DE4117325A1 - AUTOMATIC GAIN CONTROL DEVICE FOR A VIDEO CAMERA - Google Patents

Description

The invention relates to an automatic Gain control (AVR) device for a video camera according to the preamble of claim 1.

Such an AVR device for video cameras is known and shown in FIG. 4. It usually comprises a lens 1 , a first and a second sample-and-hold circuit 2 , 3 , an automatic gain control (AVR) circuit 4 , a correction electronics (processor) 5 , a matrix circuit 6 , a color encoder 7 , one AVR detector 8 , an iris driver stage 9 , a CCD driver stage 10 , a synchronizer 11 , a CCD imager 12 , an iris 17 and an iris motor 18 .

The image captured by the CCD imager 12 is photoelectrically converted into an electrical signal such that it is suitable for a video signal. The signal obtained in this way is sampled by means of a 9.54 MHz sample and hold pulse in the first sample and hold circuit 2 and by means of a second sample and hold pulse in the second sample and hold circuit 3, and the signal obtained in this way the AVR circuit 4 impressed.

Accordingly, the output signal of the AVR circuit 4 is correlated twice with a scanning signal, whereby two 4.77 MHz signals (Sp 1 and Sp 2 ) are generated.

In this way, the color beard signal, which is fed to the correction electronics 5 , is separated from the signal to be scanned. The color beard signal in turn is converted into the RGB signal in the matrix circuit 6 , and this is separated in the color encoder 7 into the Y, RY and BY signals, which are forwarded to the video recorder as a video output signal.

A conventional video camera includes the AVR circuit 4 because the video signal level occasionally changes, which is to prevent it. For this purpose, it is provided that the video input is impressed on the first input of the AVR circuit 4 and the output signal of the AVR detector 8 is impressed on the second input.

The AVR detector 8 decreases the gain in the AVR circuit 4 to lower the signal level if an input signal level higher than the standard level is present. On the other hand, the AVR detector 8 increases the gain if the input signal level is lower than the standard level.

In this way, the AVR detector 8 is constantly activated during camera operation in order to monitor the video signal, while the AVR circuit 4 reacts directly to the radiation intensity incident on the iris diaphragm 17 .

In FIG. 5, a common automatic iris system is shown, wherein the iris diaphragm 17 is controlled such that it automatically adapts to the changes in intensity of the incident radiation, to keep constant around the video signal level of the camera.

For this purpose, the iris diaphragm 17 is controlled by two signals, namely the NAM (non-additive mixed) signal and the luminance (Y) signal. The NAM signal combines the R, G and B signals with the same signal level, whereby the maximum level for the respective R, G and B signal is exceeded.

In the case of the luminance (Y) signal, it is taken into account that the mixed component of the respective color signal is equal to 0.6 G + 0.3 R + 0.1 B. As a result, the iris diaphragm 17 is regulated by direct voltage averaging of the peak value corresponding to the high-frequency sideband component.

However, in a conventional type video camera, it is practically impossible to maintain both the ideal video signal level and the ideal AVR gain level, as shown in Fig. 6A.

When the video signal level changes due to fluctuations in the light intensity, the AVR detector 8 outputs a control signal, which is proportional to the difference between the current video signal level and the standard level, to the AVR circuit 4 , which reduces the gain in the AVR circuit 4 and the Normal status is reached again.

In practice, the iris 17 must be open and the video signal level must be kept constant by means of the AVR circuit 4 . In the case where the recording process under normal lighting conditions with an open iris diaphragm 17 is made and suddenly the light intensity decreases, but the display is momentarily darkened, because the response time of the iris motor 18 is relatively high and that on top of that a hysteresis shows (see Fig. . 6B).

In the opposite case, in which the recording process takes place under weak lighting and the light intensity suddenly increases, the iris diaphragm is closed (see FIG. 6C).

If the picture is taken at a high exposure and the light intensity suddenly decreases sharply, the screen brightness is currently greatly increased, after which it returns to normal, since the gain in the AVR circuit 4 is increased. As a result, the video signal level rises to the point of inflection due to the response time of the iris motor 18 and its hysteresis. This phenomenon occurs particularly at high illuminance.

As explained above, both the conventional camcorders and professional video cameras have the disadvantage that the video signal quality is reduced due to the overshoot behavior of the AVR circuit 4 , which controls the iris diaphragm 17 , which is due to the different response times of the AVR circuit 4 and the Iris motor 18 is caused.

The object of the present invention is to overcome this disadvantage of common video cameras by creating an improved one Avoid AVR switching.

This object is achieved through the features of the claims solved.  

The general principle of solution of the present invention is that the output signal level of the AVR circuit using a microcomputer based on the queried Operating speed and current Operating state of the iris motor up to Normal operating state of the iris diaphragm is calculated and then by feedback of the output signal to an input of the AVR circuit this is kept constant.

This will make it much faster and more accurate AVR device for video cameras realized.

The invention will now be described with reference to the drawing explained. Show it:

Fig. 1 is a block diagram of an automatic gain control (AGC) apparatus for a video camera according to the invention;

Fig. 2A, 2 B and 2 C are each a graph showing the control response with respect to the video signal level of an inventive AGC apparatus;

Figs. 3A and 3B is a program flow chart for the control of an inventive AGC apparatus;

Fig. 4 is a block diagram of a conventional automatic gain control device for a video camera;

Fig. 5 is a block diagram of a conventional automatic iris device;

6A is a graph that represents the video signal level and the AGC gain level for an ideal case in a conventional video camera.

Fig. 6B is a graph showing the video signal level and the AVR gain level in the case that the iris has just been opened in a conventional video camera;

Fig. 6C is a graph showing the video signal level and the AVR gain level in the case that the iris has just been closed in a conventional video camera.

As shown in Fig. 1, the AVR device according to the invention comprises a lens 1 , a first and a second sample and hold circuit 2 , 3 , an AVR circuit 4 , a correction electronics 5 , a matrix circuit 6 , a color encoder 7 , one AVR detector 8 , an iris driver stage 9 , a CCD driver stage 10 , a synchronizer 11 , a CCD imager 12 , an iris 17 and an iris motor 18 . The AVR device further comprises a microcomputer 14 which is connected to an iris detector 13 and the output of the AVR circuit 4 , a clamping circuit which is connected upstream of the AVR circuit 4 and the correction electronics 5 , and an analog switching stage 16 which , controlled by the microcomputer 14 , the connection between the AVR circuit 4 and the AVR detector 8 or disconnects.

The response time of the iris motor 18 , signal level fluctuations and the malfunction of the AVR circuit 4 are minimized by the use of the clamping circuit 15 for regulating the microcomputer 14 and the analog circuit 16 .

As shown in the program flow chart of FIGS. 3A and 3B, the change in the AVR level, which causes the deterioration or distortion of the video image, is minimized by means of level comparison, evaluation and regulation in the microcomputer 14 .

For this purpose, the microcomputer 14 determines in the first step S 1 the video signal level at the output of the AVR circuit 4 ( FIG. 3A).

In a second step S 2 it is queried whether the video signal level corresponds to the standard value.

If this is the case, the analog switching stage 16 is activated in the third step S 3 , so that in the fourth step S 4 the video camera is operated with the normal AVR setting. For this purpose, the switching contacts a and b of the analog switching stage 16 ( FIG. 1) are connected to one another by means of a control signal from the microcomputer 14 .

If it is determined in the second step S 2 that the video signal level does not correspond to the standard value, the microcomputer 14 determines in the fifth step S 5 whether the video signal level is within the permitted tolerance range. If so, the third step S 3 proceeds as described above.

Otherwise, it is determined in the sixth step S 6 ( FIG. 3B) whether the video signal level is at the upper limit of the permitted tolerance range.

If this is the case, the microcomputer 14 calculates the lower AVR gain factor in the seventh step S 7 .

In the eighth step S 8 , the microcomputer 14 queries whether this calculation has been completed. If this question is answered in the negative, the seventh step S 7 must be carried out in the cycle until the calculation is complete.

If the answer is in the affirmative, the analog switching stage 16 is activated in the ninth step S 9 in such a way that the switching contacts a and b are connected to one another, after which the amplification in the AVR circuit is regulated.

In the tenth step S 10 , the amplification factor of the AVR circuit 4 is output.

In the eleventh step S 11 , it is determined whether the video signal level is within the permitted tolerance range. If this is the case, the video camera is operated in the normal range.

If this is not the case, steps S 5 to S 11 are run through in the cycle until the video signal level is again within the permitted tolerance range.

If it is determined in the sixth step S 6 that the video signal level is not at the upper limit of the permitted tolerance range, the microcomputer 14 checks in the twelfth step S 12 whether the video signal level is at the lower limit of the permitted tolerance range and then calculates if the answer is affirmative in the thirteenth step S 13 the higher AVR gain factor.

If it is then determined in step S 8 that the calculation of the higher AVR gain factor has been completed in the thirteenth step S 13 , steps S 8 to S 11 are carried out .

If, however, the calculation in S 13 has not yet ended, step S 13 is carried out in the cycle.

If it is determined in the twelfth step S 12 that the video signal level is not at the lower limit of the permitted tolerance range, steps S 5 to S 11 or steps S 5 , S 12 , S 13 , S 8 to S 11 in the cycle run through.

Claims (2)

1. Automatic gain control (AVR) device for a video camera, consisting of a lens ( 1 ), a first and a second sample and hold circuit ( 2 , 3 ), an AVR circuit ( 4 ), a correction electronics ( 5 ), a matrix circuit ( 6 ), a color encoder ( 7 ), an AVR detector ( 8 ), an iris driver stage ( 9 ), a CCD driver stage ( 10 ), a synchronizer ( 11 ), a CCD image converter ( 12 ), an iris diaphragm ( 17 ) and an iris diaphragm motor ( 18 ), characterized in that

• - That also an iris detector ( 13 ), a microcomputer ( 14 ), a clamping circuit ( 15 ) and an analog switching stage ( 16 ) are provided;
• - That the microcomputer ( 14 ) with the iris detector ( 13 ) and an output of the AVR circuit ( 4 ) is connected;
• - That the clamping circuit ( 15 ) is connected between an output of the AVR circuit ( 4 ) and an input of the correction electronics ( 5 );
• - That the analog switching stage ( 16 ) between an input of the AVR circuit ( 4 ) and an output of the AVR detector ( 8 ) is connected and
• - That the video signal level in the AVR circuit ( 4 ) is kept constant in that the microcomputer ( 14 ) controls the AVR circuit ( 4 ) via the analog switching stage ( 16 ) in a suitable manner.

2. A method of operating an automatic gain control (AVR) device according to claim 1, characterized in that the following steps are carried out in succession in the microcomputer ( 14 ), in whole or in part or, if appropriate, in a cycle several times:

• - In the first step (S 1 ), the video signal level at the output of the AVR circuit ( 4 ) is determined;
• - In the second step (S 2 ) it is queried whether the video signal level corresponds to a predetermined standard value;
• - In the third step (S 3 ), the analog switching stage ( 16 ) is activated if the answer in the second step (S 2 ) is positive;
• - In the fourth step (S 4 ), the video camera is operated with the normal AVR setting, for which purpose the switching contacts (a, b) of the analog switching stage ( 16 ) are connected to one another;
• - in the fifth step (S 5 ) it is determined whether the video signal level, if it does not correspond to the standard value, is within the permitted tolerance range, if this is the case, the third step (S 3 ) is connected; otherwise it will
• - In the sixth step (S 6 ) determines whether the video signal level is at the upper limit of a predetermined permitted tolerance range;
• - In the seventh step (S 7 ), if the answer in the sixth step (S 6 ) is positive, a lower AVR gain factor is calculated;
• - In the eighth step (S 8 ), a query is made as to whether the calculation of the amplification factor has been completed, and if the answer is no, the seventh step (S 7 ) is carried out in the cycle until the calculation has ended;
• - In the ninth step (S 9 ), the analog switching stage ( 16 ) is driven such that the switching contacts (a, b) are connected to one another, after which the gain in the AVR circuit ( 4 ) is regulated;
• - In the tenth step (S 10 ) the gain factor of the AVR circuit ( 4 ) is output;
• - In the eleventh step (S 11 ) it is determined whether the video signal level is within the permitted tolerance range, in which case the video camera is operated in the normal range, otherwise steps S 5 to S 11 are run through in the cycle until the video signal level is again within the permitted tolerance range lies;
• - In the twelfth step (S 12 ) it is checked if it has been determined in the sixth step (S 6 ) that the video signal level is not at the upper limit of the permitted tolerance range, whether the video signal level is at the lower limit of a predetermined permitted tolerance range, whereby in the negative case, steps S 5 to S 11 or steps S 5 , S 12 , S 13 , S 8 to S 11 are run through in the cycle;
• - In the thirteenth step (S 13 ) a higher AVR gain factor is calculated, with the following eighth step (S 8 ) checking whether this calculation has been completed; if this is not the case, the thirteenth step (S 13 ) is carried out in the cycle until the calculation is completed, whereupon steps S 8 to S 11 follow.