JPH0383459A - Video camera - Google Patents

Abstract

PURPOSE:To exactly and speedily recognize an influence to be applied to a picture by the vibration of a camera by a photographer by totally calculating the oscillation of the photographing picture from the vibration (acceleration) generated in the camera and the focal distance of a photographing lens, and displaying the degree of the oscillation in a view finder. CONSTITUTION:Based on the amount of vibration in I, II and III directions to be applied from vibration detecting circuits 34A, 34B and 34C and focal distance information to be applied from a focal distance detecting circuit 38, an arithmetic circuit 36 calculated the acceleration in the I direction (around an optical axis), II direction (tilt direction) and III direction (panning direction) to be generated in the photographing picture. An electronic view finder(EVF) display circuit 40 converts a detection signal inputted from the arithmetic circuit 36 to a signal suitable for the input of an EVF 28 and outputs the signal to the EVF 28 together with a video signal at the time of photographing. According, a warning corresponding to the oscillating direction (I, II and III directions) of the photographing picture and the degree of the oscillation in the photographing picture is displayed in the EVF 28 and attention against the oscillation of the photographing picture is promoted to the photographer.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a video camera, and particularly to prevention of camera shake in a video camera.

[Conventional technology]

In recent years, the cost of video cameras such as VTRs with built-in cameras has been reduced through the use of ICs and mass production, and they are becoming more and more popular in households. For this reason, many people are now taking pictures, and especially for women and beginners, the most desired function is to prevent the image from shaking after the picture has been taken.

As a conventional image stabilization prevention means, there is a method that prevents the camera shake itself. For example, there are gyro-type cameras that rotate a counterweight installed inside the camera and use the inertia generated by the rotation to prevent camera shake, or: There are some known methods that process

[Problem to be solved by the invention]

However, the gyro-type camera shake prevention device requires a counterweight, a motor, etc., which increases the size of the video camera as a whole, and has the disadvantage that power consumption increases because the counterweight is rotated. Furthermore, when photographed images are processed electronically, the y&image circuit becomes complicated, making it unsuitable for general consumer use in terms of cost.

Incidentally, as a device for warning about the camera posture during photographing, there is a tilt display device for a television camera described in Japanese Patent Publication No. 62-23169. This television camera's tilt display device detects the rotational tilt of the camera around its optical axis, and based on this detected value, displays a marker signal corresponding to the camera's rotational tilt on the viewfinder to alert the photographer. However, this is not a warning about camera shake.

The purpose of the present invention is not to correct camera shake itself, but to
To provide a video camera capable of warning a photographer so that the image after shooting will not be shaken. Another object of the present invention is to provide a video camera that records camera shake information of the camera itself at the same time as recording, and can correct image shake during playback.

[Means to solve the problem]

In order to achieve the above-mentioned object, the present invention provides a shake detecting means installed in a camera body to detect camera shake during photographing, a focal length detecting means detecting a focal length of a photographic lens, and a shake detecting means. and a calculation means for calculating the amount of fluctuation of the photographed image based on the detection output of the focal length detection means, and a display means for displaying the amount of fluctuation of the photographed image calculated by the calculation means or information corresponding thereto in the viewfinder. It is characterized by the following.

Further, a converting means converts the detection outputs of the shake detecting means and the focal length detecting means into a recording signal for recording on a magnetic tape, and the recording signal converted by the converting means is recorded in a predetermined area of the video tape. It is characterized by being equipped with a recording means.

[Effect]

According to the present invention, the shake detection means detects camera shake during shooting, which causes image shake, and the focal length of the photographic lens is detected by the focal length detection means, and these detection outputs are sent to the shake calculation means. input. Then, the amount of sway occurring in the captured image is calculated by the sway calculation means, and the calculated amount of sway or information corresponding to the amount of sway is displayed on the viewfinder to alert the photographer to the amount of sway in the captured image. I try to encourage them. Thereby, the photographer can take measures to prevent dynamic changes in the photographed image. In addition, since the camera shake that occurred during shooting and the focal length of the shooting lens are recorded in a predetermined area of the videotape, it is also possible to correct the dynamic feeling of the video based on this recording during playback. be.

〔Example〕

Hereinafter, preferred embodiments of the video camera according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a video camera according to the present invention, with an 8 m
A camera-integrated VTR using an m-video cassette is shown. The camera integrated VTR shown in FIG. 1 includes a camera body 20, a photographic lens 22, a front cover 24, a VT
The main components include the R section 26 and the like. The camera body 20 is provided with a shooting button, a zoom switch, etc. used during shooting.

Additionally, on the top of the camera body 20 there is an electronic viewfinder (CRT) or LCD (liquid crystal).
An EVF>28 is installed, and images are monitored using EVF28 when shooting. In addition, each arrow 30A, 30B, 30C130D, 30E that occurs on the camera body 20 during shooting
Five acceleration sensors (not shown) are attached to the camera body 20 at positions indicated by arrows 30A to 30E in order to detect acceleration in the directions.

FIG. 2 is a block diagram showing the main parts of the circuit configuration of the video camera according to the present invention. Acceleration sensors 32A and 32B
are installed at the positions indicated by arrows 30A and 30B in FIG. 1, and are connected to the shake detection circuit 34. Acceleration sensor 32A
and 32B, the acceleration detected as shake of the camera body 20 is manually inputted to the shake detection circuit 34A, and the shake detection circuit 34A takes the difference between these accelerations and outputs the acceleration detected as shake of the camera body 20.
The deflection (acceleration) in one direction of 0 (around the optical axis) is calculated.

In addition, acceleration sensors 32B and 32C, 32D and 32
E is connected to the shake detection circuits 34B and 34C, and is indicated by arrow 3.
The acceleration in the 0B and 30C, 30D and 30E directions is 34
B and 34C, respectively.

The shake detection circuits 34B and 34C are respectively indicated by the arrows 30B and 30B.
By taking the difference in acceleration in the directions 30C, 130D, and 30E, the camera-integrated VT
R's ■ direction (tilt direction) Tll and ■ direction (pan direction)
Calculate the acceleration occurring at The reason for taking the difference in acceleration is to accurately detect camera shake that affects the imaging surface image.

As shown in FIG. 2, shake detection circuits 34A, 34B, 3
4C is connected to the calculation circuit 36 and the data conversion circuit 37, and the vibration (acceleration) in the I direction, ■ direction, and ■ direction calculated by the shake detection circuits 34A, 34B, and 34C is transmitted to the calculation circuit 36 and the data conversion circuit 37. Output to.

Further, focal length information of the photographing lens 22 is manually inputted to the arithmetic circuit 36 from a focal length detection circuit 38. The arithmetic circuit 36 calculates, based on the amount of shake in the ■ direction, ■ direction, and ■ direction applied from the shake detection circuits 34A, 34B, and 34C, and the focal length information added from the focal length detection circuit 38.
Calculates acceleration in one direction (around the optical axis), ■ direction (tilt direction), and ■ direction (pan direction) that occurs in the photographed image.The focal length information of the photographic lens 22 calculates the acceleration actually occurring in the camera body. , is used to convert into the acceleration that appears in the photographed image.This is because when the photographic lens 22 is zoomed to the wide-angle side, the influence of camera shake on the image is small, and when the photographic lens 22 is zoomed to the telephoto side,
This is because even a slight shake has a large effect on the image. Then, the arithmetic circuit 36 compares the converted acceleration with preset reference data and determines whether the image is noticeably shaken, slightly shaken, or hardly shaken.
Divide into stages.

The arithmetic circuit 36 displays EVF display times i! connected to 1840,
The acceleration of the captured image calculated by the calculation circuit 36 is output to the EVF display circuit 40. EVF display circuit 40
The detection signal inputted manually from the calculation circuit 36 is sent to the EVF 2.
The signal is converted into a signal suitable for manual input to the EVF 28, and is output to the EVF 28 together with the video signal at the time of shooting via an adder point (not shown).

FIG. 3 is an explanatory diagram showing a case where the agitated state of the photographed image is displayed on the EVF 28. 31st! As shown in FIG. 1, the detection signal output from the EVF display circuit 40 is superimposed on the video signal, and together with the video signal, the detection signal is
Output. EVF 2877) CRT.

Alternatively, the oscillation state in the I direction is displayed at position 42A on the LCD, the oscillation state in the ■ direction is displayed at position 42B, and the oscillation state in the ■ direction is displayed at position 42C using predetermined characters and symbols.

As shown in FIG. 3, color filters of red, yellow, and blue (abbreviated as B, Y, and R, respectively, in FIG. 3) are provided at positions 42A, 42B, and 42C of the EVF 28.

The character symbol is clearly visible in the photographed image! It is controlled by the EVF display circuit 40 so that the display is displayed in the red position when it is Ill@, the yellow position when it is slightly shaken, and the blue position when it is hardly shaken.

Therefore, a warning is displayed on the EVF 28 in accordance with the direction of shaking of the photographed image (direction ■, direction ■, direction ■) and the degree of shake of the photographed image, to call the photographer's attention to the shake of the photographed image. For this reason, the photographer can check from the display inside the EVF 28 whether or not the image after shooting will be accompanied by unpleasant agitation! ! This makes it possible to take measures such as preventing camera shake during photography or zooming the photographic lens 22 to the wide-angle side. Thereby, it is possible to prevent the image after shooting from becoming unsightly and unsettling. Further, since the focal length of the photographing lens 22 is taken into consideration, the amount of fluctuation in the photographed image can be accurately notified to the photographer.

In this embodiment, camera shake is controlled by the EVF 28 CRT.

Alternatively, although the information is displayed on the LCD, a light emitting diode (LED) may be attached to the EVF 28 and the information may be displayed on the EVF 28. In this case, it is also possible to use the EVF 28 as an optical viewfinder.

Next, a case will be described in which the shake (acceleration) of the camera body 20 is recorded during shooting. In FIG. 2, the shake (acceleration) of the camera body 20 detected by the shake detection circuits 34A, 34B, and 34C is determined by the arithmetic circuit 36 as well as the
The data is input to the data conversion circuit 37. Data conversion circuit 37
is connected to the recording circuit 41, and records the acceleration of the camera body 20 in the ■ direction, ■ direction, and ■ direction as well as the photographing lens 22.
The detection output of the focal length information of is sequentially converted into PCM, and the PCM
It is output to the recording circuit 41 as a signal.

Further, the recording circuit 41 converts the PCM signal inputted from the data conversion circuit 37 into a signal recordable on the video tape 44, and sends the ID of the video tape 44 via the magnetic head 43.
area or a predetermined area such as the PCM area in chronological order.

By the way, to briefly explain the track arrangement of an 8-tap videotape, as shown in FIG. Between these tracks, there is provided an area for recording and reproduction by a rotating head drum.

This area consists of the area where video signals and FM audio signals are recorded (180° tape wrapping angle), and the area where the PC
It consists of an area where the M audio signal is recorded (36 degrees in tape winding angle), and a 6.88 (H) area at the top of the area where the PCM audio signal is recorded.
;horizontal scanning line) PCM post-recording margin and V-
A Pguard area is provided, part of which is ID (
It is used as an ID area for recording identification information. Therefore, the acceleration of the camera recorded in the ID area or PCM area A,
It is also possible to correct fluctuations in the photographed image by performing electronic processing or the like on the photographed image during playback based on the focal length information of the photographic lens 22.

〔Effect of the invention〕

As explained above, according to the video camera according to the present invention, the shake (acceleration) generated in the camera and the focal length of the photographic lens are combined to calculate the shake of the photographed image, and the degree of shake is determined. Since it is displayed in the viewfinder, the photographer can accurately and quickly recognize the effect that camera shake has on the image. As a result, the photographer can quickly take measures to prevent the image from moving, and it is possible to prevent the image from moving and becoming unsightly after being shot. In addition, since camera shake and focal length information of the photographic lens are recorded on the videotape, it is possible to correct fluctuations in the photographed image based on this recorded data during playback, which improves the photographic image. Contribute.

[Brief explanation of drawings]

FIG. 1 is a perspective view showing a camera-integrated VTR using an eight-camera video cassette, which is a video camera according to the present invention.
Figure 2 is a block diagram showing the main parts of the circuit configuration of the video camera according to the present invention, and Figure 3 is the camera-integrated VTR shown in Figure 1.
FIG. 4 is an explanatory diagram showing the case where the amount of oscillation is displayed on the EVF. FIG. 4 is an explanatory diagram showing the track arrangement of an 8-track videotape. 20...Camera body, 22...Photographing lens,
28...Electronic viewfinder (EVF), 3
2A132B, 32C, 32D, 32E... Acceleration sensor, 34A, 34B, 34C... Shake detection circuit,
36... Arithmetic circuit, 41... Recording circuit, 42
A, 42B, 42C...Display device, 37...Data conversion circuit, 44...Video tape.

Claims (2)

[Claims] (1) A shake detection means installed in the camera body to detect the shake of the camera during shooting, a focal length detection means to detect the focal length of the photographic lens, and a detection output of the shake detection means and the focal length detection means. A calculation means for calculating the amount of sway in the photographed image based on the calculation means, and a display means for displaying the amount of sway in the photographed image calculated by the calculation means or information corresponding thereto in the view soda. video camera. (2) a shake detection means installed in the camera body to detect camera shake during shooting; a focal length detection means to detect the focal length of the photographic lens; It is characterized by comprising a converting means for converting a detection output into a recording signal for recording on a magnetic tape, and a recording means for recording the recording signal converted by the converting means in a predetermined area of the video tape. Video camera.