DE1412343B1 - DC voltage amplifier for regularly recurring pulses - Google Patents

Description

The invention relates to a DC voltage amplifier for regular Recurring impulses in which the changed or lost DC voltage component of the input signal is reintroduced by means of a feedback rectifier arrangement is, which is biased in such a way that a capacitor, which together with one of it parallel resistor which bridges part of the amplifier input Voltage divider forms, is charged when the output signal voltage is a reference voltage exceeds.

From the Journal of the Television Society, 1949, Vol. 5, No. 9, p. 264, an amplifier circuit is known in which a differential amplifier compares the output of the amplifier circuit with a fixed voltage. The output of the differential amplifier is connected to the amplifier input via a switch tied together. This switch is controlled by control pulses, especially the line pulses of a television signal. The output of the differential amplifier is thus connected to the input of the amplifier circuit only when a line pulse is present is applied. This will reduce the negative peaks of the line pulses to a certain Voltage level held. The known circuit has the disadvantage that it has to be reintroduced the DC voltage level requires an additional control signal.

From British patent specification 464 828 an amplifier is known, in which no additional control pulses to reintroduce the direct voltage component are required and which is constructed like the amplifier defined at the beginning. The voltage divider in this case is on the one hand by the mentioned capacitor and a resistor in series therewith is formed on the other hand. It has shown that the degree of reintroduction of the DC component to be desired leaves, so that the circuit is only conditionally applicable.

The object of the invention is to improve the quality of the reintroduction of the direct voltage component to improve.

According to the invention, this is achieved in a surprisingly simple manner by that the other part of the voltage divider consists of a diode that is used when charging of the capacitor is blocked.

The fact that instead of the resistor of the known circuit a Diode is used, there is a degree of reintroduction for the DC component, as it was not to be expected in its extent.

Two embodiments of the invention will now be based on the drawing to be discribed. It shows F i g. 1 shows a conventional form of circuit for Reintroduction of the direct current component F i g. 2 is a distortion shape created by such a circuit can be brought in, FIG. 3 is a circuit diagram of a transistor image intensifier according to the invention, FIG. 4 is a circuit diagram of another amplifier according to the invention.

Fig. 1 shows a conventional diode circuit for recovery of the DC voltage level with a diode D, which is used to restore a television signal poled with a positive video information and negative synchronizing pulses is. The time constant of the RC circuit is much larger than the interval between Sync pulses and, if the anode of the diode is grounded as shown, should the peaks of the synchronization pulses of the output signal are at the 0 V level.

F i g. 2 shows the conditions under which this circuit is unsatisfactory is working. The line and frame synchronizing pulses of a synchronizing signal are shown undistorted at (a). The same signal is at (x) after an inadequate DC recovery shown, with the target level following the DC voltage Recovery is denoted by A. There have exponential shifts in the sync pulse peak level took place. As can be seen, the distortion takes place at the beginning and at the end of the broad synchronization pulses. This is due to that the mean value of the signal in the frame sync pulse interval is different so that the diode conducts for a longer time.

Through the following in connection with F i g. 3 described circuit such distortion is avoided even if the input level is only 0.1V. The gain that can be achieved with feedback is about 10, while the used Output values of 0.5 V and above.

The amplifier according to FIG. 3 has seven transistors VT1 to VT7 on. Of these transistors, the transistors form VT2 to VT6 and the associated ones Switching elements the actual DC voltage amplifier, which is within the dashed line Rectangle is shown. The input television signal becomes the base of VT2 via a DC voltage blocking capacitor Cl supplied. VT2 and VT3 are emitter follower circuits in cascade arrangement, which control the emitter of VT4, which acts as a voltage amplifier is arranged in basic circuit. VT6 is an output emitter follower circuit, and VT5 creates a feedback to the base of VT4. Therefore, VT5 is in common collector connection operated, and its base is to the junction of resistors R1 and R2 which form the emitter load of VT6, while its emitter is connected to an emitter load R3 and the base of VT4.

If the voltage gain from the emitter to the collector of VT4 is at In the absence of feedback, the achievable external gain approaches from the emitter of VT4 to the emitter of VT6 the value (R1 + R2) / R1. The feedback increases the emitter input impedance of VT4 so that the voltage gain of the base of VT2 to the emitter of VT3 approaches one. The above The formula therefore approximates the total gain of the amplifier.

The feedback to the base of VT4 could be immediate at the connection point can be taken from R1 and R2. The insertion of VT5 results in a system of base-emitter potential differences, which are symmetrical with respect to the emitters of VT3 and VT4, so that a system results, which remains almost in equilibrium despite temperature changes.

The base of VT5 is forward-biased with the help of a resistor R4 so far biased that with positive signals at the base of VT2 the transistor VT4 is blocked before the base of VT3 reaches the + O supply potential.

The collector load R5 of VT3 limits its collector current and thus the loss of energy at its collector without this transistor blocks within the operating range of the output voltages.

A phase shift capacitor C2 is connected in parallel with R2 in order to To influence the high frequency behavior of the amplifier.

Between the collector of VT4 and the emitter of VT6 there is a diode D1 switched. This diode conducts when the potential at the collector of VT4 is sufficient quickly goes positive to block VT6 because of the latter's capacitive emitter load. A decoupling diode D2 between the collector of VT4 and the base of VT5 prevents that the collector of VT4 blocks at a potential which is more positive than that at the base of VT5. This will reduce delays caused by an accumulation of minority carriers in the base of VT4 can be caused.

The transistors VTl are used to reintroduce the direct voltage and VT7, of which the transistor VTl in contrast to all other transistors is an npn transistor. The transistor VT7 is operated in emitter follower circuit, which detects the negative peaks at the amplifier output. A capacitor C3 in parallel with the emitter load resistor R6 of VT7 charges on one Voltage, which is practically equal to the negative peak voltage of the output signal is.

The emitter of VT7 is connected to the base of VTl, which acts as a voltage comparison circuit and reversal stage acts. Therefore, with the emitter of VTl is a reference voltage source v ,. connected, which consists of resistors R7 and R8, one through C4 form decoupled voltage divider.

The collector load R9 of VTl forms a controlled preload for the base of VT2, since the collector of VTl to the base of VT2 via a diode D3 is connected, its cathode to the junction of C1 and the base connected by VT2. R9 is bridged by a capacitor C5. VT2 is also with a forward bias resistor R10 between its base and the negative Supply potential - V provided.

From the above it follows that the time constants C @ R8, C @ Rlo, C3, R7R8 / (R7 + R8) and C6R9 all large with respect to the interval between sync pulses must be. There are three of these networks, namely C @ RB, C @ Rlo and C "R9 in the control signal path occur as integrators in a cascade arrangement, it is also in the interest of Tax stability recommended, one of the three time constants is much larger than the other two. For example, the time constant of the input coupling element C1Rlo can be made larger than C3R8 and C5R9.

It is required that the maximum available output voltage range is achieved by amplifying a combined television signal in which a represents positive increase in gain in white with negative sync pulses. VT4 must therefore be under, in the absence of a signal almost or entirely by bias locked and controlled by supplied signals conductive. For this purpose the resistor R10 is given such a value that in the absence of the diode D3 the Voltage at the emitters of VT3 and VT4 reverse biasing the emitter-base junction of V "supplies 4. VT4 would then be blocked and the output voltage would be the maximum assume the attainable negative value.

The reference voltage -v ,. becomes a little less negative than the one mentioned maximum negative value chosen. If the output voltage is the mentioned maximum achievable negative value is the base-emitter junction of VTl Pre-tensioned in the blocking direction and VTl blocked. When this happens, it discharges the (previously due to the voltage drop that occurred at R9 when the transistor VTl was opened charged) capacitor across the resistor R9 in the direction of a final voltage, the by the voltage divider formed from R9 and R10 with the interposition of the diode D3 is determined.

Resistors R9 and R10 have values such that when VT1 is blocked, the voltage at the base of VT2 rises enough to the + 0V voltage that VT4 is blocked by R4 and VT5. The emitter of VT6 is at its lowest possible negative value. R6 is made low enough to lock VTl when VT7 is locked.

The circuit described above is stable when the voltage at the emitter of VT6 essentially equal to -v ,. is when there is no signal or if the negative peak occurs under no-signal or negative conditions.

If the voltage at C3 is more negative than -v ,. is, VTl is blocked. The voltage divider R9, D3, R10 increases the input voltage with respect to the DC voltage amplifier on, d. i.e., the bias at the base of VT2 is increased, with the result that the mean output voltage of the amplifier becomes more positive.

If the voltage at C3 is more positive than -v ,. is, heads VTl, whereby C5 is charged more negatively. This results in D3 in the reverse direction is biased so that the base bias of VT2 against the voltage of the -V line can drop (since the current flowing through R10 is small). The mean output voltage of the amplifier therefore becomes more negative.

The negative output peak voltage deviates from -v ,. just about the difference between the base-emitter voltage drop in the forward direction of VT7 and VTl, since VTl is an npn transistor and VT7 is a pnp transistor. The negative output peak voltage is therefore at about -v ,. stabilized. The diode D3 and the peak detector VT7 are blocked by the supplied signal.

From the foregoing it can be seen that an important advantage of this The circuit consists in that the DC voltage input used is automatic also stabilizes the DC voltage amplifier against drift. A DC voltage amplifier a greater overall gain would be a DC voltage introduction of input signals with an even lower value.

The in F i g. The embodiment shown in Figure 4 has an overall gain of about 5 and is used to amplify and reintroduce the direct current component a histogram signal consisting of successive samples of the information, which are interspersed as deviating voltage values in a regular positive calibration pulse are. The peak of this pulse is the positive extreme of the signal range and is set to a certain value by the circuit. Of the the actual amplifier is again within the dashed rectangle arranged and consists of an npn transistor VT8 and a pnp transistor VT9, as complementary reversing stages with a common emitter in a cascade arrangement are switched. The input signal becomes the base of VT8 through the capacitor C6 supplied. The feedback voltage is applied to VT9 via an emitter resistor R11 created. The collector load of VT9 consists of resistors R12 and R13 in series connection, and the overall feedback is achieved in that the connection point of R12 and R13 is connected to the emitter of VT8. If the reinforcement at the In the absence of total feedback high, the gain approaches with feedback the value (R12 -I- 813) / R13. A capacitor C7 is connected in parallel with the resistor R12 and influences the high frequency behavior of the amplifier.

A resistor R14 is connected between the emitter of VT8 and the zero potential. This resistor supplies the emitter-base path of VT8 with a reverse bias voltage if the base of VT8 is kept at the - V potential: The DC voltage introduction and drift stabilization circuit has an npn transistor VT10, which is connected as an emitter follower, to determine the positive peak voltage of the output. The emitter load of VT10 therefore consists of a resistor R15 to which a capacitor C8 is connected in parallel, the latter being essentially charged to the positive peak output value.

The emitter of VT10 is connected to the base of a 'pnp transistor VTll, the emitter of which is connected to a source (not shown) for the reference voltage -v ,. connected is. VT11 is therefore switched in such a way that it acts as a voltage comparison circuit and inverting amplifier when the collector load R16 is bridged by a capacitor 9.

The bias at the base of VT8 is determined by a bias resistor R17 and by the current flowing in R16 , the junction of which with the collector of VT11 is connected to the base of VT8 via a forward diode D4.

The time constants C8815, C, Rls and 0R17 are large compared to the Interval between positive calibration pulses. These networks also occur in the control signal path on, the one time constant, e.g. B. C6817, should be much larger than the two others.

The bias resistor R17 has such a value that VT9 is blocked in the absence of D4 . The output voltage at the collector of VT9 then has its lowest possible negative value. The reference voltage -v ,. is slightly more negative than this lowest possible negative output voltage, so that VTll is blocked under these conditions.

R16 is dimensioned so that if there is no collector current in VTll the base of VT8 is sufficient despite the influence of R17 through the conductive diode D4 negatively controlled to lock VT8 and VT9. The resistor R14 facilitates compliance with this condition, under which the output voltage is negative Has maximum value.

The circuit described is stable with the output voltage im essentially equal to -v,. if no signal or control signals with positive peaks appear.

If the voltage at C8 is more positive than -v ,. is, VT11 is blocked, so that R16 and D4 pull the base of VT8 to the negative potential of the supply voltage, so that the mean output potential is less positive. If the voltage at C8 is less positive than -v ,. is, conducts VTll and is positively charged to C9. This causes diode D4 to be reverse biased so that R17 can make the base of VT8 more positive and the mean output voltage more positive.

If no signal or control signals with positive peaks occur, the output voltage deviates from -v ,. only by the values of the forward voltages of the base-emitter paths of VT10 (npn) and VTll (pnp). The diode D4 and the peak detector VT10 are blocked by a supplied histogram signal of the type described.

Claims (1)

Claim: DC voltage amplifier for regularly recurring Impulse in which the changed or lost DC voltage component of the input signal is reintroduced by means of a feedback rectifier arrangement is, which is biased in such a way that a capacitor, which together with one of it parallel resistor which bridges part of the amplifier input Voltage divider forms, is charged when the output signal voltage is a reference voltage exceeds, characterized in that the other part of the voltage divider consists of a diode (D3 or D4) that is activated when the capacitor (C5 or C9) is blocked.