DE2554829B2 - Active receiving antenna with a negative feedback impedance - Google Patents

Description

If the input impedance of the cable is used directly as a negative feedback resistor, this impedance is generally not optimal. In itself, there is an optimum feedback resistor due to the following conditions: With the growing size of the ■ - against coupling impedance increases, the negative feedback, also.die linearity of the A ytennenverstärkers. In contrast, the output power of the amplifier increases as the negative feedback resistance decreases. Because in an amplifier with strong negative feedback, the is on | _{0 of} the negative coupling impedance resulting useful voltage almost independent of the size of the negative feedback impedance and therefore the output power of the three-terminal pole D is greater, the larger the output current in the source supply line, ie the smaller the negative feedback impedance

The output power of an active receiving antenna determines the signal-to-noise ratio of the receiving system, because this system is two of each other has independent noise sources, namely the appearance of the active antenna and the noise of the Recipient. The greater the gain factor of the active antenna, the more the noise determines of the antenna, in addition to the noise from the receiver, the signal-to-noise ratio of the receiving system. Since the The noise figure of the active antenna is many times lower than the noise figure of the receiver, one strives to achieve a sufficient gain in the active η antenna to make the noise contribution of the receiver in the signal-to-noise ratio of the receiving system very small, Telecommunications journal 1968, Volume 21, pp. 322-329, there Gl. (29).

If the input impedance of the cable K is used directly as the negative feedback impedance, then, as already stated, this impedance is consistently not of the optimal size. In DE-OS 23 63 272, which is not previously published, it has therefore been proposed in FIGS. 3b and c to change the input impedance of the cable by means of a resistor R " connected in series or in parallel. However, since this R _p consumes power, this reduces the power supplied to the receiver from the output of the active antenna and thus the signal-to-noise ratio of the receiving system. Furthermore, R _{p is} an additional source of noise, so that the signal-to-noise ratio of the receiving system is worsened by R _p. The negative feedback impedance should therefore be optimized without the involvement of power-consuming resistors.

It is therefore important to find the optimal dimensioning between the requirements for linearity and after a small signal-to-noise ratio without the use of power-consuming and additional To achieve noise-generating measures.

The object of the invention is therefore to provide an antenna according to the preamble of claim 1 to significantly reduce the non-linear effects of the antenna without significantly affecting the signal-to-noise ratio.

This happens with an active receiving antenna ω> according to the invention according to the preamble of claim 1, that the low-loss passive quadrupole under Consideration of the cable and the receiver input circuit is designed so that its input impedance at the operating frequency is a minimum of the b5 Has impedance and the impedance with increasing distance of the frequency from the Company satisfaction grows.

If the negative feedback impedance is frequency-dependent, then all received frequencies appear at the output of the generally broadband antenna, and because of the frequency-dependent negative feedback with a different amplitude distribution than in the received wave. If the negative feedback impedance does not have the feature specified in the characterizing part of claim 1, strong jammers can override the receiver in this way or generate cross-modulation in it, since the different receive frequencies pass through the cable K to the receiver. Since the active antenna amplifies, its output amplitudes are often larger than those of passive antennas and therefore the non-linearity of the receiver then becomes more apparent when receiving jammers.

It is therefore essential for the invention to adjust the frequency dependency of the negative feedback by a suitable choice of the quadrupole so that the The size of the negative feedback impedance at the operating frequency has a minimum and increases with increasing distance of the interference frequency from the operating frequency, so that the gain with increasing The distance between the interference frequency and the operating frequency decreases and thereby the disruptive «effect of the Interference frequencies in the receiver become smaller the further the interference frequency is from the operating frequency is removed Since a series resonance circuit tuned to the operating frequency has the impedance properties mentioned, the present here, The more general case in the following can be expressed in such a way that the input impedance of the passive quadrupole terminal is as follows is chosen so that it acts like a series resonant circuit that is tuned to the operating frequency.

Several embodiments of the invention are shown in FIG Drawings shown and are described in more detail below. It shows

F i g. 1 shows a known active antenna with negative feedback impedance Z;

Fig.2 with an active antenna according to the invention Low-loss passive quadrupole with input impedance Z measured according to the characterizing part of claim 1;

F i g. 3 a low-loss passive quadrupole with a transformer and a series reactive resistor on the secondary side;

4 shows a low-loss passive quadrupole with transformer and parallel reactive resistance on the secondary side;

F i g. 5 shows a low-loss passive quadrupole with autotransformer and secondary-side series reactance;

F i g. 6 a passive quadrupole with autotransformer and series capacitance on the secondary side in combination with the equivalent circuit of an electrically short antenna output cable and a receiver input circuit with a tunable parallel resonant circuit and input transistor Te

The basic structure of an active antenna with negative feedback impedance gehl: from Fig.! emerged. The active antenna consists according to FIG. 1 from a passive antenna part A, an active three-pole D and a negative feedback impedance Z The passive antenna part has two connections 1 and 4, where 4 is referred to as the ground point of the active antenna and is connected to the vehicle body. The active three-pole contains at least one transistor and has 3 connections 1, 2 and 3. In the present case with

Negative feedback, in which the output signal power of the three-pole is taken from the negative-feedback impedance, 3 is the high-frequency output signal connection of the three-pole. If, for example, the three-pole has a bipolar output transistor Γ, which can also be the high-frequency parallel connection of several transistors, 3 is the emitter connection of the output transistor. The three-pole has a control connection 1 and the control voltage of the three-pole is between the connections 1 and 3. The connection 2 is used in a known manner to supply currents which are necessary for the generation of the output signal currents. There can be several such feed connections in more complicated three-pole connections. All or some of these points can be connected at high frequency to the ground point 4 of the antenna in order to form closed alternating current circuits together with the alternating currents of the three-pole. This is in FIG. 1 shown schematically by a bypass capacitor Cu between points 2 and 4. The control connection of the three-pole is connected to connection 1 of the passive antenna part. The negative feedback impedance Z lies between the output signal connection 3 of the three-pole and the ground point 4.

F i g. Figure 2 shows an antenna according to the invention. The frequency-dependent negative feedback impedance Z is formed by the input impedance of the lossless quadrupole V, whose output at terminals 6 and 7 is loaded with the input impedance of the cable K , which is terminated at its end with the receiver input circuit its input impedance Z has a minimum of the impedance at the operating frequency and the impedance increases with increasing distance from the operating frequency.

In an advantageous embodiment of the invention, the quadrupole V consists of a low loss, as firmly as possible coupled transformer, which optionally on its Pnmärseite or on its secondary side, a reactance JX in series or in parallel, the Figure 3 and 4 show as examples of the connection of the reactance JX on the secondary side. This reactance can be necessary if the input impedance of the cable contains a reactive component which is unsuitable for generating the negative feedback impedance according to the invention. The transformer can be a so-called autotransformer in order to reduce the effort, which consists of a single coil with three connections 3, 4, 5 and whose connections are connected in a known manner to connections 3 and 4 and to the cable that the required transformation arises F i g. 5 shows, as an example, the autotransformer in a circuit which transforms the input impedance of the cable including the added reactance JX into a smaller value.

If the passive quadrupole contains a transformer such. B. in Fig. 3 to F i g. 5 and this transformer is chosen so that its coupling is sufficiently strong, then it multiplies the impedance on its secondary side with a transmission factor as a first approximation. Then it is necessary for the inventive creation of a series resonance at the transformer input that the series resonance already appears in the impedance that loads the transformer on its secondary side, namely the combination of the reactance JX and the input impedance of the cable.

In the usual use case where the recipient has several tunable individual channels, the input impedance of the receiver is determined by the respective operating frequency matched input network

■ determined by the recipient's work. As long as this The input network, the receiver cable and the passive four-pole Vverluslarm are there after the general Rules about the impedance of low-loss reactance combinations always have the possibility of

κι generation of resonances of the input impedance of the passive quadrupole Vderart that the series resonance character of the negative feedback impedance by matching reactances in the input network of the Recipient arises compare H. Meinke, introduction

ι s in electrical engineering of higher frequencies, volume 1.1965; there in particular p.! 12 to! 15 and fig. 107, Fig. 108. It is assumed that, to simplify the operation of the receiving system, tuning measures in the one connected to the antenna passive quadrupole V are not provided.

There is one for the special case of today's car receivers in the long, medium and short wave range particularly simple possibility of such a frequency-dependent negative feedback with series resonance character-

2> ter for several operating frequencies by suitable coordination of the input network of the receiver. According to FIG. 6, the receiver input of today's car receivers consists of an input transistor Tb of a tunable inductance Le

in and an input capacitance Ce. The receiver cable acts like a capacitor Ck connected in parallel to the input circuit of the receiver. The input impedance of the cable is therefore the impedance of a parallel resonance circuit with variable resonance frequency. The reactance jX of the passive quadrupole V always has such a frequency dependence that X increases with increasing frequency, regardless of its structure. The tunable inductance L _E is tuned so that the input terminals 3, 4 of the

passive quadrupole at the respective operating frequency approximates a resonance in such a way that the input impedance of the passive quadrupole V at the connections 3, 4 is almost real and has the character of a series resonant circuit In the simplest case, such a series resonance can be generated by a JX from a single reactance, with an inductance or a capacitance representing a possible solution. 6 is a circuit drawn in which the jX by a

Capacitance C is shown lying on the secondary side of the transformer and in series with the input impedance of the cable. If the tunable circuit inductance Le is then set so that the operating frequency is slightly below the resonance frequency of the Ck, Ce and Le existing Parafldresonanzkreises is, the impedance of this parallel resonant circuit at the operating frequency is inductive and may form with the upstream Cdes passive quadripole a series resonance at the Betriebsfreqnenz.

If JX is an inductance, the tunable circular inductance Le of the receiver input is set so that the operating frequency is slightly above the resonance frequency of the parallel resonance circuit, so that the impedance of this parallel resonance circuit

It is capacitive at the operating frequency and with the upstream inductance of the passive quadrupole can form a series resonance at the operating frequency. To simplify the circuit of the passive quadrupole

In an advantageous embodiment of the passive quadrupole, the transformer Ü is designed so that the inductance used to represent the JX is part of the transformer as leakage inductance.

The one described here for an active antenna for receiving the long, medium and / or short wave range The arrangement can also be part of a car antenna with the same passive antenna .4 an additional transmission path for the reception of the ultra-short wave radio connected is.

For this purpose 2 sheets of drawings

Claims (8)

Patent claims: 1. Active receiving antenna, consisting of a passive antenna part, an active three-pole with source and control connection and a negative feedback impedance, whereby the active three-pole contains one or more output transistors connected in parallel and the source connection of the output transistors is the source connection of the active three-pole and this source connection is high-frequency with one terminal of the negative feedback impedance and the control terminal of the active three-terminal network is connected to one terminal of the passive antenna part and the second terminal of the negative feedback impedance is connected with the second terminal of the passive antenna part and the input impedance of a low-loss passive four-terminal network serves as negative feedback impedance, which is connected at its output to a cable leading to a receiver, the output of which is terminated with the input circuit of the receiver, characterized in that the low-loss passive quadrupole (V) is taken into account of the cable (K) and the receiver input circuit is designed so that its input impedance (Z) has a minimum impedance at the operating frequency and the impedance increases as the frequency increases from the operating frequency. 2. Antenna according to claim 1, characterized in that the input circuit of the receiver a resonance network that can be set in at least one of its reactances depending on the operating frequency is. 3. Antenna according to claim 1 and 2, characterized in that the passive four-pole (V) consists of a transformer (Ü) and a reactance connected in series or parallel to its secondary side (/ canceled. 4. Antenna according to claim 1 and 2, characterized in that the passive four-pole (V) consists of a transformer (Cl) and a reactance connected in series to its primary side. 5. Antenna according to claim 3 or 4, characterized in that the transformer has a coil with 3 Connections (3, 4, 5), d. H. a so-called autotransformer (Fig. 5). 6. Antenna according to claim 3 or 4, characterized in that the transmitter is fixedly coupled is. 7. Antenna according to claim 3, 5 and 6 in relation to claim 2, in combination with a car receiver whose input circuit has a parallel resonance circuit as a resonance network, characterized in that the reactance QX) of the passive quadrupole has a capacitance (C) in series Secondary coil of the transformer is. 8. Antenna according to one of claims 3, 4, 5 with a series inductance as the reactance of the passive quadrupole, characterized in that the transformer is designed so that this series inductance is part of the transformer as leakage inductance. The invention relates to an active receiving antenna, consisting of a passive antenna part, an active three-pole with source and control connection and a negative feedback impedance, the active '> Three-pole one or more output transistors connected in parallel and the source terminal of the output transistors is the source terminal of the active Is three-pole and this source connection has high frequencies one terminal of the negative feedback impedance ίο and the control connection of the active three-pole with the one connection of the passive antenna part is connected and the second connection of the negative feedback Impedance is connected to the second connection of the passive antenna part and as negative feedback Impedance the input impedance of a low-loss passive quadrupole that is connected to its output a cable leading to a receiver is connected, the output of which is connected to the input circuit of the Is completed 2i> Such an antenna is known from DE-OS 21 15 657, see claim 7, taking into account page 7, penultimate paragraph. In DE-AS 20 21 331 is a low-noise counter-coupled antenna amplifier with several 2> described amplifier stage, which consists of an active three-pole with several bipolar transistors and a negative feedback resistor located in the emitter lead of the output transistor; see there in Fig. \ for a three-pole with two transistors and in Fig. jo 1 for a three-pole with three transistors. In the German OS 23 28 925 Fig. 13 shows a complicated three-pole with several transistors shown, in which the output transistors are connected in parallel at high frequency and only high frequency effective negative feedback impedance is the input impedance of the cable with an upstream capacitor is. The cable leads to the receiver. In the following, the terms source connection and control connection will be explained in more detail. An active one Dreipol has a source connection, a control connection and a sink. According to the current status of Technically known basic elements of active three-pole devices are electron tubes, bipolar transistors and field effect transistors. The cathode of the tube, the emitter of the bipolar transistor or the source of the field effect transistor form the source connection of the active three-pole in each case according to their function. as well represent the grid, the base or the gate, according to their physical function, respectively Control electrode. Finally, the third connection in each case, i.e. i. the anode or the collector or the Drain electrode, the sink of the active three-pole. These basic elements can be derived from amplifier technology known manner also with the addition of non-reinforcing components to new ones combine active three-pole, as exemplified in the aforementioned DE-OS 23 28 925 in F i g. 13 is done. Active receiving antennas must be low-noise and linear. On the one hand, they are supposed to have weak signals bo good signal-to-noise ratio received, on the other hand they should show as few non-linear effects as possible, i.e. little cross modulation and few overdrive effects. The requirement for extreme linearity is particularly evident when used in motor vehicles and great oversteer resistance as particularly important because of the moving vehicles encounter constantly changing field strengths and can also get into the vicinity of powerful transmitters.