DE1227521B - Transceiver for microwaves in which part of the transmitter frequency is used as the receiver oscillator frequency - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. α .:

H03d

German class: 21 a4- 24/01

Number: 1227 521

File number: N 22621IX d / 21 a4

Filing date: January 17, 1963

Opening day: October 27, 1966

The invention relates to a transceiver for microwaves (frequency of about 10,000 MHz), such as it is described in the preamble of claim 1. Such transceivers are already largely used because they have the advantage that only one microwave tube is required for them. Although the importance of such devices lies primarily in their simplified structure, required So far, at least two directional couplers, two absorbers and two microwave detectors have been used for them. For Devices with additional built-in control devices even require at least four directional couplers, three absorbers and three microwave detectors. For such devices with an automatic Adjustment for the transmitter requires four directional couplers, four absorbers and four microwave detectors.

The object of the invention is to further simplify such a transceiver for microwaves. The aim is to reduce the number of directional couplers, absorbers and microwave detectors so that there is a higher level of operational reliability. The task is through the in the claim 1 marked invention solved.

In a further development of the invention, if the received oscillations fail, the intermediate frequency is activated tuned oscillator switched on, with its oscillations in an additional mixer diode the one exiting via the arm of the directional coupler and at the same time much more damped and further an attenuator and a band-stop filter for the upper and lower image frequencies passing through Transmission frequency is converted into the reception frequency, which is reversed after a repeated run Direction through the band stop filter, the attenuator and the directional coupler as well after the attenuation that is still required by the bandpass filter at the correct level together with the Receiver oscillator frequency reaches the receiver mixer diode. Further refinements of the invention are specified in the subclaims 3 to 5.

An exemplary embodiment of the invention is to be explained in more detail using the figures.

In Fig. La a directional coupler, as it is generally used in microwave transceivers, is shown schematically and in Fig.Ib symbolically. This directional coupler consists of a first waveguide with the two arms 11 and 12 and a second waveguide with the two arms 13 and 14. The two waveguides intersect perpendicularly and are located with a common transmitter-receiver for microwaves, in which
part of the transmitter frequency is used as the receiver oscillator frequency

Applicant:
ίο Nippon Electric Company Limited, Tokyo

Representative:

Dipl.-Ing. M. Bunke, patent attorney,

Stuttgart 1, Schloßstr. 73 B

Named as inventor:
Takeshi Kawahashi,
Takaji Kuroda, Tokyo

Claimed priority:

Japan January 18, 1962 (1809)

Wall on top of each other, in which the coupling windows 15 and 16 are provided in the first and third quadrants of the intersection. Although most of the incoming via the first arm 11 waves arrived to the second arm 12, also reaches a small portion of energy through the coupling window 15 13. Denoting the waveguide arm, the entering arm 11 performance with Pll and in the arm 13 reaching power with P 13, then the degree of coupling of the directional coupler α is given by α = P 11 / P 13. A very small amount of energy for electrical waves passes from arm 11 into arm 14. If the power reaching arm 14 is given as P 14 , then the directional effect of the directional coupler is given by η = Ρ13 / P 14. The attenuation to which a wave coming from arm 11 to arm 12 is subjected is given by the degree of coupling. The degree of coupling and directivity are generally approximately the same.
In FIG. 2 shows a transceiver 20 for very short waves that has been customary up to now. It consists of a transmitter 21, which in turn has a microwave oscillator, for example a KIy-

609 708/129

3 4

stron oscillator, for generating the carrier frequency f _t conclusion for the modulation 22, contains a directional coupler and which is arranged so that the carrier 23, a one-way line 27, a filter 32 to the wave through a suppression of the image frequency via the input terminals 22, A receiving modulation either directly or after ger 35 with the output terminals 36. All of these a corresponding amplification by a 5 components agree essentially with the modulation in the video frequency amplifier. The sender of the F i g. 2 match shown. The output power thereon is also determined via a first, second and closed antenna 30 with that in FIG. 2 third directional couplers 23, 24 and 25 of an antenna shown. The receiving mixer 33 routing 27 for suppressing undesired erosion fulfills both the task of the one shown in FIG. 2 distortions and a fourth directional coupler 28 io labeled 41 mixer for controlling the Seneiner antenna 30, which both the output power, as well as the in the Fig. 2 with the transmission, as well as the reception of the incoming, 45 designated mixer for the automatic Frein another plane polarized electrical quenznachsteuerung, and the band filter 34 is used for waves. The received waves of the reception at the same time as one in FIG. 2 with 44 designation frequency f _T are 15 neter reference circle via a fifth direction. The second, third, fourth and coupler 31 and a receiver bandpass filter 32 to the fifth directional coupler 24, 25, 28 and 31 and the suppression of the image frequency to a crystal sorber 51 to 54 of a conventional directional radio detector 33, which serves as a frequency converter, pulling device according to FIG. 2 are thus superfluous. I'm leading. The crystal diode 33 is simultaneously via an embodiment of the invention is the reception bandpass filter 34 for the local oscillator frequency / ₍ , 20 mixer 33 to control the transmitter power and which corresponds to the transmission frequency f _t , part of the transmitter frequency to a display instrument 61 schalder power which reaches the arm 13 'of the coupler 23 with the first directional coupler 23 instead of the coupler 23 connected to the first directional coupler 23. The absorber 51 (FIG. 2) connected between them is a fourth electrical frequency signal with the frequency | / <- / _r | = fi, waveguide arm 14 'with an attenuator 62 which arises at the output of mixer diode 33, is bound to 25. Furthermore, one is amplitude-limited and demodulated both on the sum as amplified and also on the difference between the reception frequency and then in the receiver part 35 amplified again, the bandum tuned to twice the intermediate frequency, taken as modulation at the terminals 36, lock 63, a crystal detector 64 to generate one to become. It should be noted that while the oscillation test frequency f _r and a display instrument 65 for gate frequency J ₁ or in the present case the carrier 30 determination whether the oscillations of an additional frequency / _; is greater than the reception frequency f _r , the oscillator 48 is mixed with the transmitter frequency, f _r = ff-fi and the image frequency f _t + fi = f _r + 2f _t . the, provided. In addition, an amplifier 68 is between

A part of the output power of the transmitter split in the second directional coupler 24 apart from the output of the receiving mixer 33 is arranged above the microwave generator in the transmitter part 21 to monitor the detector 41 to check the output line.
Stung supplied to the display instrument 42, in which, under normal operating conditions in which the power of the transmitter is displayed, whether the- F i g. 3 device shown. will some of the scythe levels be in the optimum or not. A part of the power from the frequency f _t is branched off by the direction of the coupler 23 branched off in the third directional coupler 25 and via the frequency f _t tuned to the transmission frequency filter 34 and via the frequency f t. Coordinated reference circle 44 for frequency control together with the incoming frequency / _r is fed to the receiver, from this a retuning mixer 33 is fed in the detector 45 in order to obtain the intermediate frescale voltage, which in turn is converted into an amplification f _} . Ker even in the absence amplified 46, and then the transmitter for correcting a reception frequency, a part of the transmission of a frequency on the Söllfreqüenz f _t supplied 45 frequency f _t across the filter 34 to the reception. "The apparatus 20 further includes a control mixer 33 and is at the indicator instrument 61, having a circular, as it appears the transmitter in general all such devices existing output power to a functional test even without Since only the nominal frequency f, the filter _t to allow 34 to durchankommende electric waves. can skid, this has display also at the same time This circle consists of the fourth directional coupling 50 the meaning of a rough frequency control of the ler 28, an oscillator 48, the frequency of which is not the transmission frequency f _t . The receiving mixer 33 is used approximately equal to the intermediate frequency / _; Display, the output power of the diode 49, which is used to mix the output power of the transmitter as well as the display ige of the transmission frequency,: oscillator 48 with part of the transmission output line. Whether the transmission frequency j _t only serves the purpose of the frequency f _t , the latter from 55 frequency f _t as a result of the replacement of the third directional coupler 25 and the fifth Klystrons or other tubes necessary re-directional coupler 31 is removed. If the balancing or for other reasons deviates or oscillator 48 is put into operation, you get whether it is due to a change or a failure of only one power of the frequency f _r at the output operating voltages is not available, is on the output side of the image frequency filter 32. It is therefore almost possible to assess 60 with the display instrument 61, even without the reception frequency the device is impossible. At this point it should be noted that the not-20 should be checked for its normal operation. agile performance of the oscillator for the receiving-those arms of the directional coupler, which no mixer 33 is about 1 mW (0 dbm). From this it follows that electrical power is extracted, with the fact that when the transmitter 21 has an output power from absorbers 51, 52, 53 and 54 to have any 65 100 mW (20 dbm) and to avoid the loss by borrowed reflection. . the filter 34 is 3 db for a power whose

Pas in fig. 3 shown device according to the invention frequency is equal to the target frequency f _t , then the must

60 consists of a transmitter part 21 with the coupling degree of the directional coupler 23 17 db:

In this connection it should also be mentioned that the directional coupler 23 has a power loss of less than 0.1 db for a wave advancing through it from one arm to the opposite arm and that its directional effect is 20 db, so that only a very small proportion of -17 db of the power sent into the directional coupler 23 emerges via the arm 14 '. If the frequency of the microwave oscillator of the device 60 does not correspond to the setpoint frequency, the power of 3 dbm branched off by the third arm 13 'ίο of the directional coupler is reflected on the filter 34 and passes through the directional coupler in the opposite direction without any significant loss of power and reaches it via the arm 14 'the band-stop filter 63. If the transmission frequency of the band-stop filter 63 tuned to the image frequencies f _r ± 2f _{t is} not approximately equal to the image frequency, it passes through this filter 63 and, after rectification by the detector 64, is used by the display instrument 65 to detect an in the Target frequency deviating transmitter power displayed. It is thus easily possible to assess whether the transmitter is delivering power at all or whether it is delivering power that deviates from the setpoint frequency. The test detector 64 thus has the task of displaying the transmitter power in connection with the instrument 65 that does not correspond to the setpoint frequency. The device 60 is also provided with a device for self-control. It should be remembered that if the transmitter frequency is equal to the setpoint frequency f _t and thus equal to the resonance frequency f _{t of} the filter 34, only a very small part of the transmitter energy reaches the arm 14 ′ of the directional coupler 23. In the present embodiment it is only -17 dbm. If the attenuation caused by the variable attenuator 62 is 2 db, then only -19 dbm reach the detector 64.

In the absence of an input signal, the frequency / _; which is added to the transmitter frequency f _t at the mixer 64, so that with a mixing _{loss of about 10 db the frequency / r} arises there with a level of -29 dbm. The undesired mixed products / _r ± 2 / j that arise in the process cannot pass through the band-stop filter 63, so that only the frequency f _{r occurs} at the filter output connected to the attenuator 62. After a further attenuation by 2 db, this frequency f _r reaches the filter 34 via the directional coupler 23 with a level of -31 dbm and is increased by this by a further 29 db according to the relationship

L = \ Q-2 (f, -f _r ) / W

attenuated if, according to the present exemplary embodiment, Q = 2000 f _t −f _r = 70 MHz and f _t = 10,000 MHz. The power of the frequency f _r passing through the filter 34 is accordingly only −60 dbm. The transmission frequency f _t is reflected by the input wave filter 32, but this filter does not represent a resistance for the frequency f _T , so that oscillations of this frequency branch off before the receiving mixer 32 and only reach it with a power of -63 dbm. However, this performance is sufficient for checking the rest of the receiver 35.

In order to now also use the existing components to automatically retune the transmitter to be able to make, is now either the transmitter itself or the resonance frequency of the filter 34 with Hz is weakly modulated, and it is known from the oscillation rectified in the detector 33 A retuning voltage for the transmitter 21 is obtained in the retuning unit 68. There these 50 Hz oscillations are outside the baseband, they do not affect the received one in any way Message content. The receiving mixer therefore has three tasks. In addition to his actual Task to convert the reception frequency into the intermediate frequency, he must use the transmission frequency rectify another control display and the signal for automatic readjustment.

The one with the one shown in FIG. The technical progress achieved in the device shown in Fig. 3 lies in the reduction from five to one directional coupler, from four to two mixing diodes and from four to zero absorbers. Particularly the saving of two mixer stages is important for improving the transmission quality, as each stage of the mixer creates additional distortion.

Another advantage of the invention lies in the dual use of the filter 34, once as Bandpass filter for the transmission frequency and on the other hand as a normal circuit for the automatic retuning, because this simplifies the problems with the same temperature compensation for the two components are connected, considerably.

Claims (5)

Patent claims: 1. Transmitter-receiver for microwaves with automatic retuning of the transmitter, at which part of the transmission frequency is used as the receiver oscillator frequency and which both the function of the transmitter and the receiver in terms of power and frequency support Checked with the device's own components without receiving an incoming frequency from outside can be, characterized in that by a single, four-armed Directional coupler of the transmission frequency following vibrations with the respective purpose adapted levels are branched off and, if necessary, can be fed to the individual assemblies after implementation: The receiver oscillator vibration, the intermediate frequency auxiliary oscillation for monitoring the receiver, which is used to maintain a frequency Normal circle to be supplied oscillation and that serving to monitor the transmitter power Vibration. 2. Transmitter-receiver according to claim 1, characterized in that in the event of failure of the received oscillations an oscillator (48) tuned to the intermediate frequency is switched on, with its oscillations in an additional Mixing diode (64) exiting via the arm (14 ') of the directional coupler (23) and thereby much more attenuated and also an attenuator (62) and a band-stop filter (63) For the upper and lower image frequency, the transmit frequency passes through into the receive frequency is implemented, which after another run in the opposite direction through the Band stop filter (63), the attenuator (62) and the directional coupler (23) and after the still required attenuation by the tape pass filter (34) at the correct level together with the receiver oscillator frequency on the receiver mixer diode (33) arrives. 3. Transceiver according to claim 1, characterized in that an instrument (61) is used to check the transmitter power corresponding to the setpoint frequency f _t , which instrument displays the portion of the transmitter power reaching the bandpass filter (34) rectified by a diode (33). 4. Transmitter-receiver according to claim 1, characterized in that for testing of A display instrument (65) is used for the transmitter power deviating from the setpoint frequency f _t. 5. Transmitter-receiver according to claim 1, characterized in that for automatic retuning of the transmitter either the transmitter itself or a bandpass filter (34) serving as a reference circle is weakly modulated at 50 Hz and the oscillation f _t modulated in this way by a diode (33) rectified and a retuning voltage which influences the frequency of the transmitter (21) is obtained therefrom in a known manner in a retuning unit (68). 1 sheet of drawings