JPH06292054A - Video camera provided with horizontal aperture compensation circuit - Google Patents

Abstract

PURPOSE:To attain always optimum contour compensation by varying a frequency characteristic of a horizontal aperture correction signal based on focal distance information in response to a focal distance of a lens used for replacement so as to provide an optimum aperture correction signal in response to a pattern automatically. CONSTITUTION:A delay control circuit 3 controls a delay of delay circuits 1, 2 based on sets of focal distance information fa-fc of lenses used through replacement coming from a focal distance information generating circuit 4. An arithmetic operation circuit 5 makes arithmetic operation of B-(A+C)/2 based on an input video signal A, and delayed video signals B, C delayed by the circuits 1, 2 and provides an aperture correction signal D. An adder circuit 6 adds the signal B, D to provide an output of (video signal + aperture correction signal) E. Thus, a boost frequency is automatically changed in response to the sets of the information fa-fc and optimum contour is always compensated for a pattern and an optimum picture is obtained.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an improvement of a video camera having a horizontal aperture compensation circuit and capable of switching a plurality of lenses having different focal lengths and used in combination with a microscope.

[0002]

2. Description of the Related Art Generally, a video camera is provided with an aperture compensation circuit, but the conventional aperture compensation circuit has, for example, a configuration as shown in FIG. That is, the two delay circuits 101 and 10 connected in cascade.
2, the input video signal is A, the signal delayed by the first delay circuit 101 is B, and the signal delayed by the second delay circuit 102 is C, the calculation of B- (A + C) / 2 And an arithmetic circuit 103 for outputting the aperture correction signal D,
The addition circuit 104 is configured to add the delay signal B from the first delay circuit 101 and the aperture correction signal D from the arithmetic circuit 103 to output (video signal + aperture correction signal) E.

[0003]

By the way, the boost frequency of the aperture correction signal of the conventional horizontal aperture compensation circuit is fixed and is not configured to change according to the aspect of the screen.

Originally, the boost frequency has an appropriate frequency depending on the fineness of the design, and should be low when the design is rough and high when the design is fine. That is, when the boost frequency is fixed to a low value, the resolution is increased when the pattern is rough, but when the pattern is fine, the image quality is adversely deteriorated due to the thick contour due to the low boost frequency. On the other hand, if the boost frequency is fixed to a high value, the contour is fine and the image is high quality when the pattern is fine, but when the pattern is rough, the contour is weak and the resolution is poor.

For example, FIGS. 10 (A) and 10 (B) show a part of an example of a horizontal video waveform AA 'when a vertical stripe object as shown in FIG. 9 is taken. FIG. 10A shows a waveform when the boost frequency is fixed at f _P = 2 MHz, and the contour thickness is appropriate for the design at high magnification (focal length is large), but low magnification (focus When the distance is small), the contour is overemphasized to the design, which rather impairs the resolution. FIG. 10 (B) shows a case where f _P = 6 MHz, which is fixed to a high value, and the contour thickness is appropriate when the magnification is low, but on the contrary, when the magnification is high, the contour is too thin for the pattern. The resolution is poor.

The present invention has been made to solve the above-mentioned problems in a video camera having a conventional horizontal aperture compensation circuit. The frequency of the aperture correction signal from the horizontal aperture compensation circuit depends on the focal length of the lens. An object of the present invention is to provide a video camera having a horizontal aperture compensation circuit whose characteristics can be changed and which can always obtain optimum contour compensation.

[0007]

In order to solve the above problems, the present invention provides a video camera having a horizontal aperture compensating circuit, wherein a plurality of lenses having different focal lengths can be switched and used. Means for transmitting focal length information in response to switching of a plurality of lenses having different focal lengths, and frequency characteristics of an aperture correction signal output from the horizontal aperture compensation circuit upon receiving focal length information from the focal length information transmitting means And a control means for changing the value in a stepwise manner.

Generally, when the focal length of the lens is large, the pattern is rough, and conversely, when the focal length is small, the pattern is fine. Therefore, in the video camera configured as described above, the frequency characteristic of the aperture correction signal is changed by the control means in accordance with the focal length information from the focal length information transmitting means, so that the aperture having the optimum frequency characteristic according to the pattern is displayed. A correction signal is sent out so that optimum contour compensation can always be obtained.

[0009]

EXAMPLES Next, examples will be described. FIG. 1 is a block diagram showing an embodiment of a video camera having a horizontal aperture compensation circuit according to the present invention. In the figure,
Reference numerals 1 and 2 are first and second delay circuits connected in cascade, and 3 is a delay amount control circuit, and the first and second delay circuits 1 and 2 are provided.
The control signal for controlling the delay amount is transmitted. Reference numeral 4 denotes a lens focal length information generation circuit, which uses the delay amount control circuit 3 to convert the focal length information of the lens to be used for switching.
To be sent to. Reference numeral 5 denotes an arithmetic circuit, where A is the input video signal, B is the signal delayed by the first delay circuit 1, and C is the signal delayed by the second delay circuit.
The calculation of (A + C) / 2 is performed, and the aperture correction signal D is output. An adder circuit 6 adds the delayed video signal B from the first delay circuit 1 and the aperture correction signal D from the arithmetic circuit 5 and outputs (video signal + aperture correction signal) E.

In this embodiment, the first and second delay circuits 1 and 2 are constituted by delay amount variable circuits, an example of which is shown in FIG. In this configuration example, a plurality of delay devices having delay amounts of τ ₁ , τ ₂ , and τ ₃ are connected in cascade, and the output of each delay device is controlled by a control signal from the delay amount control circuit 3. The amount of delay can be changed by selecting it by the multiplexer 7.

Here, the range of the focal length of the lens to be switched and used is classified into several stages in advance, and the delay amount is controlled according to the classified group.
For example, a focal length of less than 40 mm is f _a , 40-100 mm is f _b ,
The 100 mm than classified into three stages groups such as f _c. When a lens having a focal length in the range of f _a is used, the focal length information generation circuit 4 generates a signal corresponding to f _a , and the multiplexer 7 receives the control signal from the delay amount control circuit 3 to output the delay amount τ _d = τ ₁ of the output signals a, likewise f _b, the multiplexer 7 so as to correspond to the lens to be classified as f _c, the delay amount τ _d = τ ₁ + τ ₂
Output signal b and delay amount τ _d = τ ₁ + τ ₂ + τ ₃ are output.

The signal waveform in each part of the aperture compensating circuit configured as described above is as shown in FIG. 3, and the delay amount τ _d by the delay circuits 1 and 2 is output from the delay amount control circuit 3 based on the focal length information. By controlling with the control signal, the boost frequency changes. That is, when a lens with a large focal length is used, the pattern becomes rough, but the delay amount of the delay circuits 1 and 2 becomes large due to the control signal from the delay amount control circuit 3 based on the focal length information, and the boost frequency f _P becomes Get lower. On the other hand, when a lens having a small focal length is used, the pattern becomes fine, but the delay amount of the delay circuits 1 and 2 becomes small due to the focal length information, and the boost frequency f _P becomes high.

As described above, the boost frequency is automatically changed according to the design and the lens magnification (focal length), so that optimum contour compensation is always performed. Note that, in FIG. 4, when the vertical stripe object shown in FIG. 9 is taken, f _P = 2MH at the high magnification side.
A part of the video waveform in the horizontal direction when changing so that f _P = 6 MHz on the low magnification side z, is shown. As can be seen from this figure, it is possible to realize an appropriate outline thickness for the pattern, regardless of whether a high-magnification lens or a low-magnification lens is used.
The optimum image can always be obtained.

FIG. 5 is a block diagram showing the second embodiment of the present invention. In the figure, 11 is the first of the delay amount τ _d1 .
Delay circuit, 12 is a second delay circuit for delay tau _d2, 13 third delay circuit of same delay tau _d2, 14 in the fourth delay circuit of the delay amount tau _d1, connected in cascade, respectively There is. 15, 16
Is an arithmetic circuit, the input video signal is A, the first delay circuit 11
Is B, the delay signal of the second delay circuit 12 is C, the delay signal of the third delay circuit 13 is D, and the delay signal of the fourth delay circuit 14 is E, C- (B + D), respectively. / 2, C
The calculation is − (A + E) / 2 to output the aperture signal F having the boost frequency f _H and the aperture signal G having the boost frequency f _L , respectively.

Numerals 17 and 18 denote multiplication circuits, which are the arithmetic circuits 15 and 16
The aperture signals F and G from the coefficient generator 19 are multiplied by the coefficients K and 1-K (0 ≦ K ≦ 1) from the coefficient generator 19. A coefficient is generated based on the information. The focal length information generating circuit 20 corresponds to the focal length information generating circuit 4 in the embodiment shown in FIG. 1, and the focal length groups f _a , f _b , The signal corresponding to f _c is generated. Reference numeral 21 denotes an adding circuit, which adds two aperture signals of boost frequencies f _H and f _L whose levels are controlled by the multiplying circuits 17 and 18 to add an aperture correction signal H to the video signal.
Is generated. Reference numeral 22 is an addition circuit for adding the video signal C delayed by the delay circuits 11 and 12 and the aperture correction signal H to output (video signal + aperture correction signal).

Next, the operation of the aperture compensating circuit configured as described above will be described with reference to the diagram showing the frequency characteristic of the aperture correction signal of FIG. 6 and the signal waveform diagram of FIG. First, the four cascaded delay circuits τ _d1 and τ _d2 with delay circuits 11, 12, 13, 14 and two arithmetic circuits 15, 16
Two aperture signals F of boost frequencies f _H and f _L ,
G is generated. Further, based on the focal length information from the focal length information generation circuit 20, the coefficient generator 19 outputs coefficients K, 1-
K occurs. Then, in the multiplying circuits 17 and 18, the boost frequencies f _H and f _L are set to 2 by the coefficients K and 1-K.
The levels of the two aperture signals F and G are controlled and added by the adder circuit 21 to obtain an aperture correction signal H. Then, the aperture correction signal H and the delayed video signal C delayed by the first and second delay circuits 11 and 12 are added together by an adder circuit.
22 added, (video signal + aperture correction signal)
J is obtained.

[0017] In this embodiment, the coefficients K, 1-K by the focal length of the lens to be switched used, depending on the f _a, f _b, the signal corresponding to f _c from the focal length information generating circuit 20, For example, the aperture correction signal is obtained by changing K = 1, 0.5, 0, thereby changing the mixing ratio of two aperture signals having different boost frequencies.
Therefore, the frequency characteristic and the thickness of the waveform of the aperture correction signal are optimally controlled by the coefficient K based on the focal length information in accordance with the pattern corresponding to the lens magnification.

In each of the above-mentioned embodiments, the focal length information is generated from the focal length information generating circuit manually in accordance with the lens used, or automatically in the focal length group f _a ,
f _b, may output switching a signal corresponding to f _c. When a video camera is combined with the microscope apparatus, the lens of the camera becomes the objective lens of the microscope. In a microscope, usually, a plurality of kinds of lenses having different magnifications (focal lengths) are attached to a revolver having a plurality of holes. Therefore, if the revolver is manual, when changing the magnification of the objective lens by turning the revolver manually, manually f _a, f _b, selectively outputs a signal corresponding to f _c. When the revolver is an electric type and the magnification is selected by the objective conversion button, if the focal length information generation circuit is linked to the objective conversion button, f is automatically changed according to the magnification of the objective lens.
Signals corresponding to _a , f _b , and f _c can be generated.

[0019]

As described above on the basis of the embodiments,
According to the present invention, the frequency characteristic of the aperture correction signal is changed according to the focal length information corresponding to the focal length of the lens to be used for switching, and the aperture correction signal having the optimum frequency characteristic according to the pattern is generated, and the optimum contour is always obtained. Compensation can be made.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of a video camera including a horizontal aperture compensation circuit according to the present invention.

FIG. 2 is a diagram illustrating a configuration example of a delay circuit.

FIG. 3 is a diagram showing signal waveforms of respective parts in the aperture compensation circuit shown in FIG.

FIG. 4 is a diagram showing a part of a video waveform when the boost frequency is changed on the high-magnification side and the low-magnification side.

FIG. 5 is a block diagram showing a second embodiment of the present invention.

FIG. 6 is a diagram showing frequency characteristics of an aperture signal in the second embodiment.

FIG. 7 is a diagram showing a signal waveform of each part in the second embodiment.

FIG. 8 is a block diagram showing a configuration example of a conventional aperture compensation circuit.

FIG. 9 is a diagram showing an example of a subject.

FIG. 10 is a diagram showing video waveforms on the high-magnification side and the low-magnification side when the boost frequency is fixed low and high.

[Explanation of symbols]

 1, 2 Delay circuit 3 Delay amount control circuit 4 Focal distance information generation circuit 5 Calculation circuit 6 Addition circuit 7 Multiplexer 11, 12, 13, 14 Delay circuit 15, 16 Calculation circuit 17, 18 Multiplication circuit 19 Coefficient generator 20 Focal length Information generator 21, 22 Adder circuit

Claims (4)

[Claims] 1. A video camera having a horizontal aperture compensation circuit, wherein a plurality of lenses having different focal lengths can be switched and used, and focal length information is transmitted in response to switching of the plurality of lenses having different focal lengths. Means and a control means for receiving the focal length information from the focal length information transmitting means and stepwise changing the frequency characteristic of the aperture correction signal output from the horizontal aperture compensation circuit. Video camera with horizontal aperture compensation circuit. 2. The horizontal aperture compensation circuit according to claim 1, wherein the control means for varying the frequency characteristic of the aperture correction signal is configured to vary the boost frequency of the aperture compensation circuit. Equipped video camera. 3. The control means for changing the frequency characteristic of the aperture correction signal is configured to change a mixing ratio of a plurality of aperture correction signals having different boost frequencies of the aperture compensation circuit. A video camera comprising the horizontal aperture compensation circuit according to claim 1. 4. The horizontal aperture according to claim 1, wherein the focal length information sending means is configured to send the focal length information manually or automatically. Video camera with compensation circuit.