CS252821B2 - Picture tube's exciting stage with feedback - Google Patents

Abstract

Color screen excitation stage includes input amplifier transistor arranged with output amplifier transistor as cascade amplifier. Low impedance electrode the input transistor emitter is connected with a ground potential reference via impedance circuit. Degenerative feedback is provided from the impedance circuit to the input circuit of the input amplifier circuit.

Description

The invention relates to a feedback stage of a color screen with feedback, wherein the output of the individual signals is coupled via a preamplifier stage to an isolation transistor of the emitter follower.

The screen driving stage sometimes uses feedback to determine the signal gain and the linear operating range of the driving stage to stabilize the stage output working potential and to reduce the impedance attached to the screen. In the case of a display driver stage arranged, for example, in a cascade amplifier assembly, such feedback is used from the output of the high-level amplifier that drives the screen directly to the input of the low-level amplifier transistor that feeds the signal current to the high-level amplifier.

It should be noted here that this type of feedback can create difficulties in certain signal processing applications such as a video signal processing system using screen excitation stages designed for frequency and a much larger signal bandwidth, for example 30 MHz, compared to the relatively narrower bandwidth capability. , for example 4 MHz, often exhibited by excitation stages in conventional television receivers.

For example, a wider bandwidth capability may be required for a video monitor where high resolution display is desired. Feedback of the described type can lead to instability of signal processing, for example to oscillation of the circuit due to the effects of parasitic capacitances in a high bandwidth system.

Therefore, it is considered desirable to avoid feedback of the type described while maintaining the linear operation of the display driver stage to maintain the quality of the image reproduced by the broadband system. In this regard, it should be noted that the broadband driver stages of the screen often operate at considerably higher current levels compared to the more common narrowband driver stages as commonly used in television receivers. This result can often be attributed to the considerably lower load impedance of the broadband driver stage.

This is effective in reducing the effects of parasitic capacities associated with the screen and the driver stage of the screen itself while limiting bandwidth. Significantly higher currents lead to increased temperature scattering and heating effects, which may ultimately lead to nonlinearities in the operation of the display driver. Non-linearities from other sources, such as $ transistor fluctuations, are also undesirable in the high-bandwidth processing and display system.

The above-mentioned disadvantages of the prior art are largely eliminated by the feedback stage of the color feedback screen, where the output of the individual signals is connected via a preamplifier stage to the isolation transistor of the emitter follower according to the invention. whose emitters are connected and whose collector is connected to the emitter of the second amplifier, connected as a cascade amplifier, the collector of which is connected to the individual cathodes of the color display via an output circuit.

Advantageously, the second amplifier is connected by its base to the bias potential and its collector with load impedance, the main current path of the amplifier being formed by the collector and the emitter of the second amplifier, whereby optionally the transistor of the emitter follower is connected by its emitter to the current source and base circuit with a preamplifier circuit formed by uniformly coupled first and second transistors, wherein a feedback impedance is connected between the base of the first transistor and the emitter of the first amplifier.

It is also advantageous if the impedance includes resistors and reactances to increase the current conducted by the amplifier circuit at the high frequencies of the video signal, or the closed loop feedback signal for the first amplifier is provided primarily by the feedback impedance. Finally, it is also advantageous that if the output circuit is provided with a coupling capacitor for alternately coupling the video output signals from the second amplifier to the cathode of the color screen.

The invention will now be described in more detail with reference to the accompanying drawing, which illustrates a portion of a broadband color video signal processing system. The signal source 10 provides video signals bearing information about the red (R), green (G), and blue (B) color components of the high-bandwidth image, for example 30 MHz, for the respective processors, for the red video processor 12, green video processor 14, and blue video processor 16. Since the video signal processors 12, 14 and 16 are similar, only the red signal processor 12 is shown in more detail and will be discussed in more detail.

The signal R is supplied as a current from the high impedance source unit 10 to a preamplifier stage comprising first and second transistors 20 and 21 arranged as a differential amplifier. The amplified signals from the collector output circuit of the first transistor 20 are applied via the emitter follower transistor 24 to a display driver stage including first and second bias amplifiers 30 and 31 for Class A operation. The emitter of the transistor 24 is connected to the transistor current source output 26 24 emitter follower.

The first exciter stage amplifier 30 includes an input common-level low-level transistor with a common emitter that, together with the high-level output transistor of the second common-base amplifier 31, forms a cascade excitation stage of the color screen 45 with the high bandwidth amplification capability of 30 MHz.

The high-level red video signals from the collector output circuit of the second amplifier 31 are coupled to the red cathode 40a of the color display 45 through the coupling capacitor 50 and the output circuit 55. Similarly, the high-level green and blue video signals from the processors 14 and 16 are connected to the green and blue cathodes 40b and 40c The output circuit 55 may include a screen spark current limiting resistor and a DC voltage recovery circuit that cooperates with the coupling capacitor 50 to achieve the desired DC bias for cathode 40a color screen 45 obrazovky.

The collector load circuit of the second amplifier 31 exhibits a relatively low impedance as determined primarily by the value of the first resistor 34. The emitter circuit of the low-level first amplifier 30 comprises an impedance 36 connected between the emitter of the first amplifier 30 and the ground reference potential. The impedance 36 includes a second resistor 37 parallel to the series combination of the third resistor 38 and the capacitor 39. The function of the impedance 36, particularly with respect to the capacitor 39, is to increase the emitter current of the transistor of the first amplifier 30.

In this regard, the impedance 36 decreases with increasing signal frequency.

The impregnation 36 also serves as a current sampling circuit associated with a negative feedback loop including a feedback impedance 60, a first transistor 20, an emitter follower transistor 24, and an input transistor of the first color stage driver 45 stage amplifier 30.

The circuit comprising the first and second transistors 20 and 21 together with the decoupling transistor 24 and the first amplifier 30 and the feedback impedance 60 corresponds to the feedback opamp. The base input of the first transistor 20 corresponds to the inverting input of the operational amplifier. The ground reference potential is applied to the non-inverting input of the second transistor 21 amplifier.

The emitter current of the transistor of the first amplifier 30, which determines the output current of the collector of the transistor of the second video amplifier 31, is prone to exhibit non-linearities caused, for example, by temperature effects and transistor variations. Temperature effects become a factor of increasing importance when the transistors of the first amplifiers 30 and 31 carry relatively large currents. In this respect, it should be noted that in order to maintain the ability to amplify the high bandwidth signal, the broadband driver stage formed by the first and second amplifiers 30 and 31 exhibits considerably lower output impedance and conducts significantly higher currents compared to the narrowband driver stages as commonly used in television sets.

The described feedback loop comprising a feedback impedance 60 compensates for such non-linearities and cooperates in maintaining the thermal stability of the driver stage. The voltage generated at impedance 36 represents the magnitude of the video signal represented by the emitter current of the drive transistor of the first amplifier 30, including any non-linear current components.

This voltage is continuously fed back to the transistor base of the first stage 30 amplifier via the feedback impedance 60 of the first transistor 20 and the decoupling transistor 24 so that the base transistor signal voltage of the first amplifier 30 shows the magnitude and sense of generating a linear emitter current for the transistor. in particular, the voltage excitation base of the transistor of the first amplifier 30 includes a component relative to the non-linear component of the emitter current, but of a magnitude and sense that substantially negates the effect of the non-linearity of the emitter current.

Conducting the linear current of the transistor of the first amplifier 30 is important because the signal current through the transistor of the first amplifier 30 substantially corresponds to the signal output current through the video transistor output of the second amplifier 31. A nonlinear output signal would damage video quality generated in response to the video signals .

The described feedback arrangement avoids the problems that would result from the feedback being conducted from the collector output of the second video output amplifier 31 to the input driver stage of the display. The transistor collector exhibits an impedance which, in combination with parasitic capacitances, can lead to undesirable phase and time delay errors that would impair the feedback efficiency and reproduced image quality.

Such errors occur particularly frequently in the processing of 30 MHz high frequency video signals and can lead to distorting effects such as output signal oscillation.

In addition, a given high frequency increases the likelihood of circuit instability, for example, parasitic oscillations depending on the feedback loop gain and phase shift introduced by the parasitic capacitances. Such parasitic capacities include, for example, capacitances associated with the video output circuit itself, output wiring, and connector capacities.

In the feedback arrangement shown, the feedback control voltage is derived from the low impedance emitter of the transistor of the first amplifier 30, which greatly reduces the effect of the parasitic capacities. The described feedback arrangement exhibits good stability at high frequencies and does not exhibit disturbing phase and time delay errors of the feedback while providing current linearity compensation and temperature stability.

The feedback circuit also serves to ensure that the current of the signals driven by the video excitation stage remains in linear relationship with the voltage of the red input signal supplied from the source 10.

The described feedback stage arrangement of the feedback screen is particularly useful in conjunction with high-definition video broadband display systems, such as video monitors used in television studios to monitor the quality of the transmitted video signals, as well as in conjunction with systems intended to display good-resolution alphanumeric characters , associated video signals in a wide band. The latter type of system may include home television sets with a device for displaying alphanumeric information, such as teletext and computer-derived data, which are supplied via additional inputs, as well as leased display monitors connected to computer terminals.

Claims (6)

SUBJECT OF THE INVENTION A feedback stage of a color feedback screen, wherein the output of the individual signals is coupled via a preamplifier stage to an isolation transistor of the emitter follower characterized in that the output of the isolation transistor (24) is connected to the base of the first amplifier (30) to which emitters are connected. (36) and whose collector is connected to an emitter of a second amplifier (31) connected as a cascade amplifier, the collector of which is connected to individual color cathode (40a, 40b, 40c) via an output circuit (55). 2. The excitation stage of claim 1, wherein the second amplifier (31) is coupled by its base to the bias potential and its collector to the load impedance (34), the main current path of the amplifier being the collector and emitter of the second amplifier (31). . 3. The drive stage of claim 2, wherein the emitter follower transistor (24) is coupled by its emitter to a power source (26) and its base to a preamplifier circuit formed by uniformly coupled first and second transistors (20 and 21). wherein a feedback impedance (60) is coupled between the base of the first transistor (20) and the emitter of the first amplifier (30). 4. The excitation stage of any one of the preceding claims, wherein the impedance (36) comprises resistors (37, 38) and reactances (39) to increase the current conducted by the amplifier circuit at the high frequencies of the video signal. 5. The drive stage of any one of the preceding claims, wherein the closed signal feedback loop for the first amplifier (30) is provided primarily by a feedback impedance (60). 6. The excitation stage of claim 2, wherein the output circuit (55) is provided with a coupling capacitor (50) for alternately coupling the video output signals from the second amplifier (31) to the cathode (40a) of the color screen (45).