DE1260518B - TV receiver with automatic gain control - Google Patents

Description

Television receiver with automatic It is known in broadcast and Television gain control receive the gain of the high and intermediate frequency amplifier stages by one dependent on the amplitude or the mean value of the received signals To change DC voltage automatically for the purpose of shrinkage control. Such DC voltages are mostly derived from the device's demodulator. In many cases this is enough the direct voltage derived from the demodulator is not used to regulate the amplifier stages and must therefore be specially reinforced. Such separate DC amplifiers however, represent an undesirable effort. This effort is avoided if one of the high frequency amplifier tubes present in the circuit in addition to the Amplification of the control DC voltage is used (German patent specifications 726 513 and 734123 and "Textbook of radio reception technology" by P i t s c h, 1st edition, 1948, § 360). Operating voltage fluctuations or unfavorable shifts in the operating point however, put the double use of such high-frequency amplifier tubes in the Practice often narrow limits. To control the DC voltage regardless of the fluctuations To make the image content, it is also known to adjust the DC voltage by adding to win two voltages, the one voltage from the mean value of the rectified Intermediate frequency voltage after the intermediate frequency rectifier and the other Control voltage is obtained on the grid of a pulse separation stage (German patent 854 533). However, this combined tension is sufficient to achieve a Control stroke at the preliminary stages and / or first IF stages - under certain circumstances too small, so that reinforcement is also desirable here.

The invention is based on the object of an already present in the device Use amplifier tube in such a way that operating voltage fluctuations and Shifts in the operating point remain without influence and that is still sufficient large stroke of the control voltage is generated.

The invention consists in a television receiver with automatic Gain control in that the combined from the two DC voltages Control voltage of the control electrode of the penultimate intermediate frequency amplifier tube is supplied, in the cathode circuit of a resistor bridged by a capacitor is switched on, the end facing the cathode via a voltage divider formed resistor is connected to a terminal of negative potential, of whose tapping is a strong DC voltage to regulate the amplification of the high and / or first intermediate frequency amplifier stages is derived.

The invention is illustrated below with reference to one in the drawing Embodiment explained in more detail.

In the drawing, high-frequency amplifier, mixer and - if present - the first intermediate frequency amplifier stages of a television receiver are combined in a block 10, the output voltage of which is fed via primary and secondary windings of a transformer 11 to the grid of a tube 12 of the penultimate IF amplifier stage. The cathode of this tube is connected to ground via a resistor 14 for generating the grid bias voltage and a resistor 15. A capacitor 16 is connected in parallel with the resistor 15. The output voltage of the tube 12 is fed via a transformer 17 to the input of the last IF amplifier stage 18, the output terminals of which are connected via a transformer 20 to a circuit 21 suitable for demodulator. The embodiment shown in the drawing contains a rectifier 23, a capacitor 24 for deriving the intermediate frequency and, connected in series, a resistor 25 and a boosting choke 26. Although the main function of the demodulator stage 21 is to control the video, To supply sound and deflection circuits with the demodulated composite video signal, it is also common practice to use them to generate a voltage for automatic fading control. Such a voltage is mostly derived from the voltage across resistor 25. The negative voltage at the upper end of the resistor 25 is fed to the grid circuit of the IF amplifier tube 12 via a filter resistor 30 and a matching resistor 51. A filter capacitor. 31 connected between the lower end of the grid circle and ground forms, together with the resistor 30, a low-pass filter. Most automatic fade control circuits have the positive or lower end of resistor 25 grounded. To amplify the voltage across resistor 25, this ground connection is canceled and replaced by a capacitor 33 for video frequencies. The corresponding end of the resistor 25 is preferably connected to the cathode-side end of the resistor 15 via a filter arrangement consisting of a filter resistor 32 and the capacitor 16. If resistor 25 were grounded, a cathode amplifier effect would occur between the voltages appearing at resistor 15 and resistor 25, which would result in no amplification because the output voltage of the cathode amplifier can never be greater than its input voltage or the voltage at resistor 15 can never be greater than that at resistor 25.Because the direct current component of the demodulator alone does not always characterize the carrier amplitude, the amplitude of which is solely intended to be a measure of the control voltage, a second direct current component obtained from the grid of the separation stage is transmitted via a resistor 52 at a connection point 55 merged with the DC component of the demodulator. This second direct current component compensates for the control voltage fluctuations due to the image-dependent field strength fluctuations, since, as can be proven, it changes in exactly the opposite way to the control voltage fluctuations of the demodulator component due to the image content. Without this second direct current component, the current standardization would result in a control voltage that is too high for a predominantly black image and thus a reduced image contrast. In contrast, with a predominantly white image, the image contrast would increase significantly, although the carrier amplitude is the same for black and white images. With a suitable dimensioning of the resistors 51 and 52, the control voltage composed of the two components has a constant level at the connection point 55 as long as the input field strength does not change. A small amount JB + of the operating voltage B + is fed to the connection point 55 via a resistor 54. The current flowing through this overcomes the negative noise voltage created by the noise rectification on the demodulator and on the separation stage. When this negative noise voltage is balanced; so the threshold sensitivity is improved.

The gain of the DC component of the demodulator voltage through the tube 12 is not unfavorable for the operation of this tube because it should have an automatic fading control voltage and because this DC component such tension is. But also the small size of this DC voltage is he wishes. This is because the intensity of the carrier signal is in the last IF stages relatively large, so that a large DC voltage in these stages is the carrier signal would shift into a non-linear part of the gain curve. To avoid the distortion caused thereby is in the last intermediate frequency amplifier stages preferably a small control voltage is used.

At first it is not immediately clear that precisely the penultimate one IF amplifier stage and not the last or one of the first stages as a direct current amplifier should be used. The last IF stage is not used because this stage is in the fade control voltage is not supplied to most of the circuits. These The last stage acts as a driver stage for the demodulator circuit and must therefore deliver a large output voltage .. The fading control reduces, however always the available power; therefore, if a fading control voltage of the last Stage would be fed, this stage would not be a favorable driver stage for the demodulator. An earlier than the penultimate stage could be used, but this would be unfavorable, since in the first stages of most circuits a large fading control signal is desired. The output voltage from the demodulator But 21 is too small for these first stages. A great shrinkage control signal is desirable because the shrinkage control works better with larger control voltages. In contrast, large control voltages in the first IF stages cannot cause distortion because the carrier signal has a relatively small amplitude in these stages.

The DC load, i.e. H. the resistor 15, is preferably switched into the cathode circuit of the tube 12 to reverse the phase of the negative directed voltage from the demodulator 21 to avoid. The voltage on the ungrounded The end of the resistor 15 can be negative, although this voltage is always is positive. It may be because of a decrease in positive tension expresses that this tension becomes more negative.

The voltage across the resistor 15 cannot be directly related to the fade control line fed because it is positive. In general, this line is with the Lattice circles of the first stages connected so that with a positive fading control voltage Grid current and other undesirable effects would occur. To oppression of the positive voltage before its use becomes one of the resistors 38 and 39 and the terminal 40 existing biasing arrangement is provided. A not shown, negative DC voltage source is connected to terminal 40. This negative Voltage source must have a constant value. Such a constant, negative Voltage is in television receivers z. B. available on the control grid of the horizontal output tube. The conductor 41, which is connected to the connection point of the resistors 38 and 39 forms part of the fading control voltage line. The effect of the resistances 38 and 39 and the negative voltage applied to terminal 40 is that they adjust the voltage on conductor 41 by one of the in the absence of the signal on the resistor 15 lying positive voltage reduce the corresponding size.

There are two main requirements for an automatic fading control voltage. So this voltage should be practically zero when no signal is received will, around the amplification of a tube with little or no input signal large so that the receiver then has its maximum sensitivity. The other The requirement is that the fading control voltage should be as large as possible, because the shrinkage control is more favorable with high control voltages. As above said there is never too much fading control voltage for the system.

In the following, several equations for dimensioning the circuit are derived which determine the values for the resistors 38 and 39 to meet the first requirement and which determine the value for the voltage across the resistor 15 to meet the second requirement. In these derivatives, V5 represents the voltage at resistor 15, V40 the voltage fed to terminal 40 and R38, R39 the values of resistors 38, 39. Vag is the fading control voltage appearing at conductor 41.

The one flowing through resistors 38 and 39 Electricity is I38 = V15 + V40 R38 + R39. The fade control voltage on conductor 41 is the voltage on terminal 40 minus the voltage increase on resistor 38: In the absence of the signal, Vag is zero; thus is The dash on V5 should indicate that this value of VS applies in the absence of the signal.

From equation (2) it can be seen that resistors 38 and 39 can have many values, but corresponds to any value of resistor 38 only a single value for resistor 39, and vice versa.

In deriving the equation to determine the value of VS for maximum V ", one must remember that VS is the voltage across resistor 15 in the absence of the signal, d. H. the resting value is. This tension can of course only be achieved through the Change in the value of the resistor 15 or the DC anode feed changed will. V5 is therefore a real variable.

From the above equation (1) it can readily be seen that Ea9c is maximum when V15 becomes zero because of the direct current gain, since the subtracted quantity is then a minimum. So Substitution of equation (2) into equation (3) and thus To determine the value of VS for the largest value of VaeC,. <, The first derivative of equation (6) (according to VS) should be set to zero: therefore From equation (8) it can be seen that the voltage across resistor 15 must be infinite for maximum fading control voltage. This is done in a receiver by making the voltage VS as large as possible. In practice, a certain DC voltage must be left for the screen grid and anode of the tube, but the rest of the anode voltage can appear at the resistor 15. The voltage across resistor 15 can, for. B. have a practical upper limit of 150 V when the supply voltage B + is 250 V. This leaves 100 V for the screen grid and anode.

In the drawing, line 41 feeds the fading control voltage via diode 42 and filter 44 to the grid circles of the first IF stages for the purpose of fading control. The diode 42 prevents the fading control voltage supplied to the first stages from becoming positive. If the resistors 38 and 39 have the calculated values, there is of course no risk of a positive fading control voltage occurring. In series production, however, the values of the resistors used in television receivers change, and therefore, for safety reasons, a diode such as diode 42 should be connected between line 41 and ground in order to suppress any positive voltages that may occur. It is also advisable to use a low-pass filter 44 in the circuit in order to prevent a form of breakover oscillation called "motor boating" in the American literature. This filter also eliminates the video and IF signals contained in the fade control voltage.

A delayed shrinkage control, which is often desired, can e.g. B. by others than the calculated resistances 38 and 39 can be obtained if the new values are so are chosen so that the voltage on conductor 41 in the absence of the signal is somewhat positive will. Then the voltage on this conductor is not directed negatively as soon as a Fading control voltage occurs across the resistor 15, but there is a delay on until the resistor 15 has a certain output voltage, e.g. B. supplies 1 to 3 V, before the control voltage becomes more negative. If instead of the resistances 38 and 39 a potentiometer is used, this can be used for range control, z. B. for better reception of signals in edge areas or as a contrast control in the local area.

Claims (2)

Claims: 1. TV receiver with automatic gain control with the help of a combined control voltage, which results from one of the input field strength dependent DC voltage derived from the output resistance of the image demodulator and from a DC voltage derived from the grid circle of an isolation stage composed, characterized in that the combined of the two DC voltages Control voltage of the control electrode of the penultimate intermediate frequency amplifier tube (12) is supplied, in the cathode circuit of which is bridged by a capacitor (16) Resistor (15) is turned on, the end of which facing the cathode has a formed as a voltage divider resistor (38, 39) with a terminal (40) negative Potential is connected, from whose tap an amplified DC voltage for Regulation of the gain of the high and / or first intermediate frequency amplifier stages is derived. 2. Television receiver according to claim 1, characterized in that the voltage divider (38, 39) is a potentiometer. Considered publications: German Patent Specification No. 726 513; 734 123, 854 533; H. P i t s c h, »Textbook der Funkempfangstechnik ", 1st edition, 1948, § 360; "Radio Electronics", May 1956, P. 46.