NO855306L - DIVERSITY-RECEIVER DEVICE. - Google Patents

Description

Technical area

The invention relates to a diversity receiver device with

two signal paths for a radio connection that exhibits a large frequency band range, and where each signal path on its input side exhibits an antenna with a subsequent intermediate frequency converter and on the output side is connected to one of the two signal inputs of a coupling device, and where the coupling device exhibits a sum signal output and a differential signal output to which each receiver is connected with its signal input,

as well as where a phase rotary joint is arranged in the signal path between the coupling device and the intermediate frequency converter.

Relevant state of the art

A diversity receiver device of this kind is known

from publication EP 0 023 948 A1. With its help, it is possible to at least partially compensate the fadings that occur with superimposed radio fields with regard to their influence on the transmission characteristics. The used coupling device provides the opportunity to optimize the sum signal appearing at the sum signal output by using the difference signal appearing at the difference signal output as a setting criterion for the setting size of a phase rotary joint arranged in one of the two signal paths. In this way, an average gain of 6-10 dB can be achieved compared to a signal reception with only one antenna. However, the relatively slow regulation for the optimization of the sum signal appearing at the sum signal output does not permit any reception operation where it is necessary to quickly switch from one reception frequency to another.

Account of the invention

The basis of the invention is the task for a diversity receiving device of the kind indicated at the outset to provide instructions for a further solution which makes it possible to optimize the sum signal occurring at the sum signal output of the coupling device in dependence on the setting of a phase rotary joint with an extremely short swing-in time for the control circuit.

This task is solved with the features indicated

as characteristic in patent claim 1.

The invention is based on the essential realization that the optimization of the sum signal via the setting of a phase rotary joint in one of the two input-side signal paths can be provided in an extremely favorable way and with a very good approximation, also by using the zero phase difference between the two intermediate frequency signals at the two signal inputs of the coupling device. Interpreted with a phase comparator, this criterion delivers the desired setting result for the phase pivot with a single measurement, i.e. that the setting of the phase pivot is achieved immediately and not in an iteration process with a greater number of steps and improved approximation for each step. The settling-in time of the regulation process can thereby be limited to less than 1 ys with the traditional technology, so such a diversity receiver device up to suitable for carrying out a fast frequency jump drive ft.

The conditions are particularly favorable in this regard if the two antennas show the smallest possible mutual distance of e.g. half a wavelength of the center frequency in the radio connection's frequency band range. Because of this, it is ensured that the level of the received signals in the two signal branches at the signal inputs of the coupling device are always at least approximately equal.

If this condition does not exist, that is to say if the two antennas, which in that connection can also be of different types, show a greater mutual distance of e.g. several wavelengths of the center frequency in the radio connection's frequency band range, it is appropriate in the two signal paths at the connection to the intermediate frequency converter to arrange an automatic gain control device and in that connection to arrange the adjustable phase rotary joint in a signal path on the output side of the automatic gain control device. This gain control device is designed so that it regulates the level difference between the intermediate frequency signals at the signal inputs of the coupling device in a previously given dynamic range.

The settling-in time for the regulation in this regulation circuit, which consists of two interdependent regulation loops, is admittedly greater than the settling-in time for the regulation of a regulation circuit that only includes the setting of the phase rotary joint, but it is still so short that a diversity receiving device made in this way is also suitable for carrying out one frequency jump drive ft.

Short drawing description

The drawings illustrate the invention more closely. Fig. 1 is a block connection core for a diversity receiver device with a phase control circuit. Fig. 2 schematically shows the two antennas in the block diagram

•on fig. 1 in the azimuth plane.

Fig. 3 is a partial block diagram of a variant of the diversity receiver device of fig. 1.

Fig. 4 shows a first antenna radiation diagram for

two antennas according to fig. 1 and fig. 2.

Fig. 5 shows another antenna radiation diagram for an antenna device in accordance with fig. 1 and fig. 2. Fig. 6 shows a phase diagram which further explains the operation of the diversity receiver device in fig. 1. Fig. 7 shows another phase diagram which makes the operation of the diversity receiver device in fig. 1.

Best way to carry out the invention

The diversity receiver device according to the block diagram

on fig. 1 has two signal paths. Each signal path contains on the input side an antenna A1 or A2 and an intermediate frequency converter U1 resp. U2 in connection with an output-side filtering means in the form of a bandpass filter BP1 or BP2. The conversion oscillations are obtained by the two converters U1 and U2 from a synthesizer SYN, the frequency of which is set via a frequency address input fa from an address generator which is not shown in more detail in fig. 1.

A four-pole is connected to the bandpass filters BP1 and BP2

in the form of a regulation network RN, whose inputs e1 and e2 are connected to the outputs of the bandpass filters BP1 and BP2; and whose outputs, which will be designated in more detail, are connected to the input of each amplifier RE1 or RE2.

The regulation network RN exhibits on the input side

at the input el an adjustable phase rotary joint PH which is controlled from the control signal output from a phase comparator Pd. On the output side, the control network has the coupling device COP.

One signal input to the coupling device COP is connected to the output of the bandpass filter BP1 via the phase rotary joint PH and the other signal input is directly connected to the output of the bandpass filter BP2. The phase comparator PD compares via its two inputs the intermediate frequency signals in the two signal branches at the signal inputs of the coupling device COP and, depending on the comparison results, controls the setting of the phase rotary joint PH so that the intermediate frequency signals at the signal inputs of the coupling device COP are always in phase.

The coupling device COP combines the two intermediate frequency signals in the two signal branches at their sum signal output S

to a sum signal and at the difference signal output D to a difference signal. In this connection, the receiver RE1 receives the sum signal and the receiver RE2 the difference signal, so both signals can be further processed or interpreted as required.

Is the distance d between the antennas A1 and A2, so that

is represented in the azimuth plane X,Y in fig. 2, in the order of magnitude of half a wavelength at the center frequency in the frequency band area for the radio connection that the diversity receiver device in fig. 1 is used for, it can be assumed that both antennas A1 and A2 generally receive the signal to be received, with the same strength. This constitutes an optimal reception condition, as the phase coincidence and the same level of the intermediate frequency signals at the two signal inputs of the coupling device COP give a maximum sum signal at the signal output S and an ignorably small difference signal at the difference signal output D.

As already pointed out, the phase control circuit is very fast, so this device is also suitable for the application of a very fast frequency hopping method. In the application cases where the two antennas Al and A2 cannot be placed on a common mast, but must be mounted at a greater distance from each other in the room, it cannot be avoided that the reception field strength of the received signal at the two antennas A1 and A2 in general is different in size. In order to obtain the most optimal reception conditions for such a diversity receiver device here, too, the control circuit with the phase rotary joint PH and the phase comparator PD, as shown in the variant of the control network RN in fig. 3, is additionally expanded with a gain control device AGC.

The gain control device AGC is arranged

on the input side of the regulation network RN, i.e. in front of the phase rotary joint PH in the direction of the signal flow. In this way, it is ensured that such a phase difference of the intermediate frequency signals at the two signal inputs of the coupling device COP, which occurs in dependence on the gain regulation, is immediately equalized via the phase regulation circuit. The gain control device AGC compares the signal levels at the signal outputs of the coupling device COP with each other and regulates the amplification in the two signal branches so that the level of the intermediate frequency signals at the signal inputs of the coupling anode COP is at least approximately equal in a previously given dynamic range. Thus, the same relationship is obtained as with the antenna device where the distance d between the two antennas A1 and A2 is of the order of half a wavelength of the center frequency in the radio connection's frequency band range.

In fig. 4 is the radiation diagram of the sum signal SP

and the radiation diagram for the difference signal DP listed as functions of the azimuth angle $ between 0 and 360° for the case that the distance d between the antennas A1 and A2 is so small that one can assume equal intermediate frequency signal levels at the signal inputs of the coupling device COP. There is no gain regulation of the intermediate frequency signals in accordance with fig. 3. As the radiation diagrams clearly indicate, the radiation diagram for the sum signal has SP

a maximum when the radiation pattern of the difference signal DP has a sharp minimum, and vice versa.

Fig. 5 shows the course of the radiation diagram for the sum signal SP and the course of the radiation diagram for the difference signal DP for the case that the distance d between the two antennas A1 and A2 in fig. 1 is equal to twice the wavelength at the center frequency in the radio connection's frequency band range and the level of the intermediate frequency signal at one signal input to the coupling device is 10% lower than the level of the intermediate frequency signal at its other signal input. As it turns out, a distance of the order of 25 dB appears between the sum signal SP in the maximum of the radiation diagram and the difference signal DP in the minimum of the radiation diagram. This makes it clear that it will be possible to dispense with an additional gain regulation as long as the level difference between the intermediate frequency signals at the two signal inputs to the coupling device does not significantly exceed 10%.

In general, it cannot be assumed that the desired signal during practical operation of a radio connection is received free of interference. On the contrary, it must be taken into account that the received useful signal is superimposed on a noise signal. Such a case is shown in the phase diagram in fig. 6. The useful signal received at the antennas A1 and A2 is here represented by the useful signal vectors S1 and S2, on which is superimposed one noise signal in the form of a noise signal vector a1 or a2. The phase difference between the signals at the antennas A1 and A2 constitutes a phase angle eps which here, as a result of noise signals that are not correlated with the useful signal, fluctuates periodically between cpmin and cpmax.

As the phase control circuit is very fast, such a periodic phase variation in the rule is also largely suppressed. As can be seen from the phase diagram in fig. 6, causes the noise signal that is superimposed on the useful signal,

in addition, a periodic fluctuation of the level difference between the two intermediate frequency signals at the signal inputs of the coupling device. This variation is not equalized unless one makes use of a gain control corresponding to fig. 3 in addition.

As the radiation diagram in fig. 5 shows, level differences due to such superimposed disturbances can be readily allowed when they remain in the order of magnitude approx. 10%.

The relationships considered do not change significantly if, as indicated by a corresponding phase diagram in fig. 7, 7

superimposed on the useful signal S are two disturbances a and b, both of which are uncorrelated in relation to the useful signal and also in relation to each other. The tip of the sum vector SS describes here only a somewhat more complicated path around the tip of the useful signal vector.

Fig. 6 and 7 also make it clear that the phase and, if a gain control is used in addition, also gain control will not adjust to the strongest signal at all times. If the noise signal is significantly larger than the useful signal to be received, the sum signal of the noise therefore appears as an optimized signal at the sum signal output. In that case, the useful signal can be extracted in an extremely favorable way at the differential output D from the coupling device COP, since this noise signal is then optimally suppressed here.

Industrial applicability

The described diversity receiver device can be used with advantage wherever a wide frequency band is available for transmission and where, if necessary, a frequency hopping operation is used to increase noise resistance to intentional interference. These prerequisites are particularly present with tactical radio networks.

Claims (3)

1. Diversity receiver device with two signal paths for a radio connection exhibiting a large frequency band range, and where each signal path on the input side has an antenna with a downstream intermediate frequency converter and on the output side is connected to one of the two signal inputs of a coupling device, and where the coupling device has a sum signal output and a difference signal output to which a receiver is connected with its signal input, and where in one signal path, a phase rotary joint is arranged between the coupling device and the intermediate frequency converter, characterized in that the adjustable phase rotary joint (PH) for carrying out a frequency jump operation is controlled via a phase comparator (PD) which monitors the phase coincidence of the intermediate frequency signals at the two signal inputs of the coupling device (COP) and when a phase difference between the two intermediate frequency signals is determined, the phase rotary joint adjusts its setting accordingly. 2. Diversity receiver as specified in claim 1, characterized in that the two antennas (A1, A2) have the smallest possible mutual distance (d) of e.g. half a wavelength at the center frequency in the frequency band range of the radio connection. 3. Diversity receiver device as stated in claim 1, characterized in that both signal paths in the case of greater mutual distance (d) between the two antennas (A1,A2), e.g. on several wavelengths at the center frequency of the radio connection's frequency band range, in connection with the frequency converters (U1, U2) exhibit an automatic gain control device (AGC) and the adjustable phase rotary joint (PH) in a signal path below is arranged on the output side of the automatic gain control device, and that this gain control device outregulates the intermediate frequency signals' level difference at the signal inputs of the coupling device (COP) in a previously given dynamic range.