DE3938510A1 - Antenna auxiliary amplifier circuit for antenna diversityreception - Google Patents

Abstract

The circuit uses a feedback amplifier (7) and an impedancematching stage (8) coupled to its output, for acting as thefeedback amplifier load, when the latter is not selected forreception.Pref. an antenna diversity receiver has 2 antenna elements(1a,1b), each coupled to an auxiliary amplifier circuit (2a,2b)incorporating an impedance matching stage. The stage provides the impedance matching for the selected auxiliary amplifier circuit used for the signal reception, and an impedance load for the other auxiliary amplifier circuit.

Description

The invention relates to an additional antenna amplifier scarf device or antenna booster circuit in a radio receiver of an antenna diversity reception system. On a radio receiver in which a signal is received while the receiver is moving, i.e. for example in one Radio receiver, which is in a vehicle and the like is arranged, several antennas are provided, which the Change in the electrical field, the reusable reception and the are matched to the received signal. The antenna, which is most related to the state of the incoming Signal is suitable, is then selected automatically. This type of system is called an antenna diversity reception system designated.

Fig. 5 shows a radio receiver, which can be provided on a vehicle for use in the above-mentioned antenna diversity reception system. Two antennas 1 a and 1 b are arranged at a distance from each other. For this purpose, they can be provided on the front window and the rear window. A radio wave received by each antenna is amplified by corresponding additional antenna amplifier circuits 2 a and 2 b and fed to a switching device 3 for selecting the antennas in the radio receiver.

The switch operation of the switching device 3 is controlled by a diversity control circuit 4 , so that the antenna preferred in relation to the signal reception state is selected automatically. The radio wave which is received by the selected antenna is fed to a signal receiving device 5 which is connected to a loudspeaker 6 . The signal receiving device 5 contains an operating control for selecting a desired radio station.

As already mentioned above, in an antenna diversity reception system, the most suitable antenna is selected from the plurality of antennas with respect to the received state of the signal, so that the desired frequency-modulated (FM) and amplitude-modulated (AM) radio waves are received. The radio receiver is therefore connected as a regular load to an output terminal of the selected additional antenna amplifier circuit. The output terminal of the unused additional antenna amplifier circuit is however open in the switching device 3 and therefore in an unloaded state. The loading condition in this circuit can therefore be changed quickly between the selected and unselected times of the antenna.

In general, the above-mentioned antenna Zusatzver are more circuits 2 a and 2 b as a negative feedback amplifier (NFB) is formed so that predetermined intrinsic electrical properties, such as compensation with respect to signal attenuation, frequency characteristics, input and output impedance, suppression of noise and the like reached can be. Therefore, if the phase safety of the negative feedback amplifier is low or there is no phase safety at all, a substantially unloaded state is caused, so that the additional amplifier circuits have the tendency to become unstable in operation, or to oscillate when the gain is increased. Specifically, a phase certainty means a phase difference between a phase value which is shifted by the negative feedback amplifier and a phase of an oscillation condition of the circuit, ie 360 °, at which the circuit oscillates. If the phase reliability is sufficient, the amplifier works stably. In contrast, a phase value is shifted by approximately or exactly 360 ° by the negative feedback amplifier. The auxiliary amplifier therefore vibrates and strives to become unstable in operation.

It is the task of solving the difficulties mentioned of the invention contained in claim 1 and claim 2, respectively To create additional antenna amplifier circuit, which in Be drive is stable and with a swing even then ver is avoided if the load condition of the additional amplifier circuit when switching the operation of the antennas quickly ge will change.

The invention is explained in more detail with reference to the figures. It shows:

Figure 1 shows the basic structure of an additional antenna amplifier circuit, which is an exemplary embodiment from the invention.

Fig. 2 shows a particular embodiment of a booster circuit according to the invention;

FIGS. 3 and 4 show further embodiments for a trim circuit which is used-boosting circuit antennas in the inventive and

Fig. 5 is a circuit diagram for the basic structure of a radio receiver in an antenna diversity reception system.

In FIG. 1, an embodiment is shown of an antenna to set amplifier circuit 2 a (2 b) of an antenna diversity reception system. The booster circuit includes a negative feedback amplifier 7 and a matching circuit 8 which is connected to an output terminal of the booster and performs impedance matching with respect to a load when the antenna booster circuit is selected. The matching circuit acts as a load on the antenna booster circuit when the antenna booster circuit is not selected.

The matching circuit 8 is designed in such a way that it carries out an impedance matching with respect to the negative feedback amplifier 7 and the signal receiving device 5 of the radio amplifier in FIG. 5. Accordingly, the additional antenna amplifier circuit 2 a ( 2 b ), which is selected by the switching device 3 in FIG. 5, effectively transmits a radio wave received by the antenna 1 a ( 1 b ) to the signal receiving device 5 .

On the other hand, the output terminal of the antenna amplifier circuit receives additional 2 b (2 a), which processing of the Schalteinrich 3 is not selected by the switching means 3 an open state and is thus in a so-called non-loaded state. In the present invention, the matching circuit 8, however, has a predetermined impedance, which is connected to the output terminal of the antenna amplifier amplifier circuit 2 b ( 2 a ). Thus, the matching circuit 8 acts as a load of the unselected additional antenna amplifier circuit 2 b ( 2 a ).

Even when switching between the antennas 1 a and 1 b by the switching device 3 , the additional antenna amplifier circuits 2 b and 2 a do not come into a completely unloaded state at the time at which they are not selected. Thus, these antenna-to-amplifier circuits do not become unstable and do not oscillate, as is the case with conventional circuits.

It is possible to use the above-mentioned matching circuit 8 simultaneously as a matching circuit and as a filter circuit for improving the interference behavior, as will be explained in an individual.

Fig. 2 shows an embodiment of an additional antenna amplifier circuit according to the invention. In this figure, the same circuit parts shown in Fig. 5 are given the same reference numerals. With the reference numerals 1 a and 1 b antennas are designated, with the reference numerals 2 a and 2 b antenna additional amplifier circuits are referred to, with 9 a is a constant voltage circuit and the reference number 10 denotes a surge arrester.

Each of the additional antenna amplifier circuits 2 a and 2 b has a negative feedback amplifier 7 , a matching circuit 8 and an input filter 11th

The negative feedback amplifier 7 is composed of a field effect transistor FET 12 , a transformer for negative feedback or negative feedback, resistors 14 and 15 and a capacitor 16 . The feedback operation is provided by the transformer 13 , which provides negative feedback from the drain of the FET 12 to its source.

The adapter circuit 8 is composed of a centralized constant circuit using two capacitors 17 and 18 and a single coil 19th The matching circuit 8 also acts as a high-pass filter (HPF) for interference suppression. The capacitors 17 and 18 and the coil 19 , which form the matching circuit and the high-pass filter HPF, have optimally defined capacitances and inductivities based on the output impedance of the counter-coupled amplifier 7 , the input impedance of the signal receiving device 5 ( FIG. 5) and the Frequency band of the received signal. For example, the capacitors 17 and 18 have capacities of 33PF and 0.01µF and the coil 19 has an inductance of 0.1µH. In practice, these values for the capacitances and the inductance can also be determined in such a way that they are matched to an impedance, maintain a positional stability of the circuits and components and low frequency components, e.g. B. eliminate amplitude modulated (AM) components or the like.

During operation of the circuits described above, radio waves are received by antennas 1 a and 1 b and passed on to the corresponding additional antenna amplifier circuits 2 a and 2 b , the predetermined frequency bands of which are determined by input filters 11 . At closing, the radio waves are amplified by the opposing amplifier 7 and passed on via the matching circuits 8 to the switching device 3 ( FIG. 5).

It is assumed that the antenna additional amplifier circuit 2 a is selected by the switching device 3 . The radio wave received by the antenna 1 a is adjusted with regard to impedance by the matching circuit 8 in the antenna additional amplifier circuit 2 a and then transmitted to the signal receiving device 5 , in which a certain radio signal processing takes place.

At this time, the output terminal of the additional antenna amplifier circuit 2 b is opened on the other side by the switching device 3 . However, since the adapter circuit 8 is connected to the output of the negative feedback amplifier 7 , the LC series reactance circuit, which is composed of the capacitor 17 and the coil 19 , acts as a load of the negative feedback amplifier 7 .

Therefore, even if the output terminal of the Antenna Zusatzver amplifier circuit 2 b is connected to an open circuit on the unused side, the counter-coupled amplifier does not receive a completely unloaded state, as is the case with the conventional system.

If, on the other hand, the switching device 3 is switched to the side of the additional antenna amplifier 2 b , the radio wave is received by the antenna 1 b and transmitted to the signal receiving device 5 . Accordingly, the additional antenna amplifier circuit 2 a is then connected by the switching device 3 to an open circuit. However, since in the same way as already described above, the matching circuit 8 is connected to the output of the negative feedback amplifier 7 , the LC series reactance circuit composed of the capacitor 7 and the coil 9 , the matching circuit 8 acts as a load for the counter-coupled amplifier 7 .

Therefore, if one of the antennas 1 a and 1 b is selected by switching as a function of the reception state of the radio wave during antenna diversity reception, the respective associated Antenna Zusatzver amplifier circuit 2 a or 2 b does not take the unloaded state as is the case with conventional circuits. As a result, the additional antenna amplifier circuits do not become unstable in their operation and do not oscillate.

Fig. 3 shows a further embodiment of a fitting circuit 8 , which can be used in an antenna booster circuit according to the invention. At a pass capacitor 20 is connected to a matching circuit 8 , which, as shown in FIG. 2, is composed of capacitors 17 , 18 and the coil 19 . In this way, an inductive reactance component of the output impedance of the respective additional antenna amplifier circuit is eliminated. With such a structure, an output impedance of the antenna booster circuit can be obtained, which is formed only by a resistance component, so that the phase characteristics, the frequency characteristics and the like can be further improved.

Fig. 4 shows a further embodiment of a matching circuit, which can be used in an antenna booster circuit of the invention. In this case, the matching circuit 8 'is formed by a signal coil 21 and two capacitors 22 and 23 . This circuit acts as a low pass filter (LPF) and is used effectively when a high frequency component of the received signal is to be suppressed.

The embodiments described above deal with such cases in which the adapter circuit is composed of a centralized constant voltage consisting of capacitors and coils or inductors. However, the design of the adapter circuit is not limited to the cases shown. For example, the matching circuit can be formed by a λ / 4 circuit in which a coaxial conductor, for example a coaxial cable, etc. is used. Furthermore, a λ / 4 circuit can also be used for the construction of the adapter circuit, in which a line with non-stationary constants, for example a strip line, etc., is used. The same effects are achieved here as have already been explained above in connection with the invention. As already mentioned, an antenna booster circuit according to the invention has a matching circuit which is connected to an output of the antenna booster circuit and carries out an impedance matching with respect to a load when the antenna booster circuit is selected for reception. The adapter circuit then acts as a load for the additional antenna amplifier circuit if this is not selected for reception. Therefore, even if the auxiliary antenna amplifier circuit is not selected for the reception operation, the output terminal of the amplifier circuit does not assume the unloaded state. Therefore, the operation of the antenna booster circuit does not become unstable and does not oscillate, as is the case with conventional booster circuits. In this way, a stable antenna diversity receiver is created.

Claims (6)

1. Additional antenna amplifier circuit for antenna diversity reception, characterized by

• - A negative feedback amplifier ( 7 ) and
• - A matching circuit ( 8 ; 8 '), which is connected to an output of the amplifier ( 7 ), to form an impedance matching with regard to a load in the case of selected additional antenna amplifiers for receiving, the matching circuit ( 8 ; 8 ') acts as a load of the additional antenna amplifier circuit if the additional antenna amplifier circuit is not selected for reception.

2. Antenna diversity receiver with two antennas, which are connected via assigned additional antenna amplifier circuits to a selection switching device for selecting the antenna and the assigned additional amplifier circuit to the subsequent part of the receiver, characterized in that

• - A matching circuit ( 8 ; 8 ') in each additional antenna amplifier circuit ( 2 a , 2 b ) is provided and the matching circuit is connected to an output terminal of the respective additional antenna amplifier circuit for carrying out an impedance matching for the respective by the switching device ( 3 ) Additional antenna amplifier circuit selected for reception and an impedance load for the respective additional antenna amplifier circuit not selected for reception.

3. Receiver according to claim 2, characterized in that two matching circuits ( 8 ; 8 ') are provided, each of which is connected to one of the additional amplifier circuits ( 2 a ) or ( 2 b ). 4. Receiver according to claim 2 or 3, characterized in that each additional antenna amplifier circuit ( 2 a , 2 b ) has a negative feedback amplifier ( 7 ) that each pass circuit ( 8 ) to a series connection of capacitors ( 17 , 18 ) between the Output of the negative feedback amplifier ( 7 ) and the input of the switching device ( 3 ) and that an inductance from the center of the series circuit device is connected to ground. 5. Receiver according to claim 2 or 3, characterized in that each additional antenna amplifier circuit ( 2 a ) or ( 2 b ) has a negative feedback amplifier ( 7 ) and each matching circuit a series connection of inductors between the output of the negative feedback amplifier ( 7 ) and the input of the switching device ( 3 ) and that a capacitance from the center of the series circuit is connected to ground. 6. Receiver according to claim 2 or 3, characterized in that each matching circuit is a quarter wavelength circuit having.