FR2641433A1 - Source image anamorphosis system intended to rectangularise a viewed image - Google Patents

Abstract

So as to correct the distortions which occur when an optical device magnifies a rectangular source image, an anamorphosis of the source image is produced so that the image 62 viewed at the output of the optical system is rendered rectangular. The anamorphosis may be carried out electronically (anamorphoser) or magnetically (magnets).

Description

In the present description, the term “image generator” will mean any device producing an image, such as cathode ray tube, liquid crystal screen, plasma screen, thermoluminescence, hologram generator or any other system producing images å 2 or 3 dimensions - "source image" the image produced by the image generator; for example, if the image generator is a cathode ray tube, the source image is carried by the screen of said tube - virtual image "the image seen by the viewer through an optical system (such as a Fresnel lens) ) enlarging the source image - "mixed image" an image of real nature in the horizontal direction and of virtual nature in the vertical direction - "image seen" any image seen by the spectator - "anamorphic" any device intended to vary the source image shape.

It can be seen that a number of optical processes have been developed, such as Fresnel lens, concave mirrors, video projectors, etc.

which have the function of enlarging a source image and thus producing a viewed image (virtual or mixed image). However, this seen image sometimes no longer exhibits the rectangularity of the source image.

The present invention relates to a system intended for carrying out any manual, remote-controlled and / or automatic correction of the shape of the source image in order to obtain a rectangular view image; this correction is obtained by anamorphosis of the source image, according to an electronic process or any other correction system.

The purpose of this description is to define the elements of a system intended to obtain the rectangularization of this image seen.

Anamorphosis, in particular in the case where the image generator is a cathode ray tube, may also be obtained by - permanent magnets placed in the vicinity of said tube (we will then speak of "magnetic anamorphosis), or - a modification of the 'line' scanning and / or a modification of the 'field' scanning applied before the power amplifier stages of the scanning circuits.

FIGS. 1A, 1B and 1C represent respectively - an image generator seen from the front - an image generator whose image is corrected by an anamorphic element - the rectangular rectangular image.

FIGS. 2A and 2B respectively represent - an image generator, a concave mirror and the image seen - an image generator, a concave mirror and the image view rectangularized.

Figure 3 is a block diagram of an electronic anamorphic device.

FIG. 4A represents an infrared remote control transmission device
FIG. 4B represents a global diagram of the devices for transmitting and receiving infrared remote controls, as well as the systems controlled.

In FIG. 1A there is an image generator 56, its rectangular screen 57 seen from the front, and the rectangular source image 58 seen by the viewer. In FIG. 1B, an anamorphic image 59 can be seen seen by the viewer without an image enlargement device; this image has 4 rounded corners. This rounding effect is obtained either by an electronic processing of compression of the image at the 4 corners, or by a device acting on the electron beam in the case where the image generator is a cathode ray tube. In both cases all of the image information is retained.

Finally, in FIG. 1C are shown the image generator 56, its rectangular screen 57, the rounded source image 59, the Fresnel lens 61 and the rectangular rectangular image 62.

In FIG. 2A, a distinction is made between the image generator 76, its rectangular screen 77 and the rectangular source image 78 merged with said screen 77. This source image faces a concave reflector 81. The image seen 79 is an image greatly enlarged from the source image 78 but no longer has the rectangular shape.

In FIG. 2B, a distinction is made between the image generator 76, its rectangular screen 77 and the source image 78 having undergone an electronic or magnetic anamorphosis, the concave reflector 81 and the rectangular view image 82.

FIG. 3 represents a device 231 performing an anamorphosis of video image. There is a demodulator 100 which, from the antenna signal 101, produces a composite video signal 102. The signal 102 enters a synchronization separator 103. At the output of the separator 103, a video signal 104 and signals are obtained. synchronization lines 105 and frames 106. The signals 105 and 106 are sent to a central computing unit 107. The signal 104 is processed by a red, green, blue separator 108 which extracts the signals red 109, green 110, and blue 111. The signals 109, 110 and 111 are sent to an image memory 112. The central unit 107 calculates at any time the address 113 where the information 109, 110 and 111 must be written, according to the synchronization information 105 and 106. The address 113 is transmitted to the memory 112, and a read / write signal 114, produced by the central unit 107, is sent to the memory 112. Alternately with the writes in the memory 112, the unit central 107 performs readings res in the memory 112. These readings provide the three signals red 115, green 116, and blue 117. These three signals are mixed in the module 118 for shaping the composite video signal, which, controlled by the central unit 107, produces a composite video signal 119. The signal 119 is sent to a modulator 120, which produces an antenna signal 121, ready to be sent to the antenna input socket of a television receiver.

In the case where the composite video signal is intercepted in the television set, no demodulator or modulator is used.

In the case where the red, green, blue video signals are intercepted in the television set, no demodulator or modulator is used, and no red, green, blue splitter is used 108: the information red. green, blue are sent directly to memory 112.

Potentiometers 122 make it possible to send the central unit 107 to different dc voltages. the central unit 107 will interpret these voltages as parameters governing the calculation of the anamorphosis in progress.

Thus, the user of the device can choose different anamorphic parameters. Instead of the potentiometers, it is possible to use a keyboard comprising “arrow” keys making it possible to introduce anamorphosis parameters in a simple manner. Said keyboard can be part of the remote control keyboard of the device according to the present invention. In addition to the keys 'arrows', said keyboard may include a drawing of a television screen, the user will press with his finger on the area of the screen which interests him, then on 'arrow' keys to deform the area near said point. keyboard may be of the "tactile" type, that is to say comprise areas sensitive to the touch, and be entirely covered with a flexible film which may bear designs.

 The central unit 107 writes the information in the memory 112 linearly with respect to time, as it arrives, But the central unit 107 reads the information in the memory 112 non-linearly, in order to carry out the anamorphosis wanted by the user. At a given instant, the point that the central unit 107 must read does not generally fall exactly on a point situated on a video line of the image, as recorded when it arrived from the non-anamorphic video source. . It is therefore necessary, to know the value of the red, green, blue signals at any point, to make an interpolation between points of the existing memory. This interpolation can be done either by a calculation described in a program executed by the unit 107, or by a device in cabal logic, faster but less flexible than the calculation by program.

The parameters of anamorphosis can be, for example - deviation in position for each of the four corners of the image (or for the corners taken two by two), compared to the normal position (vertical deviation and horizontal deviation) - deviation in position for the middle of an edge of the image, compared to the normal position (vertical and horizontal distance) - curvature in the middle of the top line of the image; - curvature in the middle of the bottom line of the image ;; - curvature in the middle of the left edge of the image - curvature in the middle of the right edge of the image - narrowing or dilation of the horizontal line located halfway up the image and joining the middle of the left edge of the image in the middle of the right edge - narrowing or dilation of the vertical line located in the middle of the image and joining the middle of the top edge of the image to the middle of the bottom edge.

An alternative method consists in asking the user to introduce, not the parameters of the anamorphosis, but simply elements which describe the optical system for enlarging the image. We will call these elements "configuration elements". The configuration elements can be: - nature of the optical system (lens, mirror, lens and mirror combination, etc.) - distance between the center of a lens and the center of the source image - angle between the normal at the center of the source image and the segment joining the center of a lens to the center of the source image
- focal length of the optical system
- respective positions of the optical system and the source image.

The central unit 107 then takes into account said values, and calculates the optimal anamorphosis parameters corresponding to these values.

Once the anamorphosis parameters are known, the central unit 107 calculates at any time the address where the information in memory 112 should be read in order to send them to the module 118. This address is generally not a function linear of time. An exemplary embodiment of anamorphosis consists in gradually applying, starting from the center, the effect of anamorphosis to the image, the center of the image remaining in its place.

We could provide a device for memorizing the anamorphic parameters for each given situation (each situation corresponding to given configuration elements). Each time the lens and the source image are brought into positions already encountered before, the user can recall these stored values; he will no longer have to redo the search for the best anamorphic parameters.

We could provide a device to calculate fully anamorphosis parameters from the configuration elements. In the case where the optical system consists of a Fresnel lens, if the electro-mechanical systems actuating the Fresnel rod are for example jacks, these positions can be known by taking into account the elongations of each of the jacks. These elongations can be known to the central unit 107 in several ways - either the user reads them on the body of the rod of the jacks, and transmits them to the central unit 107 via potentiometers or a keyboard - or the jacks are provided of devices for measuring their elongation, and the results of the measurements are transmitted directly, by electronic means, to the central unit 107 - or again, taking into account the history of the instructions sent to the jacks from the moment when the latter were reaches a benchmark detected electronically.

We can provide another opto-electronic device making it possible to adjust the anamorphosis parameters fully automatically: a camera type camera bolt ", fitted with a lens and a sensitive surface (CCD network or other), is placed where the user will be to observe the image provided by the optical system. The image generator is powered by a signal representing a test pattern. The sensitive surface of said box detects the image of the test pattern and transforms it into an electronic signal (composite video or other). This electronic signal is processed by the central unit 107, which evaluates the deformation of the image as seen -by said box; the central unit 107 then calculates, based on this deformation, the best possible anamorphic parameters to ensure that the user sees in the optical system a virtual rectangular image.

When observing an enlarged video image, we see the black spaces between two consecutive video lines. To remedy this drawback, provision may be made in the electron gun of the cathode ray tube of the television set (or in the vicinity thereof), an electronic lens (or other) making it possible to produce a spot which has a shape which is not circular, but rectangular.

The rectangle obtained should have a height such that two consecutive video lines touch or even overlap slightly, so that the viewer no longer sees black between the lines. Said rectangle should have a minimum width, so that the horizontal definition on the screen is the best possible.

Note that a particular application of the electronic anamorphosis device described in FIG. 3 is the conversion from one television standard to another, in the following list: SECAM, PAL, NTSC,
High Definition.

To do this - we will comply with the video input standard (SECAM, PAL, NTSC or
High Definition) to analyze the HF input signal 101 and the input video signal 102, and to write in the image memory 112 - we will comply with the output video standard to read the image memory 112 and to create the output video signal 119 and the HF signal 121.

Figure 4A shows the remote control boltier 211 for the device according to the present invention. This 211 boot includes 2 groups of keys 212 and 213.

The group of keys 213 includes four 'arrow' keys (to the left, right, up, and down) allowing the user to define the anamorphosis parameters, ie to control the shape of the source image.

The group of keys 212 includes other keys making it possible to control any other device, such as electro-mechanical elements.

FIG. 4B represents, according to the present invention, the circuits of the infrared remote control system s and the elements of the system controlled by said remote control. There are - the remote control boltier 211 and its 2 'groups of keys 212 and 213 - the sensor 202, an electrical cord 203, the amplifier 204 connected to the central control unit 230, the electrical cord 205, the transmitter infrared 206 - the central control unit 230 is connected to the following different elements which it controls: the electro-mechanical elements 18a, 18b and 18c as well as the anamorphic element 231 described in FIG. 3 - the infrared remote control sensor 20 of the television set 1.

The amplifier 204 indiscriminately sends its amplified output signals to the transmitter 206 and to the central control unit 230.

The central control unit 230 does not react to the remote control signals emitted by the boltier 201 intended for the television 1. The central control unit 230 reacts on the other hand to the remote control signals emitted by the boltier 211.

 Obviously, the infrared signals emitted by the housing 211 must be distinguishable from those emitted by the housing 201. The housings 201 and 211 can be integrated in the same infrared remote control transmitter housing 33; the modules 204, 230 and 231 can likewise be integrated in the same housing 240.

Claims (8)

1) Source image anamorphosis system (58 or 78), characterized in that it produces deformations on said source image, such that the image seen (62 or 82) is rectangular. 2) System according to claim 1, characterized in that it further comprises a system for measuring configuration elements. 3) System according to claim 1, characterized in that it further comprises a storage system for configuration elements. 4) System according to claims 1, 2 or 3, characterized in that it further comprises an automatic system for calculating the anamorphosis parameters of the source image. 5) System according to any one of the preceding claims, characterized in that it further comprises a sensor sensitive to the shape of the image seen and allowing by retro-action on the source image, to automatically restore the rectangularity of the image seen. 6) System according to any one of the preceding claims, characterized in that it further comprises a remote control system for the shape of the source image. 7) System according to any one of the preceding claims, characterized in that said deformation is obtained by magnetic methods acting on a cathode ray tube.  8) System according to any one of the preceding claims, characterized in that said source image anamorphosis system is an electronic anamorphoser (231).