DE840262C - Arrangement for generating a control DC voltage from an AC voltage - Google Patents

Description

The invention relates to an arrangement by which a character or control voltage for operating or control purposes from an input voltage can be obtained, the amount of which can vary widely.

A practically constant signal or control voltage, which is derived from an input signal that varies greatly in intensity numerous areas of application.

An application example for such a system is a radio receiver, which is on a desired The receiving frequency is tuned by the incoming signal itself. Initiated in such voting systems a drive device, for example an electric motor, the tuning device, the frequency band to feel. When a character is received, a control voltage causes the switch-off the drive device, so that the tuning device stops and the signals from this transmitter be received. Voting devices of this type are signal-controlled voting devices or called signal search tuners.

A broadcast symbol and its sidebands only occupy a narrow frequency band. To the voting device shutdown before it has gone beyond the frequency band, the

Control means are braked before the peak of the resonance curve is exceeded; they have to have small inertia to stop quickly. With this control procedure, the changes Control voltage acting on the tuning device as a function of the strength of the received signal. When tuned to a strong local station there is a large control voltage to shut down the drive device. Does it

ίο but it is a weak remote station, then only a small control voltage is available, which is often not strong enough, for the drive device can be stopped quickly before the frequency band is traversed further. Also, cause different high control voltages that the tuning device at different points on the resonance curve stop.

The main object of the invention is an arrangement for generating a control voltage more constant Height and constant frequency selectivity for voting systems, regardless of the strength of the received signal as long as it is above a prescribed threshold.

In this way, according to the invention, there is an automatically signal-controlled radio tuning device created that exactly at a predetermined point of the resonance curve regardless of the Strength of the incoming control signal remains. The invention is based on two exemplary embodiments, illustrated by the drawings. It shows

Fig. Ι a graphical representation of a series of Resonance curves that correspond to the operating conditions of a radio receiver,

Fig. 2 is a circuit diagram illustrating the principle of the invention,

Fig. 3 is a circuit diagram of part of a radio receiver which is part of the invention;

Fig. 4 is a simplified circuit diagram illustrating the principle of the invention,

4a and 4b are resonance curves (voltage frequency diagrams) relating to that shown in FIG Refer to the system,

Fig. 5 is another simplified circuit diagram illustrating a further principle of the invention, and

5 a and 5 b resonance curves (voltage frequency diagrams) relating to that shown in FIG Refer to the system.

Fig. Ι shows typical voltage frequency diagrams of the diode rectifier voltage at the second rectifier of a superheterodyne receiver when the tuning device moves over the belt, the trajectory being plotted as the abscissa. In this figure, curve A shows the dependency on a received signal that is just enough to shut down the tuning device, the minimum operating voltage of which is represented by the line /:. The tip of the curve rises only a little above the value E , but this is sufficient to shut down the tuning device. With a tuning device that has a fixed inertia, and with a certain response time of the control relay, the time required to shutdown will be relatively constant. In this case it is assumed that the time constant or slide is represented by the distance b . If this distance is plotted on the curve, one can see that the tuning device will come to a stop almost halfway on the sloping part of the resonance curve far above the apex.

If one now assumes that the incoming signal is strong enough to allow the normal, automatic gain control in the receiver to take effect, with the signal being kept at a practically constant strength, then a diagram will result which, for example, corresponds to the curve B shown is equivalent to. Even if the strength of the incoming signal is tens of thousands of times greater than the signal on curve A, it is nevertheless reduced by the control effect. If the distance b is plotted on curve B , it will be seen that the tuning device stops at a point which is slightly in front of the apex. Assuming further that the tuning speed is higher, which is preferable, and that the gain control is not completely limiting, then one obtains diagram C. If one assumes the constant distance b as the shutdown time, then the tuning device is considerably ahead of the apex the resonance curve come to a standstill.

From the above explanation, it will be seen that in systems of this type, that of the tuner achieved stopping point that is between one already before the vertex and one considerable behind the vertex may be, entirely on the strength of the incoming character depends. The problem to be solved is to find a point to stop which is as constant as possible to determine the tuner regardless of the signal strength. This problem becomes solved by the systems described below. Even if these circuits are connected are described with radio receiving circuits, they can also be used for other purposes if it is desirable to obtain a control signal of constant strength from a greatly variable input voltage.

Fig. 2 shows part of a circuit according to the invention. An input alternating voltage e is applied to the earth terminal 2 and the line 4. A capacitor 6 is connected to the line 4 and its other end to the electrode 8 of a diode 10, the other electrode 12 of which is connected to the positive terminal of a battery 14, the negative terminal of which is grounded. A line 16 leads from the capacitor 6 to the electrode 8 and is also connected to the resistors 18 and 20. The other end of the resistor 18 leads via a line 22 to a line 24. The electrode 28 of a diode 26 is connected to a line 24, the other electrode 30 is connected to a line 32 and also to a capacitor 34, the other end of which is connected to the input line 4 leads.

A capacitor 36 is between line 24 and ground and a resistor 38 is between the lines 22 and 32. The line 32 also leads to a resistor 40, which is on the other hand on a connecting line 42 is over which the final control pulse fliel.it, and filter capacitors 44 and 46 are connected between line 42 and ground.

The battery 14 is a bias battery and its size is determined by the level of control voltage desired. The voltage e on the lines 2, 4 is now supposed to generate a voltage Ji ₁ at the resistor 20 of the diode 10 and a voltage Ji., At the resistor 3S of the diode 26. The voltage at the resistor 20 remains zero until the value of 1-4c is greater than the voltage of battery 14. If the voltage exceeds the value of battery 14, rectifier 10 will conduct and produce a voltage E ₁ which will be equal to 1-4 Ke - V , where A 'is a constant which corresponds to the rectification efficiency, and V is the voltage of the battery 14. At this point, E., will be equal to 1 x 4 Ke , assuming that the rectification efficiency of diode 26 is equal to that of 'A', of diode 10, insofar as the AC voltage applied is the same apart from the direction and no bias of one Battery is in place. Since the two voltages are oppositely applied in series and their total sum occurs on line 42, the operating or reverse voltage on line 42 results in:

E ₁ = E ₂ - E ₁ inserted:

E ₁ = ι-4Ke- (ι-4 Ke - V) ^ib and equated:

E _t = - V

In this way it is clear that the voltage on line 42, which is the operating or reverse voltage, as long as the input voltage is high, will be equal to the voltage of the bias battery and will remain constant. Every fluctuation in the alternating voltage e is applied to the two diodes in push-pull mode and is canceled out. Therefore, as soon as the voltage exceeds the voltage V , a control or blocking voltage in the amount of the battery voltage will remain as long as a signal of sufficient strength is present. In this way a constant control voltage is obtained.

It is possible to install the system described above in a radio receiver without great effort. In Fig. 3 a part of a conventional radio receiver is shown with the additional line routing that is required for the application of the regulation according to the specification. Lines 48 and 50 are connected to the last intermediate frequency stage (not shown) and apply the signal to the circuit shown via a capacitor 52 and the primary winding 54 of the intermediate frequency transformer 54-110 to line 56 and via a capacitor 58 and thus via a lead j 60 to the anode 62 of the composite tube 64. A lead! device 66 connects line 60 to a resistor | was 68, the other end back through a line 70 to the input stages of the receiver and the arrangement in this way forms for automatically \ ⁷ erstärkungsregelung. Resistor 74 is across cathode 76 of the tube and leads to the positive anode voltage terminal of the receiver. Two resistors 78 and 80 are connected in series between the cathode and ground. A line 82, which branches off from the junction of resistors 78 and 80, forms one line and line 102 forms the other line of the control loop. The control voltage, which is fed in parallel to the circuit to be controlled, is present between these two lines. The latter circle does not form part of the invention.

A resistor 84 lies between lines 60 and 86, the latter being connected to anode 88 a diode 90 is connected. Resistor 92 is between line 86 and ground and is a capacitor 94 is provided between line 86 and ground. A resistor 96 is between the line 86 and the cathode 98 of the diode 90. A resistor 100 is between the cathode 98 and a Line 102 arranged, which forms the other line of the control loop. A capacitor 104 is connected between the cathode 98 and a lead 106, which is made up of a second matched circuit, which a capacitor 108 and the secondary winding no l> est, to the electrode 112 of the low frequency amplifier tube 114 runs.

Two resistors 116 and 118 connected in series are between the tuned circuit 108, iio and the cathode 120 of the roller 114. A variable tap on the resistor 118 forms the normal volume control of the receiver and is connected to the control grid 128 via a capacitor 124 and a line 126 the tube 114 connected. A resistor 130 is connected between the line 116 and a second diode anode 132 of the tube 114. In this system, the voltage E _{1 is applied} to the two series-connected resistors 84 and 92 and is proportional to the automatic fading control voltage of the receiver. The alternating voltage e is fed to the primary winding 54 via the lines 48 and 50 and is thus effective in the secondary winding 110 in a corresponding ratio. The voltage E ₂ can be tapped at the resistor 96. The battery voltage V is applied via the resistor 74. the cathode 76 of the roller 64 is placed.

The reverse voltage Et arises between the line 102 and ground and is equal to £., Reduced by a part of E ₁ , which is determined by the ratio of the resistors 92 and 84. The two voltages E ₁ and E ₂ are no longer the same, as was the case in the system shown in FIG. In most cases the ratio is less than one, so that it is necessary to use only a part of the voltage E ₁ , the ratio part corresponding to the voltage ratio of the transformer

got to. In FIG. 3, one of the voltages, E ₁ , is therefore taken from the diode 64 via the primary winding 54 of the transformer and the other voltage, E ₂ , is taken from the secondary winding 110 of the transformer. The voltage E ₂ is rectified in the rectifier 90 and switched against the first voltage with reversed polarity, the resulting control DC voltage occurring between the line 102 and earth and having a value that is determined by the bias voltage generated by the resistor 74 at the resistors 74 and 80 is created.

In the system shown in Fig. 3, as a result, the reverse voltage is practically above one wide range of change in signal voltage constant and only a function of the selectivity of the part of the receiver lying in front of the intermediate frequency stage. This is due to the fact that the The shape of the resonance curve at this point is determined by the selectivity of this part of the receiver will.

If necessary, the curve shape of the blocking voltage can be changed from a practically constant voltage across the width of the resonance curve (which is the case if there is no difference in selectivity between the points of origin of the voltages E ₁ and Ε. ) To a sharp blocking voltage, the maximum value of which is for all signal input voltages remain the same, the resonance curve of which, however, can have a broad or pointed peak depending on the input voltage, depending on the designer's preference. In this connection, in Fig. 3, the coupling between the two windings of the intermediate frequency transformer can be chosen so that it gives a sharp blocking curve, since the voltages that are combined have their origin on both sides. This is illustrated with reference to the circuits of FIGS. 4 and 5 in their corresponding voltage frequency diagrams in FIGS. 4 a, 4 b and 5 a and 5 b, respectively. Fig. 4 is a simplified circuit in which the two voltages come from the same point, so that there is no difference in selectivity. Fig. 5 is a simplified circuit in which the voltages come from different parts of the circuit, so that there is a change in selectivity.

The system of FIG. 4 shows a tuned circuit made up of a capacitor 134 and an induction coil 136, which can form part of an amplifier system. A line 138 connects one side of this tuned circuit through a capacitor 145 with a resistor 140 and the anode 142 of a diode 144 and with a capacitor 146. The cathode 160 of the diode is connected through a battery 162 to earth. The other side of the matched circle is via line 148 to ground and to a capacitor 150. Between the capacitors 146 and 150 there is a diode rectifier 152, its cathode 154 with the capacitor 146 and its anode 156 with the capacitor 150 is connected. A resistor 158 is directly parallel to the rectifier. the both diode load resistors 158 and 14ο are connected to one another via a resistor 157.

If an alternating voltage is applied to the line 138, the resonance curve G is produced (FIG. 4a). However, since the two diodes according to FIG. 2 are connected in push-pull, the resulting curve at diode 154 is the strongly drawn line // (FIG. 4b), which rises from KuIl to a predetermined value, remains constant over a certain frequency range and then drops back to zero. This happens because the voltage on one diode rises to a certain value before the other diode can even conduct current. From this point on, the remaining parts of the two partial curves // are directed in opposite directions and partially cancel each other out. To achieve complete cancellation, the curves // would have to have the same shape.

If there is any power difference between the partial voltages, then will the resulting resonance curve will not be a straight, horizontal line representing a constant voltage represents, but it will vary depending on the algebraic sum of the two voltages change. A system which leads to this result is illustrated in FIG. One of a capacity 164 and an induction coil 166 existing resonance circuit is connected to the electrode 170 of a diode 172 via a capacitor 167 and a line 168 connected, the other electrode 174 of which is connected to earth via a battery 176. At one between the Electrode 170 and resistor 178 lying to ground have a control voltage of the specified polarity. Another line 180 connects the capacitor 167 via a resistor 181 to one second tuned circuit consisting of an inductor 182 and a capacitance 184. In this The inductance 182 is inductively coupled to the coil 166 and forms the other half of the case Coupling transformer. The resistor 181 is also connected to a resistor 186, the is connected in parallel with a capacitor 191. The other end of resistor 186 is in place on a line 188 leading to the device to be controlled leads. An electrode 190 of the diode rectifier 192 is via a line 194 with the Connected resonance circuit, which consists of the inductor 182 and the capacitor 184. The other Electrode 196 of diode rectifier 192 is directly on line 188.

It will be understood that because of the loose coupling of coils 182 and 166, the resonance curves of tuned circuit 164-166 and tuned circuit 182-184 are not identical. This difference is indicated by the two curves shown in FIG. 5 a, which almost illustrate the critical coupling of the two coordinated circles. The outer curve K is that of the primary circuit 164 to 166 and has a small saddle at the top, and the inner curve L belongs to the circle 182 to 184. When the bias of the battery 176 is effective,

5b, the curve K above and the curve L below the axis, and if these two curves are added graphically, the resulting mean wave curve M is obtained.
This curve begins below the axis, then runs upwards and drops at the midpoint M by an amount which is equivalent to the preload. The other half of the curve corresponds to the first. The blocking voltage for the control pulse

ίο is the one indicated by the lowest point N , which is below the axis. Instead of a broad, even curve of the control DC voltage with frequency (as in FIG. 4b), a narrow, pointed pulse is created. If the input signal is increased, the two curves above and below the axis in a corresponding manner no longer cancel each other out partially (as would happen with the arrangement according to FIG the saddle in the middle is much more pronounced, as shown by curve O. This is quite similar in shape to a curve obtained from a weak signal whose saddle would be roughly at point N.

The middle saddle does not extend further under the axle, but is only slightly more pointed and narrower than before. This can be done by changing the selectivity or coupling the shape of the control voltage curve can be influenced between two voltage sources, the Minimum value remains independent of the amplitude of the incoming signal.

Claims (5)

Patent claims: i. Arrangement for generating a control DC voltage from an alternating voltage, characterized in that it has a pair of rectifiers has, which are separately connected to the AC voltage source with different polarity with each rectifier in parallel with one of two in series Resistances is that one of the rectifiers is biased and that the control voltage is applied the end of the resistor series circuit hanging connected to the non-biased rectifier is removed. 2. Arrangement according to claim 1, characterized in that that the primary coil of a transformer is connected to the AC voltage source is that the secondary coil of the transformer with the second rectifier in such a way is connected that the voltages formed are oppositely polarized and a voltage is caused in the output circle by a level which is the level of the bias at the first rectifier does not exceed. 3. Radio receiver equipped with an arrangement according to claim 2, characterized in that that it has an intermediate frequency transformer with a primary and a secondary winding connected to the first or the second rectifier are connected. 4. Radio receiver according to claim 3, characterized in that a tap on the parallel to the first rectifier with the resistor parallel to the second rectifier lying resistor is connected in such a way that the second resistor and a part voltages developed in the first resistor have opposite polarity, the called tap has a ratio to the first total resistance of practically the same Has a value like the ratio of the primary to the secondary number of turns in the transformer. 5. Radio receiver according to claim 4, characterized in that the parts of the resistors are connected in series with one another but in reverse voltage and that the output circuit is connected to the series circuit so that the signal voltage developed therein becomes a predetermined one The ratio of the bias voltage does not exceed regardless of the strength of the input signal, its shape being determined by the Selectivity of the coupling is determined. 1 sheet of drawings 5038 5. S2