RU103940U1 - DIGITAL STEREO CINEMA RECEIVER - Google Patents

Abstract

1. A digital stereo filming apparatus containing a photosensitive matrix, an electronic digital recorder and a lens, the photosensitive matrix is equipped with a low-resolution video output and a high-resolution video output connected to the input of an electronic digital recorder, characterized in that it uses a stereo lens as a lens and additionally introduced a stereo video control unit , which includes a resolution and format converter, a control figure generator and an optical-electronic stereo magnifier made in the form of a binocular attachment and two mini-displays, the left and right of which are optically coupled, respectively, to the left and right eyepieces of the binocular attachment, while the first and second inputs of the converter resolution and format are connected respectively to the low-resolution video output of the photosensitive matrix and the output of the control figure generator, and the left and right outputs of the resolution and format converter are connected to the inputs of the left and right mini-displays, respectively. ! 2. The device according to claim 1, characterized in that the stereo lens is made in the form of two conjugated optical blocks with light blocking between them, sharpness and aperture adjustments common to them, adjustment of the symmetrical mutual displacement of the optical blocks relative to the center of the photosensitive matrix in opposite directions in the horizontal direction, perpendicular to the axis of the stereo lens, and the outputs of the left and right optical blocks are optically conjugated with the left and right adjacent areas of the photosensitive matrix aperture.

Description

The invention relates to the field of film technology and is intended for stereo filming.

Known stereo filming apparatus equipped with a stereo lens, with which stereo filming is performed on a single 65 mm or 70 mm film, receiving a number of stereo pairs, the frames of which are located on the film next to ["Technical and technological principles" Stereo-70 ", authors A. Ovsyannikova A. . and Slabova AE, the magazine "Technique of cinema and television", 1975, No. 3, pp. 16-26]. The design of the stereo lens, which includes two optical units, provides the same for both units for sharpening and aperture adjustment, and also adjustment of interaxal races the distance between the optical blocks, which allows you to change the location of the ramp plane (zero parallax plane) in the stereo shooting space. The device has a mirror shutter that divides each of the light beams passing through the optical blocks of the stereo lens into direct and reflected. Direct beams form images of a stereo pair on film reflected by the shutter on frosted glass The formation of stereopair images on film and frosted glass takes place alternately in accordance with the frequency of shooting. Images of stereo pairs formed on frosted glass are examined in a stereo magnifier, which is part of the device. Images are viewed separately by the left and right eye and are perceived as stereo images. On the frosted glass two identical crosshairs of horizontal and vertical segments are applied. The centers of the crosshairs are located in the centers of the stereo pair images on the frosted glass. The ramp distance (distance to the ramp plane) is controlled by the stereo image of the crosshair, perceived in the space of the scene being shot. When changing the center distance, the stereo image of the crosshair is perceived to be moving along the shooting direction in the space of the scene being shot. To set the distance of the ramp, the image of the crosshairs is combined with the object of the scene, the stereo image of which on the screen should have zero parallax.

For stereo filming devices designed for shooting on film, the above-mentioned scheme for controlling the scene being shot in stereo and for controlling the position of the ramp plane is rational and convenient, which makes it easier and faster to set stereo shooting parameters, while it is based on using standard units for film devices - a shutter and matte glass.

A disadvantage of the known apparatus is the inability to use it for digital (electronic) stereo filming.

Closest to the claimed is a digital movie camera "Phantom-65" (http://www.visionresearch.com/Products/High-Speed-Cameras/Phantom-65), containing a photosensitive matrix, electronic digital recorder and lens.

The disadvantages of this device are the inability to use stereo shooting with it, the inability to observe (control) the stereo image during shooting and the inability to control stereo settings.

The technical result is the possibility of stereo filming, the ability to observe (control) the stereo image during shooting, and the ability to control stereo settings.

The technical result is achieved by the fact that in the digital stereo filming apparatus containing an electronic digital recorder, a lens and a photosensitive matrix, which is equipped with a low-resolution video output and a high-resolution video output connected to the input of an electronic digital recorder, an additional stereo-video control unit including a resolution and format converter , a control figure generator and an optical-electronic stereo magnifier containing a binocular nozzle and two mini-displays, left and right the other of which are optically coupled respectively with the left and right eyepieces of the binocular nozzle, while the first and second inputs of the resolution and format converter are connected respectively to the low-resolution video output of the photosensitive matrix and the output of the control figure generator, and the left and right outputs of the resolution and format converter are connected to the inputs respectively, left and right mini-displays, the device uses a stereo lens as a lens, and the stereo lens is made in the form of two paired optical blocks with light blocking between them, common sharpness and aperture adjustments for them, adjustment of the symmetric mutual displacement of the optical blocks relative to the center of the photosensitive matrix in opposite directions in the horizontal direction perpendicular to the axis of the stereo lens, and the outputs of the left and right optical blocks are optically coupled to the left and right adjacent areas of the aperture of the photosensitive matrix.

Replacing the lens with a stereo lens, introducing the indicated additional elements and the sequence of their connection allows providing the possibility of stereo shooting, stereo image observation during shooting and control of stereo shooting parameters.

Figure 1 - presents a functional diagram of the apparatus.

Figure 2 is a functional diagram of a stereo video control unit.

Figure 3 - parameters of the output signal of the apparatus of the prototype.

Figure 4 - parameters of the output signal of the claimed apparatus.

Figure 5 - template bounding box.

The apparatus contains (figure 1) a stereo lens 1, a photosensitive matrix 2, an electronic digital recorder 3 and a stereo video control unit 4.

The stereo-video monitoring unit 4 (FIG. 2) comprises a generator of the control figure 5, a resolution and format converter 6, and an optical-electronic stereo magnifier 7 containing a binocular nozzle 7.1 and two mini-displays 7.2 and 7.3.

A digital stereo movie camera includes a stereo lens 1, a photosensitive sensor 2, an electronic digital recorder 3 and a stereo video control unit 4, a photosensitive matrix 2 is equipped with a low-resolution video output and a high-resolution video output connected to the input of an electronic digital recorder 3, the stereo-video control unit 4 includes a control figure generator 5 , a resolution and format converter 6 and an optical-electronic stereo magnifier 7 comprising a binocular nozzle 7.1 and two mini-displays 7.2 and 7.3, left and the right of which are optically paired with the left and right eyepieces of the binocular nozzle 7.1, respectively, while the first and second inputs of the resolution and format converter 6 are connected respectively to the low-resolution video output of the photosensitive matrix 2 and the output of the control figure 5 generator, and the left and right outputs of the converter 6 resolution and format are connected to the inputs of the left and right mini-displays 7.2 and 7.3, respectively, and the stereo lens is made in the form of two paired optical units with a light-blocking me I am waiting for them, the general sharpness and aperture adjustments for them, the adjustment of the symmetric mutual displacement of the optical blocks relative to the center of the photosensitive matrix in opposite directions in the horizontal direction perpendicular to the axis of the stereo lens, and the outputs of the left and right optical blocks are optically coupled to the left and right adjacent areas of the aperture of the photosensitive matrix .

An optical stereo magnifier does not allow to control the image formed on the matrix of a digital camera, as it is intended for end-to-end monitoring of stereo pair images discarded by a mirror shutter on frosted glass, as is the case in a film stereo film camera.

In addition, existing models of electronic stereo loops or microdisplay glasses cannot be used to control the stereo image generated on the matrix of one digital camera, for the following reasons:

the output video signal of a digital movie camera, designed to control the full image of a stereo pair in real time, has insufficient resolution for operational monitoring of the sharpness of the generated image;

this video signal is single-channel, with the image of the left angle being on the right and the right on the left, and cannot be controlled by electronic stereo loops or microdisplay glasses, in which the image angle is fed through two separate video channels.

The device operates as follows. Using a stereo lens 1 (Fig. 1), a stereoscopic image of the scene is formed on the photosensitive matrix 2, the video signal from the high-resolution video output of the photosensitive matrix 2 is fed to the input of an electronic digital recorder 3 that records the stereo image of the scene. The video signal from the low-resolution output of the photosensitive matrix 2 is fed to the first input of the resolution and format converter 6 (Fig. 2), the second input of which receives a signal from the generator 5 of the control figure. On the left and right outputs of the resolution and format converter 6, the left and right images are formed, respectively, converted by format and summed with a control figure.

In the stereo video control unit 4, the number of lines is multiplied according to the resolution of the required value for viewing on the optical-electronic stereo magnifier 7 (Fig. 2) containing a binocular nozzle 7.1 and two mini-displays 7.2 and 7.3. The registration of the stereoscopic image combined with the stereo image of the control figure is controlled by means of an optical-electronic stereo magnifier 7 by observing through the left and right eyepieces of the binocular nozzle 7.1 images of the stereo pair displayed on the mini-displays 7.2 and 7.3. In particular, as an example, the control figure can be a pair of horizontal control lines (defining the frame boundaries) (Fig. 3) and a crosshair (Fig. 5), the stereo image of which in depth corresponds to the center distance of the stereo pair frames on the photosensitive matrix 2 (Fig. 1) )

In a particular embodiment of the device, the formation of a stereo pair image (images of the right and left angles) is carried out by a stereo lens 1 made in the form of two optical units located in a single mechanical frame, which allows them to be synchronously controlled, and, in particular, to adjust the center distance between the optical units. In this case, the location of the depth of the observed scene of the stereo image of the control crosshair will be adjusted. Combining the spatial position of the crosshair with one or another object of the scene being shot, the spatial position of this object in the audience in the plane of the projection screen is set, thereby controlling the overall spatial position of the observed scene in the cinema (set relative to the plane of the projection screen).

Figure 3 shows, by way of example, the parameters of the initial output signal output from the output of the photosensitive matrix 2 (Fig. 1), and Fig. 4 shows the parameters of the low-resolution signal converted to the stereo-video monitoring unit 4 (Fig. 1), which is fed to the optical input -electronic stereo magnifier 7 containing a binocular nozzle 7.1 and two mini-displays 7.2 and 7.3 (figure 2). The resulting video signals are generated according to the template shown in FIG. 5, where, as an example, bounding frames with a projection image with a 16: 9 aspect ratio and a crosshair designed to control the position of the zero parallax plane are presented.

Two video signals output from the outputs of the resolution and format converter 6 (FIG. 2) are supplied to the inputs of the optoelectronic stereo magnifier 7 (for example, with a resolution of 1280 ^* 1024 pixels each).

The image formed by the stereo lens 1 (Fig. 1, Fig. 5) in the form of a stereo pair on a photosensitive matrix 2 is converted into a video signal, which is fed to the input of a resolution converter 6 and a format with a resolution of 1280 ^* 720 pixels, is converted into two video signals with a resolution of 1280 ^* 1024 pixels with an integrated image of the control frames and fed to the input of the optoelectronic stereo magnifier 7, made in the form of a binocular nozzle and two mini-displays 7.1 and two mini-displays 7.2 and 7.3, and is observed through two optical eyepieces of the binocular nozzle.

In this case, the total resolution multiplier for the resolution and format converters is equal to the ratio between the total resolution of two mini-displays and the resolution on the low-resolution video output, and the total format of the left and right mini-displays is geometrically similar to the total format of the left and right adjacent areas of the aperture of the photosensitive matrix.

Thus, the digital stereo movie camera provides the possibility of stereo filming, the ability to observe (control) the stereo image during shooting and the ability to control the stereo settings.

Claims (2)

1. A digital stereo movie camera containing a photosensitive matrix, an electronic digital recorder and a lens, a photosensitive matrix is equipped with a low-resolution video output and a high-resolution video output connected to the input of an electronic digital recorder, characterized in that it uses a stereo lens and an additional stereo-video control unit is introduced including a resolution and format converter, a control figure generator and an optical-electronic stereo magnifier, flashed in the form of a binocular nozzle and two mini-displays, the left and right of which are optically paired with the left and right eyepieces of the binocular nozzle, while the first and second inputs of the resolution and format converter are connected respectively to the low-resolution video output of the photosensitive matrix and the output of the control figure generator, and the left and right outputs of the resolution and format converter are connected to the inputs of the left and right mini-displays, respectively. 2. The apparatus according to claim 1, characterized in that the stereo lens is made in the form of two paired optical units with photo-locking between them, common to them sharpness and aperture settings, adjusting the symmetric mutual displacement of the optical units relative to the center of the photosensitive matrix in opposite directions in the horizontal direction, perpendicular to the axis of the stereo lens, and the outputs of the left and right optical units are optically coupled to the left and right adjacent aperture regions of the photosensitive matrix.