JPS5997276A - Video camera - Google Patents

Abstract

PURPOSE:To display the coverage of a range finder by supplying a display signal representing the range coverage of an automatic focusing mechanism to an electronic view finder monitoring an image pickup picture. CONSTITUTION:The video camera having an automatic focusing mechanism is provided with an electronic view finder monitoring the image pickup picture, a signal generator 14 generating a display signal representing the range of the automatic focusing mechanism, and a signal synthesis circuit 15 applying the display signal from the signal generator 14 to the electronic view finder after superimposing on the video signal. A range designating signal formed by a range designating section 7 is transmitted to a range finding section 8 and used to detect the range to an objective and for forming a range display signal at the display signal generator 14. Thus, the range is displayed on the electronic view finder 1 and the operability is improved.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a video camera equipped with an automatic focusing mechanism.
In particular, the present invention relates to a video camera that displays information on the distance measurement range of an automatic focusing mechanism on an electronic viewfinder.

[Background technology and its problems]

In a video camera equipped with an automatic focusing mechanism, the automatic focusing mechanism measures the distance to a subject and automatically adjusts the focus. When attempting to operate the above video camera, the viewfinder will display the range of the subject that is in focus during autofocus, i.e. the range of the subject covered by the autofocus mechanism. This is advantageous in accurately focusing on the subject. Furthermore, the smaller the distance measurement range of the automatic focusing mechanism is, the better, in order to increase the resolution of the focused portion of the captured image, and for this purpose, it is necessary to display the distance measurement range on the viewfinder.

Conventionally, it is known that the view finder of an optical still camera or the optical view finder of a video camera displays the angle of view. If you try to display the distance measurement range on the optical viewfinder of a video camera using the same method as this method of displaying the angle of view, if you use a twin-lens reflex optical viewfinder, there will be parallax between the distance measurement system and the imaging optical system. The distance measurement range cannot be displayed accurately. Furthermore, even if it is displayed, if it is displayed in a fixed manner by printing or the like, there are disadvantages in that the distance measurement range cannot be changed, and in that it becomes a hindrance when the automatic focusing mechanism is not used.

[Purpose of the invention]

Therefore, the present invention has been proposed in view of the above-mentioned circumstances, and is capable of electronically measuring an arbitrary range in the electronic viewfinder of a video camera equipped with an automatic focusing mechanism, only when the automatic focusing mechanism is operating. The purpose of the present invention is to provide a video camera that displays a distance range and improves operability during automatic focusing.

[Summary of the invention]

To achieve this object, the present invention provides a video camera equipped with an automatic focusing mechanism, which includes an electronic viewfinder that monitors captured images, and a signal generator that generates a display signal indicating the distance measurement range of the automatic focusing mechanism. and a signal synthesis circuit that superimposes the display signal from the signal generator on the video signal obtained by the imaging section and supplies it to the electronic viewfinder.

〔Example〕

Hereinafter, one embodiment of the present invention will be described based on the drawings.

FIG. 1 is a block diagram showing the basic configuration of a video camera according to the present invention. The video camera is equipped with an automatic focusing mechanism that automatically focuses a subject, and further includes an electronic viewfinder 1 using a small cathode ray tube for monitoring captured images.

In the video camera described above, incident light from a subject passes through an imaging lens 2 and forms an optical image on an image sensor 3, which converts the light into an electrical signal.

This electric signal is sent to the video signal generating section 4, and the video signal obtained here is obtained at the signal output terminal 5.

Further, the video signal is supplied to the electronic viewfinder 1, and the video camera can be operated while monitoring the video displayed on the electronic viewfinder 1. Note that the image pickup device 3 and the video signal generation section 4 constitute an image pickup section.

On the other hand, when photographing a subject using the automatic focusing mechanism, first, the power switch 6 for supplying power to the automatic focusing mechanism is turned on. Next, the user manually specifies in the ranging range specifying section 7 which range of the image displayed on the electronic viewfinder 1 is to be focused. As a result, the distance measurement range designation section 7 generates a distance measurement range designation signal indicating which range of the subject the automatic focusing mechanism should measure and focus on.

This signal is sent to the distance detection section 8. A part of the incident light from the subject is reflected by the half mirror 9, further reflected by the reflective mirror 10, and is reflected by the optical sensor 11.
image on top. The electrical signal obtained by the optical sensor 11 is sent to the distance detecting section 8, which detects the distance to the subject within the specified distance measurement range based on the distance measurement range designation signal.

The detection signal obtained by the distance detection section 8 is sent to the motor drive signal generation section 12, and the motor 13 is driven based on the morph drive signal obtained from the motor drive signal generation section 12. There is. By driving this motor 13, the imaging 1/lens 2 moves back and forth in the direction of the subject, so that the subject within the designated distance measurement range is automatically brought into focus.

Further, the electronic viewfinder 1 is provided with a mechanism for electronically displaying the distance measurement range. The outline of this mechanism is as follows.

The distance measurement range display signal generator 14 generates a distance measurement range display signal based on the distance measurement range designation signal and the video signal, and the signal synthesis circuit 15 synthesizes this display signal and the video signal, and the synthesized signal is used for electronic viewing. Supplied to finder 1. From this point on, the distance measurement range is displayed on the electronic viewfinder 1. Further, the display signal is supplied to the signal synthesis circuit 15 via a switch 16 which is interlocked with the power switch '16. therefore,
The above distance measurement range is only available when the automatic focusing mechanism is activated.
It is displayed on the electronic view finder 1. Therefore, when trying to manually focus without using the automatic focusing mechanism, the distance measurement range is not displayed on the electronic viewfinder 1, so it does not interfere with the operation. In addition, the distance measurement range is displayed on the electronic viewfinder 1 at the same time as the power is turned on to the automatic focusing mechanism, so by checking the displayed distance measurement range in the electronic viewfinder 1, the automatic focusing mechanism can be You can know that it is working.

Next, the distance measurement range display signal generator 14 is
This will be explained in detail with reference to FIG.

First, a part of the video signal shown in FIG. 3A generated by the video signal generating section 4 is supplied to the horizontal/vertical synchronizing signal separating section 14A. In this synchronization signal separation section 14A, a horizontal synchronization signal and a vertical synchronization signal are separated and extracted. This extracted horizontal synchronizing signal is sent to the sawtooth wave generating section 14B, which generates the sawtooth wave shown in FIG. 3B having the same period as the horizontal synchronizing signal. The 0 level to maximum amplitude voltage level VH of this sawtooth wave corresponds to 0 to Vl (0 to Vl) when the horizontal length of the cathode ray tube of the electronic viewfinder 1 shown in FIG. 4 is converted into voltage.

Further, the separated vertical synchronizing signal is sent to a sawtooth wave generating section 14C, which generates a sawtooth wave having the same period as the vertical synchronizing signal shown in the third diagram. From the 0 level of this sawtooth wave to the maximum amplitude voltage level V
v corresponds to O to Vv, which is the vertical length of the cathode ray tube converted into voltage.

Further, the distance measurement range designation signal generated by the distance measurement range designation section 7 is sent to the level setting section 14D, so that the level setting section 14D converts the horizontal range of the distance measurement range into voltage levels Vl, V'. Generates 2. Furthermore, when the distance measurement range designation signal is sent to the level setting section 14E, the level setting section 14E generates voltage levels V3 and V4 obtained by converting the vertical range of the distance measurement range into voltage.

Furthermore, the sawtooth wave caused by the horizontal synchronization signal and the voltage levels Vl and V2 in the horizontal range of the distance measurement range are processed by the slicing unit 1.
Supply to 4F. This slice section 14F converts the sawtooth wave to voltage level V1. Slice with V2, Figure 3C
Create the square wave shown in .

Further, the sawtooth wave caused by the vertical synchronization signal and the voltage level V3 of the vertical range of the distance measurement range. V4 to slice section 1
4(). This slicing section 14G slices the sawtooth wave and the voltage levels V1 and V2 to produce a rectangular wave shown in FIG. 3E.

By sending the rectangular wave shown in FIG. 3C created by the slicing section 14F and the rectangular wave shown in FIG. The signal shown in FIG. 3F is produced.

The signal shown in FIG. 3F is supplied to the signal synthesis circuit 15 via the switch 16 and superimposed on the video signal. The superimposed signal is supplied to the electronic viewfinder 1. As a result, as shown in FIG. 4, two vertical bright lines are displayed, and the area between these two bright lines indicates the distance measurement range.

Voltage level V1 corresponding to the horizontal range of the distance measurement range.
Since the voltage level V3゜■4 corresponding to V2 and the vertical range can be set arbitrarily, the electronic viewfinder 1 has
The desired distance measurement range is now displayed.

In this way, the distance measurement range is displayed on the electronic viewfinder 1 only during automatic focusing operation, and the distance measurement range can be specified and displayed arbitrarily, so that the distance measurement range is displayed on the electronic viewfinder 1 only during automatic focusing operation. Operability can be improved.

The distance measurement range displayed on the electronic viewfinder 1 is displayed in circular and rectangular shapes as shown in FIG.
A method of displaying the range A, a method of displaying only the four corners of the distance measurement range as bright spots 1B, a method of blurring the outline of the distance measurement range C, etc. are possible.

〔Effect of the invention〕

As is clear from the above description, according to the present invention, an arbitrary distance measurement range can be displayed on the electronic viewfinder 1 only when the automatic focusing mechanism is operating. Therefore, by confirming that the distance measurement range is displayed on the electronic viewfinder 1, it is possible to know that the automatic focusing mechanism is operating. Furthermore, when trying to focus manually, the distance measurement range is not displayed on the electronic viewfinder, so it does not interfere with manual operations. Furthermore, during automatic focusing operation, the video camera can be operated while checking the arbitrarily specified distance measurement range displayed on the electronic viewfinder 1, which significantly improves the operability during automatic focusing of the video camera. be able to.

[Brief explanation of drawings]

FIG. 1 is a block diagram of a video camera showing an embodiment of the present invention, FIG. 2 is a block diagram of a ranging range display signal generator of the video camera, and FIG. 3 is a block diagram of each part in the signal generator. FIG. 4 is a diagram showing a signal and a diagram showing a distance measurement range displayed on the eyeliner. 1......Electronic viewfinder 14... Distance range display signal generator 15... ... Signal synthesis/circuit patent applicant Sony Corporation representative Patent attorney Kodo Koike 1) Sakae Mura -

Claims (1)

[Claims] A video camera equipped with an automatic focusing mechanism includes an electronic viewfinder that monitors a captured image, a signal generator that generates a display signal indicating a distance measurement range of the automatic focusing mechanism, and a display signal from the signal generator. A video camera comprising: a signal synthesis circuit that superimposes a video signal obtained by an imaging section on a video signal and supplies the superimposed signal to the electronic viewfinder.