CS211581B1 - Connection for automatic balancing of the component signals level and for automatic maintenance thereof - Google Patents

Description

BACKGROUND OF THE INVENTION The present invention relates to an apparatus for automatically balancing the level of component signals and for maintaining them automatically when capturing and processing an image signal in a color television capture device.

In known methods the solutions according to component signals generated by scanning a defined scene adjusted either manually or automatically the gain _of each channel sensor chain, and this sets the required signal levels, i.e. the required balance of these levels.

A disadvantage of this known method is that the balance of the component signals is dependent on the stability of the video signal processing circuits and that the component signals do not contain any reference level according to which the amplification of the individual channels of the chain can be adjusted. maintain.

The above-mentioned drawbacks are eliminated by the circuit according to the invention, which is characterized in that in each transmission channel, one of which is a basic one consisting of a basic pickup tube, a basic transmission member, a control member and a set of basic sensors for evaluating and controlling voltage signal levels and at least one slave, comprising a slave tube, slave transducer, memory element, and slave array for evaluating, and controlling the voltage levels of the signal, the output terminal of each transmitter is connected to the input terminals of at least two sensors, the output terminal of the reference signal sensor it is always connected to the first control terminal of the transmission element, while the output terminal of the basic component signal sensor is connected to the control element, the output of which is connected either to the luminous flux control device of the sensor or to the comparator terminal of the slave component signal and the slave component signal output is. connected to the memory element control terminal. Second input terminal of the basic transfer member

211581 ’i 2 ~.

it is connected to the output terminal of the memory element. Connection of a reference source, a basic transmission channel composed of a base transducer, a base translator, a control member, and a base sensor array for evaluating and controlling the voltage levels of the signal and at least one sub-transmission channel and a set of slave sensors for evaluating and controlling the voltage levels of the signal introduces reference signals into the component signals. The level of the reference signals is proportional to the level of the nominal component. signals. At the outputs of the transfer members, said circuit automatically maintains the reference signal level at a predetermined value, thereby automatically maintaining the balance of the component signal levels.

An example of a wiring according to the invention is shown in the figure.

The output of the basic sensor tube Z1 is connected to the first input terminal Z21 of the basic transmission element Z2. Its output terminal Z23 is connected to the input terminal Z31 of the basic sensor Z3 of the reference signal, to the input terminal Z41 of the basic sensor Z4 of the component signal, respectively. also with input terminal Z51 of the basic sensor Z5 of the reference signal. The output of the base sensor Z3 of the reference signal is connected to the first control terminal Z24 of the basic transmission element Z2, to the second control terminal -25 of which it is connected. The output of the basic sensor Z5 of the reference signal is connected. The output terminal Z42 of the basic sensor Z4 of the component signal is connected to the input of the control member Z6.

Its output terminal Z61 is connected either to the luminous flux control device on the pickup tubes or to the comparator terminal V43 of the sub-component sensor V4. The second input terminal Z22 of the basic transmission element Z2 is connected to the output terminal A1 1 of the reference source A1. The output of the slave sensor V1 is connected to the first input terminal V21 of the slave transmission element V2. Its output terminal V23 is coupled to the input terminal V31 of the sub-sensor V3 of the reference signal, the input terminal V41 of the sub-sensor of the component signal, or the input terminal V51 of the sub-sensor V5 of the reference signal.

The output of the slave reference signal sensor V3 is connected to the first control terminal V24 of the slave transfer element V2, to which the second control terminal V25 is connected, if necessary. The auxiliary sensor output V5 of the reference signal is connected. The output of the component component secondary sensor V4 is connected to the control terminal V72 of the memory element V7. Its output terminal V73 is connected to the second input terminal V22 of the secondary transfer member V2. The output terminal A1 1 of the reference source A1 and the output terminal V73 of the memory element V7 can also be connected to the control terminals of the matrix circuit.

The base reference signal sensor Z3 evaluates the level of the reference signal inputted from the reference source A1 to the second input terminal Z22 of the basic transmission element Z 2, whose parameters it controls via its first control terminal Z24; thereby maintaining a defined output signal level at the output of the basic transceiver Z2. The component component signal base sensor Z4 either controls the luminous flux through the sensor tubes via the control element Z6, in which case a defined reference voltage is applied to the reference component terminal V43 of the component component signal 4 or controls the control element via the control element. Z6 is the magnitude of the reference voltage applied to the comparator terminal V43 of the sub-sensor V4 of the component signal, in which case the luminous flux at the sensor tubes is constant.

In both cases, a fixed relationship between the reference signal level and the component signal level is set at the output terminal Z23 of the basic transmission element Z2. The reference signal sub-sensor V3 evaluates the level of the reference signal applied to the second input terminal V22 of the sub-transmission V2, the parameters of which are controlled by its first control terminal V24; thereby maintaining a defined output signal level at the output of the transmitting member V2. The component signal sub-sensor V4 controls the memory element V7 and adjusts the reference signal at the second input terminal V22 of the sub-transmission element V2 so that its output terminal V23 has a strong relationship between the reference signal level and the component signal level. Because it is both at the output of the basic transfer member Z 2 and at the output 3

1581, the reference signal level is automatically maintained at the transceiver V2, and the balance of the component signal levels is also automatically maintained at the transceiver outputs. '’

Since the correlation between the reference signal level at output terminal A11 of reference source A1 and the reference signal at output terminal V73 of memory element V7 is influenced by luminous flux quality on the sensing tubes, the reference signal1 at output terminals A1 1 and V73 can be used as input information for matrix. circuit.

Claims (6)

SUBJECT OF THE INVENTION An apparatus for automatically balancing component levels and for maintaining them automatically, characterized in that it comprises a reference source (A1), a basic transmission channel composed of a base pickup tube (21), a basic transmission member (22), a control member (26), and a set of base sensors for evaluating and controlling the voltage levels of the signal, namely the base sensor (23) of the reference signal, the base sensor (Z4) of the component signal and the base sensor (Z5) of the reference signal, further comprising at least one a slave tube (V1), a slave transmission member (V2), a memory element (V7) and a set of slave sensors for evaluating and controlling the voltage levels of the slave signal (slave sensor (V3) of the reference signal, slave sensor) a component signal and a sub-sensor (V5) of the reference signal, wherein v the step of the base sensor tube (21) is coupled to the first input terminal (21) of the basic transducer (22) whose output terminal (223) is coupled to the input terminal (Z31) of the base sensor (23) of the reference signal and is coupled to the input signal (Z41) of the base sensor (Z4) of the component signal, the output of the base sensor (Z3) of the reference signal being coupled to the first control terminal (Z24) of the base transducer (Z2) and the output terminal (Z42) of the base sensor the component signal is connected to the input of the control member (26), whose output terminal (Z61) is connected to the cell for controlling the luminous flux on the pickup tubes or to the comparison terminal (V43) of the sub-component pickup sensor and V 1 / is connected to the first input terminal (V21) of the sub-transmission member (V2), whose output terminal (V23) is connected to the input and is coupled to the input terminal (V41) of the sub-sensor (V4) of the component signal, the output of the sub-sensor (V3) of the reference signal being coupled to the first control terminal (V24) of the sub-transmission signal. and the component signal output (V4) of the component signal is connected to the memory terminal (V72) of the memory element (V7), whose output terminal (V73) is connected to the second input terminal (V22) of the secondary transfer member (V2). wherein the output terminal jA1 1 of the reference source (A1) is connected to the second input terminal (Z22) of the base transfer member (Z2) and the input terminal (V71) of the memory element (V7) and to the comparator terminal (V43) of the secondary sensor (V4) / component signal is connected to the cell of the zero potential point, or the terminal with reference voltage, respectively. the output terminal (261) of the control member (26). 2. Connection according to claim 1, characterized in that it comprises at least two secondary transmission channels. 3. Connection according to claim 1 or 2, characterized in that the output terminal (261) of the control member (Z6 ') is connected to the luminous flux control device on the sensing tubes and the comparator terminal (V43) of the component sensor (V4) is a cell. or a potential reference point. 4. Connection according to claim 1 or 2, characterized in that the output terminal (Z 6-1) of the control member (Z6) is connected to the comparator terminal (V43) of the secondary sensor (V4) of the component signal. 5. The wiring of claim 1, 2, 3 or 4 wherein the output terminal (Z23) of the base transducer (Z2) is coupled to the input terminal (251) of the base sensor (25) of the reference signal whose output is coupled to the second control terminal. (225) of the base transducer (22) and the output terminal (V23) of the sub-transducer (V2) is coupled to the input terminal (V51) of the sub-sensor (V5) of the reference signal whose output is coupled to the second control terminal (V25) member / V2 /. 6. The circuit according to claim 1, 2, 3, 4 or 5, characterized in that the output terminal (A1) of the reference 2 source (A1) and the output terminal (V73) of the memory element (V7) are connected to the control terminals of the matrix circuit.