DE1249915B - Self-floating ironless pulse generator with improved oscillation behavior and stabilization of the pulse width - Google Patents

Description

' FEDERAL REPUBLIC OF GERMANY Int. CL:

H03k

GERMAN

PATENT OFFICE German class: 21 al -

DESIGN SCREEN

Number: 1249 915

File number: T 29402 VIII a / 21 al

Filing date: September 14, 1965

Opened on September 14, 1967

The invention relates to a self-oscillating ironless pulse generator, in particular a control generator for a Vertikala blerik formwork in a television receiver, with improved oscillation behavior and stabilization of the pulse width.

As a control generator for a vertical deflection circuit, so-called blocking oscillators are known which consist of an amplifier element and a transformer. The transformer is used to convert the to bring about phase reversal necessary for feedback. Such transformers are proportionate extensive and have a relatively high weight, which is particularly evident in the case of portable devices has a detrimental effect. Efforts are therefore made to replace such blocking oscillators with so-called ironless ones Replace pulse generators.

For this purpose it is known to replace the said transformer with a second transistor « In a known circuit of this type (German Auslegeschrift 1068 756) is a first Transistor in emitter circuit provided, the collector circuit of which is connected to the input of one to the first complementary and used for phase reversal second transistor connected in the emitter circuit is «whose collector circuit is connected to the base of the first transistor via a frequency-determining / iC element is fed back. Due to the feedback, this circuit is self-oscillating and works such that alternately either both transistors are simultaneously conductive or non-conductive.

With such a circuit, the generated one results, in particular with a large pulse duty factor Tension, difficulties in achieving sufficient security against oscillation. For improvement the starting security is one in this circuit in the collector circuit of the second transistor Throttle provided. However, such a throttle is a relatively expensive and heavy component. if the pulse generator is supposed to generate an exact square wave voltage, causes such a choke in the output circuit also an undesirable deformation of the output voltage. ;

The invention is based on the object of the described known To enable pulse generator with simple means and also the width of the generated pulses to stabilize, ι. · ■■ · .. ' - The invention consists in that the emitter of the first transistor is connected to a tap of the resistor in the collector circuit. of the second transistor is connected and between the base of the first Transistor and earth the series connection of a

Self-oscillating ironless pulse generator
with improved oscillation behavior
and stabilization of the pulse width

κ- ^Applicant:; L ·, ..- ,. ;

Telefunken S.

; Patent collecting society m. B. H.,

Ulm / Danube, Elisabethenstr. 3

j; named as inventor:

j Otto Daute, Heilbronn / Neckar

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The resistor is connected to a diode polarized in such a way that this diode is non-conductive in the case of non-conductive transistors and conductive in the case of conductive transistors.

The invention ensures that the pulse generator starts to oscillate properly. aside from that the pulse duration and thus also the frequency is stabilized and from temperature fluctuations and Fluctuations in the data of the transistors are made largely independent.

The invention is illustrated below with reference to FIGS. 1 explained in more detail. In Fig. 2 are waveforms the voltages and currents shown. The numbers on these curves correspond to the associated circuit points in Fig. 1.

According to FIG. 1, the pulse generator consists of a transistor 1 and a transistor 2, which is used to reverse the phase, and which is complementary to the transistor 1 Transistor 2 is connected. The emitter of the transistor 2 is connected to the negative operating voltage terminal 3 and its collector via: the series connection of a resistor 7 with a resistor 8 connected to ground. The base of the transistor 1 is connected to the terminal 3 via an adjustable resistor 9 and a resistor 10

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tied together. The collector of transistor 2 is connected to the base of transistor 1 via the series circuit a resistor 11 connected to a capacitor 12, which is used as the frequency and the pulse width determining feedback path is used. According to the invention, the emitter of transistor 1 is on the connection point 13 of the resistors 7, 8 connected and the base of the transistor 1 via the series connection of a diode 14 with a resistor 15 connected to earth.

The mode of operation of the pulse generator is illustrated in FIG. 2 explained in more detail. It is assumed that at the time I ₁ both transistors are non-conductive and that there is a positive voltage at the left end of the capacitor 12. Since the terminal 17 is then practically at ground potential, there is a positive voltage at the switching point 16, ie at the base of the transistor 1, which causes the transistor 1 to be blocked. As a result of this blocking, the circuit point 6 is at a strongly negative potential, so that the transistor 2 is blocked. The diode 14 located between the circuit point 16 and earth is then also blocked because there is a positive voltage at the point 16. The capacitor 12 is now slowly discharged through the resistors 10, 9, so that the voltage at point 16 drops in the direction of zero potential. At time t ₂ , the voltage at point 16 passes through earth potential and becomes somewhat negative. The transistor 1 becomes conductive, so that the voltage at point 6 becomes more positive, that is, it rises from minus towards ground potential. This also makes transistor 2 conductive, so that the voltage at terminal 17 changes in the direction of the voltage at terminal 3 and reaches the base of transistor 1 via capacitor 12 and controls transistor 1 to continue conducting in a cumulative process. The circuit flips over so quickly to the state in which both transistors are fully conductive. The voltage at point 13 becomes negative, while the voltage at point 17 practically assumes the voltage at terminal 3. During the time beginning at the point in time L ₂ in which both transistors are conductive, the resistors 9, 10 can essentially be disregarded. The capacitor 12, which is still discharging at the time t ₂ , is now charged via the resistor 11 because the full negative voltage of the terminal 3 is at the circuit point 17 and approximately ground potential is at the circuit point 16. _{A charging current I 1} flows in the capacitor 12 and decreases according to an exponential function. Since the diode 14 _{is conductive after the time f 2} due to the negative voltage at the point 16, this current I _{1 is divided} into a current / ₂ through the diode 14 and a base current i ₃ at the base of the transistor 1. At time J ₃ , the charging current i, has dropped so far that, taking into account the approximately constant current I ₂ through the diode 14, the remaining low "base current" / is no longer sufficient to keep the transistor 1 conducting. At time t _z , transistor 1 then becomes somewhat less conductive, so that the voltage at point 6 becomes more negative and also makes transistor 2 somewhat less conductive. This creates a positive voltage change at point 17, which continues to control transistor 1 non-conductive via resistor 11 and capacitor 12, so that the circuit quickly switches to the state in which transistors 1 and 2 are non-conductive as a result of this cumulative process . On the left surface. of the capacitor 12 then arises again a positive voltage, which causes the blocking of the transistor 1, so that the process described begins anew. The resistor 9 is used to set the frequency. The resistor 10 limits the frequency setting range. ,

The initial oscillation security is determined by the inven- '. according to the circuit achieved in the following manner

ίο For the oscillation safety of such a circuit is characteristic of the extent to which the circuit is able in the absence of a feedback path 11, 12, To amplify voltages or currents. Only when this ability to reinforce is given can low Voltage changes, e.g. B. Noises, which are decisive for an oscillation, are amplified If there is no feedback path 11, 12, d * e tilts Circuit in the conductive state, because then the base of the transistor 1 via: the resistors 9, 10

ao is connected to the negative operating voltage terminal.

'■ · The transistors then saturate and can not strengthen jmehr. The resistors 9, 10 could indeed be made so high that this effect is avoided. But then you have to

»5 the feedback path will also become higher impedance ■ As disadvantages! this then results in poor feedback (possibly no oscillation as a result) and a high influence of the transistor data and temperature on the frequency and the pulse duty factor. Characterized in that, according to the invention, the emitter of the transistor 1; is connected to the connection point 13 of the resistors 7, 8, the voltage at the emitter and at the base of the transistor 1 is increased in the negative direction when the transistors 1 and 2 are conductive. Characterized flows through the diode 14 and the resistor 15 a current which is subtracted from the current drops in the resistors 9, 10 so that the remaining base current of transistor 1 and transistors 1, 2 are again conductive less. ¹ The emitter voltage of transistor 1 cannot rise above a certain value, since otherwise the base current in transistor 1 would be zero. By connecting the emitter of the transistor 1 to the tap 13 and the diode 14, the collector current of the transistors 1, 2 is limited to a desired value in such a way that both transistors, if correctly dimensioned, are in the conductive state and there is no feedback path 11, 12 are not saturated. This is because the transistors are then able to amplify low voltages, so that the entire circuit starts to oscillate properly if the feedback path 11, 12 is present. The resistor 4 is used to limit the current in the transistor 1 between the times I ₂ and t _z , and proper switching must be guaranteed. On the other hand, if there is no feedback, the result is that the transistor 1 cannot automatically be saturated. The Wideistand 5 serves to take over the collector-BaMS reverse current of the transistors 1, 2, that is to say for the proper blocking of the transistor 2.

The stabilization of the pulse width at the terminal

17, d. H. the time in which the transistor 2 is conductive, is achieved in the following way: the unlikely Case be assumed that the · ■ 'current in the resistors 9, 10 is smaller than the minimum base current required to maintain the conductive state of transistors 1, 2

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of the transistor 1. Without the diode 14, the charging current Z _{1 of} the capacitor 12 would drop until it has reached the low value of the base current / ₃ (minus the current in the resistors 9, 10). in which the transistor 1 becomes non-conductive, e.g. B. at time t _v Since this value of the base current is low, the slope of curve Z ₁ at time / ₄ of transistor 1 becoming conductive would also be very small. Changes in the base current (e.g. due to different current amplifications) at which transistor 1 becomes conductive therefore have a strong effect on the point in time at which transistor 1 becomes conductive. In the circuit according to the invention, a substantial part of the charging current Z ₁ , namely the current i ₂ , now flows. through the diode 14, so that the transistor 1 already _{becomes conductive again at a relatively large charging current I 1} , namely at r ₃ , so that the base current of the transistor 1 or its scatter now play a subordinate role. With a larger charging current7, the slope of curve I _{1 is} greater, so that changes in the current at which transistor 1 becomes conductive have a significantly smaller influence on the point in time at which transistor 1 becomes conductive. TJie pulse width on the clamp. So 17 is stabilized. »5

By switching on an iiC parallel circuit with a time constant that is high compared to the period of the generated voltage in the base line of the transistor 2, a possible impairment of the operation of the circuit in the case of an excessively high collector-base blocking current of the transistors 1, 2 or an excessively small resistor 5 be reduced. The resistor 15 in series with the diode 14 is dimensioned so that when the transistors 1, 2 are conducting, the desired diode current Z ₂ flows during the flyback time.

For each application of the invention in a vertical deflection circuit, for example, terminal 17 is connected via a diode to an electrode of a charging capacitor that is periodically charged in the shape of a saw tooth. The diode then acts as a switch for fast discharging (or charging) _the charging capacitor .during the. Return time between times f ₂ and / ₃ . The generator can be synchronized from a terminal 18 ″ via a /? C element 19 by means of vertical synchronizing pulses.

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Claims (4)

Patent claims: 1. Self-oscillating ironless pulse generator with improved oscillation behavior and Stabilization of the pulse width, in particular a control generator for a vertical deflection circuit in a television receiver, with a first transistor in the emitter circuit, whose collector circuit to the input of a second complementary to the first and used for phase reversal The transistor is connected in an emitter circuit, the collector circuit of which has a frequency-determining circuit i? C element is fed back to the base of the first transistor, alternately both transistors are conductive or non-conductive at the same time, characterized in that that the emitter of the first transistor (1) to a tap point (13) of the resistor (7, 8) connected in the collector circuit of the second transistor (2) and between the base of the first Transistor (1) and earth the series connection of a resistor (15) with a polarized Diode (14) is that this diode (1.4) with non-conductive transistors (1, 2) non-conductive and with conductive transistors is conductive. 2. Pulse generator according to claim 1, characterized in that the tap point (13) is chosen and the resistance (15) of the series circuit is dimensioned so that in the absence of a feedback path (11, 12) the conductive transistors (1, 2) are not saturated. 3. Pulse generator according to claim 1, characterized in that between the collector of the first transistor (1) and the base of the second transistor (2) a resistor (4) dimensioned in this way is that a sufficient base current flows in the second transistor (2) at maximum load. 4. Pulse generator according to claim 1, characterized in that in the base line of the second Transistor (2) a parallel connection of a resistor and a capacitance with im Compared to: Period of the voltage generated with a high time constant. j Considered publications:
German Auslcgeschrift No. Ϊ 068 756. • For this 1 sheet of drawings Ml : i "1 "y.'ziw Wed mm mi mm tliifliffi I'll! m U ^; : 1 II I Ii Ϊ υ : Si-IW 709 647/443 9. Sl Q Bundesdruckerei Berlin ⁿⁱ l ^:: i | '| t! f ₇ , ^ . T ^ w. "Η, I ₁ ^ ₇ V ₇ .