WO2006097071A1

WO2006097071A1 - Active reception antenna system

Info

Publication number: WO2006097071A1
Application number: PCT/DE2006/000415
Authority: WO
Inventors: Jörg LOGEMANN
Original assignee: Eads Deutschland Gmbh
Priority date: 2005-03-16
Filing date: 2006-03-10
Publication date: 2006-09-21
Also published as: EP1859510A1; ZA200705912B; DE102005011999A1

Abstract

The invention relates to an active reception antenna system comprising a magnetic reception antenna (R) and an amplifier arrangement mounted downstream therefrom. According to the invention, the amplifier arrangement is embodied as a transimpedance amplifier (T).

Description

Active receiving antenna system

The invention relates to an active receiving antenna system, in particular for Beilung, with a magnetic antenna and downstream amplifier arrangement.

In active magnetic receiving antennas, in particular for the long and short wave range, e.g. 150kHz ... 30MHz, which are used in direction finding systems, there is a requirement to achieve a good and even sensitivity over a very large frequency range (more than 2 decades) combined with high intermodulation resistance. Since a square frame with one turn and 1 m edge length is typically used as the receiving frame for reasons of space, conventional amplifier arrangements are to be expected to have poor sensitivity at low frequencies, although at high frequencies (15 to 30 MHz) the gain is not should be too high.

Typically, 50 ohm amplifiers, usually composed of individual transistors and a number of additional components used. Also finished amplifier ICs in 50-ohm technology are used. By means of 50 ohm technology, however, no optimal frequency-independent coupling of the antenna can be achieved. In finished amplifier ICs, a high power consumption is needed to achieve a sufficient intermodulation distance. In discrete amplifiers many winding materials (ferrite transformers) are present, resulting in high production costs.

The invention has for its object to provide an active receiving antenna system, which overcomes the above-mentioned problems of the prior art, so in particular an improved sensitivity and increased bandwidth while allowing lower production costs. This object is achieved with the objects of claims 1 and 2. Advantageous embodiments are objects of dependent claims.

According to the invention, the active receiving antenna system comprises an amplifier arrangement which is designed as a transimpedance amplifier.

A transimpedance amplifier is defined as an operational amplifier circuit which transforms a (usually only a few μA) current signal into a voltage signal, the non-inverting input of the operational amplifier is grounded, the current signal is present at the inverting input, and the operational amplifier is ohmic Resistor coupled, which determines the gain.

With modern operational amplifiers, which have cut-off frequencies in the GHz range, very low noise figures and high intermodulation distances, real current / voltage converters can be realized that also work effectively in the high-frequency range. The output signal of the amplifier arrangement of the active antenna according to the invention is independent of the frequency at a constant field strength. At the same time, the antenna system is easier to set up and less expensive than conventional systems.

For example, an analogue amplifier AD8045 from the company Analog Device Corp. may be used. be used.

The transimpedance amplifier should advantageously have a cutoff frequency that is at least a factor of 10 higher than the maximum useful frequency of the DF antenna system. The active receiving antenna system according to the invention is in principle not limited to a specific frequency range. It can be used in particular in the LF (low frequency), HF (High Frequency), VHF (Very High Frequency) or UHF (Ultra High Frequency) range.

The transimpedance amplifier has a low input resistance near zero ohms, for example in the range of less than 1 ohm.

In order to achieve an increased immunity to electric fields, in a further inventive solution, a balanced amplifier circuit with two transimpedance amplifiers are used, which are each connected to one end of the magnetic receiving antenna. Each of the two amplifiers thus receives an antiphase signal relative to the other. To obtain an in-phase signal, the amplifier output signals are coupled to a push-pull single ended converter, e.g. a push-pull transformer, summarized.

The magnetic receiving antenna of the receiving antenna system according to the invention may in particular be a loop antenna, for example an aerial frame antenna or a ferrite frame antenna.

The receiving antenna has a square cross-section in a further embodiment.

The receiving antenna may advantageously have only a single turn.

The invention will be explained in more detail by means of embodiments with reference to drawings. Show it:

1 shows a first embodiment of the active receiving antenna according to the invention system with a transimpedance amplifier;

2 shows a second embodiment of the erfindungemäßen active receiving antenna system with two transimpedance amplifiers in the same circuit as in Fig. 1, but with symmetrical control.

1 shows a first embodiment of the active receiving antenna system, designed as a DF antenna system with a loop antenna R and an amplifier designed as a transimpedance amplifier T. The loop antenna R consists in this embodiment of a square frame with a turn and 1 m edge length.

The output voltage of the loop antenna R is calculated as follows:

1 )

or

2)

where v = speed of light

U = voltage in VA = frame area in m ²

N = number of turns

E = electric field strength in (amplitude or rms value)

H = magnetic field strength (amplitude or rms value)

Zo = field wave resistance = 120 π .Ω λ = wavelength in m f = frequency in Hz

The frame voltage thus behaves inversely proportional to the wavelength or increases at a constant field strength H proportional to the frequency. This is based on a small frame compared to the wavelength. If the frame voltage is removed with high resistance, a receive voltage is obtained, which increases in proportion to the frequency. According to the invention, however, the loop antenna R is allowed to operate on a short circuit. Here, a current is impressed by the antenna, which depends essentially on the reactance of the frame inductance. The ohmic losses and the radiation resistance are in the milliohm range and can therefore be neglected.

The frame current is therefore calculated as follows:

3)

where X frame is the reactance of the loop antenna R, ie

4) X _frame = 2.π. f .L

Where f = operating frequency in Hz

L = frame inductance in H. Thus, will

5)

Thus, in the case of the amplifier input resistance of 0 ohms, the loop antenna current behaves inversely proportional to the frequency if the frame voltage were constant. However, this behaves as described in 1) and 2).

Substituting 2) in 5) results in:

6)

The frame current is thus independent of frequency at a constant field strength H.

The transimpedance amplifier T has an input resistance of about 0 ohms and converts an input current into an output voltage according to the equation

7) U _out = R _f • I _frame .

R _f is the feedback resistance of the amplifier. The output voltage of the entire active antenna arrangement is thus

8th)

Parallel to the above-mentioned feedback resistor Rf is still a series RC Ried Rb and Cb, which drops above the working frequency range, the gain. The series resistance Rs ensures an adaptation to the supply line, prevents oscillation tendency with capacitive load and at the same time limits the output current of the operational amplifier.

In order to ensure a clean reception of the magnetic component of an RF field, a high suppression of all E-field components (in particular those that are generated in the near range by interference sources) should be ensured. The embodiment of FIG. 2 is characterized by an increased immunity to electrical fields. With her a common mode rejection is realized. The circuit is symmetrical and comprises two transimpedance amplifiers T1, T2. In addition, the receiving frame R is grounded at its center.

The two operational amplifiers OP1, OP2 are used in the same circuit as in FIG. 1, but the control takes place symmetrically, so that each amplifier T1, T2 receives an opposite-phase signal relative to the other. Consequently, both amplifiers T1, T2 must be combined at the output with a push-pull single-ended converter, here designed as a push-pull transformer W, in order to again generate an in-phase signal. Alternatively, e.g. also the summary with an operational amplifier in instrument amplifier circuit possible to save the transformer W. The disadvantage of this arrangement, however, is a lower third order intermodulation distance.

For a high 2nd order intermodulation distance, the circuit must be strictly symmetrical, regardless of which of the variants is used. Advantageously, additional Symmetrieeinstellregler be provided.

Claims

claims

1. Active receiving antenna system with a magnetic receiving antenna (R) and a downstream amplifier arrangement, characterized in that the amplifier arrangement is designed as a transimpedance amplifier (T).

2. Active receiving antenna system with a magnetic receiving antenna (R) and a downstream amplifier arrangement, characterized in that the amplifier arrangement comprises two transimpedance amplifier (T1, T2), which are each connected to one end of the magnetic receiving antenna (R).

3. Active receiving antenna system according to claim 2, characterized in that the magnetic receiving antenna (R) is grounded in its center.

4. Active receiving antenna system according to one of claims 2 or 3, characterized in that the output signals of the two transimpedance amplifier (T1, T2) are combined in a push-pull single-ended converter (W).

5. Active receiving antenna system according to one of the preceding claims, characterized in that the magnetic receiving antenna (R) is a loop antenna, in particular an air frame or ferrite frame antenna.

6. Active receiving antenna system according to one of the preceding claims, characterized in that the magnetic receiving antenna (R) has exactly one turn.

7. Active receiving antenna system according to one of the preceding claims, characterized in that the magnetic receiving antenna (R) has a square cross-section.

8. Active receiving antenna system according to one of the preceding claims, characterized in that the or the transimpedance amplifier (T, T1, T2) have an input resistance of less than 1 ohms.

9. Active receiving antenna system according to one of the preceding claims, characterized in that it is adapted for use in the LF, HF, VHF or UHF range.

10. Active receiving antenna system according to one of the preceding claims, characterized in that the or the transimpedance amplifier (T, T1, T2) have a cutoff frequency which is higher by at least a factor of 10 than the useful frequency of the DF antenna system.