DE3490533T1 - Diversity combiner - Google Patents

Description

Diversity combiner

Technical area

The present invention relates to a diversity combiner in accordance with the preamble of
following independent claim.

Background Art

In one type of diversity reception of radio signals, in which the signals impinge on separate receiving antennas, the signals being converted into in-phase signals which are combined into one signal to be fed to a demodulator, the combined signal is sent to the facilities
is fed back or fed back, in which the received signals are converted into signals in phase
will. The principle of such a feedback or feedback is reproduced by I. Granlund in "Topics
in the design of antennas for scattering ", Lincoln Lab, MIT, Cambridge, Techn. rep 135, Mass. USA, November 1956.

In diversity combiners, which were produced according to the principle, it was common that the incoming
received signals with their frequencies a multiple

Mixing process or have been exposed to cause in-phase signals at a different frequency
than that of the incoming signal. The property of the high frequency mixer, an output signal in the form of a
Output AC voltage with a phase angle which is the sum or difference of the phase angles of the input

gnale is used in such a case. An example of an apparatus completed in this way is described in patent CA-A-1141437. The Insertion of signals with multiple frequencies than with incoming Signal, however, has the accompanying disadvantage that false signals can be formed, which influence each other with the desired signal in certain conditions. In addition, a Large number of matched bandpass filters in the device ~ compels.

Disclosure of the invention

In accordance with the present invention, the high frequency mixer is used for each received signal as completes a modulator which is capable of being controlled by a signal having a zero frequency and which includes a DC voltage which is connected to the modulation input of the modulator; In addition, a phase shifter is provided, which for each of the radio signals before the phase-sensitive detector is arranged to convert the radio signals into a sub-signal, which forms an in-phase signal, and a sub-signal is divided, which forms a phase shift signal.

With a diversity combiner designed in this way, the effective prevention of false signals caused by the appearance of signals in the device which achieved have some different frequencies.

Another advantage of the device designed in accordance with the invention is that it is simpler in its construction than the devices manufactured earlier

is because only a simple low-pass filter is required for the signal coming from the detector, while the earlier device required band-pass filters for corresponding high-frequency auxiliary signals.
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Best description of the drawings

A device according to the invention is hereinafter referred to described on the accompanying drawings, in which

Fig. 1 basically shows the circuit of the diversity combiner represents

Fig. 2 shows the characteristics of a phase sensitive detector,

Fig. 3 shows the characteristics of a modulator, Fig. 4 shows the characteristics of the detector and modulator represents in cooperation,

Figures 5 and 6 are vector diagrams for the undervoltage, both before and after processing in one of detectors and modulators, and Fig. 7 (a, b, c) a wiring diagram for a completed Represent the diversity combiner.

Description of an exemplary embodiment

The diversity combiner of the type of the present invention is intended the combination of radio signals that hit two separate receiving antennas. The radio signals have the same frequency and the same information content. A high frequency amplifier is with every antenna linked, as well as a number of mixer stages with local oscillators and assigned intermediate frequency amplification stages, in order to successively

gnal down to a final intermediate frequency, in in this case 460 kHz. The received radio signals are frequency-modulated with audio signals or digital frequency shift signals (Frequency shift keying FSK). The devices mentioned are so far of known training and are therefore not described further. The intermediate frequency signals are the input signals for the diversity combiner.

The gain from the antenna to the intermediate frequency signal is the same for both signals, this being done by adaptation of the device was achieved.

The input signals are at such a low level that the linearly operated circuits of the diversity combiner result in a dynamic range of at least 40 dB above the noise level of the input signals.

Both input signals can have different levels and different phase angles due to the fading. It is therefore the task of combining the signals with the aid of the diversity combiner into an output signal with a given level for forwarding to a detector.
25th

For this purpose the combiner is suitable to convert each of the input signals into a new signal with the same phase angle to convert like that of a reference signal with the same frequency. The actual phase angle of the Reference signal has no meaning.

The principle of signal processing in the combiner is first described with reference to FIG. 1. An entrance

signal S, which is also called S ₁ . is mentioned for reasons that will become apparent later, is amplified in an amplifier 1 with limitation and is fed to a phase-sensitive detector 2, where its phase angle is compared with a reference signal on a line A. The output signal at B has a magnitude which is a function of ^ P, which is the phase difference between the two supplied AC voltage signals. Basically, it is a DC voltage that is separated from the intermediate frequency, but that contains other superimposed signals. The amplifier 1 and the phase detector 2 are combined in an integrated circuit Z6, here of the TBA 1205 type. The circuit is conventional and is therefore not described further.

A low pass filter 3 is used to filter out the output signal inserted by phase detector 2.

The filtered output signal from the phase detector is used in a modulator Z2 _{to modulate the original signal S 1} at the intermediate frequency so that the output signal of the modulator at C is an AC voltage with a frequency equal to the intermediate frequency, with a magnitude of S ₁ .cos ^) and with a phase angle · -, which is equal to the phase angle of the reference signal at A. The modulator is an integrated circuit here of the type MC 1596. The circuit is conventional and is therefore not described further.

The operation of the phase detector 2 in cooperation with the modulator Z2 will now be described with reference to FIG. The output voltage u at B in Fig. 1 depends on the phase difference ψ> in the diagram

illustrated way. In the modulator Z2, its inclination or gradient , ie (output current / input voltage), which is measured in Siemens (S), changes as a function of the control voltage u, in the manner shown in the diagram according to FIG. A combination of the two diagrams shows that the gradient G of the signal S ₁ . changes as a function of the phase angle <p in a manner illustrated in the diagram according to FIG. 4. To a good approximation, the gradient is proportional to cos <p. .

In order to enable the restoration of the input signal S ₁ with unchanged amplitude when the information relating to its phase angle is transmitted by the DC voltage signal from the phase-sensitive detector, S _{1 is divided} into two _{sub-signals S 1.} , Which is equal to S ₁ , and S ₁ divided, which is phase shifted in a positive direction by a phase shifter 4 by 90 °; this is referred to as the phase shifter signal, see. Fig.

1. The signals are shown in the vector diagram of FIG. The phase-shifted signal S ₁ is processed in a phase detector Z7 and a modulator Z3, which are identical to the units Z6 and Z2 described above. The sub-signals are added after their processing at D of Fig. 1, where the sum signal can be referred to as S ₁ '. The following relationship then applies:

S ₁ = S ₁ JCOs ψ ^ + S ₁ cos (U ^ ₁ + 90) = S ₁ -. cos GZ ₁ - S ₁ sin UP ₁

A sum vector is created with the size S ₁ by vector addition of the two contributions to S ₁ 'according to Fig. 6 and having a phase angle which exceeds the reference voltage with the

3A90533

agrees, since the sizes of S ^ and S. are both equal to the Size of S. are.

The second signal S is shown in exactly the same way Processed circuits which are suitable for this, in such a way that a sum vector is formed from it, namely as follows:

* + S _2q CO ₈ (^ ₂ ♦ 90 °) = S ₂ . .

with the size S2 and with a phase angle that is also corresponds to that of the reference voltage.

The signal voltages are now in phase and are added in an adding amplifier Z8. The sum signal at E in Fig. 1, which contains the entire frequency modulation that _{contained the input signals S 1} and S2, is emitted by the diversity combiner and forwarded for processing in a subsequent frequency detector 5. The output amplifier in Z8 for the sum signal is limiting, so that the output signal has a constant and a fairly high level.

It is typical of the diversity combiner like the one here it was described that the reference voltages, which in all phase-sensitive detectors Z6, Z7, Z9 and Z10 were used, are taken from the output voltage at E, i.e. they are fed back or fed back. By avoiding a special oscillator for generating a reference voltage at the frequency of the input signals it became possible to avoid false signals that usually occur in other cases when a change

voltage from a special oscillator with the input signals is mixed. In this device, according to the invention, the content is frequency modulation of the reference voltages the same as that of the input signals, with the result that the signals received by the detectors Z6, Z7, Z9, Z10 were fed back, no frequency modulation included, since the modulation in both voltages supplied cancel each other out.

It should be mentioned that the feedback circuit for the reference voltage has a bandwidth of 3 kHz, which is essentially determined by the low-pass filter 3 etc.

The completion of the diversity combiner is illustrated in detail in the circuit diagram of FIG. The designations of the integrated circuits in this line diagram are the same as in FIG. 1. Buffering and phase shifting by 90 ° of the input signals S ₁ and S2 are carried out by NPN transistors V5, V6 and by the oscillator circuits L1C2 and L.2C4, which are based on the Carrier frequency of the input signals are matched. The phase shifted S ₁ and the non-phase shifted S .. sub-signal are fed to the amplifier input in limiters, i.e. input 14 at Z6 etc. and in push-pull modulators, input 1 at Z2 etc.

The combined output of the diversity combiner is formed by connecting the signal C from the outputs 6 of the four push-pull modulators Z2 to Z5 with a common load, the tuned circuit L3C46. The The combined signal is limited in the Z8 and as a symmetrical or equilibrium signal E at the outputs 6 and

10 and fed back as a reference signal A to the inputs 7 and 9 in the four phase detectors Z6, Z7, Z9, Z10. The signal output for modulation is on
Get exit 8. Resistors R35 etc. determine the level of the output signal. The RC Filger C15R21C27 etc.,

which corresponds to the low-pass filter 3 in Fig. 1 is inserted, to filter out the radio frequency and set the control circuit bandwidth to about 3 kHz.

The modulation signal B is fed to the input 7 of Z2 and so on. A bias voltage is picked up by the potentiometer R66 and fed to the balancing input 8. The bias is obtained by supplying a current to Z6 to Z10, which flows through resistor R48. The supply

supply current changes with the temperature of the device and
thus the bias voltage at input 8 also changes
and some amount of compensation for the temperature change is obtained.

The preload for the amplifier stages in Z2 to Z5

is obtained by voltage division R17R18. The limiters have built-in bias networks.

The required bias voltages for the modulator inputs from Z2 to Z5 are obtained by supplying them with +11 V. The limiters are supplied with +8 V.

The amplifier Z8, which is also of the type TBA 1205 here, contains a superfluous detector, the frequency detector is used for the diversity combiner output signal E. The phase shifter reference voltage for this Detector is obtained from the balanced circuit L4C40. The demodulated signal appears at output 8.

Claims (1)

Patent claims: 1. Diversity combiner for adding before demodulation two or more received radio signals that have defined carrier waves of the same frequency, the combiner for each of the radio signals (S ₁ ; S ") having a phase-sensitive detector (2), which by a reference signal (A) is controlled, which is common to all detectors and has an output signal which contains information relating to the phase angle of the radio signal and a device (Z2-Z5) which is determined by the output signal of the associated phase-sensitive detector (2) is controlled in order to convert the radio signal into an alternating voltage signal (C) with the same phase angle as that of the reference signal (A), and for all radio signals together an adder (Z8) contains for adding the in-phase alternating voltage signals from the conversion device (Z2-Z5 ) to a sum signal (E) in which the received radio signals are added, the sum ignal (E) is connected to the control inputs of the phase-sensitive detectors (2) in order to act there as a common reference signal for all detectors associated phase-sensitive detector (2) are suitable, this signal has a zero frequency and is DC-connected to the modulation input of the modulator. Combiner according to claim 1 , characterized in that a phase shifter (4) is provided for each of the radio signals the phase-sensitive detector (2) is arranged to convert the radio signals into a sub-signal (S - ..; S ~.), forms the in-phase signal, and to subdivide it into a sub-signal (S; Sp), which is a phase shifter signal forms.