JPH0424692Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Technical Field of the Invention] This invention relates to a color television camera device, and is particularly capable of setting the pedestal level without being affected by gamma correction characteristics, and with a wide range of master level control. This invention relates to an improved device that can maintain consistency in pedestal levels of video signals.

[Technical background of the invention] Currently, the system most practically used as a color television camera for broadcasting is a system that uses image pickup tubes for each of the three primary colors of red, green, and blue. This method is based on the video processing system shown in FIG. 3, particularly gamma correction and pedestal control.

That is, the video signals output from each of the red (R), green (G), and blue (B) image pickup tubes 11a to 11c are amplified by the respective amplifiers 12a to 12c, and then clamped by a DC clamp circuit (not shown). After that, the adders 13a to 13c superimpose the signal on the pedestal control signals from the pedestal control circuits 14a to 14c. Then, the variable gamma correction circuits 15a to 15c output gamma control signals S _R ,
Gamma correction is performed according to S _G and S _B , blanking processing is performed using a blanking signal S _BBL in blanking mixing circuits 16a to 16c, and further output to matrix circuits (not shown) via linear clipper circuits 17a to 17c, respectively.

Here, in the above video processing system, each of the red, green, and blue pedestals can be made to match the same pedestal level by each pedestal control input of Rp, Gp, and Bp. Then, by using the master pedestal control input of Mp, the pedestal levels of the three primary colors, generally referred to as master pedestal control, can be brought into relative agreement and the levels can be controlled over a wide range.

[Problems with Background Art] However, the pedestal control method in the conventional color television camera device as described above has the following problems. That is, the gamma correction characteristics for each of red, green, and blue must be adjusted to different characteristics in order to reproduce achromatic colors over a wide range of light input levels. This is mainly because the gamma characteristics of the image pickup tubes 11a to 11c are slightly different for each primary color, and this is particularly noticeable for red. Therefore, in broadcast systems that require a wide range of color reproduction, gamma correction is adjusted for each primary color, thereby setting its characteristics to different values.

An example of variation in this gamma characteristic is shown in FIG.
Figure a is a gamma characteristic diagram of the variable gamma correction circuits 15a to 15c, and a, b, and c in the figure show gamma characteristics of red, green, and blue, respectively. Figure b is an input waveform diagram of the correction circuits 15a to 15c (red,
(It is assumed that the green and blue video signals and the pedestal control signal are the same.) Figure c is an output waveform diagram of the correction circuits 15a to 15c.
γb and γc are red, green, and blue gamma characteristics a, respectively.
The outputs corresponding to b and c are shown.

As can be seen from FIG. 4, when video signals having the same pedestal and the same video level are input to variable gamma correction circuits with different characteristics,
Each output has three different types. In other words,
Even if the pedestal correction amount of the gamma correction input is the same, the pedestal of the correction output is different because the gamma characteristics are different. In other words, the output pedestal ratio (that is, pedestal control gain) to the pedestal control input is different due to the change in the gamma characteristic.

For this reason, in the past, by adjusting the red and blue pedestal control gains using variable resistors Rr and Rb in Figure 3, the red, green, and blue pedestal levels after gamma correction with respect to the master pedestal control input Mp were adjusted. We are practicing unity. but,
In this case, if gamma correction is performed on each video signal, the fourth
Since the characteristics shown in the figure will change, the variable resistors Rr and Rb must be readjusted. If the gamma correction is finely adjusted during or before shooting, the pedestal level will not be able to maintain good agreement with the master pedestal control input Mp within the variable range, and color reproduction will deteriorate. Furthermore, even if adjustment is made using the variable resistors Rr and Rb, the slopes of each gamma characteristic do not match over a wide range, so the pedestal control gain can be adjusted over a wide range for each primary color using the master pedestal control input Mp. However, it is extremely difficult to match them.

Furthermore, in computer-controlled color television camera apparatuses that have recently been put into practical use, gamma correction causes changes in the pedestal, resulting in a problem that the automatic adjustment procedure becomes long and complicated.

[Purpose of the invention] This invention was made in order to improve the above-mentioned problems. It is possible to set the pedestal level without being affected by the gamma correction characteristics, and it is possible to set the pedestal level without being affected by the gamma correction characteristics. It is an object of the present invention to provide a color television camera device capable of keeping the pedestal levels of each video signal consistent.

[Summary of the invention] That is, the color television camera device according to the invention performs gamma correction after performing pedestal control on each of a plurality of video signals, in which the blanking period of each video signal after the gamma correction is adjusted. The present invention is characterized in that the level is detected after blanking mixing and before linear clipping, and the level of the pedestal control is adjusted based on the detected level.

[Embodiment of the invention] Hereinafter, an embodiment of the invention will be described in detail with reference to FIGS. 1 and 2. However, in Fig. 1, the same parts as in Fig. 3 are indicated with the same reference numerals.
Only the different parts will be described here.

FIG. 1 shows its configuration, in which the outputs γa to γc of the variable gamma correction circuits 15a to 15c are supplied to the blanking circuits 16a to 16c via buffer amplifiers 20a to 20c, respectively, and sample and hold ( S/H) circuit 21a~
21c. These sample and hold circuits 21a to 21c each sample the input signal during the positive polarity period of the sample pulse SP and hold it during the negative (or 0) polarity period, and each output Esr, Esg, Esb is a pedestal control circuit. 22a to 22c.

The red pedestal control circuit 22a connects the output Esr of the sample and hold circuit 21a to the (-) input terminal of the operational amplifier Aa via a resistor R1, and connects the pedestal control input Rp to the resistor R _R and variable resistor Rr via a resistor R2. A master pedestal control input Mp is also supplied through the pedestal, its (+) input terminal is grounded, and a feedback system stabilizing capacitor Cr is connected between its (-) input terminal and output terminal. Pedestal control circuit 22 for green
b is the operational amplifier Ab and resistors R1' and R as in the red one.
2′, R _G and a capacitor Cg, and the blue pedestal control circuit 22c also includes an operational amplifier Ac,
It consists of resistors R1'', R2'', R _B , variable resistor Rb, and capacitor Cb. The outputs of the pedestal control circuits 22a-22c are respectively supplied to the adders 13a-13c.

The operation of the above configuration will be explained below. Note that since the operations are the same for red, green, and blue, only the operation for red will be described here.

First, the pedestal control and gamma corrected video signal appears at the output γa of the variable gamma correction circuit 16a as shown in FIG. 2a.
This output signal γa is supplied to the sample hold circuit 21a.
Then, as shown in FIG. 2b, the sample is held in response to the sample pulse SP which becomes a positive polarity pulse during the vertical beam retrace period. This sampled and held potential Esr is applied to the pedestal control circuit 2.
2a, the signal is mixed with the red-only pedestal control input Rp and the master pedestal control input Mp, and then supplied to the adder 13a, where a feedback loop is formed.

Now, set the output level of the sample hold circuit 21a to Esr [V], and set the level of the pedestal control input Rp to
Epr [V], and the level of the master pedestal control input Mp is Em [V]. If the amplification degree of the operational amplifier Aa is sufficiently large and its input impedance is also sufficiently large, then from the above feedback loop, Esr/R ₁ +Epr/R ₂ +Em/Rrm=0...(1) (However, Rrm=R _R +Rr) The following relational expression holds true. That is, from equation (1), the output Esr of the sample and hold circuit 21a is Esr=-(R ₁ /R ₂ )Epr-(R ₁ /Rrm)Em (2). Therefore, as can be seen from equation (2),
The relationship between Esr and Em is not affected by the variable gamma correction circuit 15a. From this equation (2), the relational expression ΔEsr=-(R ₁ /Rrm)ΔEm ...(3) holds true, so the potential during the sample and hold period at the gamma correction output γa (the potential indicating the pedestal level) is The relationships in equations (2) and (3) will be maintained.

Here, in equation (2), the first term is each gamma correction output γa,
The second term means the master pedestal control by the master pedestal control input Mp, and the variable resistors Rr and Rb
If we set R ₁ /Rrm=R ₁ ′/R _G =R ₁ ″/Rbm (where Rbm=R _B +Rb), then ΔEgr, ΔEsg,
ΔEsb can be matched. It is clear from equations (2) and (3) that none of these is affected by the respective gamma corrections. In addition, variable resistance
Setting Rr and Rb is a gain adjustment for Em, so repeat the adjustment several times to match Esr, Esg, and Esb at any point of the master pedestal control using the single pedestal control inputs Rp, Gp, and Bp. and make Esr, Esg, Esb variable resistance at any other point.
Match by adjusting Rr and Rb. The above gamma correction outputs γa, γb, γc are provided by the buffer amplifier 20a.
After passing through steps 20c and 20c, blanking and mixing are performed as before, and black level clipping is performed by a linear clipper. The pedestal potential offset of these circuits is determined by the pedestal control inputs Rp, Gp,
It will be corrected by Bp.

Therefore, by configuring the color television camera device as described above, it has the following advantages.

(1) Even if the gamma correction amount is changed, the pedestal level of each primary color signal does not change at all in the final output.

(2) The relative level relationship of the pedestals of each primary color signal depends only on the single pedestal control input and is not affected by gamma correction.

(3) The relative coincidence of the pedestals of each primary color signal with respect to changes in the master pedestal control input is not affected by changes in the amount of gamma correction. That is, there is no need to readjust the variable resistor when changing the gamma correction amount.

(4) From the above, even if the gamma is slightly changed by adjusting the color reproduction of the camera device, there is no need to readjust the pedestal level or readjust the relative coincidence of each primary color signal pedestal.

(5) In camera devices that automatically adjust using a computer, etc., gamma adjustment and pedestal adjustment can be performed independently, simplifying control procedures (programs, etc.) and speeding up automatic adjustment time. .

Note that this invention is not limited to the above embodiment; for example, detection of γa, γb, and γc can be performed in the amplification stage before blanking and mixing if it is performed after gamma correction (variable or semi-fixed). The output of a corrector etc. may also be used. Further, the sample hold may be performed during either the vertical or horizontal retrace period as long as it is within the retrace period. Furthermore, it is well known that primary color video signals can be used for signals other than red, green, and blue, and it is also possible to implement the same method in a single-tube camera device if gamma correction is performed for each color after color separation. be.

[Effects of the invention] As detailed above, according to this invention, the pedestal level can be set without being affected by the gamma correction characteristics, and the pedestal level of each video signal can be adjusted even with a wide range of master level control. It is possible to provide a color television camera device that can maintain consistency of color.

[Brief explanation of the drawing]

FIG. 1 is a block circuit diagram showing an embodiment of a color television camera device according to this invention, FIG. 2 is an output waveform diagram for explaining the operation of the embodiment, and FIGS. 3 and 4 are 1A and 1B are a block circuit diagram and a waveform diagram, respectively, for explaining the configuration and operation of a conventional color television camera device. 11a to 11c... image pickup tube, 13a to 13c...
... Adder, 14a to 14c, 22a to 22c...
Pedestal control circuit, 15a-15c...
...Variable gamma correction circuit, 16a-16c...Blanking mixing circuit, 17a-17c...Linear clipper circuit, 20a-20c...Buffer amplifier, 21a-21c...Sample hold circuit.

Claims (1)

[Scope of utility model registration request] In a color television camera device that performs gamma correction on a plurality of video signals after performing pedestal control, and then performs blanking mixing and linear clip processing, the level of the retrace period of each video signal after gamma correction is determined. A color television camera characterized by comprising: a detection means for detecting before the blanking mixture and before the linear clip, and an adjustment means for adjusting the level of the pedestal control based on the level obtained by the detection means. Device.