FI72415B - KOPPLINGSANORDNING FOER ANTEN FOER FLERANTENNMOTTAGNING - Google Patents

Description

ESiF ^ l ANNOUNCEMENT „? »TSIplP B 11 UTLÄG G NIN GSSKRIFT 't41 0 C / ^ ¾ Pj.u6ii ύ id jii.iu .. i.y' * p- * r., -,. . ^ Ί ^ 1 .. L ~ | I / * \ - (51) Kv.lk. * / Lnt.CI. * H 0 ** 8 7/08 FINLAND —FINLAND (21) Patent application - Patentansökning 800366 (22) Filing date - Ansökningsdag 06.02.80 (FI) ( 23) Start date - Giltighetsdag 06.02 .80 (41) Has become public - Blivit offentlig 07.08.8l

National Board of Patents and Registration Date and date of publication - 30.01.87

Patent and registration authorities '' Ansökar) utlagd ocli utl.skriften publicerad (86) Kv. application - - Int. ansökan (32) (33) (31) Privilege claimed - Begärd priority (71) (72) Nikolai Alexandrovich Sartasov, ulitsa 5, Vistochnaya 10, kv. 22,

Omsk, Valery Ivanovich Levchenko, ulitsa Khudenko, Sat, kv. 7b,

Omsk, Vladimir Vasilievich Leontiev, ulitsa Gusarova 28, kv. 11,

Omsk, Valeria Vasilievna Sakharova, Pereulok Aviatsionny 1, kv. b,

Bryansk, Vladimir Konstantinovich Tatarenkov, ulitsa Volgogradskaya 2, kv. 92, Omsk, Alexandr Vladimirovich Lappa, ulitsa Maslennikova 92, Omsk, Ivan Grigorievich Kirienko, Prospekt Kosmonavtov 36, kv. 71, Leningrad, USSR (SU) (7 * 0 Oy Kolster Ab (5 * i) Antenna switching device for multiple reception -

Coordination of antennas for antennas

The invention relates to an apparatus for automatic antenna switching in multipath reception according to the antenna diversity method, the apparatus comprising a main control device consisting of logical structural elements which provides control pulses for connecting the antenna to the antenna switch selection electronics.

As radio waves in certain frequency ranges progress, oscillation (fading phenomenon) occurs, which is characterized by varying the strength of the received signal reaching relatively high levels (up to 20-40dB), as well as varying the phase of the carrier.

This phenomenon arises in the ionosphere and troposphere and is related to the cases where an electromagnetic wave enters the receiving site through several different propagation channels. If the channel has a so-called ad-ditive interference, then the signal oscillation causes a situation in which the noise exceeds the signal in question at certain time intervals, with errors on the receiving side, although the value of the average relative noise level 1 noise ratio is considerable.

Multipath reception based on the use of multiple antennas is an effective way to eliminate the fading phenomenon. Due to the multipath method and related to either the signal polarization or the pitch of the location where the oscillation occurs, the antennas operate virtually independently of each other. Therefore, the better signal portions of the different antennas can be combined so that the usability of the obtained data content (data) is significantly improved compared to the reception with one antenna.

The probability of erroneous reception can then be calculated by a number coefficient of several tens.

In multipath reception, a multipath antenna array is commonly used, with each antenna having its own receiver; the signals are analyzed and then combined simultaneously from their outputs. Such a method is disadvantageous in that many receivers have to be used, whereby the size and cost of the equipment increase accordingly. However, there are also devices in common use that can directly combine antenna output signals when using only one receiver.

However, the latter devices are difficult to construct because it is almost impossible to analyze the signals simultaneously so that the correct antenna connection time and type can be determined for the best reception conditions. However, such conditions exist because only one receiver output signal is available for measurement. In such devices, the limit value of the antenna connection must be used. Po. according to the method, the signals of all antennas do not have to be measured, but the antenna is connected to the receiver, which gives a parameter that corresponds to a signal quality exceeding a predetermined reference level. However, if the signal quality is inferior to a predetermined level due to the fading phenomenon, the devices in question turn on and connect the antennas at the receiver input according to a certain successive period, so that an antenna is obtained that obtains a signal parameter exceeding a predetermined level.

An associated, already known device comprises an antenna switch in which the signal inputs are connected to the receiving antennas 3 72415 and the control inputs to the outputs of a multistable circuit (the so-called ring counter). One output is connected to the input of the receiver, the receiver comprising an intermediate frequency voltage connection (output) and an amplifier and an intermediate-frequency envelope indicator (intermediate-frequency envelope), which is used as a signal parameter meter. The device also has a comparator that compares the level of the signal envelope to the reference level determined by the reference level audio box. The output of the comparator is connected to the control input of the control unit, and the output of the control unit is connected to the input of the above-mentioned multi-position circuit, whereby a series of switching pulses are obtained depending on the signals at the control input.

Po. in the device, the control unit starts generating pulses at the moment when the comparator outputs a signal corresponding to the output signal of the detector, which is larger than the signal of the reference signal box.

As the signal level drops due to oscillation, the comparator generates a voltage that triggers a control unit that begins to generate a series of switching pulses at its output.

Each subsequent pulse affects the input of the multi-position circuit, so that po. the state of the circuit changes sequentially, corresponding to the state in which the next antenna is connected to the receiver.

The antenna connection is then continued until an antenna is found that provides a certain signal level. However, if no such antenna is found, the switching cycle is repeated.

Po. the device is advantageous in that it is simple in structure and can perform multipath reception without increasing the number of receivers. When using the optimal value of the reference level, the the device can receive data with higher accuracy; this can be compared to approximately the reception accuracy achieved in multipath reception using multiple receivers.

However, the efficiency of the device described above depends very much on the accuracy with which the reference level is determined.

If the reference level is too low, then the interference effects will exceed it. As a result, the control unit is not able to generate switching pulses and no antenna switching takes place. The device actually works 4 72415 so-called. as a single reception and cannot achieve better noise reduction.

If the reference level is again too high compared to the optimum amount, the device is on the search function for a significant part of the time. Since the reference level is not only a means of determining the transition of the device to the search function, but also of selecting the required antenna, the selection of the best antenna does not take place at the end of each search period; the power of the device is at a lower level.

The optimum value of the reference level changes very much due to the variation that occurs under the conditions under which the signal propagates. However, this occurs not only during the transition from one communication period to another, but also during a separate communication period. Adjusting the reference level value close to the optimum requires constant careful concentration by a professional. And the result, however, is that the power of the device is low under normal operating conditions.

Po. Another disadvantage of the device is that there may be additional noise at the switching points due to differences in the signal phase and amplitude in the different antennas.

The "most dangerous" connections occur when testing reception conditions in an antenna with virtually no signal and also in an antenna where the phase of the signal carrier differs from the signal phase in the case of the original antenna by about 180 °.

When receiving narrowband frequency electrification signals and phase modulated signals, such phase hops in the receiver output signal generally cause erroneous signal modulation.

Suppose that po. the known device has more than two antennas, the powers of which vary greatly during a given communication period, for example due to the combined effect of their radiation patterns, or because the orientation of the moving object comprising the antennas changes, or depending on the pitch of the antennas. Thus, during each paging period, the device sends a query to all antennas, i.e. also those antennas which, due to their poor orientation, do not receive any signals at all.

il 5 72415 As a result, more data is lost during the survey phase.

Ko. the device does not have any match between the repetition periods of the antenna interrogation periods and the signal jitter frequency. The repetition periods usually depend on the maximum value of the wobble frequency, which in turn causes harmful switching disturbances to occur when the wobble is relatively slow.

Therefore, the invention aims to develop a device for automatic antenna switching in multipath reception, which is equipped so that it can select from several antennas exactly an antenna with a better parameter than the output value, which is generally considered as a measure of the received signal quality. The device according to the invention is furthermore equipped so that it is possible to perform phasing of antenna signals by means of a carrier and also a two-phase antenna search. In this case, the multipath reception system is made to operate in the best possible way in all reception conditions and data is lost as little as possible during antenna connection.

The present invention is thus characterized in that the device comprises a signal combiner at the input of which the signals of the two receiving antennas are such that the signal of the first antenna is added together almost unimpaired, while the signal effect of the second antenna is only about 30-70 and the second antenna practically detaches from the signal combiner for the signal quality measurement and thus compares the original sum value thus memorized only with the new signal quality value of the first antenna and when the new value exceeds the previous one, this comparison triggers a 180 degree phase change of the second antenna and involves an antenna switching cycle , which provides better signal quality, via the main and auxiliary antenna switches as the first antenna to the signal adder.

Preferred embodiments of the invention are described in the appended subclaims.

The device according to the invention operates efficiently at all possible values of signal oscillation depth and frequency.

The invention will now be described in more detail by way of example with reference to the accompanying drawings, in which Fig. 6 72415 Fig. 1 shows an antenna switching device for multipath reception, Fig. 2 is a block diagram po. Fig. 3 is a block diagram of a device with two antenna inputs and received signal phasing and summing devices, Fig. 4 is a block diagram of an additional control unit of the device shown in Fig. 3, Fig. 5 is a block diagram of a phase inverter of the device shown in Fig. 3, Fig. 6 is a block diagram of the device summing unit of Fig. 3, Fig. 7 shows an antenna switching device for multipath reception (performs two-phase antenna selection), Fig. 8 is a block diagram of the dual channel antenna unit of Fig. 7, is a block diagram of a main control unit with additional outputs cooperating with the device of Fig. 7, Fig. 12 shows the connection of the outputs of a two-channel switch in a device with phase inverters in the signal circuits of the main switch, Fig. 13 is a structure of an antenna switching device used for dual in an ideal antenna selection, Fig. 14 is a block diagram of an additional logic unit used in the apparatus of Fig. 13, Fig. 15 shows an antenna switching device structure equipped with a signal parameter meter with an automatic current control amplifier and detector, Fig. 16 is a block diagram of a quantization unit 19 are pulse diagrams and illustrate the operation of the main control unit in three different cases where different signals are input to the input of the control unit, and Figs. 20 and 21 show pulse diagrams of the additional control unit. The main switch of the device according to the invention (Fig. 1) has two or more signal inputs 2 of antennas 3 and the same number of control inputs 4. Fig. 1 illustrates a single channel switch 1 with four signal inputs 2, four control inputs 4 and one output 5.

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When the control signal is applied to the control input 4 of the switch 1, a situation arises in which the switch output 5 receives a signal from the signal input 2 corresponding to the control input 4. The switch 1 is controlled by a multi-position circuit 6 having one input and a number of outputs corresponding to the control inputs 4 of the switch 1. The circuit 6 is constructed in such a way that it generates a control signal at only one of its outputs. When a switching pulse is applied to the input of the circuit 6, the circuit moves to a position for which there is a control signal at the output (the serial number in question). When the last position is reached, the circuit 6 moves to its first position, etc. A ring counter can be used in the circuit 6. The output 5 of the switch 1 is electrically connected to the input of the receiver 7, and the output 8 of the receiver is connected to a parameter meter 9 which measures a parameter reflecting the quality of the received signal. Such a parameter is usually an intermediate frequency voltage level measured in a frequency band that does not exceed the effective width of the spectrum of the signal in question. However, other measurements can also be used, such as the relative interference level 1. noise ratio and signal distortions.

For a comparator 10 with inputs 11 and 12, a conventional circuit or operational amplifier can be used. The phasing of the comparator should take place so that a signal occurs at its output when the signal at the first input 11 exceeds the signal at the second input 12.

The control unit 13 is intended to perform adaptive control for resetting the switch 1. The switching pulse output 14 of the control unit 13 is electrically connected to the input of the multi-position circuit 6. The control input 15 of the control unit 13 is in turn connected to the output of the comparator 10.

The pulse generator 16, which generates pulses at controlled intervals, determines the time at which the search for a new antenna 3 begins. The generator input 17 is connected to the output of the parameter meter 9. The interval between the pulses generated by the generator 16 depends on the value of the signal quality parameter in question and decreases as the quality deteriorates. If the signal quality parameter is voltage, any conventional generator circuit that can be controlled by voltage can be used in generator 16. In addition, the generator may have a locking device which operates when the measured parameter reaches a certain value which is greater than, for example, the biscuit value measured during signal jitter 8,72415. The conversion ratio between the time interval and the voltage should be chosen so that the average of the intervals of the output pulses is approximately equal to the autocorrelation interval of the fading random process.

The controllable memory element 18 takes care of storing the signal entering the data input 19 and transmitting it to the output when a pulse is applied to its control input. The data input 19 is connected to the output of the parameter meter 9.

The control unit 13 has a so-called the slave trip input 20 and the pulse shut-off output 21. The control unit uses standard logic elements. When the signal is applied to the slave triggering input 20, the output 14 generates a series of pulses. The first pulse in the series is generated regardless of whether there are 15 pulses in the control input, while the next pulses in the series are generated by the time a pulse encounters a signal at the control input 15. The pulse interval corresponds to the signal parameter measurement time measured by the meter 9. If no signal appears at the control input 15, the generation of pulses ceases, and the control unit is reset when the number of output pulses is equal to the number of inputs 4 of the main switch 1. During the time when the switching pulse train is generated, a continuous pulse is generated at the second input 21 of the control unit 13.

The output of the wood generator 16 is connected to the slave trip input 20 of the control unit 13.

Figure 2 shows a structure of a control unit 13 comprising a timing generator 22, a first flip-flop 23, a second flip-flop 24, a delay 25 for a timing pulse, an OR gate 26 and an AND gate 27, and a pulse counter 28.

The output of the thought generator 22 used for the output 14 of the control unit 13 is connected to the input of the delay 25 and the first input of the pulse counter 28, the output of the counter 28 being connected to the first input of the OR gate 26.

The first output of flip-flop 23 used for output 21 of control unit 13 is connected to the input of timer generator 22, while the second output of flip-flop 23 is connected to the reset input of pulse counter 28 and the first input of flip-flop 24, the second input of flip-flop 24 being connected to delay 25 output.

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The output of flip-flop 24 is connected to the first input of AND gate 27; the second input of the gate 27 is used for the input 15 of the control unit 13. The output of AND gate 27 is connected to the first input of OR gate 26, and the second input of gate 26 is connected to the output of pulse counter 28, while the output of gate 26 is connected to the first input of flip-flop 23. The second input of the flip-flop 23 is used for the input 20 of the control unit 13.

The block diagram of Fig. 3 shows a signal summing unit 29 with signal inputs 30, 31, a control input 32 and an output connected to the input of the receiver 7. The signal input 30 is connected to the output 5 of the main switch 1.

In the case of the signal input 30, a maximum transmission ratio of about one is selected for the summing unit 29. The input 31 transmission ratio is about 0.3 to 0.7 of the input 30 transmission ratio. The summing unit 29 comprises means for further reducing the transmission ratio of the input 31 when a signal is applied to the input 32.

The auxiliary switch 33 corresponds to the main switch 1 with two signal inputs 2. They are connected to the respective signal inputs 34 of the auxiliary switch 33. The control inputs 35 of the auxiliary switch 33 are connected to the respective inputs 4 of the main switch 1. The output of the switch 33 is connected to the summing unit 31

The signal circuits of switches 1 and 33 include phase inverters 36 and 37. Each has a signal input electrically connected to the respective antenna 3 and an output connected to the corresponding signal input 2 of the switch 1.

The phase inverters 36, 37 have pulse control inputs 38, 39 and reset inhibit inputs 40, 41, which are connected to the corresponding control inputs 4 of the main switch 1.

Phase inverter 36 (or 37) operates so that the signal goes to its output without phase variation or when the phase is rotated 180 °. The phase shifter 36 (37) enters the second position when a pulse is applied to its control input 38 (39), provided that no signal is applied to its reset input block (40).

The auxiliary control unit 42 has inputs 43, 44 and outputs 45, 46, 47, 48 and is intended to control phase inverters 36, 37 and a signal summing unit 29.

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The output 45 is connected to the control input 32 of the summing unit 29, the output 46 is connected to the control inputs 38, 39 of the phase inverters 36, 37, the output 47 is connected to the input 20 of the main control unit 13, the input 43 is connected to the output of the pulse generator 16, and the input 44 is connected to the output.

The auxiliary control unit 42 operates as follows. When a trip pulse is applied to input 43, a pulse is generated at output 45. When this pulse stops (its duration should correspond to the time required to measure the parameter in parameter meter 9), unit 42 generates (or does not generate) a short duration pulse at output 46, depending on whether there is a signal at control input 44 or no signal. A pulse is generated at output 47 when output 45, 46 has generated its pulse. The pulse continues at output 48 as long as outputs 45, 46 generate their pulses. The OR gate 49 comprises a device which connects the respective shut-off outputs 21, 48 of the control units 13, 42 to the control input of the memory element 18.

Figure 4 is a block diagram of the additional control unit 42.

The trigger circuit 50 has one output and two separate inputs, one of which acts with the input of the delay 51 as the input 43 of the control unit 42.

Delay 51 causes a certain delay for the pulse during the measurement of the signal parameter. Its output (51) is connected to the second input of the trigger circuit 50 and the first input of the AND gate 52, the second input of the gate 52 acting as the input 44 of the unit 42. Further, the output of the delay 51 is connected to the input of the delay 53. Delay 53 also causes a certain delay for the pulse during the measurement of the signal parameter. The output of delay 53 is output 47 of unit 42. The output of delay 51 is also connected to the first input of OR gate 54, with the output of gate 54 acting as output 48 of unit 42. The output of trigger circuit 50 connected to the second input of OR gate 54 acts as output 45 of control unit 42 .

Figure 5 shows a block diagram of a controllable phase inverter 36.

An antenna 3 is connected to the input of the phase inverter transformer 55, and the output of the transformer 55 is connected to the first switch 56.

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7241 5 11 to the output of the phase inverter 36, and the input of the transformer 55 is connected via a second switch 56 to the output of the phase inverter 36. Switches 56 are controlled by output signals from a complementary flip-flop 57, the input of which is connected to the output of a blocking circuit 58. The first input of circuit 58 is used for input 38 of phase inverter 36 and the second input is used for input 40 of phase inverter 36.

Figure 6 illustrates a block diagram of a summing unit 29.

The input 31 of the summing unit 29 is connected via a damper 59 and a controllable switch 60 to the second input of the adder 61; the inputs then have similar transmission ratios. The second input of the adder 61 is the input 30 of the adder unit 29, and the output of adder 61 acts as the output of the adder unit 29.

The dual channel antenna switch 62 (Fig. 7) has a number of inputs corresponding to the number of antennas 3. Switch 62 has two outputs, either of which can be connected to any antenna 3, but not to the same antenna 3. To this end, switch 62 has a device by which antenna 3 (any) connected to another channel is bypassed when sending a query to antennas 3 belonging to another channel. Both channels of switch 62 have a common switching input 62. The channels are controlled separately by supplying signals to the switch inhibit inputs 64. The outputs of the dual channel switch 62 are connected to the signal inputs 2 of the main switch 1, while the switch inhibit inputs 1 are connected to the control input 1.

The dual channel counter 65, which separately counts the number of switching cycles of the main switch 1 for each channel, during which the return to the respective channel takes place, has a count input 66 and an output 67 which generates a pulse when the other channel is in use. In addition, the counter 65 includes a reset 1. reset input 68 and separate inhibit inputs 69, 70 connected to the respective control inputs 4 of the main switch 1. The logic unit 71 used to control the dual channel switch 62 has a trip input 72 connected to the output 67 of the counter 65 connected to the reset input 68 of the counter 65 and to the switch input 63 of the switch 62. The logic unit 71 transfers to the output therein the pulses from the second input 73 from the moment the pulse appears at the first input 72 until the pulse appears at the third input 74. , or until the number of output pulses is equal to the number of antennas 3 minus one. The pulse generator 16 has an external trip control input 75 connected to the output of the logic unit 71, the function of which is to convert the device according to the invention to a comparison function, whereby the signals are compared whenever the two-channel switch 62 connects the antennas 3.

To perform the two-stage antenna search function, the main control unit 13 has additional outputs 76, 77. The output 76 connected to the input 66 of the counter 65 and the input 73 of the logic unit 71 is intended to indicate the state where the sum of switching pulses differs from one at the end of the operation period of the unit 13. The output 77, connected to the input 74 of the logic unit 71, again indicates that the sum of the switching pulses is one at the end of a certain operating period of the unit 13.

The dual channel antenna switch 62 (Fig. 8) has single channel switches 78, 79, the inputs of which are connected to antennas 3. The outputs 80, 81 of the switches 78, 79 act as the first and second outputs of the switch 62, respectively.

Switch 62 also has ring counters 82, 83 with respective control inputs 84, 85. In addition, switch 62 includes an OR gate 86, a blocking port 87, 88, the first inputs of which act as inputs 64 of switch 62, and AND gates 89, 90, 91, 92, the inputs of which are connected to the respective control inputs of the switches 78, 79 and the outputs of the ring counters 82, 83, po. the gate outputs being again connected via OR gate 93 to the input of timer generator 94. The repetition frequency of the pulses generated by the timing generator 94 is at least ten times the repetition frequency of the switching pulses generated by the main control unit 13 (Fig. 1).

The first input of OR gate 86 (Fig. 8) is connected to the output of timer generator 94, and its second input acts as input 64 of switch 62. The output of gate 86 is connected to the second inputs of block gates 87, 88.

Figure 9 is a block diagram of a dual channel counter 65.

Calculator 95 has a common reset input that is used

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13 7241 5 for input 68 of calculator 65. The other inputs of the counters 95 are connected to the outputs of the blocking gates 96, and the first inputs of the gates 96 are connected to form the input 66 of the counter 65. The second input of the first blocking port 96 is the input 69 of the counter 65 and the second input of the second blocking port 96 is the input 70 of the counter 65 The outputs of the calculators 95 are connected to the input of the OR gate 97, the output of the gate 97 being the output 67 of the calculator 65.

Figure 10 is a block diagram of a logic unit 71.

The flip-flop 98 has a first input 99 which acts as an input 72 of the logic unit 71, and its output (98) is connected to the first input of the AND gate 100, po. the second input of the gate being the input 73 of the logic unit 71.

The output of the AND gate 100, which acts as the output of the logic unit 71, is connected to the first input of the counter 101. The output of the calculator 101 is connected to the first input of the OR gate 102. The second input of the gate 102 is the input 74 of the unit 71, and the output of the gate 102 is connected to the second input of the flip-flop 98. The output of flip-flop 98 is connected via a NOT gate 104 to the second input (reset) of the counter 101.

Figure 11 shows the arrangement of the two additional outputs 76, 77 of the main control unit 13. The output of the AND gate 27 acts as the output 76 and the output of the pulse counter 28 as the output 77.

Fig. 12 illustrates the connection of the outputs of the two-channel switch 62 to phase inverters 36 and 37 located in the signal circuits of the main switch 1.

In order to be able to compare the standby antennas 3 (Fig. 13) during the interrogation operation with one, i.e. worse than the previously selected antennas, the device according to the invention is provided with an OR gate 105 and an additional logic unit 106. A signal from its first input 108 can be transmitted to the additional logic unit 106. The input 108 is then connected to the output of the main logic unit 71. In addition, a series of pulses can be generated at the output 107 of the unit 106, starting after the pulses appear in succession at its first and second inputs 108, 109 and ending when the sum of the pulses at the output 106 and the third input 110 of the unit 106 - excluding those pulses generated by the second input 109 between 14 s241 5 s and the next pulse of the third input 110 corresponds to the number of antennas 3. The pulse applied to the third input 110 of the unit 106 is then the pulse that appears at the auxiliary output 111 of the dual channel switch 62 at the moment when the current channel is bypassed. The additional output 111 connected to the third input 110 of the logic unit 106 is the output of the timing generator 94 of the switch 62 (Fig. 8).

The second input 109 (Fig. 13) of the logic unit 106 is connected to the output 77 of the main control unit 13, while the output 107 of the unit 106 is connected to the input 63 of the switch 62.

The output of the OR gate 105 is connected to the input of the multi-position circuit 6. The first input of the gate 105 is connected to the output 14 of the main control unit 13, and its second input is connected to the output 67 of the counter 65.

Figure 14 is a block diagram of the additional logic unit 106.

The first input of flip-flop 112 and the first input of AND gate 113 together form input 106 of unit 106. The first output of circuit 112 is connected to the second input of AND gate 113, and the output of gate 113 is connected to the first input of OR gate 114. The second input of gate 114 is connected to the output of timing generator 115, and the trigger input of generator is connected to the output of first flip-flop 116.

The output of the AND gate 117 is connected to the first input of the flip-flop 116, and the first input of the gate is connected to the first output of the flip-flop 112, the second input of the gate 117 being used for the input 109 of the unit 106.

The interval between the pulses generated by the timing generator 115 should be 1.5 to 2 times the generation of the timing generator 94 (Fig. 8) of the dual channel switch 6 2 with respect to the interval between the pulses.

The counter 118 of the unit 106 (Fig. 14) generates a pulse at its output connected to the second inputs of the flip-flops 112, 116 when the input of the counter receives so many pulses that their number corresponds to the number of antenna inputs of the dual channel switch 62 (Fig. 7). The reset input of the counter 118 (Fig. 14) is connected to the second output of the trigger circuit 112. The output of the OR gate 114, which acts as the output 107 of the unit 106, is connected to the first input of the OR gate 119. The second input of gate 119 is connected to the second input of trigger circuit 116, which acts as input 110 of unit 106. The output of OR gate 119 is connected to the first input of AND gate 120, and po. the second input of the gate is connected to the output of the trigger circuit 116 and the output of the gate to the input of the counter 118.

Fig. 15 shows a parameter meter 9 for measuring a parameter describing the quality of the received signal. The meter comprises an amplifier with automatic gain control and a signal envelope detector. The meter 9 has a locking input 121, a control voltage output 122 and a detector output 123. The pulse generator 16 with a controlled pulse interval has an additional input 124 for slave triggering. The output of the quantization unit 125 included in the device is connected to the input 124, and the output of the high-pass filter 126 is connected to the input 17 of the generator 16.

The amplifier of the parameter meter 9 has an automatic gain control circuit, which allows the signal envelope voltage to remain constant at the detector output 123 when the signal at the output 8 of the receiver 7 varies. The time constant of the auto gain adjustment should be less than the auto-correlation interval associated with signal jitter. Information related to the level of the received signal is included in the control voltage level. By selecting the element to be controlled by the amplifier, it is possible to determine the functional connection between the control voltage and the input signal level.

It is preferable to use an amplifier in which there is a logarithmic connection between the control voltage and the input signal voltage. Then, when the quantization unit 125, in which the quantization levels are evenly distributed, is placed between the control voltage output 122 and the slave trip input 124, the device can be switched to the search function whenever the level of the received signal decreases by the same factor.

During the search phase of the antenna 3, a blocking pulse is applied to the above-mentioned interlock input 121. Thus, the control voltage remains constant at a certain level, while the voltage at the detector output 123 varies according to the level of the received signal. The high-pass filter 126 between the output 123 of the parameter meter 9 and the control input 17 of the pulse generator 16 separates the control voltage component applied to the input of the filter 16 7241 5 126 from the DC component of the signal component, which has no signal oscillation information. The cut-off frequency of the filter 126 should not exceed the lowest frequency in the useful spectrum of the random process of signal jitter. Filter 126 may be an active filter circuit with an operational amplifier.

The quantization unit 125, in which the quantization levels are evenly distributed, may be in accordance with the block diagram shown in Fig. 16. Then, capacitors 128, 129 and diode 130 are connected to the first input of comparator 127. The output of the comparator is connected by a single-acting multivibrator 131 to the output of the unit 125, and the second input of the comparator 127 is connected to a reference level picker 132. The output of the single-acting multivibrator 131 is connected to the control input of the electronic switch 133.

The quantization unit 125 shown in Fig. 16 does not generate output pulses as the input voltage increases. This is not necessary in the multipath receiving device according to the invention with the unit 125, because in this case the signal reception conditions of the initial antenna 3 (Fig. 15) are improved. As the input voltage decreases, the output of unit 125 (Fig. 16) generates a pulse each time the voltage variation is determined as the value of the ratio between the value of capacitors 128, 129 and the reference level generated by pickup 132.

The device according to the invention (Figure 1) operates in the following way.

At the end of the search period, in which case one antenna 3, referred to above as the initial antenna, is connected to the receiver 7 by means of switch 1, the parameter meter 9 performs an evaluation of the present values of the measured parameters. Then, after some time - the length of time generally depends on the measured parameter - the pulse generator 16 generates a pulse which is fed to the input 20 of the control unit 13. From this moment the search period begins to find the best antenna 3.

The output 21 of the control unit 13 generates a pulse, whereby the memory member 18 switches to the memory function. In this case, the output of the memory element 18 determines the value of the parameter describing the quality of the received signal (this is the signal available at the beginning of the search phase), namely the signal from the initial antenna 3.

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The main output 14 of the control unit 13 for the time now forms a series of switching pulses which affect the input of the multi-position circuit 6, so that po. the circuit 6, when all the pulses have been input, moves to the next position corresponding to the situation when the respective antenna 3 is connected to the receiver 7. The first pulse appears at the output 14 at the beginning of the search period without conditions, meaning that its occurrence does not depend on whether there is a signal 15 in the control input of the control unit 13. Therefore, the connection from the initial antenna 3 to the next antenna takes place automatically. The generation of additional switching pulses again depends on whether there is a signal at the input 15 of the control unit 13 at the moment corresponding to the the appearance of a pulse. If the comparator 10 does not generate that signal, which in turn means that the reception conditions of the test antenna 3 are worse than in the initial antenna 3, the control unit 13 stops generating pulses at its outputs 14, 21 until the next search period begins (first query for all antennas 3 and return). the first antenna).

It is assumed that the comparator 10 indicates an improvement of the measured parameter compared to the data stored in the memory element 18 just at the moment when the switching pulse in question appears. This then means that an antenna 3 is connected to the receiver 7, which has better reception conditions than the initial antenna 3. In this case, the switching pulses stop and the control unit 13 is reset.

The device operates in such a way that it successively compares the reception conditions of the antennas 3 so that the receiver can be connected to the best antenna. This maximizes multipath reception. The operation of the control unit 13 of Fig. 2 described above is illustrated in pulse diagrams in Figs. 17, 18, 19, which correspond to three different cases as follows: Fig. 17 illustrates a situation where there is no signal at the control input 13 (Fig. 1) during the general search period; a situation in which, after the two connections of the antennas, there is a signal at the control input 15 (Fig. 1) (Fig. 18c), and the quu. 19 shows a situation in which the comparator 10 (Fig. 1) generates a signal after the first connection of the antennas 3.

18 7241 5

Figures 17a, 18a and 19a show a pulse at the input 20 of the control unit 13 (Figure 1). Figures 17b, 18b and 19b show a pulse at output 14 (Figure 1), and Figures 17c, 18c and 19c show a pulse at output 21 (Figure 1).

The circuit shown in Figure 2 comprises logically structured elements operating in a manner known to those skilled in the art.

The device according to the invention shown in Fig. 3 operates as follows: Before the search step, the signals received by the two multipath antennas 3 are fed to different inputs of the summing unit 29, because the shift control takes place by means of the main switch 1 and the auxiliary switch 33. The summing unit 29 performs the summation of these signals by means of various coefficients; the larger one is related to the channel of the main switch 1 and the smaller one to the channel of the auxiliary switch 33. The sum of the signals is then fed to the input of the receiver 7. It should now be noted that the phase inverters 36, 37 have not been reset, and the transfer ratios of the summing unit 29 do not vary between search periods.

When the search period in question begins, the generator 16 generates a pulse which triggers the additional control unit 42. This tests the carriers of the signals summed for correct phasing and corrects one phase of the signal if necessary. This is the signal applied to the input of the unit 29; the transmission ratio is lower. In order to perform the phase test correctly, the output 45 of the unit 42 generates a pulse whose duration corresponds to the time required to evaluate the signal parameter in the parameter meter 9. Po. the signal is then applied to the control input 32 of the summing unit 29. During the input of the pulse, the transmission ratio of the unit 29 (input 31) is close to zero. At the same time, the control unit 42 acts on the memory element 18 via the OR gate 49, so that this switches to the memory function.

When the pulse stops at output 45, the comparator 10 determines the increase in the signal quality parameter.

If the quality of the output signal of the receiver 7 has deteriorated, this is an indication that the phasing of the signal carriers before summation (in unit 29) had been performed correctly. In this case, the unit 42 does not generate signals at its output 46.

When the reception conditions have improved after the elimination of one summable signal, which means that the phase difference of the signal carriers is more than 90 °, the unit 42 generates its output.

II

19 7241 5 at the end of the pulse in the pulse 45 at the output 46 of the short-term pulse connected to the inputs 38, 39; for pulse control of phase inverters 36, 37.

Since the inputs 40, 41, which prevent the resetting of the phase inverters 36, 37, are connected to the corresponding control inputs of the switch 1, po. the pulse causes the second phase inverter 36, 37 to change state. In this case, it is a translator dealing with a signal temporarily deducted from the amount. The signal is then added to the sum again when its carrier phase is corrected.

When phasing is complete, the pulse at output 48 ceases. Therefore, the value of the signal parameter is corrected in the memory element 18, and the output 47 of the unit 42 generates a pulse which is used to trigger the main control unit 13.

From this point on, the device operates in a manner similar to the device of Fig. 1, except that the main and auxiliary switches 1, 33 are connected simultaneously.

The search period ends when the main switch 1 connects the antenna 3 with the best signal parameter value to the first input 30 of the summing unit 29 and the auxiliary switch 33 then connects the second antenna 3 to the second input 31 of the summing unit 29.

Thus, the device performs signal synchronization before connecting the antennas 3. In addition, it performs signal summation during and after switching so that the better signal gets a higher factor and the worse signal gets a smaller one.

Since the sudden variation of the phase and amplitude of the signal fed to the input of the receiver 7 by the device according to the invention is made very much smaller, the multipath reception now takes place at an efficient level.

The operation of the auxiliary control unit 42 is illustrated by the pulse diagrams of Figs. 20, 21, which either have no or have a pulse that controls the resetting of the phase inverters 36, 37 (Fig. 13).

Figures 20a and 21a show a pulse at trip input 43 (Figure 3) and Figures 20b and 21b show a pulse at output 45 (Figure 3). Figures 20c and 21c show the signal at control input 44 (Figure 3), and Figures 20d and 21d show the pulse at output 46 (Figure 3). Figures 20e and 21e show the pulse at output 47 (Figure 3).

20 7241 5

The auxiliary control unit 42 (Fig. 4) uses logical elements of normal structure, the operation of which is already known to those skilled in the art.

In the controllable phase inverter 36 shown in Fig. 5, one switch 56 is closed and the other is open again, depending on the state of the trigger circuit 57. When there is no signal at the inhibit input 40, the pulse applied to the input 38 passes through the inhibit port 58, and the trigger circuit 57 enters another state. In this situation, the phase of the signal passing through the phase inverter 36 changed 180 °.

In its initial position, the switch 60, which belongs to the summing unit 29 of Fig. 6, is closed. When a pulse is applied to the control input 32 of the unit 29, the switch 60 opens, and the transfer ratio of the unit 29 to the second input 31 decreases even more. The device shown in Figure 7 operates as follows. The signals applied to the signal inputs 2 of the main switch 1 are processed in the same way as in the device of Fig. 1, which has already been described above. However, the difference is that at the end of each work cycle of the main control unit 13 (Fig. 7), the usability of the performed search cycle is determined.

If the search period during which the conditions of the main switch 1 change ends, po. the switch returns to the state it was in before the search operation began, it is considered to have failed. This is confirmed when a pulse is generated at the first additional output 76 of the main control unit 13.

If the above situation does not occur, the application period can be considered successful; the pulse appears at the second auxiliary output 77 of the main control unit 13.

In the case of a switch 1 with two inputs 2, a failed search cycle causes two switching pulses to be generated at the output 14 of the main control unit 13. If the search cycle is successful, only one pulse is generated. In the dual channel counter 65, the failed search operations are counted separately for the first and second inputs 2 of the switch 1.

The 65 channels of the calculator have equal capacities. The capacity of each channel is selected using a feasible relationship between the interrogation period of all antennas 3 connected to the dual channel switch 62 and the interrogation period of the two antennas 3 connected to the two signal inputs 2 of the main switch 1 by the switch 62.

Il 21 7241 5 This ratio is usually 10-20. If the channel capacity of the calculator 65 is e.g. 10, then the accumulation of 10 cycles of the failed search function (in which case a certain antenna 3 is used) causes one channel of the calculator 65 to become completely full. As a result, the output 67 generates a signal which affects the first input 72 of the logic unit 71, whereby the device starts to process the remaining or standby antennas 3.

At that time, the better initial antenna 3 (a total of 2) is connected to the input 2 of the main switch 1.

The logic unit 71 operates according to its algorithm and transfers to its output a pulse which is applied to the second input 73.

A pulse acting on the switching input 63 of the dual channel switch 62 switches the antennas 3 in the channel free from switching blocking, i.e. in the channel where a worse initial antenna 3 was selected (tot.

2 pieces).

At the same time po. the pulse resets the dual channel counter 65 and starts the main control unit 13 by means of an external trip input 75 of the pulse generator 16.

The device then starts to compare the reception conditions for the better initial antenna 3 and one standby antenna 3 connected to the second signal input 2 of the switch 1.

If the signal of the standby antenna 3 is worse, then the appearance of a pulse at the output 76 of the unit 13 causes the logic unit 71 to generate the next pulse, and the switch connects the next standby antenna 3 instead of the tested antenna. These operations are then repeated until all the standby antennas 3 have been queried or a pulse has appeared at the additional output 77 of the main control unit 13, indicating that an antenna 3 which is better than the better antenna of the initial antenna pair 3 has been found.

The dual channel switch 62 remains in this state for the entire processing time of the selected antenna pair 3. When one channel of the counter 65 is completely full, the interrogation period of the standby antennas 3 is repeated again.

Thanks to the two-stage interrogation function of the antennas 3, the power of the device is higher when the operating conditions cause the antennas 3 to be oriented differently in the direction of the received signal, po. as the orientation changes during the communication period. The increase in the efficiency of the device according to the invention is due to the fact that the 22 72 4 1 5 antennas 3 which do not receive a signal cannot be selected by the two-channel switch 62, and are interrogated considerably less frequently than the main antenna pair 3.

The two-channel switch 62 shown in Fig. 8 operates as follows. Initially, the channel switches 78, 79 connect both antennas 3 to the respective outputs 80, 81, which act as the outputs of the dual channel switch 62.

Connecting antenna 3 to the two outputs has been eliminated. In this case, the ring counters 82, 83 are in a similar state and one AND gate 89-92 generates a signal which starts a timing generator 94 via the OR gate 93. This again generates an output pulse which passes through the OR gate 86 and also the second blocking port 87, 88 and receives causing the second ring counter 82, 83 to move to the next position corresponding to the free antenna 3 in the second channel.

The pulses applied to the switching input 63 pass through the OR gate 86 to the inputs of the blocking ports 87, 88 and further through a port whose signal has no signal at the blocking input.

The dual channel counter 65 operates in a manner known to those skilled in the art.

The logic unit 71 of Fig. 10 starts operating at the moment when a pulse appears at the first input 72 of the unit 71. As a result, flip-flop 98 begins to operate, and its output generates a logic "1" pulse which is applied to the input of the AND gate 100 and the input of the NOT gate 104. As a result, the AND gate 100 transfers the pulses at the input 73 of the unit 71 to its output, while instead the signal at the output of the NOT gate 104 ceases (counter 101 in the zero state).

The operation cycle of the logic unit 71 ends when the flip-flop 98 is reset, which occurs when a signal is applied from the output of the counter 101 or the input 74 of the unit 71 to the second input of the trigger circuit 98 via the OR gate 102.

A pulse indicating that the interrogation period of the initial antenna pair 3 (Fig. 7) ends with the change of antennas appears at the output of the AND gate 27 (Fig. 11) of the main control unit 13 (Fig. 11) because the output signal of the second flip-flop 24 and the pulse at the control input 15

II

! Ί 23 7 2 4 1 5 occur simultaneously. If this is not the case, the output 77 generates a pulse when the initial antenna 3 (Fig. 7) is reselected and the counter 28 (Fig. 11) is full.

The device of Fig. 12 operates in a manner similar to the device of Fig. 7. In this case, the characteristics of the device of Fig. 3 have been taken into account. Thus, the device of Figure 12 combines the advantages of the devices shown in Figures 3 and 7.

The device 13 operates in such a way that the standby antennas 3 are compared during the interrogation operation with the worse and not the better of the previously selected antennas 3, as in the case of the devices shown in Figures 7 and 12. The device according to Figure 13 operates as follows. When the second channel of the two-channel switch 65 (Fig. 13) is full, the output 67 generates a pulse which causes the device to start, i.e. the interrogation of the standby antennas 3 begins. As a result of this pulse passing through the OR gate 105, the circuit 6 (flip-flop) switches to its previous state. In this case, the main switch 1 operates and supplies to the receiver 7 a signal from the antenna 3, which has poorer reception conditions.

The first pulse from the output 107 of the auxiliary logic unit 106, which goes to the switching input 63 of the two-channel switch 62, causes the better antenna 3 to be replaced by a standby antenna.

The device then compares the reception conditions of the remaining and newly connected antennas 3.

If the new antenna 3 gives a signal of lower quality, then at the end of the comparison function and when a pulse appears at the output 76 of the unit 13 and when the respective pulses appear at the input 108 and the output 107 of the unit 106, the next standby antenna 3 is selected.

If the results of the analysis are negative, the switching process ends when the two-channel switch 62 is reset, whereby its outputs connect the initial antenna pair 3.

If one of the standby antennas 3 is better than the worse antenna of the initial pair, then after the query, the switch 1 remains in the state in which it connects po. to the antenna receiver 7, and the output 77 of the main control unit 13 generates a pulse which is applied to the second input 109 of the auxiliary logic unit 106.

From this point on, the unit 106 quickly performs the successive connections of the two-channel switch 62. When this phase is completed, the inferior antenna 3 connected to the main switch 1 is replaced by a better antenna which is temporarily disconnected before the interrogation phase of the standby antennas 3 begins.

24 7241 5 To this end, the unit 106 starts generating pulses at its output 107 when a pulse is applied to its second input 109.

Because po. the pulses affect the input 63 of the dual channel switch web 62, they provide a fast switching phase in the channel where the inferior antenna from the initial antenna pair 3 was selected.

The connection ends when the better antenna of the initial antenna pair is selected in the channel. This time is determined as follows.

When a pulse is sent to the input 109 of the auxiliary logic unit 106, the counter 108 (Fig. 14) stops counting. The counter 108 is locked until the pulse from the two-channel switch 62 appears at the input 110 of the unit 106, which again means that when switching, the so-called pulse of the channel switches 78, 79 (Fig. 8) has been detected. coincident. From this point on, the counter 118 of the unit 106 (Fig. 14) continues to count the pulses at its output by adding them to the pulses that have appeared at the input 110 after the start of the interrogation period of the standby antennas 3 (Fig. 13).

When the sum of the pulses of the counter 118 (Fig. 14) corresponds to the number of antenna inputs of the dual channel switch 62 (Fig. 13), the auxiliary logic unit 106 terminates its operation and is reset.

In this case, the better antenna of the initial antenna pair 3 is selected in the switched channel of the switch 62.

Since the standby antennas 3 are compared to the antenna of the initial antenna pair which is not a better antenna, the device according to Fig. 13 detects a better standby antenna even when the signal of the better antenna of the initial antenna pair is not worse than in the case of standby antennas. This situation occurs in antennas with very different gains and when signal flicker is low.

The additional logic unit 106 shown in Fig. 14 operates as follows. With unit 106 in its initial position, the signals at the first output of flip-flop 112 and the output of first flip-flop 116 are logical zeros, while the signal at the output of second flip-flop 116 is logical one.

A logic one (1) at the second output of flip-flop 112 affects the reset input of the counter 118 and keeps the counter in the zero state.

When a pulse is applied to input 108, logic 1 appears at the first output of flip-flop 112 and then goes to the inputs of AND gates 113, 117, while logic 0 is at the second output of circuit 112.

25 7241 5

The input pulse passes through AND gate 113 and OR gate 114 and is fed to counter 118 via OR gate 119 and AND gate 120.

If no pulse is applied to input 109, then all subsequent pulses that affect input 108 pass through the same circuits, and counter 118 counts these pulses by adding them to the pulses entering output 110 and the pulses passing through gate 119.

When the counter 118 is full, its output generates a pulse which is used to reset the trigger circuit 112.

If a pulse is applied to input 109, which is used to reset the trigger circuit 112.

If a pulse is applied to input 109 before counter 118 is filled, it passes through AND gate 117, whereby the first trigger circuit 116 enters a state where its output generates a logic one (1), while a logic zero (0) is generated at the output of the second flip-flop 116. . As a result, the timing generator 115 starts, and the AND gate 120 prevents the respective pulses from entering the input of the counter 118 until a pulse is applied to the input 110 of the unit 106, which returns the second flip-flop 116.

The counter 118 then continues counting, i.e., it counts the pulses passing through the AND gate 120. When the counter 118 is full, it resets the flip-flop 112 and the first flip-flop 116.

The search period repetition period is adjusted to the signal jitter depth and frequency in the device shown in Fig. 15 as follows: Between two paging cycles, an amplifier with automatic gain control belonging to parameter meter 9 monitors the received signal jitter, so the signal remains approximately constant at output 123. The control voltage of the amplifier at the output 122 of the parameter meter 9 is applied to the input of the high-pass filter 126 and the input of the quantization unit 125. The AC component of the envelope level caused by signal oscillation is applied to the main input 17 of the pulse generator 16. The generator 16 is designed so that a change in the control voltage in a direction corresponding to a certain decrease in the received signal level causes a certain decrease in output pulse interval. Therefore, the repetition period of the search periods can be adjusted to the depth of the jitter.

26 7 2 4 1 5

Increasing the repetition period of the search cycles as the frequency of the signal jitter increases is possible because a change in the control voltage of the amplifier by a certain value causes the quantization unit 125 to generate a pulse affecting the input 124, whereupon the pulse generator 16 starts. The quantization function is selected so that the generator 16 starts each time the signal level decreases by a factor of 1.5-2 with respect to the maximum value measured in the time interval in question. Since the lock input 121 is connected to the control input of the memory member 18, the gain of the amplifier is locked when the reception conditions of the interrogated antennas 3 are compared. In this case, the signal level at the output 123 of the parameter meter 9 varies exactly in a manner corresponding to the variation of the signal at the output 8 of the receiver 7.

Units 9, 16, 125 and 126, when used in other structures of the device described above, then operate in the same manner.

Operation of the quantization unit 125: A pulse appearing at its output affects the control input of the switch 133 so that the switch closes. In this case, the potential of the point connecting the capacitors 128, 129 is zero.

Since the potential generated by the reference level picker 132 is maintained at the second input of the comparator 127, the comparator is reset and the single-acting multivibrator 131 is not started in this case.

As the input voltage of the unit 125 increases, the potential of the contact point of the capacitors 128, 129 does not vary, even if the switch 133 is open after the output pulse has stopped. This is because the charge current of the capacitor 128 passes through the conducting diode 130, leaving the comparator 127 in its initial state.

As the input voltage decreases, current flows through capacitor 128 in the opposite direction, diode 130 no longer conducts, and capacitor 129 charges. The increase in voltage of capacitor 129 is proportional to the current, which in turn is proportional to the quantitative calculation of voltage at the input of unit 125.

When the voltage of the capacitor 129 and the voltage generated by the reference level picker 132 are equal, the comparator 127 generates a pulse which starts the single-acting multivibrator 131. Thereafter, the operation cycle of the unit 125 is repeated again.

27 7 2 4 1 5

Since the repetition period of the paging periods is independent of the depth and frequency of the signal oscillation, the data loss due to inappropriate connections of the antennas 3 (Fig. 15) is minimal. As a result, the device according to the invention has a better operation.

Claims (5)

7241 5 28 An apparatus for automatic antenna switching in multipath reception according to the antenna-diversity method, the apparatus comprising a main control device (13) consisting of logical structural elements, which provides control pulses for connecting the antenna to the selection electronics (6) of the antenna switch (1). -frequency and signal quality value are constantly recorded in the memory device (18), characterized in that the device comprises a signal counter (29) at the inputs (30,31) of the signals of the two receiving antennas so that the signal of the first antenna (at 30) is while the signal of the second antenna (at 31) has an effect of only about 30-70 and that at the beginning of the search period the second antenna practically disconnects from the signal adder (29) for the signal quality measurement (device 9) and the original sum 18) compare only to the new value of the signal quality of the first antenna, and when the new value exceeds the previous one, this comparison triggers a 180 degree phase change of the second antenna, and that an antenna switching period is involved, which switches the antenna with better signal quality to the main and auxiliary antenna switch (1 -33) as the first antenna to the signal adder (29) (Figure 3). Device according to Claim 1, characterized in that only two antennas (2) out of the number n antennas (3) are connected to the main antenna switch (1) via the two-channel antenna switch (62) and that the signal quality of the two antennas is determined periodically until a predetermined number of measurement results indicating that the signal quality of the second antenna is inferior to that of the other, this detection being performed by a two-channel counter (65) which, when the preset number is reached by the main control device (13), starts a search period together with the logic device (71); , with which the remaining number of n-2 antennas are examined in order until an antenna better than that still present in the main switch (1) is found, or until the initial state is reached again (Fig. 12). Il 29 7241 5 Device according to Claim 1 or 2, characterized in that devices for phase correction (36, 37) are arranged between the outputs of the two-channel switch (62) and the inputs of the main antenna switch (1). Device according to Claim 2 or 3, characterized in that the OR element (105) uses a surplus of one counter of the two-channel counter (65) to compare the signals from the two-channel antenna switch (62) by means of the selection electronics (6) of the main antenna switch (1). the worse signal of the antenna signals to the signals of the n-2 backup antennas (3) in subsequent search cycles (excerpt from the switch diagram in Fig. 13). Device according to one of Claims 1 to 4, characterized in that in order to adjust the frequency of the repetition frequency of the controlled pulse generator (16) to the fading depth (amplitude change) and frequency (fading frequency) of the fading intervals 126), the cut-off frequency of which is below the average of the fading frequency, is connected so that when the gain is adjusted downward, the pulse frequency of the pulse generator (16) decreases, and on the other hand this control voltage is connected to a quantizer (125) with an electronic switch (127), a series connection of the capacitors (128,129) and a single lever (131) provide the pulse generator (16) with a number of pulses corresponding to the fading frequency (circuit diagram excerpts in Figures 15 and 16). 30 7241 5