KR100229053B1 - Video camera - Google Patents

Abstract

The present invention relates to aperture control of a lens as a video camera suitable for application to a video camera capable of interchangeable lenses.

In the aperture control, the opening and closing positions of the apertures are detected, and the ratio between the amount of light required for imaging and the actual amount of light is detected to generate an aperture driving signal so that the aperture control can be satisfactorily performed at high speed.

Description

Video camera

1 is a block diagram showing one embodiment of a video camera of the present invention.

FIG. 2 is an explanatory diagram showing a gain adjustment sequence of the example shown in FIG.

3 is a configuration diagram showing an example of a conventional video camera.

* Explanation of symbols for main parts of the drawings

1: video camera body 6: central control unit

10 lens unit 12 aperture

15: aperture driving circuit 21: Hall element

23: lens side central control unit

The present invention relates, for example, to a video camera suitable for application to a video camera with interchangeable lenses, and more particularly to aperture control of a video camera lens.

The present invention detects the opening / closing position of the aperture in the control of the aperture of the video camera and simultaneously detects the ratio between the amount of light required for imaging and the actual amount of light, and generates a drive signal for the aperture based on the detected ratio. Aperture control is satisfactory at high speed by multiplying a coefficient that changes according to the opening and closing position of the driving signal by supplying it to the driving means of the aperture, and simultaneously setting the change characteristic of the coefficient to when the ratio of light quantity is 1 or more and 1 or less. It is to be done.

Various lenses have been developed in the related art which can exchange lenses. The video camera that can be replaced with this lens can cope with various shooting conditions by appropriately exchanging a lens having a required focal length and brightness.

By the way, in the interchangeable lens device, the diaphragm for adjusting the amount of incident light is mounted on the lens device side, and the diaphragm is adjusted by supplying a signal for controlling the diaphragm to the lens device on the video camera main body side. That is, as shown in FIG. 3, the lens device 10, which is detachably attached to the video camera 1, is attached, and the light from the subject is transferred into the video camera 10 through the lens device 10. FIG. An image is formed on a face plate of the installed solid-state imaging device (hereinafter referred to as CCD) 2. Thus, the imaging signal output from the CCD 2 is supplied to the video signal processing circuit 3, and the video signal processing circuit 3 converts the imaging signal into a predetermined video signal, and the video signal is converted into an output terminal ( In 4), a video tape recording unit (not shown) is supplied for recording.

Thus, the detection circuit 5 detects the level of the luminance component of the image pickup signal supplied to the video signal processing circuit 3, and supplies the detection signal to the central control device 6 composed of a microcomputer. The central control apparatus 6 controls various circuits of the video camera and supplies various control signals to the lens apparatus 10. In this case, the reference voltage generator 7 is connected to the central controller 6, and the central controller 6 detects the level of incident light from the detection signal supplied from the detector 5 to the CCD 2. At the same time, the ratio between the actual incident light quantity level and the incident light quantity level required for imaging is determined from the output reference voltage of the reference voltage generator circuit 7 set based on the incident light quantity level required for imaging, and the aperture control is performed so that this ratio becomes 1. Output the signal. Expressing this fact as an expression, when the detection level of the incident light amount is V and the reference voltage level is Vr, the aperture control signal I is

I = V / Vr .... (1)

It becomes

Thus, this digitally signaled aperture control signal I is supplied to the lens-side central controller 13 mounted on the lens apparatus 10. The lens device 10 includes a photographing lens 11 composed of a plurality of apertures and an aperture 12 for adjusting the amount of light reaching the CCD 2 through the lens 11. The driving signal output from 13) is supplied to the aperture driving circuit 15 through the digital analog converter 14.

Therefore, the lens-side central control device 13 supplies a drive signal to the aperture driving circuit 15 so that the aperture control signal I supplied from the central control device 6 of the video camera body 1 becomes 1.

By doing in this way, the control of the diaphragm 12 mounted in the lens apparatus 10 is performed. In this case, a control signal is transmitted from the video camera main body 1 to the lens device 10 side by digital communication, and aperture control is performed by digital processing.

However, when the diaphragm control is performed by digital processing in this way, the driving signal supplied to the diaphragm driving circuit 15 is determined by the output reference voltage of the reference voltage generating circuit 7, and it is inconvenient to take time to open and close the diaphragm. There was this. In particular, in the case of a video camera having a separate lens device as described above, since it takes time to communicate from the video camera main body to the lens device, there is a delay in signal processing, which simply increases the gain of the driving signal. Only by hunting, it was easy for hunting to continuously move in front of and behind the target position.

SUMMARY OF THE INVENTION An object of the present invention is to enable stable aperture adjustment at a high speed of a video camera that is interchangeable with a lens.

The video camera of the present invention forms an image on a predetermined surface of the imaging means 2 via a predetermined lens device 10, for example, as shown in FIG. 1, and outputs the imaging means 2. In the video camera which obtains an image signal from the signal, the opening and closing position of the diaphragm 12 mounted on the lens device 10 is detected by the hall element 21, and at the same time the amount of light required for imaging and the predetermined surface of the imaging means 2 are actually detected. Detecting a ratio with the amount of light reaching and generating a drive signal of the aperture based on the detected ratio, multiplying the drive signal by a coefficient that changes according to the opening / closing position of the aperture, and supplying it to the driving means 15 of the aperture; At the same time, the change characteristic of this coefficient is set opposite to when the ratio of the quantity of light is 1 or more and 1 or less.

By doing in this way, the gain of the drive signal of an aperture changes favorably according to the control state of an aperture, and favorable opening / closing position control of an aperture can be performed at high speed.

Next, an embodiment of a video camera of the present invention will be described with reference to FIGS. 1 and 2. In FIG. 1 and FIG. 2, the part corresponding to FIG. 3 is attached | subjected with the same code | symbol, and the detailed description is abbreviate | omitted.

In FIG. 1, reference numeral 1 denotes the entire video camera, and the video camera 1 is provided with a lens device 10 which is freely attached and detached, and the light emitted from the subject is transferred to the lens device 10. FIG. By forming an image on the face plate of the CCD 2 installed in the video camera 1, an image signal is obtained from the image signal output terminal 4 based on the captured image signal output from the CCD 2, and a video tape recording diagram ( (Not shown). Thus, the detection circuit 5 detects the level of the luminance component of the image pickup signal supplied to the video signal processing circuit 3, and detects the detection signal by the central control unit (CPU) 6. Thus, the ratio between the determined luminance signal level and the output reference voltage of the reference voltage generator circuit 7 set based on the incident light quantity level required for imaging is obtained, and the ratio between the actual incident light quantity level and the incident light quantity level required for imaging is obtained. Is detected by the above expression (1).

Thus, the detected ratio data is supplied as digital data to the lens device 10 connected to the video camera main body 1. In this case, the supply of the digital data from the video camera main body 1 is performed through a predetermined terminal (not shown) provided in the connecting portion of the lens device 10, and every new frame of each video signal (every two feeds) is provided. Supply the data.

So, the lens device 10 is. A plurality of photographing lenses 11 and an aperture 12 for adjusting the amount of light reaching the CCD 2 through the lens 11 are provided, and the opening and closing positions (rotational positions) of the aperture 12 are hall elements. Detected by (21), the detection signal of this Hall element 21 is supplied to the lens side central controller 23 via the amplifier 22. Further, the ratio data V / Vr supplied from the video camera body 1 to the lens device 10 is supplied to the lens side central controller 23.

Therefore, the lens-side central control unit 23 determines the F value (opening and closing degree of the aperture) of the lens from the detection signal of the hall element 21. Thus, in this example, the lens-side central controller 23 stores the conversion table of the coefficient data corresponding to this F value, and obtains the coefficient data based on this conversion table. In this case, when converting into this coefficient data, the ratio data supplied to the lens side central control unit 23 is discriminated at this time, and when the ratio data is 1 or less and when it is 1 or more, coefficient data is obtained based on another conversion table. . That is, for example, as shown in FIG. 2, when the F number of the lens device 10 is changed from F1.4 to F16, if the ratio data is 1 or less, the coefficient 0.4 is set at F1.4. Set the coefficient 1.0 at F16 and gradually change the coefficient between them. If the ratio data is 1 or more, the coefficient 1.0 is set at F1.4, the coefficient 0.1 is set at F16, and the coefficient is gradually changed therebetween.

Therefore, the lens-side central controller 23 performs a process of multiplying the coefficient set in this way by the ratio data supplied to the lens-side central controller 23, and multiplies the multiplied data by a constant proportional constant, A drive signal of the diaphragm 12 is assumed. That is, if the ratio data is V / Vr, the coefficient is G, and the proportional constant is K, the drive signal D is

D = K × (V / Vr) × G ... (2)

It becomes

Further, the ratio data V / Vr becomes 1 or less when the F value set by the current aperture 12 is smaller (darker) than the target F value, and when the ratio data V / Vr becomes 1 or more, the current aperture 12 The F value set by) is greater than the target F value (brighter). In addition, in the example shown in FIG. 2, setting the minimum coefficient when the ratio data is 1 or less and smaller than the minimum coefficient when the ratio data is 1 or less indicates that the loop gain of the aperture control is small. This is to compensate for the increase.

In this way, the drive signal D calculated by the lens-side control device 23 is supplied to the digital analog converter 14, converted into an analog signal, and the analog signaled drive signal is supplied to the aperture driving circuit 15. The iris 12 is driven.

Next, a description will be given of an operation performed when the aperture control is performed by the video camera of the present example. The lens device has a control in which the ratio data supplied to the lens-side central control unit 23 from the video camera main body 1 is 1; In this example, in this example, the current F value is determined, and a coefficient to be multiplied by the ratio data is set based on the conversion table of the F value. The optimum level is set according to the opening and closing position. In this case, it is determined whether the ratio data is 1 or more and 1 or less, and it is determined whether the aperture 12 is to be closed or opened, and the gain change state is reversed with respect to the other side. When the aperture 12 is large in motion, such as when opening from a narrowed state or when it is much narrowed, the gain of the drive signal is set to be large first and gradually decreases at any time. Therefore, the aperture 12 is close to the target position with a rapid movement at first, and a high-speed operation is performed with a short time until the target position is approached. At the same time, the aperture 12 slows down, and stops accurately at the target position. The occurrence of a phenomenon can be prevented. Therefore, as in the present example, the lens device 10 can be exchanged separately, and even when the ratio data of brightness is supplied at a relatively long period, the aperture can be quickly controlled in a good state.

In addition, this invention is not limited to the above-mentioned embodiment, Of course, other various structures can be obtained.

According to the video camera of the present invention, the gain of the drive signal of the aperture changes well according to the control state of the aperture, the response time can be made faster, and the occurrence of hunting phenomenon can be prevented, and the aperture can be satisfactory at high speed. There is an advantage that the open / close position control can be performed.

Claims (1)

In a video camera in which light emitted from a subject is imaged on a predetermined surface of an image pickup means through a predetermined lens device, and an image signal is obtained from an output signal of the image pickup means, Light amount detecting means for detecting the opening / closing position of the diaphragm mounted in the lens device and detecting a ratio between the amount of light required for imaging and light actually reaching a predetermined surface of the imaging means; The drive signal of the aperture is generated based on the ratio detected by the light quantity detecting means, and the drive signal is multiplied by a coefficient that changes according to the opening / closing position of the aperture and supplied to the drive means of the aperture. And a control means for reversing the change characteristic when the ratio is 1 or more and 1 or less.