DE4326898A1 - Method for evaluating recorded image signals (picture signals, video signals) for an image sharpness display - Google Patents

Abstract

In the case of LCD viewfinders having a low resolving power (resolution capability), there is the disadvantage that the image-recording element (CCD) has a higher resolution, and so optimum image-recording monitoring is not possible. The object is to provide a display which includes the image sharpness. For this purpose, the amplitude of the higher-frequency video signal components is evaluated and an image-sharpness display A is obtained as a function of the amplitude, the display being located in the viewfinder. For video cameras, in particular. <IMAGE>

Description

The invention is based on a method for evaluating captured image signals for a focus display according to the Preamble of claim 1.

The color finders used in cameras recently compared to conventional cathode ray viewfinders in cameras the disadvantage that their resolution due to The number of pixels is severely limited. The dissolution of the imaging element (CCD) is higher than that of the Image control via the LCD viewfinder. A manual focus is therefore difficult to carry out or excluded.

The invention has for its object to egg in a simple manner ne evaluation of the captured image signal so that a Focus display is enabled. This task is accomplished by solved the features of the invention specified in claim 1. Before Partial developments of the invention are in the dependent claims Chen specified.

In the image signal evaluation according to the invention, in Dependence on the amplitude of the higher frequencies Video signal shares won the focus display. These Focus display is in the viewfinder of the camera as a bar, Pointer or level display can be shown. From the amplitudes of the vertical and horizontal higher-frequency signal components won the focus display after making their amount. If the amplitude is large, the picture is sharp if the amplitude is low, the sharpness of the image decreases. The higher-frequency video signal components are in a camera than two-dimensional aperture signal already available, which usually used to increase the frequency response. With analog In cameras, this signal is the hardware of the focus display for digital cameras is the information for the Focus indication can be taken from the existing bus.  

The focus display can preferably in the viewfinder of the camera can be shown via an ON SCREEN DISPLAY. In this way it is possible to display this ad as desired to let.

The focus display is also advantageous if it is not only in the viewfinder of the camera, but on the camera itself, because so even from some distance the user is enabled who Control image sharpness.

This focus display becomes a focusing aid created with the one based on the displayed level quick statement about the image sharpness is made possible. These Focusing aid also has for view finders with cathode ray tubes an advantage because if the setting of the Eyepieces from the viewfinder focus on the OSD display can be done.

With such a sharpness display, a Focusing aid created, which also makes it possible with one simplest viewfinder to achieve optimal image acquisition.

Higher frequency video signal components are a measure of that Sharpness. These higher-frequency signal components (H Aperture, V Aperture) are already generated in every camera and serve, added to the main signal path, as a height lift (Peaking and aperture). Compared to conventional ones According to the invention, focusing circuits are also used here higher-frequency signal components in the vertical direction considered.

These correction signals are, after formation of the amount, the A / D converter of the microprocessor supplied, which in turn then digital control signals for ON SCEEN DISPALY (OSD) and / or for direct focus display. Depending on the amplitude of the higher-frequency two-dimensional video signal components the displayed display has a higher or lower level Show.  

Through temporal evaluation of the higher-frequency signal components can also selectively only a certain area of the recorded Image can be used as a focus criterion.

The invention is explained below with reference to the drawing. In it show:

Fig. 1, the image focus indicator according to the invention,

Fig. 2 shows an arrangement according to the invention for obtaining the focus display and

Fig. 3 shows another arrangement according to the invention for obtaining the focus image.

Fig. 1a) and 1b) show the captured image area, the object O and the focus display A. In Fig. 1a) the captured object O is out of focus, so that the focus display A signals this blur by the short bar display. It is now possible to focus using the bar display, so that there is an image sharpness according to FIG. 1b). In this case, the object is in focus, which is indicated by the length of the bar graph. In a viewfinder with a low resolution, the object O is always sharply depicted as in FIG. 1b). The focus can only be checked via the focus display.

Fig. 2 shows an arrangement for obtaining the focus image GE. The image-recording element (IMAGER or CCD) forwards the brightness signal recorded by the lens system L to the video processor VP. The video processor VP on the one hand passes on the CVBS signal and on the other hand the detail aperture signals for horizontal H and vertical V. The CVBS signal arrives at the output OUT and via an addition point to the LCD viewfinder S. The aperture signals horizontal H and vertical V get to a microprocessor µP via an interface I. The microprocessor also receives signals from the control buttons T. The microprocessor µP transmits an output signal via the ON SCREEN DISPLAY OSD and the addition point to the LCD viewfinder S. A further output signal from the microprocessor µP is immediately fed to the focus indication AE. Interface I evaluates the horizontal H and vertical V aperture signals depending on the amplitude of the higher-frequency video signals. The level thus obtained for the focus display is fed to the focus display AE on the one hand and to the LCD viewfinder S via the ON SCREEN DISPLAY OSD and the addition point. The LCD viewfinder S is thus able to display the focus display A.

Fig. 3 shows a further arrangement for obtaining the sharpening display. The Y signal obtained electronically during image acquisition is fed to an addition point, the ON SCREEN DISPLAY OSD and a point K. From the point K, the Y signal reaches the vertical amplifier VV via the line delay 1 H and the horizontal amplifier HV via a delay of 100-200 nsec. Furthermore, the Y signal Y is fed directly to both amplifier stages VV and HV. The vertical amplifier stage VV passes the vertical aperture signal V to an addition stage C. The horizontal amplifier stage HV forwards the horizontal aperture signal H to the addition stage C. The signal passes from the addition stage c to a further addition stage D and to a unit E which forms the amount. This unit E has the diode as a symbol. The signal from the amount-forming unit E is fed to the A / D converter of the microprocessor μP. This in turn sends the signals to the focus display AE and / or to the ON SCREEN DISPLAY OSD. The ON SCREEN DISPLAY OSD, which is connected to the LCD viewfinder, now enables focus display A in the viewfinder.

Claims (5)

1. A method for evaluating captured image signals for an image sharpness display in a camera, characterized in that an image sharpness display (A, AE) takes place as a function of the amplitude of the higher-frequency video signal components (V, H). 2. The method according to claim 1, characterized in that the Focus display in the camera's viewfinder as a bar, pointer or level meter is shown. 3. The method according to claim 1, characterized in that from the amplitudes of the vertical (V) and horizontal (H) higher-frequency signal components, by forming their amount, a manipulated variable to control the focus display is won. 4. The method according to claim 1, characterized in that about an ON SCREEN DISPLAY (OSD) the focus display (A) is displayed. 5. The method according to claim 1, characterized in that the Focus indicator (AE) is displayed outside the viewfinder becomes.