DE889614C - Tuning indicator for wireless receivers - Google Patents

Description

The usual voting indicators are designed so that their display of the strength of the received Sign is directly proportional. As a result, a faint sign only gets an imperceptible one Display, so that the exact matching of the receiver to such characters is very difficult is. The display sensitivity is even for medium-strong characters the voting indicator is only pretty moderate because the highest display sensitivity for the strongest received characters must be reserved.

It has been proposed to avoid this disadvantage by providing the voting indicator a control voltage variable with the degree of detuning of the receiving device is supplied which increases the sensitivity of the voting indicator in inverse proportion to The strength of the received characters changes. In this case, the voting display is therefore within a wide range The range of received character strengths is approximately the same size, so that the recipient also can easily be fine-tuned for the faintest characters it is still able to reproduce can.

The invention relates to a voting indicator of this type and is characterized in that the first control voltage is generated by a frequency demodulator whose output voltage two control organs of the voting display device fed in two different ways which are such that the two tensions are mutually opposite Change meaning.

The invention is explained in more detail with reference to the exemplary embodiments shown in the drawing.

Fig. Ι shows the circuit diagram of a with the invention Voting indicator equipped receiver for frequency-modulated waves. The recipient contains one connected to an antenna n, 12 High-frequency amplifier 10, to which a superimposed stage 13, an intermediate frequency amplifier. 14, another intermediate frequency amplifier 15, a frequency demodulator 16, a low frequency amplifier 17 and connect a loudspeaker 18. With the output circuit of the frequency demodulator 16, a voting indicator 19 is connected. Parts 10 through 18 of the receiver can be of the usual type, so that a more detailed explanation of their structure and mode of operation is superfluous.

The tuning indicator 19 is a cathode ray tube having an anode 22, a cathode 23 and deflection electrodes 24 and 25. The deflection electrodes are connected to the screen grid 26 and to the anode 27 of an electron tube 21. The electrodes 26 and 27 receive positive voltages via resistors 28 and 29. The tube 21 can, for example, be a power distribution tube, the inner control grid of which is connected to the cathode 31 and the outer control grid of which is connected to the input terminals 20 of the tuning indicator via a screen consisting of a series resistor 32 and a cross capacitor 33. A control voltage is fed to the input terminals 20 from the frequency demodulator 16, the magnitude of which depends on the degree of detuning of the receiver and the polarity of which depends on the direction of this detuning.

According to the invention, the voting indicator receives a second control voltage, which also varies with the degree of detuning of the receiver and which changes the sensitivity of the voting indicator in inverse proportion to the strength of the received characters. This second S expensive voltage is derived from the intermediate frequency amplifier 14, which contains an amplifier tube 34, the control grid 35 of which is connected to the output circuit of the superimposed stage 13 via a doubly tuned band filter 36. The anode 37 of the tube 34 is connected to the input circuit of the intermediate frequency amplifier 15 via a band filter 38 that is also twofold. The control grid 35 of the tube 34 also receives a control voltage for the automatic control of the volume from the intermediate frequency amplifier 15 via a filter network consisting of a series resistor 39 and a shunt capacitor 40. The screen grid 41 of the tube 34, which is connected to a positive voltage source and which receives its bias voltage via a resistor 42 and is grounded via a capacitor 43, is connected via a line 44 to the anode 22 of the tuning indicator tube 19. The mode of operation of the voting indicator is explained with reference to FIGS. 2, 3 and 4. Curves A and B of FIG. 2 show the sensitivity of the receiver, curve A for the reception of strong characters and curve B for the reception of weak characters. As can be seen, the sensitivity in the range between the frequencies f ₁ and f _{2 is} approximately uniform. Since the strength of the character voltages reaching the intermediate frequency amplifier 15 is also a function of the sensitivity characteristics of the receiver, curves A and B simultaneously also show the change in the control voltage for the automatic volume control as a function of the "tuning" of the receiver within its operating frequency range and D sensitivity characteristics of the frequency demodulator 16 is, namely, the curve C is true for the receiving strong character, and curve D for the reception of weak character. As can be seen, the sensitivity of the frequency demodulator is subject to a particularly strong variation in the center frequency / ₀ of the operating frequency range of the Recipient.

It is now assumed that the receiver is precisely tuned to the desired wavelength, so that the frequency-modulated intermediate-frequency voltage of the receiver has the mean frequency / ₀ . Here, the low-frequency filter 32, 33 suppresses all low-frequency modulation components in the output circuit of the frequency demodulator 16, and -den. No control DC voltage is fed to input _{electrodes go} 30, 31 of tube 21, since the average output voltage of the frequency demodulator in this case is zero, as curves C and D show. For this operating state the resistors 28 and gs 29 are chosen so that with the normal operating currents of the screen grid and the anode of the tube 21 the deflection electrodes 24 and 25 of the display tube 19 receive positive voltages of the same magnitude. Each of the deflection electrodes 24 and 25 causes a shadow angle on the fluorescent anode 22 of the display tube 19, the size of which depends on the size of the control voltages applied to the deflection electrodes. At an anodic voltage of about 150 V at the anode 22 changes _1O g to · the shadow angle, depending on the the deflection electrodes 24 and 25 voltages applied in accordance with the curve E in FIG. 3, the horizontal axis represents the deflection voltage applied, vertical during their n ₀ axis shows the magnitude of the deflection. The amount of deflection is the angle enclosed by the boundary lines between the light and dark areas. If the deflection electrodes receive the same voltages, the shadow angles become the same, and the image shown in FIG. 4 a results at the anode of the tube 19 with the dark areas F, G and the light areas H _11. This symmetrical image a sign that the receiver is precisely tuned to the desired wavelength iao.

Now assume that the receiver is out of tune. Then results in the starting circle of the frequency demodulator 16 an average DC voltage, the size of which depends on the degree of mood, and their polarity from the direction

depends on the upset. This DC voltage is applied to the input electrodes 30, 31 of the tube 21. When positive, it increases the anode current and the screen grid current decreased, d. H. the screen grid voltage is increased and the anode voltage is decreased. As a result, the voltages applied to the deflection electrodes, the display tube 19 are not now more equal, so that either at the anode of this tube depending on the direction of detuning the image according to FIG. 4b or the image according to FIG. 4c results.

As a result of the already mentioned supply of the control voltage for the automatic volume control to the control grid 35 of the tube 34, the current of the screen grid 41 of the tube 34 is reduced as the character voltage increases. Since the current of the screen grid 41 flows through the resistor 42 and generates a voltage drop in this, the voltage of the screen grid 41 changes with the strength of the received character. As a result, the voltage applied to the anode 22 of the display tube 19 also changes in accordance with changes in the received character strength. If no character or only a weak character is received, the intermediate frequency amplifier 15 does not supply any control voltage, and as a result the voltages on the screen grid 41 of the tube 34 and on the anode 22 of the display tube 19 have their lowest value. The electrons emanating from the cathode 23 of the tube 19 therefore move at low speed, so that they are deflected by large angles even with small values of the voltages supplied to the deflection electrodes 24, 25. The curve / of Fig. 3 shows the sensitivity characteristics of the display tube at a small constant voltage of the anode 22 of the tube. An increase in this voltage as the received character strength increases results in an increase in the speed of the electrons in the tube, and consequently larger voltage changes are required at the deflection electrodes 24, 25 in order to achieve a given shadow angle. The curves K, E, L of Fig. 3 show sensitivity characteristics of the display tube 19 with increasing voltages on the anode 22 of this tube.
Accordingly, while the sensitivity of the display tube decreases as the symbol voltage increases, the steepness of the sensitivity characteristic of the frequency demodulator increases, as was demonstrated earlier on the basis of curves C and D in FIG. As a result, any deviation of the center frequency of the received character voltage from the mean intermediate frequency f _Q , which results for example during the tuning of the receiver, the deflection electrodes 24 and 25 via the tube 21 supplied control DC voltages, the magnitude of which increases with increasing character voltage. These larger control voltages thus counteract the decreasing sensitivity of the display tube 19 with increasing character voltage and have the consequence that the changes in the shadow angle. become the same size when receiving weak characters as when receiving strong characters.

The size of the resistor 42 in the amplifier 14 is selected in relation to the screen grid voltage of the tube 14 and in relation to the characteristics of the tubes 34 and 19 so that the sensitivity curve of the display tube 19 would have the shape of the dashed curve M in Fig. 3, if the changes in the voltage applied to the anode 22 of the tube 19 and the control voltage applied to the tube 21 would be variable simultaneously and in direct proportion to the character strength received.

The actual mode of operation of the tuning indicator differs from this, however, because the control voltage for the automatic volume control changes when the receiver is tuned according to curves A or B in FIG. This control voltage is therefore essentially constant in the frequency range between the frequencies Z ₁ and f ₂ , while the control voltage for the tuning display changes to a very large extent _{on both sides of the center frequency / 0.} The constant control voltage for the automatic volume control results in a constant anode voltage of the tube 19, the actual value of this voltage, as already mentioned, being variable with the received character strength, so that the display tube operates within the above-mentioned frequency range with a sensitivity characteristic which one corresponds to the curves /, K, E or L of FIG. So while the control voltage supplied to the tube 21 for the tuning display within the frequency range Z ₁ -Z ₂ changes depending on the received signal strength according to curves C or D , the tuning display changes in the same frequency range according to one of the curves /, K, E or L of FIG. 3 or according to a curve lying between these, starting from a shadow angle of 90 ^° up to that smallest shadow angle at which the relevant sensitivity curve intersects the curve M shown in dashed lines.

In this way, a clear tuning indication is achieved in which the greatest change the shadow angle has the same value, regardless of whether it is the reception of a weak one or a strong sign. As a result, the greatest sensitivity is no longer required here of the voting indicator to reserve the largest character widths, as before was required.

The voting indicator according to the invention can of course also be used for reception at receivers amplitude-modulated carrier waves are used. In this case you want next to the ad To get an indication of the direction of the detuning of the degree of detuning, one must the device, however, in addition to the usual tuning demodulator, also has a frequency demodulator

8891614

for generating the control voltage for the tuning indicator. To the resulting To avoid additional costs, one will usually be satisfied with a voting indicator that only shows the degree of detuning. Fig. 5 shows an advantageous embodiment of a such simplified voting indicator according to the invention. So here follows the intermediate frequency amplifier 14, 15 an amplitude demodulator 16 ', which also provides the control voltage for the automatic volume control supplies. The tuning indicator tube 19 'is different from that in receivers type commonly used for amplitude modulated carrier waves and includes one of a Cathode 23 ', a control grid 45 and an anode 46 consisting of triode part. The anode 46 of the triode part is connected to the deflection electrode 24 'of the display part, behind which the Display anode (luminescent screen) 22 'is located. The anode 46 and the luminescent screen 22 'receive theirs Voltage also from the screen grid 41 of the tube 34 via a resistor 47.

An arrangement 48 is used to generate the display voltage, which contains a parallel resonance circuit 49 of high figure of merit, which is sharply _{tuned to the mean intermediate frequency / 0} 'of the amplifiers 14 and 15. The pass band of the circuit 49 is much narrower than that of the receiver and should not be more than 2 to 3 kHz in the event that the pass band of the receiver is about 10 kHz. The resonance circuit 49 is shielded, as indicated by the dashed-line rectangle, and is connected to the output circuit of the intermediate frequency amplifier 15 via a small capacitor 50, the capacitance of which should be 1 to 2 pF: This small capacitance is desirable to prevent the effect of the resonance circuit 49 to the resonance circuits of the intermediate frequency amplifier 15 and the amplitude demodulator 16 '. A rectifier 51, a load resistor 52 and a capacitor 53 connected in parallel therewith are connected in series to the resonance circuit 49. The size of the resistor 52 should expediently be several megohms so that this resistor does not reduce the figure of merit of the resonance circuit 49. The capacitance of the capacitor 53 should be so large that the time constant of this capacitor and the resistor 52 is large in relation to the period of the lowest modulation frequency of the received carrier wave, so that the modulation is suppressed by the switching elements mentioned. Resistor 52 and capacitor 53 are connected between control grid 45 and cathode 23 'of display tube 19'.

The operation of the arrangement of FIG. 5 is substantially similar to the arrangement to that of FIG. 1. They will be explained with reference to FIG. 6, in which the curve N, the sensitivity characteristic of the receiver when receiving strong character and the curve O, the sensitivity characteristic of the Receiver when receiving weak characters. Within the frequency range which is limited by the frequencies f { and / _{2 'on both sides of the g 5} mean intermediate frequency / ₀ ', the sensitivity of the receiver is approximately uniform. The curves P and R represent the resonance curves of the resonance circuit 49, namely the curve P applies to large character thicknesses and the curve R for small character thicknesses.

The control voltage taken from the demodulator 16 'for the automatic volume control changes when the receiver is tuned in accordance with its sensitivity characteristics, so that the curves iV and O simultaneously also output the changes in this voltage. This control voltage controls the voltages of the screen grid 41 of the tube 34 as well as of the anodes 22 'and 46 of the display tube 19' for the reasons set out in connection with FIG the curves N and O run.

It can therefore be seen that the anodes 22 '. and 46 voltages applied to the tube 19 'remain substantially the same within the tuning range f - [- f £ of the receiver. Conse- _go whose dieEmpfindlichkeitscharakteristik the display tube according to the strength of the received character one of the curves /, K, E or L corresponds to FIG. 3. In the rectifier 51, a part of the output voltage desZwischenf requenzverstärkers is g ₅ 15 rectified, and in the load circuit 52, 53 there is therefore a direct voltage which is free of modulation components and which is fed to the control grid 45 of the display tube 19 '. Since the magnitude of this DC voltage, when changing the tuning of the receiver changes very quickly and its minimum value at the central intermediate frequency / ₀ 'has, while the anode voltages of the display tube 19' approximately within the entire tuning range are equal, _lo g, it is apparent that the entire tuning display is also variable according to one of the curves /, K ₁ E or L of FIG. 3, depending on the size of the control voltage for the automatic volume control, ie depending on the strength of the received character. A received character of relatively low strength, e.g. B. one, upon receipt of which the sensitivity characteristic of the display tube 19 'corresponds to the curve / of FIG. 3, causes a lower display voltage in the switching arrangement 48. This voltage can e.g. B. be shown by the curve R in FIG. Although the largest value of this voltage is relatively small, this voltage can cause a significant change in the shadow angle of the display tube due to the steep sensitivity characteristics of the display tube 19 ', as shown by the curve / Fig. 3. On the other hand, a received character of greater strength, which has a reception running according to the curve L of FIG.

Sensitivity characteristic of the display tube ig ' causes a larger display voltage corresponding to curve 0 of FIG. 6, which also causes a large change in the shadow angle of the display tube ig' . The switching elements of the voting indicator can easily be dimensioned in such a way that, at the mean intermediate frequency f ₀ ', a display of the same size results when receiving weak characters as well as when receiving strong characters.

Since the anode 46 of the triode part of the display tube 19 'also receives its voltage from the screen grid 41 of the amplifier tube 34 receives, there is a greater amplification when strong characters are received the display voltage applied to the control grid 45 of the tube 19 '. If this is undesirable is, the anode 46 can be connected to a fixed voltage source.

Experience has shown that it is advantageous for achieving a uniform tuning display if the demodulator 16 'effects a delayed automatic volume control. The magnitude of the volume control voltage should be determined with regard to a relatively weak character, for example with regard to a character whose reception the sensitivity characteristic of the display tube 19 'corresponds to the curve / of FIG. 3. In this case, should be such that 'no control voltage is generated before the shadow angle of the tube 19' in the demodulator 16 has up to about 45 ⁰ closed when tuning the receiver, the size of the delayed volume control voltage.

Another advantage of the on-order according to the invention is that the luminosity of the Display tube 19 'depends on the strength of the characters received. As the vote progresses of the receiver on a desired character is the brightness of the bright parts of the The display picture is getting bigger, so that in this way one is already a sign of the approach to the desired wavelength before the tuning indicator actually comes into effect.

7 shows a modification of the arrangement according to FIG. 5, in which a display device ig " with pointer and scale is used in place of the display tube ig ' . This device has a field winding 54 connected to the cathode circuit of the amplifier tube 34 and one connected to the switching arrangement 48 connected movable winding 55, to which a pointer 56 is connected.

The mode of operation of the arrangement according to FIG. 7 differs from that of the arrangement 5 in that the control voltage supplied to the control grid 35 of the amplifier tube 34 for the automatic volume control both the anode current and the screen grid current the tube 34 changes. Since these currents through the cathode circuit of the tube 34 and thus also flow through the field winding 54 of the display device 19 ″, occurs when there is a change in the received Character strength also a change in the sensitivity of the display device 19 ". Strength Characters that generate a large volume control voltage and the discharge current of the tube 34 reduce, also cause a correspondingly large weakening of the electromagnetic field of the Field winding 54. The large display voltage supplied to the movable winding 55 here causes an adjustment of the pointer 56 by an angle which is the same as that which is at Reception of a weak character results in a smaller volume control voltage and thus causes a larger current in the field winding 54.

Claims (1)

PATENT CLAIMS: i. Voting indicators for wireless receivers with a voting indicator, for example a cathode ray tube, one with the degree of detuning of the receiving device variable control voltage is supplied, the tuning display device also with the degree of detuning of the Receiving device variable second control voltage is supplied, which the sensitivity of the voting display device changes in the inverse proportion of the strength of the received characters, characterized in that that the first control voltage is generated by a frequency demodulator whose output voltage two control elements of the voting display device via two different ones Paths are supplied which are such that the two voltages merge into one another change in the opposite direction. 2. voting indicator according to claim 1, characterized in that the first control voltage is the control grid of a power supply divider tube is fed and fed to the two control elements of the voting display device Voltages taken from the screen grid or from the anode of the power distribution tube will. 3. voting indicator according to claim 1 or 2, characterized in that the second control voltage is derived from the control voltage generated in the receiver for the automatic volume control, n ₀ 4. voting indicator according to claim 3, characterized in that the second control voltage taken from the screen grid of a tube regulated by the volume control voltage will. 5. voting indicator according to one or more of the preceding claims with a than Voting display device serving cathode ray tube, characterized in that the the first control voltage of the deflection electrodes and the second control voltage of the anode of the Display tube is supplied. 6. voting indicator according to one or more of the preceding claims with a than Voting display device serving cathode ray tube and one of these upstream or amplifier tube bayed together using a common cathode, characterized in that the first control voltage is applied to the control grid of said amplifier tube and the second control voltage is applied to the anode of the amplifier tube connected to the deflection electrode of the display tube. . - J. Tuning indicator according to Claim 6, characterized in that the first control voltage is generated by a rectifier connected to the receiving channel of the receiver and is fed to the control grid of the amplifier tube via a highly selective resonant circuit. 8. voting indicator according to one or more of claims ι to 5, characterized in that that the tuning indicator consists of a moving coil instrument, one of which Winding the first control voltage and its other winding the second control voltage (or currents dependent on these voltages) is (are) supplied. Referred publications:
.. German patent specification No. 691 718. 1 sheet of drawings © 5389 8.53