DE4121736C1 - Switching pulses generating circuitry e.g. for vertical deflection in TV receiver - has oscillator with capacitor controlled from current sources and connected via terminal to integrated circuit - Google Patents

Abstract

The circuitry includes an integrated circuit (IC) which with the aid of an oscillator produces switching pulses (SP), supplied to a pulse signal output (P2) of the integrated circuit. The oscillator is based on a capacitor (C1) controlled by two current sources and connected externally to a capacitor terminal pin (P1) of the integrated circuit. An auxiliary circuit (HS) changes the width/spacing ratio of the switching pulses, its input being connected to the pulse signal output and its output to the capacitor terminal pin. The input signal of this circuit is provided by the output voltage (UA) of the integrated circuit with the switching pulses superimposed. USE/ADVANTAGE - The pulse width/spacing ratio can be varied without altering the integrated circuit, e.g. for specific t.v. norms or monitors.

Description

The invention relates to a circuit arrangement according to the preamble of claim 1.

Such a circuit arrangement is for example from the literature reference "Electronics Practice", No. 3, March 1984, p. 122.

In integrated circuits - especially for the Ab steering part of television receivers - are often in the generates and processes pulse-shaped signals; this Si Signals can be connected to the integrated circuit for the control of further circuit units for Will be provided. Starting point for the Im pulse signal generation is often an oscillator, which provides a sawtooth-shaped signal; this sawtooth signal is generally generated by an on the integrated circuit of externally connected Kon capacitor charged by appropriately switched currents which is unloaded and again.

In Fig. 3 the basic circuit diagram of such a gene oscillator is shown - with the charging capacitor C ₁ connected to the connecting pin P _{1 of} the integrated circuit IC and with two current sources which are characterized by the two currents I ₁ and I ₂ . The Fi gur 2 shows the voltage curves over time on the charging capacitor C ₁ - voltage U _C ( Fig. 2a) - and on the connection pin P ₂ - pulse signal output voltage U _A ( Fig. 2b); the pulse-shaped voltage U _A is derived in the integrated circuit from the sawtooth-shaped oscillator voltage U _C. The capacitor C ₁ is charged by the charging current I ₁ until the voltage U _{C reaches} a first (comparator) threshold value U _S1 (time t ₁ ), whereupon the switch S switches over and the discharge begins. During the discharge process, the discharge current I ₂ flows accordingly until the voltage U _C across the capacitor C _{1 reaches} a second (comparator) threshold value U _S2 (time t ₂ ); then the charging process etc. begins again after the switch S has been switched internally. The values of the currents, the ratio of charging current I ₁ to discharge current I ₂ and the switching threshold values U _S1 , U _S2 are generally fixed by the integrated circuit given. From the sawtooth-shaped signal U _C ( FIG. 2a) of the oscillator, the output signal U _A with the pulse SP ( FIG. 2b) is won in the integrated circuit, the pulse duration t _{p of} the discharge time (period from t ₁ to t ₂ ) of the Capacitor C ₁ corresponds. The duration of the period is designated T in FIG. 2; the pulse duty factor is defined by the ratio of pulse duration t _p to period duration T.

The integrated circuit for generating the Schaltim pulse is always designed for certain operating conditions winds and dimensions. By varying the components ment values of the external components can now be added for example, the total time from charging and discharging change, but not the relationship between charging and discharging current:

For example, it is common in television receivers to use like circuits in the vertical deflecting part. The charging time of the capacitor then corresponds to that Vertical run-up time and the discharge time of the vertical Ramp-down time. The pulse corresponding to the discharge time SP becomes, for example, the return blanking in the video signal processing circuit. At TV receivers with a vertical deflection frequency of  50 Hz - this corresponds to a vertical deflection period duration of 20 ms - is the vertical retrace time 1.4 msec or 7% of the total deflection time. The pulse-shaped generated in the integrated circuit Ge output signal thus points for the 50 Hz deflection frequency a pulse duration of 1.4 ms during a pulse pause of 18.6 ms. Should the integrated circuit for others Television standards (other deflection frequencies) are used those who differ from the dimensioned case appropriate ratio between charge and discharge current can request an adjustment by changing either one current value or both current values; to is generally an intervention in the integrated Circuit required.

The invention has for its object a scarf arrangement according to the preamble of the patent to specify claim 1, in which a variation of the key ratio is possible. without making any change the integrated circuit is required.

This object is achieved by the features solved in the characterizing part of claim 1.

Advantageous further developments of the invention result from the subclaims.

In the circuit arrangement of the invention, the integrated circuit an auxiliary circuit connected sen, through which a variation of the duty cycle is possible. An integrated circuit for egg NEN specific application - for example for one certain television standard - has been specified can now also with other norms and standards - for example for monitors - are used; the area of application  such integrated circuits is therefore by significantly expanded the use of the auxiliary circuit. The ratio between charging and discharging current or between charging and discharging time can be by the auxiliary circuit varies in a simple way and the be adapted to the desired requirements. The external Auxiliary circuit is used with two existing ones Connection pins of the integrated circuit connected. The Auxiliary circuit preferably has a transistor, by its collector current the discharge time of the condenser sators is influenced. However, since the loading time of the Kon capacitor through the collector current of the transistor the desired change can not be influenced change in the relationship between loading and unloading current or between charging and discharging time.

The invention is based on an Ausfüh example are described - an auxiliary scarf device to change the duty cycle at one an integrated circuit generated vertical blanking pulse.

In such an integrated circuit for the one set in a television receiver are generally two Pins provided for connecting external components: on first capacitor the pin is connected, by its capacity value the total time of the verti calender deflection period is determined; at the second connection pin is the output for the vertical out Tastimpuls that for further use in others Circuit units - such as B. in video signal processing part - is available. This one from the saw toothed oscillator signal obtained blanking pulse  is usually used for blanking the picture tube used during the vertical retrace time.

To vary the duty cycle or the pulse duration of the blanking pulse, the auxiliary circuit HS is provided in accordance with FIG. 1, the input of which with the connection pin P ₂ for the pulse-shaped output signal U _{A of} the integrated circuit IC, and the output of which with the connection pin P ₁ for the connection of the capacitor C _{1 is} connected. The auxiliary circuit HS consists, for example, of the transistor T ₁ , the resistors R ₁ , R ₂ and R ₃ and the capacitor C ₂ . The output voltage U _A or the output pulse SP is supplied via the resistor R ₁ and the capacitor C _{2 to} the base of the transistor T ₁ ; The resistor R _{2 is} connected between the base of T ₁ and the reference potential. The emitter of the transistor T ₁ is also at the reference potential, the collector is connected via the resistor R ₃ to the capacitor pin P ₁ .

If there is an output voltage U _A as shown in FIG. ₂ b at the connection pin P _2, the transistor T _{1 is} controlled in the conductive state when the pulse SP is sufficiently large while the pulse SP is present. Since the collector current I ₃ flows through in addition to the discharge current I ₂ - the capacitor C ₁ is consequently discharged by the total current from I ₂ and I ₃ and thus more quickly. The lower (comparator) threshold value U _S2 ( FIG. 2a) for switching the switch S is thereby reached earlier, so that the width of the blanking pulse SP (pulse duration t _p ) is shortened; since at the same time the duration of the pulse pause remains unchanged, the pulse duty factor - the ratio of t to period T - is influenced. The resistors R ₁ and R ₂ are dimensioned so that during the blanking pulse SP the transistor T _{1 is} safely turned on and the auxiliary circuit HS practically does not affect the pulse signal output P ₂ . Via the resistance value of R ₃ , the collector current I _{3 of} the transistor T ₁ and consequently also the change factor for the pulse duration t _{p of} the off pulse SP and consequently for the duty cycle can be set.

If the integrated circuit is designed so that if the vertical deflection fails at the pulse signal output P _2, a permanent high level is output - in order to switch the picture tube to continuous blanking and thus prevent a strip from being burned in on the screen - the capacitor C ₁ permanently discharged by the collector current of transistor T ₁ and the oscillator could not oscillate if the dimensions are unfavorable; the same effect can also occur when the device is switched on. By standing between the opposing R ₁ and the base of the transistor T ₁ or a connection of R ₂ inserted capacitor C ₂ , a permanent switching of the transistor T _{1 is} avoided. The capacitance value of C ₂ or the time constant of the RC element from C ₂ with R ₁ and R ₂ is to be dimensioned such that the capacitor C ₂ does not influence the switching behavior in normal operation.

In the exemplary embodiment according to FIG. 1, the auxiliary circuit HS shortens the pulse duration and therefore reduces the pulse duty factor. However, it is in the same way an extension of the pulse duration and thus an increase in the duty cycle possible if the current I ₃ Chen receives a negative Vorzei and thus not the total current, but the residual current from I ₂ and I ₃ discharges the capacitor C ₁ .

Likewise - in another circuit arrangement, the charging phase and the discharging phase of the capacitor C ₁ can be interchanged, so that the switching pulse is then applied during the charging of the capacitor. Furthermore, the reference points of auxiliary circuit and external capacitor can be selected differently or correspond to the highest available voltage potential.

The pulse signal output of the integrated circuit can be low impedance as emitter follower output or it can be used as an "open collector" output - with an ent switched external resistance - reali be settled; the dimensioning of the auxiliary circuit must be adapted to the respective case.

Claims (5)

1. Circuit arrangement with an integrated circuit (IC), which generates switching pulses (SP) by means of an oscillator, which are output at a pulse signal output (P ₂ ) of the integrated circuit (IC), the oscillator being powered by one of current sources (I ₁ , I ₂ ) controlled capacitor (C ₁ ) is realized, which is connected externally to a capacitor connection pin (P ₁ ) of the integrated circuit (IC), characterized in that in addition to the integrated circuit (IC), an auxiliary circuit (HS) to change the Tastver ratio of the switching pulses (SP) is provided, the input of which is connected to the pulse signal output (P ₂ ) and whose output is connected to the capacitor connecting pin (P ₁ ) of the integrated circuit (IC), and that the input signal the auxiliary circuit (HS) is given by the output voltage (U _A ) of the integrated circuit (IC) applied with the switching pulses (SP). 2. Circuit arrangement according to claim 1, characterized in that the discharge time of the external capacitor (C ₁ ) can be influenced by the auxiliary circuit (HS). 3. Circuit arrangement according to claim 1 or 2, characterized in that the auxiliary circuit (HS) has a Tran sistor (T ₁ ), the collector of a load (R ₃ ) with the capacitor connecting pin (P ₁ ) of the integrated circuit ( IC) is connected. 4. Circuit arrangement according to one of claims 1 to 3, characterized in that in the auxiliary circuit (HS) to the base of the transistor (T ₁ ) a voltage divider of two resistors (R ₁ , R ₂ ) is connected, one connection of the first resistor (R ₁ ) of the voltage divider is connected to the pulse signal output (P ₂ ) of the integrated circuit and a connection of the second resistor (R ₂ ) of the voltage divider is connected to reference potential. 5. Circuit arrangement according to claim 4, characterized in that a capacitor (C ₂ ) is arranged between the first resistor (R ₁ ) of the voltage divider and the base of the transistor (T ₁ ).