DE2460227C3 - Reception system in the vicinity of sources of interference - Google Patents

Description

The invention relates to a reception system that receives by means of a receiving antenna a useful signal and whose Empfangsan'enne is located in the vicinity of one or more transmitting antennas that transmit interference signals of certain, different from the frequency of the useful signal frequencies, and for one or u) a plurality of Interfering frequencies via an additional transmission path, the relevant interfering signal is fed in again, with the additional transmission path (s) being designed and connected to the receiving system in such a way that the interfering signal that is picked up directly by the receiving system via the receiving antenna is at the output of the receiving * system is largely suppressed by the effect of the relevant additional transmission path and

any additional transmission path from a probe that records the field of the interference source, preferably a further receiving antenna, and consists of a four-pole transmission, and the four-pole transmission a device for influencing the amplitude, Amplitude actuator called, and a device for influencing the phase of the at the output of the contains additional transmission path existing interference signal, called phase control element

The total signal picked up by the receiving antenna consists of the useful signals and the interference signals from the transmitting antennas mentioned. Receiving systems of this type for receiving messages or for radio navigation can be found on ships, for example. They should also receive when the ship's powerful transmitter is transmitting. Another example is the two-way communication in a larger communications center with several voice connections that work simultaneously on different frequencies and that can send and receive at the same time. Interference signals mix with the useful signals and appear at the output of the receiving system in addition to the useful signals. However, if they are sufficiently strong, they can also generate non-linear effects in the non-linear components of the receiving system, for example sum frequencies, difference frequencies and cross-modulation, or completely block reception by overdriving non-linear components of the receiver.

The usual method in two-way communication of alternately sending and receiving, i.e. switching off the transmitter while receiving, cannot be used if different radio services are working independently of one another in a control center at the same time. It is then often common practice to place the transmitting antennas at a greater distance from the receiving antennas. This means additional work in the form of longer connecting lines to the central office and is not possible in many ^r Aellen of spatial realities such. B. on ships.

In DFIP 4 67194 it has already been proposed that a useful signal from interference in the receiver to be freed by using a second air conductor (wire antenna) tuned to the interference signals If the output signals via a four-pole transmission, the interference in the receiving circuit is caused by negative feedback lift. In this prior publication, this second air duct is located near the first aerial conductor feeding the receiver, and the quadrupole transmission is set up so that it connects to receiving frequency largely blocks, so that the negative feedback the signals of the receiving frequency largely left in the same strength. This is done, for example, by a trap circuit in the four-pole transmission that is tuned to the reception frequency.

The negative feedback is also used in DRP 5 14 831 used to eliminate an interfering signal in the receiver. Here the interference signal is on the same Frequency as the useful signal. The second duct is closer to the source of the disturbance than the one first air guide, so that the output signal of this second antenna contains almost only the interference signal. the Interference contains a mixture of different frequencies, and both antennas contain resonance circuits of this kind, (if they had the same resonance curves and thus all interference frequencies in both antennas suffer the same phase shift and so in Compensation circuit for all interference frequencies at the same time The compensation occurs This method is only suitable for low frequencies, where a Phase rotation due to connecting lines of different lengths does not have a noticeable effect

In the DRP 5 50 580 is for improved differentiation between telegraphing impulses and by atmospheric Interference generated interference pulses in addition to the first, tuned to the frequency of the useful signal Receiver, a second receiver is provided which is tuned to an adjacent frequency band is and does not receive the useful signal Provided that between the interfering signals the there are certain connections between the two recipients,

By comparing the signals from both receivers, it is easier to decide whether one from the first receiver received, impulsive character is a telegraph impulse or an interference impulse.

The DAS 11 17 662 describes e- ^r i arrangement for eliminating Reflexionsstörungpn in television reception with 2 directional antennas, one of which is a to the transmitter and the second directed to the reflection point where from the second A; recorded signal .tenne of the signal first antenna in

.25 of a certain amplitude and phase is added and that The amplitude control element and the phase control element are set so that the reflection interference largely The amplitude control element consists of a variable resistor network in the

JO feed line for the second antenna and is on regardless of frequency in the relevant waveband adapted to the wave resistance of the line. The variable phase shift is created by shifting the connection point of the feed line of the second antenna to the feed line of the first antenna.

In the Funkschau, issue 15/1959, page 370, there is a similar arrangement for the interference suppression of a television picture described with the help of a second antenna. Here, the amplitude actuator consists of one Potentiometer and the phase control element from one terminated at the end with the characteristic impedance Line changeable length.

To simplify the illustration, the following description relates to the case of a single transmitting antenna,

■ Ti that emits an interference signal of a defined operating frequency. F i g. 1 shows the scheme of the arrangement with a source of interference and an additional transmission path. A transmitting antenna 1 which transmits the useful signal in wave form sends these waves on the path 2 to the receiving antenna 3 of the receiving system E. The transmitting antenna 1 of the useful signal is referred to below as the useful source. The receiving antenna 3 sends the output signal to the following part 6 of the receiving system. The transmission path of the signal

>> via path 2 and antenna 3 and circuit 6 is hereinafter referred to as the direct transmission path. The transmitting antenna 4 sends an interference signal in Form of electric and / or magnetic fields, for example as a wave, on the way 5 to

wi receiving antenna 3. The additional transmission path consists of a probe 7, which picks up the interference signal on the path 8 and a transmission quadrupole 9 and a coupling device 13 which leads to the connection point 11 of the receiving system. The coupling

· ■> of the additional transmission path takes place capacitively via the capacitor in the example shown 13, in FIG. 2 by way of example by means of a transformer the coils 14 and 15. 6ä is another part of the

Receiving system in which the interference signals of the direct transmission path and the additional transmission path are included together. 12 is the exit of the receiving system.

Often the probe 7 also receives the useful signal on the path 10, so that the useful signal can also be transmitted via the additional transmission path of the receiving system is supplied. If the reception system is designed like this is that the interference signal is compensated by subtraction at connection point 11, it is possible that in this case, the useful signal in part 6a also becomes considerably smaller if the additional transmission path The ratio of the useful signal is about the same as in the direct transmission path. Hence the additional Transmission path designed in such a way that the ratio of interfering signal to useful signal at its output is different, is preferably noticeably larger than in the sum signal that the receiving antenna directly on paths 2

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A particular problem is the correct setting of the amplitude control element and the phase control element, to set the minimum of the disturbance. In the prior publications, this is done by observes the output signal of the receiving system and sets low-interference reception This is particular then simply when the interference frequencies are close to the useful frequencies or are identical to them. Therefore, the prior publications do not contain any information about an advertisement with the help of which the Arrangement can be set, and therefore no instructions such as an automatic setting could take place without the assistance of the operating personnel. In the use cases outlined above the interference frequencies are often noticeably different from the useful frequencies. Furthermore, the interference frequencies how the useful frequencies are generally variable, e.g. B. in shortwave traffic, and every change in frequency requires a readjustment of the compensation, especially in systems with frequency-dependent phase-rotating lines.

The object of the invention is to build an electrical display device into the receiving system, which is for each Interference frequency gives a simple display that can be used to set the interference minimum correctly and also makes an automatic setting possible

This object is achieved in that the amplitude of the in the receiving system behind the connection point of the additional transmission path still present interference signal by the direct current is displayed at the output of a mixer and this mixer the signal of the between the connection the additional transmission path and the output of the receiving system part of the receiving system is supplied and this direct current by adjusting the amplitude actuator and the phase actuator is set to a minimum

F i g. Figure 2 shows the connection of the mixer 16 to the part 6a of the receiving system and the additional transmission path 9. Direct current is generated in a mixer when two signals of the same frequency mix. So the direct current of the mixer shows the Amplitude of the interfering signal in the receiving system is still included behind the connection point 11 of the additional transmission path

If the interfering signal is very strong, it will appear without Application of the compensation according to the invention at the output of the receiving system not only in addition to it the useful signal, but because of the non-linearity of some components of the receiving system Interfering signal also includes non-linear combination frequencies, cross modulation and overload. This will affects the output current 17 of the mixer and the minimum to be set may be less pronounced. In order to avoid this, the additional transmission path is therefore used at such a point 11 connected to the receiving system that all those components of the receiving system that are without Compensation of the interfering signals according to the invention show non-linear effects to an inadmissible extent would, only the interference signals reduced by the compensation are fed. This would be part 6a in Fi g. 1 and 2. Part 6, in which the interference signals are still present in full size, is therefore in a advantageous embodiment of the invention designed so that between the points at which the interference signal in the Receiving system enters path 5 for the direct transmission path and path S for the additional one

Transmission path, and the two associated connections of the mixer to the transmission paths only passive, linear components are present.

Such an arrangement is advantageous in those cases in which the input transistor of the receiving system cannot be protected against the interference signal by selective, tunable pre-circuits. A An example of this are broadband, active antennas. Dz antennas consistently at some distance from the Receivers are set up and difficult to access, it is generally too expensive, tunable circuits to be built into the antenna. If the interfering signals are so strong that the input transistor of the active Antenna shows non-linear effects to an inadmissible extent and on the direct transmission path up to junction 11 only passive, linear components are allowed, is then in Fi g. 1 the antenna 3 only the passive part, the radiation: receiving part the active part Antenna. The part 6 of the receiving system does not exist then and the amplifying circuit of the active one Antenna is part of part 6a of the receiving system. The additional transmission path is then to the Theiv part of the active antenna is coupled

If the mixer is to give a correct output display, the two supplied to it must

■? 5 voltages are largely decoupled from one another, in particular, the signal of the direct transmission path should not be noticeable via the coupling element in the Terminal 11 penetrate into the additional transmission path, so that the behavior of the additional

The transmission path becomes independent of the processes in the receiving system £ It will be there additional transmission path at its output 11 loosely coupled to the receiving system This loosely Coupling can take place in a manner known per se in parallel in such a way that the impedance of the additional transmission path at the connection point 11 parallel to the existing impedance there A technical embodiment is a coupling via a small series capacitance

f »n did 13 as in Fig. 1. The coupling of the additional The transmission path can also, as in FIG. 2 take place in such a way that the output of the additional transmission path has a coil 14 as the primary coil of a transformer to one in the

b "> Reception system existing coil 15 is coupled

An advantageous form of the reaction-free coupling of the additional transmission path to the receiver is given by a transistor,

whose control connection is fed by the additional transmission path and whose output is connected to point 11. Such a transistor, preferably a field effect transistor, decouples the receiver from the additional transmission path through its hichtfezipfokes behavior while at the same time amplifying the compensating interference signal. It also provides a phase shift n which is largely independent of frequency and which can advantageously be used in many compensation processes.

The direct current 17 of the mixer 16 is advantageously used in systems with a variable reception frequency and variable interference frequency to adjust the amplitude control element 9a and the phase control element 9b with the aid of known control processes so that the amplitude of the interference signal at the receiver output, i.e. the direct current 17, reaches a minimum . The further embodiment of the invention relates to

simple automatic regulation. The phase control element should have a large phase variation range and cover the required frequency range. If longer lines are present in both transmission paths, a phase variation of 360 ° must be required in order to be able to cover all applications. In principle, circuits with adjustable reactances are known for this, but the effort is usually great and the setting difficult because several reactances have to be changed at the same time for greater phase variation, on the other hand in the case! the automatic control to demand by the DC 17-dial operation for the phase variation is one-button operation, for the adjustment of the amplitude of the actuator to the DC capable of driving actuators that adjust the arrays 9a and 9b are known, including one-button operation is to be required both actuators It is known that you can automatically set two actuators to a display minimum with a single direct current if the time constants of the two setting processes are significantly different. See beisDielweise Offenleeunesschrift 17 66 720, Az .: P 17 66 720.8-35, in which on page 8 of the description the control of two varactor diodes with only one measuring element using a slow and a fast control process is described

In an advantageous embodiment of the invention, a goniometer is used in combination with a bridge. The goniometer in FIG. 3 consists of two non-changeable coils 25 and 26 which are perpendicular to one another and are designed so that their magnetic fields cross one another. In the crossover area of the fields, the interference signal generates a rotating field in a manner known per se in that the interference signal is fed to the two coils in the same amplitude and with a phase difference of π / 2. In the rotating field there is a third coil 27, which is mechanically rotatable opposite the two first-mentioned coils. By rotating the third coil, the phase of the output voltage of this coil changes in a manner known per se, with an approximately constant amplitude, roughly like the mechanical angle of rotation. This process is largely independent of the frequency.

To power the goniometer, a circuit is required in the additional transmission path that produces the two coil currents with the same amplitude and different in phase by n / 2. Since the compensation of the interference signal according to the invention also requires an amplitude control element, in an advantageous embodiment of the invention said circuit is designed so that it also contains the amplitude control element in such a way that the amplitude set by the amplitude control element appears at the output of the third coil 27

3 shows an example of a suitable one

; o circuit. The probe is direct or via a supply line 7 connected to a circuit that consists of the parallel connection of two impedances. The first Impedance is the series connection of an adjustable capacitor 20 and a resistor 22, the

• ■ 5 resistance value small compared to the reactance of the capacitor 20 at the interference frequency is The second impedance is the series connection of an adjustable Resistor 21 and a resistor 23, the resistance value of which is small compared to the resistor

; o stand is 21 and its resistance value is preferably equal to that of resistor 22 The voltages U \ and Ui existing at resistors 22 and 23 have a phase difference π / 2 if these resistances are sufficiently small. The end points of the two resistors are connected to the respective associated coil 25 and 26 of the goniometer. With the aid of a display element 24 which compares the voltages U \ and Lh with regard to their amplitude, for example measures their difference, the value of the capacitance 20 is first set so that the amplitudes U \ and Ui are sufficiently exactly the same. This setting can take place automatically in a manner known per se. Then the adjustable resistor 21 is the amplitude control element, which sets the amplitudes U \ = Ui to the value required for the compensation, with each setting of this resistor 21 and with a frequency change through automatic variation of the capacitor 20 always the equality U \ = U ₂ of Amplitudes is established This gives an arrangement that sets the amplitude and phase in the simplest possible way using two separate operating buttons and can be set automatically using two setting motors. The two control processes of the automatic setting have different ones

Time constants, so that the first setting is quick and the second is much slower

For this purpose 3 sheets of drawings

Claims (9)

Patent claims: 1. Receiving system that receives a useful signal with the help of a receiving antenna and the receiving antenna is located in the vicinity of one or more transmitting antennas that emit interference signals of certain frequencies different from the frequency of the useful original, and for one or more interference frequencies over each An additional transmission path is used to feed the interference signal in question again, the additional transmission path (s) being designed and connected to the receiving system in such a way that the interference signal that is picked up directly by the receiving system via the receiving antenna is largely passed through the receiving system at the output of the receiving system Effect of the relevant additional transmission path is suppressed, and each additional transmission path consists of a probe receiving the field of the interference source, preferably a further receiving antenna, and a transmission quadrupole, and the transmission quadrupole a device for influencing the amplitude e, called amplitude control element, and a device for influencing the phase of the interfering signal existing at the output of the additional transmission path, called phase control element, characterized in that the amplitude of the _{existing in the receiving system behind the connection point (II) of the additional transmission path X} 9) Interference signal is indicated by the direct current (17) at the output of a mixer 116) and this mixer receives the signal of the relevant additional transmission path (9) and the signal between the connection (111) of the additional transmission path and the output (12 ) the receiving system lying part {Sa) of the receiving system is supplied, and this direct current is set to a minimum by adjusting the amplitude control element (9a) and the phase control element (9b) 2. Receiving system according to claim 1, characterized in that the two connections of the Mixer (16) are placed so that between the points at which the interference signal in the receiving system Entrance (paths 5 and 8) and the two associated connections of the mixer only passive linear components are present. 3. Receiving system according to claim 1, characterized in that the coupling of the additional Transmission path to the receiving system with the help of a transistor, preferably one Field effect transistor, with the additional transmission path being the control connections of the transistor feeds and the output of the transistor to the connection point (11) of the additional transmission path is connected to the receiving system. 4. Receiving system according to claim 1, characterized in that the direct current of the display member with the aid of known control processes the amplitude actuator (9a) and the phase sub-element (^ adjusts 5. Receiving system according to claim 1, characterized in that the phase control element is constructed so that two voltages are obtained from the interference signal of the additional transmission path, have the same amplitude and which phase angles differ by π / 2 , and the two coils are fed to both voltages and the coils are spatially perpendicular to one another are arranged so that their magnetic fields cross each other, and a third coil in the crossover area the fields in the form of a goniometer is rotatably arranged so that when turning the third coil the phase angle of the output voltage of this coil roughly proportional to the uechanical Angle of rotation changes and the amplitude of the output voltage remains about the same and this output voltage is the phase-shifted output voltage of the phase control element. 6. Receiving system according to claim 5, characterized in that the circuit which generates the two equal amplitudes and in phase by jc / 2 different and serving to feed the goniometer coil currents, at the same time contains the amplitude actuator in such a form that at the output of the third coil the amplitude set by the amplitude control element appears. 7. Receiving system according to claim 6, characterized in that the feeding the goniometer The circuit consists of the parallel connection of two impedances and one impedance consists of the There is a series connection of a capacitance (20) and an effective resistance (22), this effective resistance is significantly smaller than the reactance of the capacitance in the operating frequency range, and the second impedance from the series connection of an active resistor (21) and a much smaller one Resistance (23) exists and each of the two much smaller effective resistances (22, 23) is connected at both ends to one of the first two coils (25, 26) of the goniometer. 8. Receiving system according to claim 7, characterized in that a second display element (24) is present that the amplitudes of the two input voltages (U \. Uj) of the goniometer compares, for example, their difference forms, and the series capacitance (20) of the goniometer feeding circuit is set with the help of the second display element so that the amplitudes of the two input voltages of the goniometer are equal. 9. Receiving system according to claim 8, characterized in that the larger series resistance (12) the second impedance is the amplitude control element in the form of a potentiometer.