DE649682C - High frequency receiver with automatic control of the selectivity - Google Patents

Description

High-frequency receiver with automatic control of the selectivity The present invention relates to fidelity control devices for high-frequency communication systems and in particular arrangements for automatic control of playback fidelity in radio receivers.

Various arrangements have been proposed in order to be effective Resonance curve of a tunable network automatically depending on changes in amplitude to regulate the recorded signal energy. The main purpose of these facilities consists in such a control of the selectivity of a high-frequency signal transmission system, that this works more selectively for weak signals than for strong ones and that as a result the selectivity when receiving a strong local station is lowest when recording weak stations but is greatest.

In the present application, further arrangements for automatic Change the selectivity and improve the fidelity of the reception strong signals indicated. In each of these arrangements there is a double system used by amplifiers, one amplifier from the amplitude changes the recorded signal energy are influenced to the effect that upon reception of signals from remote stations improves the selectivity of the receiver However, fidelity is degraded while other amplifiers operate to Reduced selectivity when picking up strong signals from a local transmitter, however, the fidelity is increased.

Therefore, it can be said that one of the main objects of the present invention consists in automatically acting devices to regulate the fidelity of reproduction to create, which cause a change in the fidelity of a radio receiver, by making them dependent on changes in the amplitude of the recorded signal energy make use of amplifiers with predetermined selectivity properties.

. Another important subject of the present invention is in the fact that at least two amplifiers working in parallel in a radio receiver are provided, one of which has a sharp selection characteristic and the other has a flat one, and that the receiver has additional facilities for differential influencing of the transmission efficiency of the named amplifiers contains, so that when receiving weak signals, the amplifier with the sharp selectivity predominates, while predominantly when receiving strong signals the amplifier with the wide tuning is effective.

Another object of the invention consists in equipping a radio receiver with a selective push-pull amplifier, which has a sharp resonance curve in normal operation, but contains devices to automatically shut off certain tubes of the push-pull amplifier make for the purpose of broadening the resonance curve when receiving strong signals, e.g. from a local transmitter.

The invention also aims to improve automatically acting Devices for controlling fidelity in radio receivers in general and the creation of control systems that are not only reliable in operation, but are also easy to manufacture and incorporate into the receivers.

The structure and the mode of operation of the subject matter of the invention should now with reference to the drawing, which represents various exemplary embodiments, explained in more detail will. In the various figures, the same elements are given the same reference symbols Mistake.

Fig. I shows a radio reception arrangement in the usual representation, who makes use of your inventive concept. The. Arrangement includes a signal energy source i, which consists of signal interceptors and the high frequency amplifier of a Superlieterodyne receiver may exist. The signal source is followed by a network -a, which combines one Oscillator detector circuit (self-oscillating 1Iischrohr) known type or a first rectifier to which the vibrations generated by a local superimposed bearing may be supplied, may contain. In any case, it is at the exit of the network 2 lying circle I tuned to the existing intermediate frequency and - for example 1I1- coupled to the tunable input circuit II of the intermediate frequency amplifier 3; the intermediate frequency amplifier preferably includes a screen tube, and circle II is tuned to the intermediate frequency that occurs.

The anode circuit of the tube 3 contains a resonance circuit III, its one side with the positive pole -1- B of a (not shown) voltage wave connected is; this oscillating circuit is tuned to the intermediate frequency - around 1I2 - with your circuit IV, which is also tuned to the intermediate frequency coupled. The circuit IV is connected to the input electrodes of the second rectifier .4 connected and contains a coil 5, which with your tuning capacitor and the Secondary winding of the coupling transformer 11I = is connected in series.

The coupling 1I1 is looser than the critical = doubling, so that the The resonance curve at the grating of the tube 3 is relatively sharp; the same is also true for 1I2. The intermediate frequency signal energy is transferred from the circuit I at the same time the capacitor 7 of the screen grid tube 6 is supplied. The cathode of the tube 6 is above earth with the lower potential side of circle I. connected, while the capacitor 7 is the end located at the higher potential of the circuit 1 with the control grid of the tube 6 connects.

The anode circuit of the tube 6 contains a resonance circuit V, which at .113 is coupled to a resonance circuit VI; the latter is on the input electrodes connected to the Schirrngitterversärkerröhre ii, whose anode circuit the resonance circuit VII contains. The coil 5 of the rectifier input circuit IV is connected to the circuit VII magnetically coupled. The circles V, VI and VII are tuned to the intermediate frequency.

The DC blocking capacitor 15 forms a coupling path to one downstream low-frequency amplifier undi 'or a playback device for the low frequency component contained in the rectified intermediate frequency energy. The line 16 connects the grid circuit of the tube 3 with a control voltage source 16 'of a type known per se, for example a rectifier arrangement.

The resonance curve on the grating of the tube 6 has a substantially flat apex and is wider than the resonance curve at the grid of tube 3. The the tubes 6 and 3 by 'the lines 16 and 17 impressed control voltages are dimensioned so that they work differentially. The line 17 is between the Grid of the tube 6 and a further control voltage source 17 'connected. at an extremely strong signal, the amplification by the tube 3 becomes complete disabled, and the signals pass through tubes 6 and i i. The output voltages the tubes 3 and i i become the common input circuit IV of the rectifier tube q. fed; however, the output voltages of the tubes 3 and i i can also are rectified separately and only merged in the low-frequency circuit.

The differential biasing of the pointed and broad-tuned amplifiers is such that the gain of the pointed-tuned amplifier is greater than that of the broad-tuned amplifier when receiving weak signals, while the opposite is true when receiving strong signals. Between these two states there is a value of the signal strength at which the two amplifiers have the same gain and a medium degree of selectivity is obtained. The control unit 6 'which feeds the grid of the tube 3 can, for example, be a biased detector, and its anode DC voltage component would then be used to reduce the gain of the tip-tuned amplifier at high signal input voltages. The control device 17 ' can be a grid leakage detector (Audion), the broadly tuned amplifier would operate with the greatest gain for large signal input amplitudes because the anode DC voltage component is a minimum for these input voltages. When the signal input is weak, the sharply tuned amplifier works with maximum gain, while the broadly tuned amplifier provides the minimum gain. Any other type of gain control device may be used in place of 16 'and 17' provided that their operation is similar.

As can be seen, two parallel amplifier systems are provided between the rectifier 4 and the first rectifier 2, both of which operate on an intermediate frequency. One of these systems has a sharp selectivity while the selectivity of the other is poor. The signal coming from the first rectifier can be made to pass through one of these two systems or to be split in some ratio and pass through both systems. The connections between the two control voltage sources i6 ', 17' with the two parallel amplifier systems are such that they operate the amplifiers differentially, and the differential bias voltage is obtained as a function of the changes in the signal amplitude. As a result, the selectivity and fidelity of the receiver changes in accordance with the signal energy received.

To increase the change in selectivity with signal strength, can add one or more amplifier stages between the tube 3 and the Rectifier 4 and between the tube 6 and the rectifier 4 are inserted. Where such additional stages are used, the couplings in the system should with the tube 3 should be below the critical value, while the couplings in the system with the tube 6 should be greater than the critical coupling.

In Fig. 2 a modification of the circuit shown in Fig. I is shown, wherein the pointed intermediate frequency amplifier contains the tube 3, the Tuned input circuit II inductively coupled to resonance circuit I at 1V11 is. The sharply tuned amplifier contains an amplifier stage 3 ', its input circuit 18 is coupled to the tuned output circuit of tube 3 at i9, the Coupling i9 is smaller than the critical coupling. A coordinated circle 2o is magnetically coupled to the matched output circuit of 'tube 3'; The circle 2o acts as a phase correction circuit: The sharply tuned amplifier system ends with a circle similar to that used by the broadly tuned amplifier begins, and this fact makes the output phase angles of the two amplifiers almost the same.

The broadly tuned amplifier arrangement contains the tube 6 which is coupled to the tuning circuit I via the capacitor 7; the grid of the tube 6 is connected by the line 17 to the gain control device 17 ' . The cathode of the tube 6 is grounded. The tube 6 is followed by the tube ii, and the output voltage of the circuit VII is impressed on a resonance circuit 21. The lines 16 and 17 lead to the grid circles of the tubes 3 and 6, as was the case with Fig. I. The coupling M3 and the coupling between the circles VII and 21 is greater than the critical coupling. A special tube 22 combines the output voltages of the pointed and wide-tuned amplifier, in that the output voltages of these two amplifiers are pressed onto the control grids a3, 23 'of the tube 22, which are arranged parallel to one another.

The tube 22 contains a positive screen grid between the parallel ones Grids 23, 23 'and the anode. The anode circuit of tube 22 is with the rectifier input circuit IV coupled by a voting circuit III. Of course, the anode circuit the tube 22 is also connected to a further intermediate frequency amplifier stage will. The effect of this circuit is the same as in Fig. I.

In Fig. 3 is another arrangement with parallel working, pointed and broadly tuned amplifiers. In this arrangement, the pointed and the broadly tuned amplifier input circuits of the same design. the end for this reason no special circles are needed to correct the phase angles. A different output voltage collector circuit is shown, in which two screen grid tubes usualex execution can be used (3 " and 6 "), their anodes through Lines q.o and 41 are connected. The common voting circle .I2 is with his on the high potential side connected to the conductors 4.o, .41 and at .I3 magnetically coupled to the rectifier input circuit IV.

The standard biases will be pointed to the point and broadly tuned to yours Amplifier is supplied via lines 16 and 17, respectively. In this embodiment leads the line 16 from the control voltage source 16 'to the grids of the tubes 3, 3' and 3 ", while the line 17 from the control device 17 'to the grids of the tubes 6. 6 'and 6 "leads. The control biases are fed to the parallel amplifiers in fed in such a way that it depends on the changes in the signal amplitudes regulated differentially, as stated earlier.

Another embodiment of the inventive concept is shown in Fig.4 shown. There lie between the matched input circuit IV of the detector q. and the signal energy source i two cascaded push-pull amplifier arrangements. The first cascade contains a pair of screen grid tubes So and 51 in a push-pull arrangement, their control grid via capacitors with opposite ends of the matched Input circuit 52 are connected; which is the mean of the inductance of the circuit 52 Grounded through a high frequency capacitor 53.

The tuning circuits sd. And 55 are connected in series between the anodes of the tubes So and 51. The control grid of the tube So is given a fixed bias voltage through the bias resistor 56, while the grid of the tube 51 is supplied with a control voltage through the resistor 57. The second push-pull stage contains a pair v of Schiringitterröhren 6o and 61. The ungrounded side of the resistor 1.4 is connected to the control grid circuit of the tube 6o by a line 62, a line 63 and the grid resistor 6.I; the same point is connected to the grid of the tube 51 by a current path which contains the lines 62, 65 and the grid resistor 57. Between the grid and cathode of tube 61 is a grid resistor 66 and a fixed grid bias voltage source. If the tubes So, 51, 6o and 61 operate with the same control grid corer voltages, they are at the carrier frequency. coordinated circles 5d. and 55 effective in parallel to one another. In this case the resonance curve is the same as that of an ordinary amplifier with one oscillating circuit per stage. If now the biases of the tubes 51 and 6o are increased so far. that these tubes are put out of action, form the circles 5d. and 55 a pair of coupled ribbon filter circuits, with tube So working on the primary side and tube 61 picking up the signal from the secondary side. If the coupling .11 has the correct value, a band filter clear characteristic is obtained at this stage. Of course, you can also use the tubes So and 6o instead of the tubes 51 and 61; however, this results in a lower selectivity. It is desirable to keep the center of each grid circle of the cascaded push-pull amplifier tubes at ground potential. The coils 70 and 71 are not tuned to the signal frequency.

One can now imagine that an arrangement is shown in Fig. D is wherein a selective push-pull amplifier is turned into a system of coupled single-tube circles as soon as certain tubes are put out of action. As the signal amplitude increases, the ungrounded side of resistor becomes 1I more negative, with the result that the grid circles of the tubes 6o and 5 i applied biases are sufficiently large to make these two tubes ineffective close.

As explained above, this results in a conversion of the cascade push-pull arrangement into a bandpass filter amplifier arrangement, in which the tube couples the resonance circuit 52 with the coupled tuning circuits 5.4 and 55; The latter circuits have a bandpass filter characteristic and the tube 61 draws energy therefrom via the secondary coils 70 and 71. In this way the circuit is made less selective, but the fidelity has been improved. The opposite effect takes place when weak signals are picked up.

Claims (5)

PATENT CLAIMS: i. High frequency receiver finite automatic control the selectivity, characterized in that depending on the mean value of the received vibrations the gain of a tube group is changed. and thereby more or less energy via another parallel lying, possibly im opposite sense regulated tube group with associated coupling circles of others Selectivity properties flows. 2. High frequency receiver according to claim i, characterized characterized in that one part of the tubes in an amplifier with a narrow resonance curve and the other part of the tubes in a parallel amplifier wider resonance curve and that the gain of the two amplifiers is regulated in the opposite sense. 3. High frequency receiver according to claim z, characterized characterized in that the outputs of the two amplifiers are connected to one for demodulation serving tubes are laid with two equivalent grids. q .. High frequency receiver according to claim z, characterized in that the one amplifier with a phase correction element is provided. 5. High frequency receiver according to claim i, characterized in that that the tubes belonging to the two groups are located alternately on the two sides of a push-pull amplifier and belonging to the same stage, in push-pull lying oscillation circles are coupled together to form a band filter, which only acts as a band filter when the gain of one group of tubes is reduced will.