DE1027719B - Oscillating circuit with controllable frequency, especially for television receivers - Google Patents

Description

GERMAN

The invention relates to an oscillating circuit with a controllable frequency.

Controllable frequency oscillator circuits are used for numerous purposes. It has to be z. B. be guaranteed when receiving television characters that the image scanning in the receiver is always synchronized with that of the transmitter. For this purpose, included by broadcasting stations broadcast television characters line frequency and frame frequency synchronization pulses, which in the receiver serve to control the line rate and frame rate deflection. It turned out to be Proven to be particularly advantageous, an automatic frequency control for the line frequency synchronization circuit in the receiver to be provided in order to prevent the synchronous operation from being stepped out in the event that significant interference signals from time to time Time to be superimposed on the television sign. To ensure that synchronization is inevitable, can adjust such automatic frequency control. for example consist of a phase comparison arrangement, which together with a reactance tube or another frequency control circuit is operated. Usually there are special levels of receivers for each of the tasks of synchronizing pulse separation, the phase comparison between the incoming Synchronization pulses and the locally generated deflection pulses and the frequency control the local deflection generator provided. In addition, another deflection generator is usually used, to frame rate deflection pulses for the television picture display device to deliver.

Furthermore, in the known television receivers with automatic frequency control for the line frequency deflection generator often has diodes for phase comparison of the incoming synchronization pulses used with those of the locally generated deflection pulses. With such an arrangement Interference pulses that occur between the adjacent synchronization pulses can affect the control voltage affect that gets to the frequency control circuit, resulting in incorrect synchronization Consequence. In order to avoid such incorrect synchronization, it is known that incoming Blanking out synchronization pulses; the arrangements used for this have the disadvantage that they need an additional number of switching elements and therefore in the commercially available Television receivers are generally not used.

According to the invention, in an oscillating circuit with a controllable frequency, the desired Frequency control carried out without a special control stage, for example in the form of a Reak oscillating circuit

with controllable frequency,

especially for television receivers

Applicant:

Zenith Radio Corporation,
Chicago, 111. (V. St. A.)

Representative: Dr.-Ing. H. Ruschke, Berlin-Friedenau,

and Dipl.-Ing. K. Grentzenberg, Munich 27,

Pienzenauerstr. 2, patent attorneys

Robert Adler, Northfield, 111. (V. St. Α.),
has been named as the inventor

Dance tube or the like. Is required. The new circuit is particularly for a synchronization circuit of a television receiver.

The circuit according to the invention consists of an oscillating circuit with controllable frequency, in which an almost sinusoidal symbol is delivered by a filter in response to an applied periodic symbol is, with which a limiter circuit, through which the sinusoidal symbol in a symbol with periodic sudden changes in the steepness is converted, which in turn is coupled with a differentiating circuit for generating pulses of opposite polarity on said sudden change in the steepness. Furthermore, this differentiating circuit is with coupled to an arrangement that only responds to pulses of one of the two polarities to win of a periodic character and is connected to the input of the filter, whereby a closed feedback loop for undamped oscillations is created; further is a device to apply a control character to the limiter to change the phase of the sudden Change of slope provided for controlling the frequency of the oscillations.

709 959/133

The invention is now based on the drawing with periodic sudden changes in the pitch explained in more detail. to be replaced. Circuit 3 can be any

1 shows a block diagram of a differentiating device known from vibration Circuit with controllable frequency according to the. The direction-sensitive arrangement 4 can Invention; 5 from a diode or triode rectifier or

Fig. 2 and 3 show circuit diagrams of oscillation but from a deflection generator with a disconnection with controllable frequency according to the charge tube with or without power output stage beErfindung dar; stand.

FIG. 4 shows schematically a television receiver. The circuit diagrams of the exemplary embodiments of FIG

with an oscillating circuit according to the invention; io oscillating circuits with controllable frequency according to Fig. 5 illustrates another television receiver incorporating the invention are shown in Figs. According to an oscillating circuit according to the invention. Fig. 2 is a current resonance circuit, consisting of

The oscillating, shown schematically in FIG. 1, the capacitor 7, the inductor 8 and the Circuit with adjustable frequency according to the invention primary winding 9 of a transformer, as a filter for application contains a filter 1, a limiter circuit 2, 15 delivering an almost sinusoidal oscillation, a differentiating circuit 3 and a directional The ferromagnetic core 10 of the transformer

sensitive arrangement 4, the pulses only one is used for trimming as a result of the existing Allows polarity to pass; Furthermore, the line 5 is hysteresis. Therefore, the core 10 consists of one the direction-sensitive arrangement 4 with the FiI material with a step-shaped magnetization window 1 coupled so that the characteristic of this arrangement 20, ζ. B. comes from a known nickel character to the filter 1, a ge-iron alloy. The differentiation takes place in an closed feedback loop arises and in a known manner as a result of the inductive resistance Circuit undamped oscillations generated state of the secondary winding 11, which with the one. The filter 1 provides an almost sinusoidal output circuit to which the triode 12 is coupled. The triode 12 Vibration which, by means of the limiter 2, is converted into a 25 due to its lattice discharge resistance rectangular or otherwise modified bias voltage that it only applies to positive pulses on-waveform speaks with sudden changes in slope. The load on the triode 12 consists of the is reshaped. Pulses with the opposite current resonance circuit mentioned above, whereby the reverse polarity coupling loops arise in response to such sudden changes. The control character is generated by the differentiating circuit 3; In the terminals 13 and 14 of the pulses lying on the core 10 of only one polarity are fed through the auxiliary winding 15. In practice direction-sensitive arrangement 4 passed, the leakage inductance of the primary winding can reduce the that a periodic output pulse arises, which replace the special induction coil 8, is in turn fed back to the filter 1. In operation, the sinusoidal generated in the

Amplifier stage, not shown, can provide a current flowing almost to the right, so that at least one amplification of an angular curve of the magnetic flux in the core 10 Neper is ensured, so that damped oscillations circulate in the circuit due to its step-shaped magnetization characteristics, although a forward line. The steep front and rear waves, preferably the switching elements 1, 2, 3 and 4, should be front of the rectangular magnetic flux curve so that they will deliver a sufficiently large voltage due to the differentiating effect of the amplification and also their other inductance of the secondary winding 11 perform tasks assigned to them in tension. A control pulse of opposite polarity is converted; character source 6 is coupled to the limiter 2, the negative pulses are blocked by the triode 12 to the phase of the sudden change in slope.

at the output of limiter 2 compared to phase 45 The phase position of the leading and trailing edges of the input character supplied and around the rectangular curve of the magnetic flux thus controlling the frequency of the oscillation. That by the core 10 changes accordingly control characters coming from voltage source 6 control characters applied to terminals 13 and 14, can - with an automatic frequency control- In the same way, the phase of the differential circuit changes - a unidirectional sign or 50 ornamental impulse on the input circuit of the same a frequency modulator a news reporter. Such a phase change becomes Be signs. z. B. respond to phase shifts

The individual circuits of the oscillating circuit with the oscillator cause a change in the operating frequency adjustable frequency according to the invention can occur. With it an automatic frequency control be constructed in different ways. In this way, the filter 1 55 can take place, the terminals 13 and 14 can be fed z. B. from a passive oscillation circuit with control characters a unidirectional, from one concentrated inductances and capacitances, output piezoelectric originating from a phase comparison arrangement Be crystal or any other tension; to consist of a frequency-modulated off-resonance circuit. The limiter 2 can supply the control character as an output voltage Deflection control tube, as an intensity control 60 but also of a different nature, z. B. a lowerable tube with a step-like transmission frequency sign.

characteristic or be designed as a transformer core, in the circuit of FIG

which has a stepped magnetization curve a piezo-electric crystal 16 controlled, sine, by each of these switching means the sinusoidal oscillation to the input grating 17 of the Shaped input oscillation in a rectangular 65 electron tube 18 of the type with intensity symbol pulse reshaped. Control and stepped transfer characteristic

However, this is not the main self-supplied. The cathode of this tube 18 is on the shaft of the limiter 2, and it can be grounded through a resistor 19, and between the input simple Half-wave rectifier or another pre-grid 17 and earth is connected to the capacitor 20, Direction to Generate Altered Character 70 The anode 21 of the tube 18 is on the positive

Voltage pole B + via the primary winding 22 of the output transformer 22, the secondary winding 23 of which is connected to the diode or the germanium rectifier 25 via the series resistor 24. To close the feedback loop, the rectifier 25 is coupled to the piezoelectric crystal. The terminals 26 and 27 for applying the control characters are connected to the terminals of the resistor 19.

In operation, the piezo-electric crystal 16 acts like a filter that responds to vibrations, as a result of which an almost sinusoidal oscillation occurs on the capacitor 20, and a step-shaped transfer characteristic having tube 18 serves as a limiter to the sinusoidal input character in to reshape a rectangular sign with steep anterior and posterior impulse fronts. The front and rear pulse fronts are differentiated due to the inductance of the secondary winding 23 and deliver pulses from alternately opposite directions. The negative impulses will be deleted via the rectifier 25. The positive pulses are transmitted to the piezo-electric crystal 16 fed, which works like a passive oscillation circuit and stimulates sinusoidal oscillations will.

The oscillating circuit with adjustable frequency according to the invention is particularly for synchronizing suitable in a television receiver as shown in FIG. With this television receiver the incoming television characters are received by an antenna 28 through a high frequency amplifier 29 amplified and converted in frequency by a superposition stage 30. the Intermediate frequency tone signals coming from the superimposition stage 30 are generated by the intermediate frequency amplifier 31 amplified and limited to it by means of a limiter and frequency demodulator 32 and rectified. The low-frequency output voltage of the demodulator 32 is through the Low frequency amplifier 33 amplified and a loudspeaker 34 or other sound reproduction device fed.

The intermediate frequency picture symbols coming from the superimposition stage 30 are represented by a Intermediate frequency image intensifier 35 is amplified and fed to an image demodulator 36. The one from the image demodulator 36 coming rectified image characters are the image intensifier 37 and from there the Input circuit of a cathode ray tube 38 or other picture display device supplied.

Optionally a differential carrier system can be used, in which case the intermediate frequency gain of visual and audio signals is made in a single channel.

In order to ensure that the receiver runs synchronously, there is also a synchronization circuit with the image frequency deflection generator 39 and the line frequency deflection generator 40 are provided. the Frame rate deflection voltages from generator 39 and the line rate deflection voltages from generator 40 are applied to the associated deflection coils 41 and 42 of the image display device 38.

In the known television receivers, the synchronous operation of the image frequency and line frequency deflection generators by a synchronizing circuit with a synchronizing pulse separator, a phase comparison stage and a reactance tube for automatic frequency control or another frequency control circuit, the synchronizing pulses of the rectified television signal for the frequency and phase synchronization of the respective deflection generator responds, achieved; with the known Recipients are provided with these tasks by a rather intricate circuit of at least three Electron tubes solved. On the other hand, all these tasks can be achieved by the oscillating circuit according to the invention can be carried out in a simple manner.

The demodulated television signal with positive line frequency and frame frequency synchronization pulses is transmitted from the terminals 43 and 44 of the image intensifier 37 via a coupling capacitor 45 and a grid resistor 46 to the control grid 47 and the directly grounded cathode 48 in the left system 49 of the electron tube 50 (cf. 4) fed. Bundling electrodes 51, 52 and 53 are connected to cathode 48 inside the tube. The acceleration electrodes 54 and 55 are connected to the positive pole B + of a DC voltage source via the resistor 56 and are grounded via the bypass capacitor 57. The anode 58 is connected inside the bulb to the deflection electrode 59 of the right system 60 of the electron tube 50 and also via the series resistors 61 and 62 to the positive pole B + of the voltage source; The capacitor 63 is parallel to the resistor 64, and a further capacitor 64 is connected between the junction 65 of the capacitors 61 and 62 and earth. In the same way, the anode 66, in particular inside the bulb, is connected to the deflection electrode 67 of the right-hand system 60 and also via the series resistors 68 and 69 to the positive pole 5+ of the voltage source. The capacitor 70 is parallel to the resistor 68; capacitor 71 is connected between junction 72 of resistors 68 and 69 and ground. Each junction 65 and 72 is connected to the end anode 73 via the resistor 74 and 75, respectively. The end anode 73 is connected to the positive pole B + of the voltage source via the output load resistor 76 and also to the frame rate deflection generator 39; The grounded, storing capacitor 77 is also connected to the end anode 73.

The electron gun 48, the focusing electrode 51, and the accelerating electrodes 54 and 55 of the left system 49 of the electron tube 50 are also built into the right system 60. The right system 60 also includes electrostatic deflection electrodes 59 and 67 which are connected to the anodes 58 and 66 of the left system 49. The system 60 on the right also has the output anode 78 and the collecting anode 79 with its collecting end 79 α, which is arranged in the center with respect to the undeflected path of the electron beam emanating from the cathode 48. The collecting anode 79 is connected to the acceleration electrodes 54 and 55 inside the piston. The output anode 78 is connected to the positive pole B + of the voltage source via the load resistor 80 and to the line frequency deflection generator 40 by means of a differentiating circuit containing the coupling capacitor 81 and the input resistor 82.

The z. B. trained in a known manner generator 40 feeds the deflection coil 42, with which a small Resistor 83 is connected in series. The voltage drop across resistor 83 becomes the series connection from the one with the electron tube 50

7 8

cooperating magnetic deflection coil 84, capacitor 81 and resistor 82 coupled,

and the tuning and phase capacitor 85 which are dimensioned so that this series connection a

out, which is tuned to the line frequency. Has time constant, which compared to the line

In operation, the demodulated television frequency period is short, which results in a differentiating

character that creates the positive line frequency and image rendering effect.

Containing frequency synchronization pulses, over which the zero crossing of the current in the coil coupling capacitor 45 and the grid resistor 84 are not exactly in phase with the incoming 46 on the control grid of the left system 49 of the line frequency synchronization pulses, the electron tube 50 is given. In order to obtain a separated double phase of the limited synchronization character appearing at the resistor 80, the output pulse is automatically rotated forward in such a direction by an amount per time constant of the input circuit containing the capacitor 45 and the input circuit, which is proportional to the deviation from the synchronism and resistor 46, that the synopsis is at least so large that it is restored to the period chronism,
corresponds to the frame synchronization frequency. Since the incoming line frequency synchronization characteristic of the control grid 47 a stepped 15 pulses can z. B. temporarily compared to the curve with two input voltage ranges with deflection current flowing through the coil 84 with a slope of almost 0, which lag behind through an input phase. If the polarity of the current flowing through the coil voltage range of high gradient is such that it points, the control grid 47 allows the left part of the sheet-like electron beam from the collecting sheet-like electron beam to pass through the anode 79 to the output anode 78 , ie when the control grid potential exceeds a predetermined when the oscillation of the deflection current almost in the minimum positive value, ie, the instant passes through zero when a line frequency control grid 47 acts as a selective beam blocker. Synchronization pulse is expected, the grid current during the synchronization pulse from the anode 66 is greater than that of the grid 47 flowing through the control grid 47 the anode 58 collected; Gaps automatically pre-tensioned. Since the voltage at the anode 66 will thus decrease against the control grid 47 to a slotted acceleration above that at the anode 58. Therefore, the electrode follows, the grid current characteristic is limited, electrostatic deflection field, between which with and only the central synchronizing pulse parts are directly connected to the anode 58 and 66 in the electrodes 59 and 67 in the coil that pass through the control grid 47 84 reproduced electron beam. against the built-up magnetic deflection field,

If now the one by the magnetic deflection coil and the lateral deflection of the beam in the right

84 flowing alternating current such a phase up system 60 of the electron tube 50 from left to

shows that it runs through zero exactly when the 35 on the right is delayed.

Line frequency synchronization pulses occur, then during the oscillation period under consideration fi the electron beam passing through the control grid 47 will therefore stop the movement of the beam delayed during the line frequency synchronizing anode 79 to the output anode 78, and pulse gaps running, not deflected and the negative pulse appearing at resistor 82 divided equally between the anodes 58 and 66 - 40 remains in phase with the incoming line frequency. As a result, the output voltages are synchronizing pulses.

On the other hand, the line frequency synchronism occurs at the output circuits of the anode 58 or 66

the other is the same if the deflection current is exactly in sierimpulse in an instant that of the coil 84

Phase with the incoming line frequency syn- supplied deflection characters before, the span-

chronisierimpulsen is located. 45 voltage at the anode 58 compared to that of the anode 66

At the same time, the part of the planar is reduced, and the articulating field between the deflecting beam, the electrostatic field which is set by the electron gun 48 electrodes 59 and 67 in the right system 60 of the electron tube 50, is deflected in such a direction that it transmits, periodically in a lateral direction the lateral deflection of the beam in the right is supported in accordance with the system 60 built up by the coil 84, and the triggering of the alternating magnetic deflection field is deflected. If a negative pulse occurs at resistor 82, a negative pulse at resistor 82 is accelerated. In this way, the phase will occur every time the beam moves from the shifting of the deflection of the collecting anode 79 occurring in the coil 84 to the output anode 78, current with respect to the incoming line frequency and a positive pulse arises at the resistor 82 compensates for 55 synchronization characters,
whenever the beam moves back from the exit anode 78 through the left system 49 of the electron tube 50 to the collecting anode 79. the synchronization characters are thus separated and the deflection current flowing through the coil 84, the phases for the automatic frequency control, as has already been assumed, compensate for such. A deviation from the phase lock phase to go through zero exactly in the eye between the incoming line frequency gazes when the line frequency synchronizing synchronizing pulses and the pulses from the generator 40 occur and when the coil 84 is mirrored with respect to supplied deflection pulses in an under. Electron tube 50 is magnetized so that the symmetry between the voltages at the anode electron beam in the right system 60 in these 58 and. 66 reflected. This voltage asymmetry is instantaneously moved from the collecting anode 79 to the output 65 directly to the electrostatic deflection anode 78, so occur at the resistor 59 and 67 in the sense that the negative output occurring at the 82 synchronous with the line frequency resistor 82 negative output -Synchronization pulses on. These pulses are used to compensate for the phase difference by accelerating or rator 40 a just sufficient amount to trigger the line frequency deflection gene, and therefore are to be decelerated with generator 40 of 70. The line frequency deflection gene

rator 40 is triggered at exactly the right moment to deflect the image receiver synchronized with that of the transmitter.

In order to avoid synchronization errors and "falling out of step" when the incoming line frequency synchronization pulses are temporarily covered by external interference, is the output circuit that works with the anodes 58 or 66, in the one case the resistor 62 and the capacitor 64 and in the other case the resistor 69 and the capacitor 71 contains, so dimensioned in its time constant that it is the multiple of one Line duration corresponds to. The time constant can e.g. B. approximately equal to a hundred times the length of a line to get voted. As in the known automatic frequency control arrangements, however, must storing effect of the output circuits so far limited that the line frequency deflection generator can initially operate in phase with the incoming line frequency synchronization pulses, when the receiver is put into operation.

The capacitors 65 and 70 serve to divert those occurring between the deflection electrodes 59 and 67 Alternating components of the control voltages, for the same purpose, can be placed between the deflection electrodes 59 and 67 a single capacitor, not shown, can be switched. Because those on the electrodes 58 and 66 occurring voltages for the automatic frequency control by systems to the Electrostatic deflection electrodes are used, these voltages can be applied directly to the deflection plates be placed; Blocking capacitors are not needed because of an electrostatic deflection system works most effectively when equal positive biases are applied to the electrostatic deflection electrodes lie.

Since the time constant of the input circuit containing the capacitor 45 and the resistor 46 at least as long as the period of the frame rate is made the frame rate sync pulses also separated, and the middle parts of these impulses supply the load resistance 76 negative pulses with constant amplitude.

These pulses can be integrated by the capacitor 77 and the frame frequency deflection generator 39 are fed to the synchronism of the frame frequency deflection in the receiver with that of the transmitter maintain. It should be noted that parts of the frame sync pulses in the resistor 76 output characters are not reproduced because the beam passes through the anodes 58 and 66 is temporarily caught when it hits these anodes by the magnetic deflection coil 84 is steered. Due to the symmetrical arrangement of the anodes 58 and 66 with respect to the path of the undeflected electron beam passing through the control grid 47 ensures that these non-uniformities in the frame rate output pulses on the interlaced scan im Recipient does not exert an unfavorable influence. In the arrangement of FIG. 4, however, the irregularities in the frame rate pulses that are used to drive the generator 39, by the Resistors 74 and 75 avoided, which are connected in such a way that the output voltages of the Anodes 58 and 66, to which the Enidianode 73 sum to get the frame rate output pulses.

In addition, the image frequency output pulses can also be obtained directly from the anodes 58 and 66 if these anodes are made sufficiently wide to completely absorb the electrons of the beam deflected laterally by the deflection current applied to the coil 84.
Such an arrangement makes a separate collection anode unnecessary; however, as will be explained later, it may be preferable to use a collector anode in conjunction with narrow anodes 56 and 66 to avoid interference.

ίο Because the magnetic distraction for the right System 60 of electron tube 50 by the output current of line frequency deflection generator 40 takes place and the output voltage of the anode 78 of this system tilting pulses for the line frequency deflection generator 40 supplies, a feedback loop is established through the self-exciting Deflection vibrations are generated. The line deflection generator 40 could in itself also be externally excited However, a generator is used to ensure the use of the oscillation in the feedback disc preferable that provides self-excited vibrations.

If a sweep generator is used that is responsive to positive tilting pulses, it is merely required to reverse the direction of the magnetic field generated by coil 84.

In the example shown, it is recommended that the lateral magnetic deflection of the sheet-like electron beam be effected by an external coil 84 which is fed with the line frequency deflection current. In order to obtain a maximum deflection for a given field strength, it is advisable to manufacture all electrodes following the second acceleration electrode 55 from non-magnetic material. As the material for the electron gun and the intensity control system, each magnetic or non-magnetic material ^v is concerned, since the deflection is quite unimportant in this part of the device.

While in the arrangement according to FIG. 4 a branched off part of the output current from the deflection generator is used to energize deflection control coil 84, it will be understood that for this purpose another current running synchronously with the line deflection frequency can also be used. Around Achieving a sufficient lateral deflection of the electron beam is in practice a deflection field of about 10 Gauss required; this equates to less than 1% of that indicated by the lines-Sun frequency deflection coils 42 in the yoke of the image display device 38 consumed energy.

A synchronization control unit built according to the invention grants great advantages in a television receiver. The SynAronisierzaichm separation, the Phase comparison for automatic frequency control and the frequency control of the line frequency deflection generator are all in one stage by a single simple electron tube with a minimum Effort achieved by associated circuits.

In the arrangement of FIG. 4, a further advantage is also achieved. While the control grid 47 is controlled in such a way that there are selected central parts of the incoming synchronizing pulses passes, foreign interference pulses of sufficient amplitude are also allowed to pass, see above that they extend into the sync pulse area between adjacent sync pulses. However, these extraneous glitches in no way contribute significantly to the output voltage of the

709 959/133

11 12

Phase comparison arrangement at, since the supplied by the 85, whereby a periodic, lateral down control grid 47 is caused during the gaps between the steering of the electron beam inside the tube through the adjacent synchronizing pulses through 86. The electrons emanating from the generator 40, all but two small incoming line frequency pulses, are applied to the time segments of each line frequency period due to the action of the deflection control coil 84 of the image display device. Collective anode 73 are added. It will thus- The electron tube 86 and its associated with the elimination of a substantial part of the circuit components contain a phase distortion impulse in addition to the other described equal arrangement in which the phase reaches the line frequency results. While this per se known ^lo synchronizing with the Zeilenfrequenzist this result, types is always compared only by an additional number in operation among the recipients of earlier Ablenkimpulse, which are applied to the coil 108th Im balanced, has been achieved by circuits. . auszeich-In by an accurate phase synchronism to one another in Fig training 5 nenden illustrated state, the resistors 98 and to the execution example of the invention are the syn S ¹ 99 DC potentials occurring chronisierzeichentrennung equal to each other and the phase comparison; and therefore occurs between the electrical devices commonly used for the automatic frequency control through static deflection electrodes 59 and 67 of the tube 86; on the other hand, there is no DC voltage difference. The electron frequency control of the line frequency deflection beam in the tube 86 is carried out according to the magneto generator by an electron tube 86, ²⁰ alternating magnetic field of the magnetic deflection, which only the right system 60 of the coil 84 shown in FIG at put electron tube contains. Resistor 80, as has also been discussed in connection with FIG. 4. Terminals 43 and 44 of the television image intensifier, periodic output pulses 37 according to FIG. 5 are applied to the sync mark separators. These pulses are coupled through the capacitor circuit 87, which ^{can be differentiated and used in a known 25} 81 and resistor 82 manner. Frame rate synchronism to trigger the line rate deflection generation pulses from the separating circuit 87 are fed to the rator 40. Each positive or negative output frame rate detection generator 39, and the pulse can, depending on the structure of the deflection output pulses from the generator 39, be the non-generator can be used to trigger a tilt. The image frequency deflection coils shown are supplied to the image display device with ³ ° polarity of the output pulses, which are arranged in synchronism. with the line frequency synchronizing pulses, the line frequency synchronizing pulses of the syn- th by the magnetic field direction of the capstan 84 chronisierzeichen separating circuit 87 are set to one with respect to the tube 86; the polarity can middle tap 88 where the coil 89, by reversing the clamping connections of the terminals to the anode 90 and 91 of a ³⁵ coil 84 are reversed. In the embodiment double diode rectifier 92 via the block example according to FIG. 5, a periodic capacitor 93 or 94 can also be connected. The lateral deflection of the electron beam in the cathode 95 of the diode 92 is connected to the tap 96 electron tube 86 by applying a sinusoidal preload resistor 97, the shaped voltage in synchronism with the ⁴ ° line frequency deflection pulses connected between the positive pole B + and earth between the distractor. The connection from the anode 90 or to the electrodes 59 and 67 is brought about so that the cathode 95 also takes place via symmetrical loading no external magnetic deflection coil required load resistors 98 and 99. is. This is essential so that a deflection field created in the interior of the anode 90 with the deflection electrode 67 of the electron tube is created in the electron tube 86 via a network of a ⁴⁵ direction perpendicular to the electron path, where resistor 100 and a shunt capacitor through a periodic lateral beam deflection and 101 coupled to earth. In the same way, the beam is periodically directed from the up anode 91 via a series resistor 102 and a catch anode 79 to the output anode, and vice versa, with the deflection capacitor 103 and the deflection electrode 59.

coupled to the electron tube 86. The cathode 104 ⁵ ° in the exemplary embodiments according to FIGS. 4 and 5

the tube 86 is grounded, and the acceleration pulses are the tilt pulses for the line frequency

electrode 105 is connected via resistor 106 to the deflection generator of one with the output anode

positive pole B + and is obtained via the capacitor 107 78 coupled output circuit; and the

grounded. The collecting anode 79 is with the acceleration collecting anode 79 is with the same voltage as

generation electrode 105 connected; the output anode 78 ^{55 operated} the acceleration electrodes. In the meantime

is connected to the positive via the load resistor 80, the collecting anode 79 can, if desired, be electrical

tive pole B + of the voltage source. The output independent of the acceleration electrodes

anode 78 can also be controlled via a differentiating, so that output pulses with a

Network of a coupling capacitor 81 and opposite the polarity of the resistor 82

an input resistor 82 with the line frequency ^6o occurring pulses of opposite polarity on

Deflection generator 40 coupled. differentiating, with the collecting anode 79

The line frequency impulses or the load circuit coupled with them are caused

pulses synchronously running pulses are generated by genes, which has not been shown.

rator 40 one of the induction coil 108 and the subcircuits 1, 2, 3, 4 and 6 according to FIG. 1

Capacitor 109 constructed current resonance ^{circuit to 6} S correspond to the circuits of the example according to

guided; the induction coil 108 is with the coil 89 Fig. 4. The coil 84 and the capacitor 85 provide

inductively coupled. The line frequency pulses represent a passive oscillation circuit, which like

also feed the small resistor 83 and the filter 1 acts. The separating limiter 2

the series connection from the deflection control speaks to the right system 60 of the electron tube

coil 84 and the tuning and phase capacitor? ° 50, in which the sinusoidal symbol wave at the

Coil 84 is converted into a square pulse at the output anode 78. The condenser and the resistor 82 constitute the differentiating circuit 3; and the line frequency deflection generator 40 shows the direction-sensitive arrangement 4, which only responds to negative pulses. The phase indicator anodes 58 and 66 in the left system 49 of the electron tube 50 serve as a control symbol source 6th

In all of the illustrated oscillating circuits with controllable frequency, the creation of a control character leads to the limiter to phase shift the two oppositely polarized pulses of the differentiating output circuit in opposite directions. When the feedback loop, without the direction-sensitive arrangement being switched on, being closed, so were the two phase shifts cancel and no frequency change would be achieved. The phase shift occurs by suppressing the one pulse in the transmission circuit of the impulse of opposite polarity to its full effect.

In this way, according to the invention, a highly effective oscillating circuit is controllable Frequency created, which is particularly useful for synchronization circuits in television receivers o. The like. Suitable, since they perform various tasks previously performed by separate recipient levels a simple, compact, and inexpensive circuit that is fairly small Contains number of switching elements.

Claims (9)

Claims: 35 1. Oscillating circuit with controllable frequency, in particular for television receivers, characterized in that that through a filter (1) on an applied periodic symbol an almost sinusoidal Character is supplied and that with the filter a limiter circuit (2) through which the Sinusoidal characters transformed into a character with periodic, sudden changes in slope is coupled, that further with this circuit (2) a differentiating circuit (3) to generate pulses of opposite polarities connected to the sudden Slope change responds that an arrangement continues to be connected to the differentiating circuit (3) (4) connected only to pulses of one polarity to generate a periodic Character responds and is coupled to the filter (1) by a line (5) through which the generated periodic characters reaches the filter (1) through the closed feedback path and thus undamped oscillations circulate in the oscillating circuit, and that finally a control character supplied by a circuit (6) to regulate the oscillation frequency that is sent to the limiter circuit to change the phase position of the sudden change in slope is created. 2. Sahwing circuit according to claim 1, characterized characterized in that the filter (1) is a passive oscillating circuit with concentrated inductance and capacitance (7, 8, 9), a piezo-electric crystal (16) or some other resonant circuit serves. 3. oscillating circuit according to claim 1, characterized in that the limiter (2) is a tube (50) with deflectable electron beam control, an electron tube with a stepped characteristic (18), a Trarasformatorkern (10) or a Half-wave rectifier is used. 4. oscillating circuit according to claim 1, characterized in that as a direction-sensitive arrangement (4) a diode or a triode (12) or a television deflection generator (40) is used. 5. oscillating circuit according to claim 1 or 3, characterized in that the limiter (2) consists of an electron tube with a deflectable electron beam (50) which is an electron gun (48), electrostatic deflection electrodes (59, 67), the output anode (78) and the Auxiliary anode (79), the effective parts of which are on opposite sides of the undeflected Path of the electron beam are located, and that the filter (1) supplied, sinusoidal Oscillation an alternating deflection field in an almost perpendicular to the electron beam Direction in the tube (50) generated and that thus the electron beam is periodic moves from one anode to the other and a pulse with steeper at the output anode Leading and trailing flank occurs. 6. oscillating circuit according to claim 5, characterized in that as a direction-sensitive arrangement the deflection generator (40) of a television receiver for supplying the periodic character serves by the character feeding the filter associated with the electron tube (50) is that works as a limiter and the deflection alternating field is the electron beam from one moved to the other anode (78, 79) that further electrostatic deflection electrodes (59, 67) of the Tube (50) receive a control voltage which is supplied by a phase comparison arrangement, to which the synchronization pulses and the pulses of the deflection generator (40) are fed, and that finally to maintain the synchronous running of the generator according to the Synchronization pulses with the output anode (78) via a differentiating network (81, 82) is coupled to the deflection generator (40). 7. oscillating circuit according to claim 6, characterized in that the two electrostatic The control voltage is supplied to deflection electrodes (59, 67) from the phase comparison arrangement will. 8. oscillating circuit according to claim 1, characterized in that the filter (1) consists of one Resonant circuit (7, 8, 9), the limiter circuit (2) from a ferromagnetic core (10) one Transformer, the differentiating circuit (3) from the secondary winding (11) of the transformer, the direction-sensitive arrangement (4) from the triode (12) operated as a rectifier, the is loaded by the mentioned resonance circuit, and that the control character to an additional winding (15) is applied to the transformer core (10) (Fig. 2). 9. oscillating circuit according to claim 1, characterized in that the filter (1) is a piezoelectric Crystal (16) and the limiter (2) an electron tube (18) with a controlled electron beam, which have a stepped working characteristic contains, that is, the difference diary Circuit (3) from a transformer (22, 23) and the direction-sensitive arrangement (4) consist of a rectifier f25), the Closing the feedback loop is connected to the piezo-electric crystal, and that also the control character on the cathode resistor stand (19) of the electron tube (18) is applied (Fig. 3). Documents considered: German Patent No. 816 271. 1 sheet of drawings © 709 959/133 4.58