a controller ( 30 ) for generating a sensitivity control signal for adjusting the sensitivity of the receiver circuit ( 1 ), wherein a supply circuit ( 24 . 26 . 28 . 29 ) for the amplifier ( 20 ) is provided for the sensitivity control signal for adjusting a power supply ( 32 ) for the amplifier ( 20 ) and thereby the sensitivity of the receiver circuit ( 1 ), the supply circuit ( 24 . 26 . 28 . 29 ) parallel circuit branches, including a first, high-impedance branch and a second, low-resistance branch between the amplifier ( 20 ) and the power supply ( 32 ), including a switch ( 28 in the low-impedance branch for switching the low-resistance circuit branch in response to the sensitivity control signal, and wherein the sensitivity is changed such that during a learning procedure the controller ( 30 ) the switch ( 28 ) and after the learning procedure of the controller ( 30 ) the switch ( 28 ). An access system according to claim 1, wherein the high-impedance branch has a high resistance ( 24 ) and the low-impedance branch has a low-resistance ( 26 ) and a transistor ( 28 ) in series, and wherein the conductive state of the transistor ( 28 ) is controlled by the sensitivity control signal such that: when the transistor ( 28 ), the total resistance of the two circuit branches between the power supply and the amplifier ( 20 ) is less than the resistance of the low resistance ( 26 ) and at least the major part of the power supply ( 32 ) the amplifier ( 20 ) and thereby the amplifier provides high gain; and if the transistor ( 28 ), the total resistance of the two formwork branches between the power supply ( 32 ) and the amplifier ( 20 ) near the resistance of the high resistance ( 24 ), and at least the major part of the power supply voltage to the high-impedance resistor ( 24 ), and thereby the amplifier ( 20 ) provides low gain. A vehicle having an access system according to a any of the claims 1 or 2.