DE671169C - Receiver with simultaneous shrinkage and severity control - Google Patents

Description

Receiver with simultaneous shrinkage and selectivity control The The invention relates to a receiver with simultaneous fading and selectivity control.

It has been shown that receivers with facilities for automatic Shrinkage control does not work as desired when it has strong signals, for example from a strong local transmitter with high power, because the first amplifier stages and the tubes used there were not effectively protected against overloads.

According to the present invention, in a receiver with simultaneous Shrinkage and selectivity control reduces this override in that the Selectivity of the tuned circles closer to the receiver output is reduced to a greater extent with increasing input voltage than the selectivity the circles closer to the entrance.

The advantages of the invention emerge from the following consideration: Let us assume a receiver with automatic shrinkage control for which how common between a shrinkage-controlled tube located near the entrance and the rectifier supplying the fading control voltage a strong selection of the carrier frequency signals takes place. If strong signals occur, the Shrinkage control of the receiver for sufficiently strong negative grid biases of the tubes in front of the regulating rectifier and thus prevents overdriving of these tubes. If there is now a slight disgruntlement, the vote will not cease more precisely takes place on the carrier wave, so the voltage arii takes control rectifier noticeably, since the selection is already largely advanced here. To the Input tubes, however, the voltage has hardly changed, since the one calculated up to there overall selectivity of the receiver is still small. If now the shrinkage control process begins, the grid pre-stresses of all tubes are automatically less negative, until the old voltage is present again at the receiving rectifier. The entrance tube is now overdriven.

A second case is that you listen to a weak station, the is close to a strong, neighboring one on the wave scale. At Due to the advanced selection, only the weak high-frequency signals from the weak or distant transmitter, to the grid of the input tube or the grids of the input tubes but at the same time still the High frequency voltages of the strong transmitter with considerable amplitude. The consequence is. again an override of the initial stages. The reason lies in both cases the fact that the voltage at the control rectifier does not have a picture of the voltage is on the control grid of the input tube, and that is again due to the fact that between Input tube and control rectifier highly selective transfer elements switched on are.

In order to avoid the abuses just described, one has next the funding for an automatic shrinkage, which has so far mainly been considered and power control: i. strongly incident stations are with low gain and selectivity, weakly incident with high gain and selectivity too still receive the following requirement: 2. the discriminatory power between one fading-sailed tube and the associated control rectifier lying transmission elements must be as small as possible, so that as little as possible in this part of the receiver additional selection takes place; in other words: the heavyweight of the selection is to another point of the receiving channel, z. B. in the circles in front of the regulated Laying tubes.

The latter requirement, however, is based on the current status of the Technology contradicts the requirement i, as far as this is in the case of weakly incident Transmitters require a high degree of selectivity from the entire receiver. The rule of the present Invention now allows the best compromise between each signal strength to establish both claims; while when receiving a weak station the Input circuits must be as selective as possible and the selectivity of the next the steps away from the entrance must still be so high; that the whole Selectivity is sufficient; As the signal strength increases, the above formula becomes always better fulfilled that the lowering of the selectivity of those lying further back Circles to a greater extent than those of the circles closer to the entrance.

Fig. I shows as an embodiment of the invention the circuit diagram of a heterodyne receiver with a high frequency amplifier tube i, a first rectifier 3, an intermediate frequency amplifier tube 5 and a second rectifier 7. Die. High frequency amplifier tube i contains a cathode 9, a control grid i i, a screen grid 13, a braking grid 15 and an anode 17. The input circuit of the tube i contains a high frequency transformer igä whose primary winding 21 is connected to antenna 25 and earth and whose secondary winding 23 is connected through one part a rotating capacitor 27 forming a uniform running capacitor set is bridged and connected to the upper end with the control grid ii. The capacitor 29 forms a high-frequency path between the cathode 9 and the lower, grounded end of the secondary winding 23.

The anode 17 receives a positive voltage from that at the voltage source 33 lying voltage divider 31, namely it is with the upper end of the voltage divider Connected via a tuning circuit 35, which has an inductance 37 and a rotary capacitor 39 contains, which forms another part of the synchronizing capacitor.

The control grid i i is by means of the bias resistor 41 in the Cathode lead held at a negative potential.

The first rectifier 3 is also a retarder tube, however In addition to the elements contained in tube i, it also contains a rectifier electrode 4.3, which is located near the lower end of the cathode 45; these two Elements form a diode rectifier. In addition, the tube 3 still contains the Control grid 4.7, the screen grid 49, the braking grid 51 and the anode 53.

The top of the matched coupling circuit 35 is with the control grid 47 connected via a coupling capacitor 55. The lower end of the circle 35 is connected to the cathode 45 by a circuit, which is the following takes: district 35; Conductors 57 and 59, through the bypass capacitor 61 to earth and from there via the bypass capacitor 63 to the cathode 4.5.

The (not shown) superposition oscillation generator is with the Control grid 47 coupled by a transformer 65, the secondary winding of which 67 lies in the grid circle of the mixer tube. The high frequency path of this grid circle leads from the grid 47 through a resistor 69, the secondary winding 67 and the Bypass capacitor 71 to earth and from there through the bypass capacitor 63 to cathode 45. The direct current path for the grid bias of this circle runs from control grid 47 through resistor 69, secondary winding 67 and a resistor 73 to earth and from there through a resistor 7 5 in the cathode line to the cathode 45. Resistor 73 and capacitor 71 act as a filter for suppression of Hum that is introduced into the grid circle by the grid bias.

The superimposition frequency is adjusted by means of a (not drawn) capacitor, which is also part of the synchronizing capacitor forms. The circuit of the superimposer and its coupling with the mixer stage is irrelevant to the invention.

Energy is withdrawn from the anode circuit 35 of the tube i by a coil 77, which are coupled to the inductor 37 and their upper end to the electrode 43 of the mixing tube 3 is connected; the lower end of coil 77 is across the resistor 79 grounded.

If high frequency energy, which exceeds a certain amount, occurs in the coupling circuit 35, part of it is applied to the coupling coil 77 transmitted and rectified in the diode path of the tube 3. The current in the The rectifier circuit is such that the upper end of the resistor 79 is negative is against earth. Apparently no rectification occurs in this circle until the The peak value of the signal voltage exceeds the voltage drop across resistor 75. This fact causes a desired delayed use of the shrinkage control.

The negative end of resistor 79 is through a filter resistor 81 connected to the braking grid 15 of the high-frequency tube i. Filter capacitors 83 and 85 are connected between the ends of resistor 81 and ground to provide the filter out high and low frequency components occurring in the rectifier circuit. The dimensioning of the filter elements is such that the braking grid 15 supplied to yours Control voltage in accordance with the mean incident carrier wave amplitude fluctuates. The capacitor 83 also acts as a high-pass capacitor for the resistor 79. As the receive amplitude increases, the top of resistor 79 becomes more negative and the negative bias applied to the brake grid 15 increases.

This causes an increase in the negative retarder bias a decrease in the gain of the tube i and increases its internal resistance down. The reduction in internal resistance broadens the tuning curve of the Circuit 35, since the internal resistance is connected in parallel to the circuit. It's closed notice that the anode current decreases a little as soon as the retarder grid goes negative is made, thereby reducing the negative bias of the control grid will. Although this tends to increase the gain of the tube, it can the effect is neglected in comparison to the influence of the braking grille; with regard to the degree of separation control, the effect of the control on the brake grille supported by those on the control grid.

The anode 53 of the mixing tube 3 is connected via a coupling circuit 87 the positive terminal of the voltage divider 31 is connected. The circle 87 is on the Intermediate frequency matched in the usual way by superimposing the input signal is formed with the vibration supplied by the superimposed vibration generator. The circuit 87 consists of a coil 89 @ and a tuning capacitor connected in parallel 91. The circle 87 is fixed at some frequency, in general is lower than the frequency of the input oscillation.

The intermediate frequency amplifier tube 5 is of the same type as the mixing tube 3; it contains a cathode 93, a control grid 95, a screen grid 97, a braking grid 99, an anode and a rectifier path 103.

The control grid 95 is connected to the upper end of the coupling circuit 87 connected through the capacitor 105. A high frequency path between the cathode 93 and the lower end of the circle 87 is formed by a circle drawn from the Cathode 93 via a bypass capacitor 107 to earth and from there via the Capacitor 61 leads to the lower end of circle 87. The control grid 95 receives a negative bias through an in. of the connection between the cathode 93 and earth bias resistor io9, at the junction of which it is connected by a Grid resistor i i i is connected. It will be noted that in this case the grid bias is smaller than the total voltage drop across the resistor io9, or, with in other words, is less than the delay voltage in the control loop. The height the delay voltage depends on the working conditions of the receiver.

In some cases it may be desirable to adjust the delay voltage to be omitted entirely, so that the widening of the transmitted frequency band starts immediately after receiving a signal. If the delay voltage is lost the cathode is grounded and the grid in the usual way with a negative point of the mains voltage divider connected.

In the same way as. In the previous stage, a coil 113 is coupled to the inductance 89 of the circuit 87 in order to supply high-frequency energy to the electrodes 9.3 and 103 of the diode path in the tube 5 '. The diode circuit extends from the upper end of the coil i13 to electrode 1 03 and through the discharge path to the cathode 93, through the so-called resistance to earth and from there through the resistance i15 to the bottom end of the sink 1. 13

The braking grid 51 of the mixing tube 3 is connected to the upper end of the resistor 115 via a filter resistor 117, whereby the braking grid receives a negative potential, the size of which depends on the amount of energy transferred from the circuit 87 into the coupling coil 113. The capacitors i 19 and 121 connected between the ends of resistor 117 and earth play the same role as capacitors 83 and 85 in the previous stages: more energy is transferred from circuit 87 to the connected rectifier circuit than from circuit 35 to the associated rectifier circuit because the signals were amplified in the mixer. As a result, the braking grid 51 of the mixing tube 3 receives a higher control voltage than the glass braking grid 1 5 of the high-frequency amplifier i. Since the incident signal makes the braking grid 51 more negative than the braking grid 15 of the preceding amplifier stage i; it is clear that the tuning curve of the output circuit 87 of the mixer is widened more with increasing signal strength than that of the preceding tuning circuit 35. In addition, the gain of the mixer 3 is reduced to a greater extent than the gain of the high-frequency amplifier tube i.

The anode ioi of the intermediate frequency amplifier tube 5 is positive Terminal of the voltage divider 31 via a. further voting circuit 123 connected, which includes a coil 125 and a parallel capacitor 127.

The receiving rectifier tube 7 is of the same type as the tube 3 and 5 and contains a cathode 129, a control grid 131, a screen grid 133, a braking grid 135, an anode 137 and a rectifier electrode 139.

The control grid 131 is connected to the upper end of the coupling circuit 123 through a coupling capacitor. The high frequency path between the cathode 129 and the bottom of the circuit 123 is through the bypass capacitor 143 to ground and thence through the bypass capacitor 61 and conductor 59. As in the previous stage, the control grid 131 is negatively biased by the between the cathode 129 and ground connected resistor 47; the grid is connected to one point of the resistor 147 via a resistor 149. The rectifier electrode 139 is connected to the upper end of the coil 151, which is inductively coupled to the coil 125 of the circuit 123. The lower end of coil 151 is connected to cathode 129 through resistor 153, ground, and resistor 147. The negative potential occurring at the upper end of the resistor 153 during the transmission of signal energy to the coil 151 is fed to the braking grid 99 via a filter resistor 155. Capacitors 157 and 159 serve the same purpose as the corresponding filter capacitors in the previous stages.

From the above description and explanation it is apparent that the most effective selectivity control occurs in your last intermediate frequency circuit. Assuming therefore that the two intermediate frequency circuits 87 and 123 are absent of an input signal have the same selectivity, such Increase in signal strength that the volume and selectivity control effective the resonance curve of the second circle 123 will be wider than that of the previous one Circle 87, although the resonance curve of circle 87 itself is also essential was widened.

While in general the resonance curve of the high frequency circles is wider than that of the intermediate frequency circuits, it may be desirable to set the circuits so that that for very strong signals from a local transmitter, the resonance curve of the latter intermediate frequency circuit is wider than that of the high frequency circuits. This state is very easily obtained because the attenuation of the intermediate frequency circuits is extremely high as the signal strength increases grows rapidly compared to the high frequency circuits, where the control voltage is necessary is small.

The low-frequency signal excerpt from the receiving rectifier 7 is a low frequency amplifier (not shown) via a low frequency transformer 161 fed, whose primary winding 163 between the anode 137 and the positive Terminal of the voltage divider 31 is connected. The braking grid 135 is immediate connected to the cathode 129.

The screen grids 13, 49, 97 and 133 of the tubes 1, 3, 5 and 7 receive a positive voltage through lines which are connected to one point of the voltage divider 31. The screen grids are grounded in terms of high frequency through a capacitor 165.

Although the diode rectifier circuits in Fig. I with the anode circuits would be shown inductively coupled; everyone can other suitable Coupling can be used. Two such couplings are shown in Figs. 2 and 3, in which the same reference numerals appear for the parts that correspond to Fig. i.

In Fig.2 is the diode rectifier of the tube 5 with the output circuit of the tube 3 is coupled by a capacitor 167 which is connected between the anode 53 of the Tube 3 and the rectifier electrode 103 of the tube 5 is located. As you can see is the remainder of the switching arrangement is the same as the coupling circuit between the tubes 3 and 5 in Fig. I with the exception that the coupling coil 113 and the filter capacitors 119 are missing. The main difference is that in the case of Fig Series feed of the rectifier and in Fig. 2 a so-called parallel feed is present.

In Fig.3 the rectifier of the tube 5 is fed in parallel by means of the coupling capacitor 167; the difference to Fig.2 is that there the anode voltage is fed to the anode 53 via the tuning circuit 87, while this here by a coupling impedance, z. B. a resistor 169 takes place.

In Fig. 3, the capacitor is loosely between the anode 53 and the Coupling circuits 87, the negative bias voltage generated by the resistor log dem Grid 95 is fed through circle 87. . The coupling capacitor 167 is connected between the top of the circuit 87 and the rectifier electrode 103.

The coupling shown in Figs. 2 and 3 can be used in all amplifier and rectifier stages, which circuits for automatic volume and selectivity control own, be applied. However, some of the rectifiers can also be connected in parallel and another part can be connected in series.

Claims (5)

PATENT APPLICATIONS: i. Receiver with simultaneous shrinkage and selectivity control, characterized in that the selectivity of the with increasing input voltage closer to the output of the receiver to a greater extent is reduced than the selectivity of the circles closer to the entrance. 2. Receiver according to Claim i, characterized in that the selectivity is one each of the tuned circuits is regulated by means of a control voltage, which is achieved by rectification the voltage occurring on this circuit is obtained. 3. Receiver according to claim i and 2; characterized in that the negative as the signal strength increases Braking grid pre-tensioning of the tubes, in the anode circuit of which the regulated circuits lying, be made more negative. q .. Receiver according to claims i to 3, characterized characterized in that composite tubes are used which have an amplifier system Braking grid and a diode path included and connected in such a way that the Diode supplied some of the signal energy to the previous stage and passed through Rectification of the same DC voltage obtained to the braking grid of the previous one Tube is fed in such a way that its potential with increasing signal strength decreases. 5. Receiver according to claim i to q., Characterized in that the diode path receives a negative quiescent bias, consequently rectifying the supplied Signal energy only occurs as soon as it exceeds a threshold value.