JPH0457152B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Technical Field) The present invention relates to an imaging device such as a video camera, and particularly to an imaging device that can obtain appropriate AGC characteristics depending on the state of the screen.

(Prior art) In conventional video cameras, a device for switching AGC characteristics according to the screen condition was developed in Japanese Patent Application Laid-open No. 57-
There was something like No. 4667. This is shown in FIG.

In the figure, 1 is a lens, 2 is an aperture, and 3 is an imaging device as an imaging means for converting an optical image taken through the lens 1 into an electrical signal. The aperture 2 is driven by a drive coil 2' to change the size of the aperture. A signal output photoelectrically converted by the imaging device 3 is supplied to a preamplifier 4. The output signal of this preamplifier 4 is the amplifier 10
The rectified pressure is supplied to the comparator 8 and compared with the reference voltage _V1 , and the output of the difference between the two is supplied to the drive coil 2' of the tie 2 through the drive circuit 7. The aperture 2 is controlled so that the preamplifier 4 obtains a video output signal such that the output of the average value rectifier circuit 9 and the reference voltage V ₁ are equal, and the amount of light entering the imaging device 3 is adjusted. The output signal of the preamplifier 4 is supplied to the AGC amplifier 5, and the output of this AGC amplifier 5 is passed through the buffer amplifier 6 to the average value rectifier circuit 1.
3. The peak value rectification circuit 14 performs average value rectification or
Peak value rectified. One of these rectified outputs is selected by the switching circuit 12 according to the output of the comparator 16 and is supplied to the comparator 11. This comparator 11 compares it with the reference voltage _V2 , and the output of the difference between the two is fed back to the AGC amplifier 5, and the gain of the AGC amplifier 5 is automatically controlled so that the rectified output becomes equal to the reference voltage _V2 . This controlled signal output is supplied to the subsequent circuit. Here, the AGC amplifier 5, the amplifier 6, the rectifier circuits 13 and 14, and the comparator 11 constitute automatic gain control means.

On the other hand, the output of the amplifier 10 in the preceding aperture loop is also supplied to a peak value rectifier circuit 15, and this peak rectified output is supplied to a comparator 16 and compared with a set reference voltage _V3 . This comparator 21
The output is at a roll level when the peak value rectified output level is lower than _V3 , and is at a high level when the peak value rectified output level is higher than _V3 .

Incidentally, the output of this comparator 16 is connected to the switching circuit 1 for changing the characteristics of the automatic gain control means as described above.
2, and the switching circuit 12 is supplied to the comparator 16.
When the output is low level, the peak value rectified output is supplied to the comparator 11, and when the output is high level, the average value rectified output is supplied to the comparator 11.

Here, the aperture mechanism loop consisting of the above-mentioned aperture 2, image sensor 3, preamplifier 4, amplifier 10, rectifier circuit 9, comparator 8, and drive circuit 7 rectifies the imaging output and performs control using its DC level. but,
The rectified output level V ₀ changes depending on the ratio of bright and dark parts of the object and the output signal peak level V _P of the preamplifier 4. That is, if the proportion occupied by bright parts to the entire screen is k, and the rectification characteristic is expressed as a function of k, the rectification output level V ₀ can be expressed as V ₀ =V _P f(k). In the comparator 8, the feedback loop works so that the rectified output V ₀ is equal to the reference voltage V ₁ , so V ₁ =V _P f(k) ∴V _P =V ₁ /f(k) . There are two main types of rectification methods: average value rectification and peak value rectification. When examining the k-V _P characteristics of these methods, average value rectification is as shown in Figure 2, and peak value rectification is as shown in Figure 3. . Since the aperture mechanism loop is an average value rectifier circuit, its k-V _P characteristic is as shown in FIG. Further, the output of the pre-amplifier 4 is also supplied to a peak value rectifier circuit 15 through a buffer amplifier 10, and the peak voltage V _P can be detected and compared with a set voltage V ₃ by a comparator 16.

For example, if you set V ₃ so that k = 0.3, that is, equal to the peak level of the output of amplifier 10 when the bright part occupies 30% of the entire screen; when k becomes 0.3 or less, the aperture control Since the loop is an average value rectifier, the peak value V _P of the amplifier 10 is higher than when k=0.3 according to the k-V _P characteristic shown in FIG.
Therefore, when this is detected by the peak value rectifier circuit, the output of the comparator 16 becomes high level, and the switching circuit 1
2, the rectifier circuit of the AGC loop becomes an average value rectifier circuit, and conversely, when k is 0.3 or more, the peak value V _P
becomes lower than k=0.3, and the output of the comparator 16 becomes low level, forming a peak value rectifier circuit.

In other words, when there is a bright part of the screen, such as a fluorescent light, the AGC loop becomes an average value rectifier circuit and is controlled so that the average value of the output of amplifier 6 is constant, so the dark part This prevents the phenomenon of collapse. Also, the phenomenon of bright areas being crushed can be prevented. Further, when the bright portion exceeds 30%, the AGC loop uses the peak value rectification method and is controlled so that the peak value of the output of the amplifier 6 is constant, so there is no level fluctuation in the bright portion.

However, in an imaging device that switches the rectification characteristics of the AGC loop depending on the screen condition, when capturing a scene with a spotlight shining on a person in the center of the screen and a dark surrounding, the ratio of bright parts to the entire screen changes. Since k is low, the rectification characteristic of the AGC loop is average value rectification, and the average value of the output of amplifier 6 is controlled to be constant, so bright areas (people and objects exposed to spotlights) will be over-leveled and blown out. There was a flaw that became a phenomenon.

(Purpose) The present invention is an imaging device equipped with an exposure control circuit that switches and controls the characteristics of the AGC loop depending on the proportion of the bright part of the screen. In dark scenes where bright areas occupy a small proportion of the entire screen, the level of the target high-brightness subject exceeds the level, which eliminates the problem of overexposure, and even in such scenes, the level of the target subject is captured at an appropriate level. The purpose of the present invention is to provide an imaging device that enables the following.

(Examples) Hereinafter, the present invention will be explained in detail based on Examples. FIG. 4 is a block diagram showing an embodiment of the invention, in which the same reference numerals as in FIG. 1 indicate the same elements. 17 is a gate circuit for gating the output of the amplifier 10, and 18 is a gate pulse generation circuit for forming gate pulses to be described later. The light of the object focused by the lens 1 is controlled by the diaphragm 2, and is supplied to the preamplifier 4 where it is photoelectrically converted by the image sensor 3. The output signal of the preamplifier 4 is supplied to the average value rectifier circuit 9 through the amplifier 10, the rectified output is supplied to the comparator 8 and compared with the reference voltage _V1 , and the difference output between the two is supplied to the aperture 2 through the drive circuit 7. The aperture 2 is controlled so that the preamplifier 4 obtains a video output signal such that the output of the average value rectifier circuit 9, which is supplied to the drive coil, is equal to the reference voltage _V1 , and the amount of light entering the image sensor 3 is adjusted. The output signal of the preamplifier 4 is also supplied to an AGC amplifier 5, and the output of this AGC amplifier 5 passes through a buffer amplifier 6, and this signal is subjected to peak value rectification or average value rectification in an average value rectifier circuit 13 and a peak value rectifier circuit 14. be done. One of these rectified outputs is selected by the switching circuit 12 according to the output of the comparator 16, and is supplied to the comparator 11. This comparator 11 compares it with the reference voltage V ₂ and the output of the difference between the two is sent to the AGC amplifier 5.
The gain of the AGC amplifier 5 is controlled so that the rectified output becomes equal to the reference voltage _V2 . This controlled signal output is supplied to the subsequent circuit.

On the other hand, the output of the amplifier 10 of the aperture loop in the previous stage is output by the gate circuit 17, and the horizontal pulse generated in the gate pulse generation circuit 18 as shown in FIG.
When gate pulses synchronized with the vertical television rate are mixed and added, only the video signal in the peripheral area of the screen as shown by diagonal lines in FIG. 6 is gated and supplied to the peak value rectifier circuit 15. This peak control output is supplied to a comparator 16 and compared with a set reference voltage _V3 . The output of the comparator 16 is determined to be low level when the peak value rectified output level is lower than _V3 , and high level when it is higher than _V3 . Here, 40 surrounded by a dotted line constitutes a discriminating circuit as discriminating means for performing such discrimination. Note that the output of this comparator 16 is supplied to the switching SW circuit 12 as described above.
The switching circuit 12 operates by supplying the peak value rectified output to the comparator 11 when the output of the comparator 16 is low level, and supplies the average value rectified output to the comparator 11 when the output is high level.

In this way, the brightness distribution state of the screen excluding the center is determined, so even if a high level of brightness occurs, it will not be detected by the peak rectifier circuit 15, so in a scene where the brightness is high at the center of the screen and the rest is dark, Since the rectification characteristic of the AGC loop is peak value rectification, AGC works so that the part of the screen where the brightness level is high is at an appropriate level. Generally, the desired subject is often placed in the center of the screen, so
If a gate pulse with reduced weight at the center of the screen is used as in the present invention, a good sensitivity state can be obtained even in a scene where the target object has a high brightness level.

FIG. 7a shows the gate pulse generation circuit 18 of FIG.
2 is a diagram showing an example of a circuit configuration of a gate setting circuit 19. FIG. In the figure, 70 to 73 are delay circuits;
4,75 is flip-flop, 76 is NAND
It is a circuit.

FIG. 7b is a diagram showing the operation timing in the configuration shown in FIG. 7a, in which the delay circuit 70 gives a delay time _t1 to the horizontal synchronizing signal _HD , and the delay circuit 71
gives the delay time t ₂ .

Further, the delay circuits 72 and 73 provide delay times t ₃ and t ₄ respectively to the vertical synchronizing signal V _D. The flip-flop 74 is set at the rising edge of the output of the delay circuit 70 and reset at the rising edge of the output of the delay circuit 71, forming an output as shown in e of FIG. 7b.
Further, the flip-flop 75 is set at the rising edge of the output of the delay circuit 72, and reset at the rising edge of the output of the delay circuit 71, forming an output as shown in f of FIG. 7b. Therefore, a low level signal is outputted to the output terminal of the NAND circuit 76 while both signals e and f are at high level. As a result, the peak cannot be detected by the peak rectifier circuit, so the output of the comparator 16 becomes low level.

Therefore, for example, if the screen is not centered on a person in a spotlight in a darkened theater, the optimal sensitivity adjustment for the person's brightness will be automatically performed.

FIG. 8 shows a second embodiment of the invention, in which the same numbers as in FIG. 4 indicate the same elements. 20 is amplifier 10
21 is a modulation signal circuit that generates a modulation signal. In this embodiment, a modulation circuit 18 is provided in place of the gate circuit 17 shown in FIG. 4, and the parabolic waveform synchronized with the horizontal and vertical TV gates as shown in FIG.
1 and mixed with the output of the amplifier 10 in the modulation circuit 20 to perform modulation. This results in a signal waveform in which the periphery of the screen is weighted, as shown by diagonal lines in FIG. When this signal is supplied to the peak value rectifier circuit 15, the peak value rectifier circuit 15 becomes almost unable to detect the peak signal that exists around the center of the screen, so the output of the comparator 16 becomes low level, and the switching SW circuit 12 outputs the peak value. Rectifier circuit 14
The output of is led to the comparator 11.

Therefore, AGC works according to the level of the peak value around the center of the screen, and as described above, optimal sensitivity adjustment is made even for a person in the center of the screen who is exposed to a spotlight, for example. In this embodiment, a block 41 surrounded by a dotted line constitutes a discriminating circuit as discriminating means.

(Effects) As described in detail above, according to the present invention, the distribution state of brightness in the area other than the center of the image capturing screen is determined, and the AGC characteristics are changed based on the results of this determination. The sensitivity will be appropriate even if a spot-lit subject is in the center, and if there are streetlights around the screen during night shooting, the sensitivity will be adjusted to match the dark areas that make up most of the screen. The effect of this can be obtained.

[Brief explanation of the drawing]

Figure 1 shows a conventional circuit example, Figure 2 shows the k-V _P characteristic of average value rectification, Figure 3 shows the k-V P characteristic of peak value rectification, and Figure 4 shows the k-V _P characteristic of peak value rectification. A block diagram of the imaging device of the present invention, FIGS. 5a and 5b are diagrams showing an example of gate pulses, FIG. 6 is a diagram showing a gated part of the screen, and FIG. 7a is a diagram of the gate pulse generation circuit. A configuration example diagram, FIG. 7b is an operation timing diagram, and FIG. 8 is a block diagram of another embodiment of the present invention.
Figures 9a and b are diagrams showing parabolic modulation waveforms,
Figure 0 is a diagram showing weighted portions on the screen. 1 is a lens, 2 is an aperture, 3 is an imaging device, 4
is the preamplifier, 5 is the AGC amplifier, 6 is the amplifier,
7 is a drive circuit, 8 is a comparator, 9 is an average value rectifier circuit, 10 is an amplifier, 11 is a comparator, 12 is a switching circuit, 13 is an average value rectifier circuit, 14, 15 is a peak value rectifier circuit, 16 is a comparison circuit 17 is a gate circuit, 18 is a gate pulse generation circuit, 20 is a modulation circuit, 21 is a modulation signal generation circuit, and 40 and 41 are discrimination circuits.

Claims (1)

[Claims] 1. Imaging means for converting an optical image into an electrical signal; a first gain control mode for automatically controlling the gain of the output signal of the imaging means based on the average value of the output signal level; automatic gain control means capable of switching between a second gain control mode that performs gain control based on a peak level value, and a detection means for detecting a luminance level of the output signal corresponding to a peripheral portion of the imaging screen excluding the central portion. . An imaging device comprising a switching control means for switching between the first gain control mode and the second gain control mode of the automatic gain control means in accordance with the output of the detection means.