DE657728C - High frequency receiver with automatic volume control - Google Patents

Description

High-frequency receiver with automatic volume control The invention refers to high-frequency receivers with automatic volume control, at which amplify an incident signal by regulating the bias voltage one or more grids of one or more amplifier tubes regulated in this way that the gain for small signal amplitudes is reduced relatively strongly (mute control), is little influenced for signals of medium strength and only again more significant for signals whose strength exceeds a predetermined value is reduced (delayed regulation).

According to the invention, this desired dependency is obtained by d.that two control voltages are taken in the same direction from one resistor each, each of which belongs to a control loop in which in series with this resistor a bias source, an additional resistor to which by rectification, des Received signal generates a direct voltage opposite to the bias voltage is, and a directional resistor - preferably a valve with a noticeable reverse current - lies, being bias sources and directional Resistors are polarized so that if there is no high frequency in one control circuit Current in the forward direction, in the other control circuit current in the opposite direction Direction - preferably the blocking current of the valve - flows.

Dry rectifiers are preferably used as direction-dependent resistors used.

The invention is illustrated, for example, in the drawings, in which Fig. i is a schematic view of the power circuits of a portion of a Represents broadcast receiving apparatus according to an embodiment of the invention.

Fig. 2 is a graph showing the effect of the device and FIG. 3 shows, in a view similar to FIG. 1, the invention in its application to a battery-powered receiver.

In the arrangement of Fig. R, the coupling transformer is between the last high-frequency stage and the detector of the apparatus are designated by T. He has a primary winding i and two secondary windings 2, 3. The circuit of the Secondary winding 2 includes a dry patch rectifier D1, which is the detector of the apparatus and is connected in series with a resistor R1. Here is a point q. between the detector D1 and the resistor R, to the input circuit connected to the first low frequency stage of the apparatus by means of line 5. Further is the point 4. through a dry surface rectifier V1 in the reverse direction with a line 6 and a resistor 7 connected to a control grid 8 one, which can be either a high or low frequency amplifier tube. She owns a characteristic with an exponential course and serves as a volume control = tube.

The cathode 1o of the tube 9 is through a resistor R through a Conductor 11 connected to a point B on a potentiometer resistor 12 from which one terminal to a ground line 13 and the other to the negative high voltage terminal HT of the apparatus, as can be seen, is connected. The head 6 is at the point B connected to the resistor L2 through a gain control resistor R2. The resistor 12 is traversed by a considerable current which z. B. by the actuation of the tubes of the apparatus arises with the result that the point B has a negative potential with respect to the potential of the grounded conductor 13.

The - circuit of the secondary winding 3 of the transformer T closes a dry surface rectifier U2 connected in series with a resistor R3 and point 14 between rectifier V2 and resistor R3 is through a rectifier h3 in the reverse direction with point 15 between line 6 and Resistor R2 connected. The other end 16 of the resistor R is through a Resistor R4 connected to a point A on the potentiometer resistor.d 12, the with respect to the above-mentioned point B is negative.

The mode of operation of the apparatus is as follows: The potential on which the cathode 1o of the tube 9 is held during its actuation is evident (apart from the voltage drop in resistor R) is the potential of point B. of resistor 12 and is somewhat negative with respect to earth. The potential of the grid 8 of the tube 9 is the potential of the point 15, which is accordingly the strength of the received signal due to the action of the transformer windings 2, 3 and their associated circuits changes.

Let us first consider the effect of the transformer winding 2, see above as long as a signal is not received from the apparatus, the resistor R1 are not traversed by the current from the winding 2. A small stream will meanwhile the resistor R1 from the ground line 13 through the resistor RI, the rectifier V1 in its reverse direction, flow through resistor R2 to point B in resistor 12. Due to the large voltage drop in the rectifier V1, the point 15 in the essentially have the `, potential of point B, so that the` @tential of the lattice 8 of the tube 9 can be weakly positive with respect to the cathode 1o. will, namely by an amount equal to the difference between the voltage drops in resistors R2 and R corresponds to. As the received signal strength increases, it becomes a DC potential as a result of the current flowing through the transformer winding 2 and the detector Dl, received at the terminals of the resistor R1 and an increase in the current and voltage drop inside the resistor R1 causing the current in the resistor R., and the positive potential of point 15 and consequently of grid 8 is reduced.

As soon as that at the terminals of the resistor R1 of the received Signal current developed the potential between conductor 13 and point B of the potential Resistor 12 is the same, the current flow in resistor R2 is reduced to zero, and the potential of the point 15 and the grid 8 becomes the same as that of the Cathode 1o (apart from the voltage drop in resistor R).

A further increase in the strength of the received signal causes that the current flowing through the detector Dl in the resistor R1 developed Potential becomes greater than the potential between conductor 13 and point B, whereupon current through the resistor R. and the rectifier V1 in the passage direction of this Rectifier flows. The potential of point 15 suffers under these conditions a sudden and rapid change due to the reversal of the direction of current flow in the rectifier Ui, and the point 15 and grid 8 become increasingly negative with Regarding the cathode i o.

The above-described effect is shown in curve 117 in FIG. In this, the input alternating voltage is along the horizontal axis 0-I1, along the vertical axis shows the potential difference between the grid and the cathode. The point O means the cathode potential. It can be seen that under the sole Influence of the transformer: 2 the potential of the grid 8 a small positive Would have value if a signal is not received, and that this potential gradually drops to zero as the signal strength increases and then rapidly decreases falls a relatively high negative value.

Let us now consider the effect of the transformer winding 3. If a signal is not received, current flows from point B on the Potentiometer resistor 12 through resistor R2, the rectifier 1j3 in his Passage direction, resistor R3 and resistor R4 to point A in the resistor 12. As a result of the potential drop in resistor R2, point 15 is on a relative basis high negative potential held under these conditions, as shown in curve N of the Fig. 2 indicated.

If a signal is now received, it develops from the transformer winding 3 current supplied a voltage at .the terminals of resistor R3, which corresponds to the voltage drop at these terminals as a result of yaw the effect of the potentiometer resistance described above 12 counteracts, and the current flowing through the resistor R2 increases with it Signal strength decreased, whereby the potential of point 15 becomes less negative, until at a predetermined signal strength as soon as the resistor R3 through the Winding 3 impressed the voltage across the resistor 12 between the points A. and B tapped voltage exceeds the direction of current flow in the resistor R2 is reversed so that this current then reverses the rectifier V3 flows through. This has the consequence that the potential of the point 15 is growing rapidly Measure becomes positive when the signal strength continues to grow as out of the shape the curve N in Fig. 2 results.

The respective potential of the point 15 for different values of received signal strengths will obviously be the resultant of the above-described effects of the transformer windings 2 and 3, ie it will be the sum of the potentials indicated by the curves M and N in FIG , be. This resulting potential of the point 15 and consequently of the grid 8 of the tube 9 is represented by the curve S in Fig. 2, which is the sum of the curves .41 and N, and it is thus clear that for weak signals received, the potential of the Grid 8 will be negative, thereby causing a corresponding reduction in the gain of the tube 9 and ensuring the desired mute control. When the received signal strength increases, the potential of the grid 8 becomes less negative and under certain circumstances reaches a maximum positive value at a predetermined signal strength which corresponds to the normal maximum gain. A further increase in the signal strength beyond this value causes the potential of the grid 8 to become less positive and under certain circumstances to a rapidly increasing extent negative, so that the desired reduction in the gain of the tube for strong signals is achieved.

It can thus be seen that the arrangements described above do allow a mute control and delayed volume control of the played To receive the signal automatically, so that the playback is automatically suppressed, until signals of a certain strength are received, whereupon the receiving apparatus immediately becomes fully sensitive, while for stronger received signals the reproduction strength is regulated automatically. It is also desirable that when signals from the particular Strength received, any temporary decrease in signal strength, e.g. B. as a result of fading, does not cause the suppression of the signal, and this can by suitably setting the time constant of the circuit for the mute control be effected, so z. B. by the arrangement of a suitable capacitor Cl, the is switched in the manner shown in Fig. i. The voltage drop across the Resistance R in line i i between cathode io of tube 9th and the point B is always added to the control voltage tapped at resistor R._,.

In Fig. 3 the invention is in its application to a simpler one Shown in the form of receiving apparatus, in which the various required Potentials can be obtained from primary or secondary batteries.

In this form of the apparatus, the cathode is the control tube 9 connected directly to line 13. The resistor R3 is with its one End to the conductor 5, which leads to the first low frequency stage of the apparatus, and with the other end connected to the negative terminal of a battery 17, whose positive terminal is connected to line 13.

The circuit supplied by the transformer winding 2, which the The rectifier Dl and the resistor R1 also includes a battery 18 one, the effect of the winding 2 on the flow of current in the resistor R1 counteracts, one end of this resistance, as can be seen, by the Grid voltage battery i9 is connected to line 13.

If no signal is received, the battery 18 causes a small current to flow through the rectifier Dl in its reverse direction and the resistor R1, so that the potential: of the point 15 is somewhat positive, while if a signal of sufficient strength is received , which causes the supply of current from the winding 2, the direction of the current flow through the rectifier. D1 is reversed and current flows through this rectifier in its forward direction. The potential of the point 1 5 therefore drops to zero and is then rapidly growing negative as ornamental in curve M Fig. 2.

As for the action of transformer winding 3, when no signal is received, current flows from line 13 through resistor R2, rectifier IT3 in its forward direction and resistor R3 to the negative terminal of battery 17. The potential of point 15 is therefore negative with respect to line 13 , but when and as soon as a signal is received and the strength of the signal increases, the current flowing through rectifier Vg decreases due to the increasing potential of point 4, while the current through detector V2 increases until the direction of the current flow through the rectifier V2 is reversed under certain circumstances and the potential of the point 15 becomes positive, as shown in the curve N of FIG.

From the above explanation it will be clear that the potential of the point 15 to which the grid 8 of the tube c) is connected, accordingly the strength of the received signal changed so that the desired mute control and delayed volume control is achieved.

The volume control potentials corresponding to the curves M and N of FIG. 2, instead of being combined and individually pressed onto a grid 8 of a tube g, as shown in FIGS or different tubes can be created.

It should be noted that the invention is not limited to the special Power circuits or arrangements of the individual parts of the volume control apparatus, as described above, for example, and shown in the drawing, limited should be, but these details can be changed in many ways, without departing from the scope of the invention.

Claims (3)

PATENT CLAIMS: i. High-frequency receiver with automatic volume control, in which the amplification of an incident signal by regulating the bias voltage one or more grids of one or more amplifier tubes automatically in this way it is regulated that the gain for signal strengths below a lower limit value is small, for signal strengths between this and an upper limit value Maximum increases and again in one for signal strengths above the upper limit value decreases with increasing signal strength, characterized in that two control voltages can be taken in the same direction at one V resistor each, which each belongs to a control circuit in which a bias voltage source is connected in series with this resistor, an additional resistor (R1, R3) to which the received signal is rectified a direct voltage opposite to the bias voltage is generated, and a directional resistance - forward. preferably a valve with a noticeable reverse flow - Lies, with bias voltage sources and directional resistors being polarized so that in the absence of high frequency in one control circuit, current in the forward direction of the direction-dependent resistance, in the other control circuit current in the opposite direction Direction - preferably the blocking current of the valve - flows. 2. High frequency receiver according to claim i, in which the bias of only one grid is regulated thereby characterized in that the control voltage is common to one of the two control circuits Resistance (R2) is removed. 3. High frequency receiver according to claim i and 2, characterized in that one of the to obtain a control voltage from the Receiving signal serving rectifier (D1 in Fig. I, V2 in Fig. 3) at the same time as Demodulator is used to reproduce the signal.