JPH08509582A - Subliminal message display system - Google Patents

Abstract

(57) [Summary] A subliminal message display system that allows the display of "subliminal messages" is disclosed. The display is generated by switching the programming input video signal (91) during a single field of the display to display the subliminal message (92). A retrace (93) of the rasterized display occurs and the erase signal (94) is used to erase the subliminal message from the display. Downward progression (95) of the rasterized display is forced to compensate for display time loss in rendering the erase signal (94). The program image signal (96) is then re-enabled. Various embodiments have been described which allow both rendering and erasing of subliminal messages within a single display field of a rasterized display.

Description

Detailed description of the invention Subliminal message display system Field of the invention The present invention relates to subliminal message (hereinafter referred to as subliminal message) communication, and more particularly to a method and apparatus for displaying a subliminal message on an ordinary video or raster display. Background of the Invention The human mind is considered to have a conscious (conscious) part and a subconscious (subconscious) part. Sensory inputs are first filtered by a conscious mind before being passed to the subconscious. The importance of the subconscious mind to human health is due to the many variants of therapies that directly affect the subconscious mind, some of which may be collectively known as hypnosis and meditation. To be emphasized. Although still the subject of much research, the images and messages seen by human subjects for only a fraction of a second have the effect of filtering the conscious mind to directly influence the unconscious mind. It has been shown that it may be possible to bypass. Therapy based on this idea can be used to positively influence individual behaviors. For example, weight loss and weight maintenance programs can be improved through the use of subliminal communication. To be valid, the subliminal message must be presented to the beneficiary only for a short duration. Most studies suggest that this duration should be 12 ms or less. If you are interested in this relationship, please refer to the following references: (1) Weinberger, J .; Hardaway, R .; "Separating Science from Myth in Subliminal Psychodynamic Activation", Clinical Psychology Review, Vol.10. , Pp.727-756, 1990; (2) Berry, DM; Abramowitz, SI; "Educative / Support Groups and Sub liminal Psychodynamic Activation for Bulimic College Women", International Journal of Eating Disorders, vol 8, pp.75- 85,1989; (3) Silverman, LH; Martin, A .; Ungaro, R .; Mendelsohn, E; "Effect of Subliminal Stimulation of Symbiotic Fantasies on Behavior Modificati on Treatment of Obesity", Journal of Consulting and Clinical Psychology, Vol. 46, pp.434-441, 1978. One conventional subliminal message system is the taxiscope, which is a mechanical instrument with a mirror, lens and electromechanical shutter arrangement. Human objects generally stare at a viewer in a still image on the card. At some point, under researcher's or computer control, the shutter is activated, exposing another card, called a "stimulus card", to the object. This exposure is for a very short and controlled period before the original image is restored. While such an arrangement is found to have certain benefits, it requires the manufacture of precise mechanical metrology equipment, which is generally expensive. Furthermore, the taxiscope is disadvantageous to use when the object is conscious of the fact that a subliminal message is displayed when looking at the observer. Subliminal messages are also marketed on standard videotape material. In general, the main program material is some form of natural landscape intended to relax human objects. However, in such an arrangement, the subliminal message is displayed for the entire duration of the video frame, and as a result, the message is not entirely subliminal because it can be read instantaneously. This is because the retention of the human eye and its sensitivity, even at a rate of 25 frames per second, can be clearly discerned even on landscapes where the bold text is moving. However, unlike taxiscopes, subliminal videotape formats desirably allow the programming material to provide sufficient distraction to the object, thereby providing a conscious knowledge of subliminal programming. Get rid of. Purpose and Summary of the Invention It is an object of the present invention to provide an alternative arrangement that can represent subliminal messages. According to one aspect of the invention, a method of displaying a subliminal message to a viewer by means of a rasterized display, displaying video source material consisting of a plurality of sequential fields, wherein one part of said fields is displayed. Displaying a subliminal message to the display and immediately after displaying the subliminal message, erasing the subliminal message from the display before restarting the unforbidden display of the video source material. A method is disclosed. Erasure of the subliminal signal can be performed by retracing the subliminal signal with the erase signal. Alternatively, if the subliminal signal is the same interlace as the following field, that portion of the subsequent field that corresponds to the subliminal signal will have a minimum illumination intensity sufficient to overwrite, blank or prevent the subliminal message. Clamped. According to another aspect of the invention, a subliminal image display system for reproducing a subliminal message on a display, the subliminal image display system being obtained from an output of a processor system determined from a source material video input signal and the image generator, A video processor configured to provide a message signal containing a subliminal message, a video timing detector configured to extract a sync signal from the input signal, and a video timing detector configured to detect the input signal in a predetermined manner. A controller configured to control the processor to provide an indication of the message signal in a field, and an erase structure configured to erase the subliminal message shortly after the indication of the subliminal message. A subliminal image display system is disclosed. In general, the subliminal message may include text and / or an image to be displayed. The erasure structure preferably includes a clamp that clamps the video intensity of the source material in a subsequent field of the input signal. Example Hereinafter, various embodiments of the present invention will be described with reference to the accompanying drawings. The preferred embodiment is configured for use with standard video (television) displays, whereby the viewing subject is treated with a subliminal message while at the same time being broadcast or prerecorded. (Eg video tape / disc) programming material can be viewed. Television receivers reproduce an image by scanning an electron beam across the surface of the screen. A picture consists of a series of horizontal lines that are transmitted serially and appear below each other on the screen. At the end of each horizontal line, the electron beam quickly returns to the beginning of the next line. This is called "line flyback", "line blanking period", or "horizontal retrace". When it reaches the bottom of the screen, the electron beam is returned to the top of the screen to prepare for the next image. This is referred to as "field flyback" or "field blanking period" or "vertical retrace". When the sequence of images is repeated at a sufficiently high rate, flicker between fields is not perceived due to the residual human eye, and a smooth image is drawn. All the information needed to recreate a video image, including the electron beam, any associated audio signals, and all the signals needed to position the image detail itself is called the "composite video signal". Carried in a single signal. The timing associated with the horizontal scanning of the electron beam is referred to as the "line time base". In the Australian PAL system, each line is 64 microseconds long, and the composite video signal will always maintain this period. The line sync pulse triggers a line flyback that must be completed in about 10 microseconds. In the Australian PAL system, fields are transmitted at a rate of 50 per second (60 for NTSC systems per second). At the completion of each field, the composite video signal contains specially formed lines, called field sync pulses, hereinafter referred to as Vsync pulses, which are detected by the television receiver. Once the field sync pulse is detected, the receiver triggers a vertical retrace, which moves the electron beam to the top of the screen. Vertical retraces take multiple line periods to complete (about 25 lines for the Australian PAL system). At the end of the vertical retrace period, the beam can return to its known vertical position, or vertical origin, regardless of its horizontal position, and immediately begin its downward scan. Interlacing is used in many displays to reduce the bandwidth required to carry the composite video signal. This means that successive lines of the composite video signal will actually trace out every other line on the video screen. The lines in between are traced into the next vertical scan, or field. This means that adjacent lines on the screen are updated at only half the vertical scan rate, which can lead to local flicker. It also means that it takes two vertical scans, or fields, to complete the rendering of one image. This is accomplished in PAL and NTSC systems by having an odd number of lines per video and by starting each "odd field" with half a line and ending each "even field" with half a line. . The remaining start and end lines are in the complete line. Referring to FIG. 1A, a timing diagram is shown in which signal A represents a composite video signal received by a television receiver. This signal is divided into a series of fields (n, n + 1), each starting with field sync signal 2. Following the field sync signal 2 is a program signal 3 for scanning (scan out) an appropriate even or odd field. With further reference to FIG. 1A, the present invention is implemented by replacing a portion of one field of the composite signal 1 with a subliminal message signal 5, as shown by the trace of signal B in FIG. 1A. The signal B is the time T after the start of the field signal 2 one before. ₁ Starting with the field sync signal 6 timed to occur at, and returning the electron beam to the top of the display. Subsequent to the field sync signal 6, the subliminal message signal 7 is scanned to render the desired subliminal message on the video display. The subliminal message in this example includes text, but can also include images, or a combination of both. After the signal 7 is completed, a further field sync signal 8 is inserted to bring the scanning electron beam back to the top of the screen, as shown in FIG. 1A. At this point, the erase signal 9 erases the subliminal message, thereby preventing any residue of the object on the eye. The duration of one field sync pulse 6, 8 plus the duration of one message or erase signal 7, 9 is T _s Is. T ₁ Is (T ₁ + 2T _s ) Is equal to one field period. The result of the combination of signal A and signal B by this method is also the output signal 10, as shown in FIG. 1A. It is clear from the output signal 10 that the subliminal signal 7 and the erase signal 9 have a higher priority for the display than the program signal 1 when they are activated. 2A to 2E, the sequence of field images displayed in FIG. 1A is illustrated. FIG. 2A shows an image in the field (n-1) showing the cartoon character configured in the initial position. FIG. 2B shows the time (T) for field (n) where about 60% of the image is traced and the rest is blank (eg, black, assuming no phosphor residue on the display). ₁ ) Shows the same image in. FIG. 2C again shows field (n) but at time T ₁ + T _s And represents the end of the subliminal signal 7 overwriting the top part of FIG. 2B. FIG. 2D shows the time T when the erase signal 9 blanks out the subliminal image. ₁ + 2T _s Field (n) in FIG. FIG. 2E shows an image at the end of field (n + 1) displaying all fields of the cartoon character in different positions. In this way, the duration of the subliminal message when displayed depends on its size, as represented by the number of displayed lines, given that the display time for each line is constant. It will be apparent from the above that it can be tightly controlled. Furthermore, the use of the erase signal effectively erases the subliminal message, thereby preventing any residue on the eye. In addition, the overall field synchronization of the composite video signal is not flipped, even though the entire process is contained within a single field so that subsequent fields can be used for normal display. FIG. 3 shows the construction of a subliminal message system 20 which receives an input video signal 21 in the form of a composite video signal. The signal 21 may be derived from a broadcast television transmission, or a signal such as reproduced from within a video tape, laser disk or computer device or the like. The input composite video signal 21 is input to a line and field sync extractor 22 which extracts a field sync signal 23 and a line sync signal 24. These signals are input to the timing and control unit 26, respectively. Timing and control unit 26 outputs line and field timing signals on bus 35 to image generator 27, blanker unit 28 and field sync generator 29. The input video signal 21 is also supplied to an even field detector 25 which outputs a pulse to a timing and control unit 26 corresponding to the detection of each even field. The timing and control unit 26 determines a certain time T after the last field sync signal 23 is received from the video input signal 21. ₁ Wait for a while. It then switches the video switch 31 to switch the composite output signal 32 from the input signal 21 to the generated signal 33 output from the further video switch 30. The video switch 30 is supplied with a subliminal signal corresponding to the signal B in FIG. Time T ₁ Is such that two field sync pulses, one subliminal image scan and one erase scan contained in signal B are completely terminated just when the input video signal 21 begins the next field sync pulse. Must be timed accurately. The subliminal message is placed towards the end of the field of the input signal 21, rather than at the beginning, as this results in minimal interference with the standard composite video signal. If the subliminal message is placed first, the input video signal 21 will be split through the next field when restoring the original video after completion of the subliminal message to write at the top of the screen. Start. Therefore, the image appears to jump upwards, giving the television receiver akin to a horizontal hold fault. Time T ₁ Upon completion, the subliminal message signal is initiated by generating a field sync signal in the field sync generator, returning the electron beam to the top of the screen, and the details of the subliminal message provided by the image generator 27 are returned. Follow it. Since the subliminal message is encoded as a composite video signal, it can be played directly through the television receiver. An important point to note is that the vertical size of the subliminal message is less than the total video height. One full image requires 20 ms to display and another 20 ms to erase. Such times are well within the conscious perception of humans. However, the appropriate therapeutic subliminal message need not fill the entire screen. A 10 millisecond image can fill about half of the screen and a 5 millisecond image can fill about one quarter (1/4) of the screen height. To ensure that there is no residual subliminal image left on the human object, it is necessary to erase the image by overwriting with another. The blanker unit 28 is provided for this purpose and is enabled after a further sync pulse is generated by the field sync generator 29 which returns the electron beam to the point on the screen where the subliminal message started. Most importantly, subliminal messages and blanking images are not interlaced. The blanking image must overwrite the same line used to display the subliminal image. When the last line of the subliminal image is erased by the blanking image, the timing and control block 26 resets the video switch 31 so that the input signal 21 is supplied directly to the output 32. It is important that the interlacing of successive fields of the input signal 21 is maintained. Interlacing is such that for every field the first line is a half line and the last line is a full line or vice versa. Works with. The timing and control unit 26 must determine whether the field in which the subliminal message is displayed is even or odd, which is performed by the even field detector 25. Another approach is to have a subliminal message of one type, even or odd, and use the timing and control unit 26 to wait until the correct field of the input signal arrives. Alternatively, when the video switch 31 is toggled, the last line, or the last few lines of the same field of the input signal 21, is output 32 before the next field sync of the input signal 21. You can make it appear. It is further advantageous to have the erased image overwritten by the next field of the input signal 21 so that the erased image does not remain on the screen longer than necessary. To achieve this, the cancellation signal, and thus the subliminal signal, must be in the same interlace as the next field (n + 1) of the input signal 21. This is the case if all fields of the subliminal signal start and end with one form of line, either full or half, and the next field of the input signal 21 also starts with a line of the same form. Can be achieved. The rate at which the subliminal message is displayed is controlled by the dose manager 34 which enables the timing and control unit 26. The dose rate for subliminal messages is not well understood by psychologists, and the dose rate ranges from 1 dose per minute to 1 dose every few hours. Can change. When compared to the field rate of video displays, which is 50 times per second (60 times per second in the United States), it is a very slow and isolated event with a high percentage of optimal dose. Can be considered to be. However, such a reasoning is not related to the operation of the system of FIG. 3 which is noticed by a person skilled in the art, and the ratio of the irradiation line amount which changes from the second unit to the day unit or the week unit using a real-time clock or the like. , Can be easily achieved. FIG. 4 shows an alternative configuration which obviates the need for the blanker unit 28 and field sync generator 29 of the embodiment described above. In FIG. 4, a subliminal imaging system 40 is shown which receives an input composite video signal 41 which feeds a field timing unit 42, a line timing unit 43 and an even / odd field detection unit 44 in a manner similar to the embodiment described above. Has been done. The timing and control unit 45 is provided in the same way as in the previous embodiment. In this particular embodiment, the subliminal message is retained in the digital image store 46 and converted into a video image by the converter 47 under the control of the timing and control unit 45. The dose manager 48 is provided in the same manner as before. In this embodiment, the subliminal message signal is output from the converter 47 to an audio decompression unit 49 which combines that signal with the audio components of the video input signal 41. Such an arrangement maintains the audio continuity of the composite video signal provided at output 52. However, in this embodiment, a clamp unit 51 is provided following the video switch 50. The clamp unit 51 is enabled by the completion of the display of the subliminal message to clamp all subsequent (program) video signals at the appropriate times to the minimum display level. The minimum display level is selected to ensure the elimination of subliminal messages. After the subliminal message portion of the field has passed, the clamping is disabled and the input signal is passed unimpeded to the output 52. In the example of FIG. 3, it is clear that a significant part of the input image, corresponding to the bottom part of the image, is lost. This information is not refreshed until after two fields due to interlacing. However, about half of this video loss can be avoided using the configuration of FIG. The arrangement of FIG. 4 has the great advantage of requiring only one extra field sync pulse instead of two in one field of the input signal 41 and reducing the number of lost images. The result is a less perceptible interference with the composite signal. Also shown in FIG. 4 is an intensity detector and controller 53, which allows optional but preferred adaptive control of brightness and clamp levels of the subliminal message. The controller 53 monitors the average brightness of the input signal 41 over that part of the display in which the subliminal image is to be displayed in the field containing the subliminal message. Luminance averages, or other mathematical manipulations thereof, are used to control the brightness of subliminal images. This ensures that the subliminal image has sufficient brightness and achieves visibility (visibility) across the input signal without it stimulating the object as it is too bright. FIG. 1B is similar to that of FIG. 1A, but the subliminal signal 7 is _s Is placed at the end of field (n) for and the clamping of signal 10 is in period T in subsequent field (n + 1). _s 5 shows a timing diagram for the embodiment of FIG. 4, which is active as indicated at 11 for. The above method is preferably such that the subliminal message and the cancellation signal are the same interlace to achieve proper cancellation. However, the cancellation signal may achieve acceptable performance, albeit with different interlaces. The extent to which the message signal remains visible to the observer in such situations is the respective text color (if appropriate) of the message and / or blanking signal, and any background color, video display. Of phosphors (age), and the electron gun accuracy (beamwidth) of video displays depends on many considerations. There is a limit to the above effectiveness in commercially available television (TV) receivers. Some TV and video monitors do not perform the desired vertical flyback due to the internal nature of the TV or monitor. However, as will be explained, there are techniques to overcome these limitations that require some background understanding of vertical deflection systems. Although there are many different circuits for carrying out the vertical (or field) deflection of the electron beam of a TV or video monitor, most are suitable with reference to the functional block diagram of FIG. Can be explained. The field oscillator 61 is synchronized with the input field sync (Vsync) pulse 62. Here, the Vsync pulse is derived from the input composite video signal in the case of TVs and some types of video monitors and complies with standards such as MGA, CGA, EGA, and VGA (as just one example). In the case of a computer monitor, it is obtained directly from the video signal provided by the drive device, which is typically a computer. The field oscillator 61 controls the charging / discharging circuit 63 that charges and discharges the field charging capacitor 64 and is synchronized with the input Vsync pulse, as shown in FIG. 6, where the sawtooth voltage 70 is across the field charging capacitor. Make it appear. The sawtooth voltage 70 is processed and amplified by a vertical deflection amplifier 66 and applied to a vertical scan coil 67 of a TV or monitor cathode ray tube (CRT). The current generated by the scanning coil 67 causes the electron beam of the CRT to be completely scanned from the top to the bottom of the screen, at the same time image details are written, and quickly flyback to the top of the screen during vertical flyback, Prepare your video frame or field. Although the two waveforms have different amplitudes, different offset levels, and can be inverted from each other, the current in the scan coil 67 generally follows the sawtooth voltage 70 across the field charging capacitor 64 very closely in shape. . It has been found that a monochrome electron display uses a single electron beam and a color video display typically uses three electron beams. Thus, throughout this specification, references to single-person electron beams should also be construed as references to multiple electron beams in a suitable display system. Further, the position of the electron beam defines the instantaneous image display position on the display, which is scanned by the horizontal and vertical scan signals. Straightness correction circuit 68 is required to ensure that the electron beam moves at a constant velocity over the plane of the image screen. The details of such circuits are well known to those skilled in the art and are not critical to the operation of the invention. Some of the possible variations of the vertical deflection system include the following: -A straight line (or S-correction) circuit 68 is a signal that appears across the field charging capacitor 64 rather than feedback to the vertical deflection amplifier 66. , Some of the functional blocks shown in FIG. 5 can be combined into circuits that do not have a unique functional boundary. A common example is a field oscillator circuit that includes both a field charging capacitor 64 and a charge / discharge circuit 63. The vertical deflection amplifier 66 output stage can be implemented in many ways, including: single transistor, push-pull, class A, class AB, class B, class C, and class D (many There is a permutation, also known as switch mode). A common feature of all vertical deflection systems is that each has a signal that represents the vertical position of the electron beam on the screen at any one time. This signal is typically a sawtooth voltage waveform 70 that appears across the field charging capacitor 64. Ensuring that the electron beam follows the sawtooth signal 70 is the purpose of the rest of the vertical deflection system. Some field oscillators do not trigger on Vsync pulses that occur too soon after the previous Vsync pulse, and further, the rest of the vertical deflection system, especially the charge / discharge circuit 63, does not work satisfactorily with the present invention. Let's do it. However, it is possible to overcome the limitations of existing vertical deflection systems by directly modifying the sawtooth voltage 70 via external circuitry, which implements embodiments of the present invention. By changing the sawtooth voltage 70, the vertical position of the electron beam can be controlled in a desired manner, which is determined by the rest limits of the vertical changing system. As shown in particular in FIG. 6, the sawtooth voltage waveform 70 includes a vertical flyback portion 71 and a vertical image scanning portion 72. The flyback portion 71 represents the portion where the electrons on the beam retrace from the bottom of the screen 73 to the top of the screen 74 where it starts a new vertical video scan 72. It should be noted that the sawtooth waveform 70 and subsequent waveforms are not drawn to scale. In particular, the vertical flyback portion 71 is about 500 microseconds, and the vertical scan 72 is typically about 19 (for interlaced at 25 frames / second). It takes 5 microseconds. Referring now to FIG. 7, there is shown a first variation 80 of the sawtooth waveform that implements the subliminal message display. In this embodiment, the vertical flyback 71 brings the electron beam to the top of the screen 74, as shown in the image adjacent to the waveform, where the vertical video scan 82 begins. Scan portion 82 displays the head portion of the manga character previously shown in FIG. The sawtooth waveform 80, showing the neck and upper torso of the manga character, rather than continuing with the vertical video scan portion 83, includes a sharp downward transition or progression 84 that represents the jump of the electron beam on the screen. The character's neck and that part of the upper torso display are omitted. Next, a message portion 85 representing the desired subliminal message is displayed. Once the message is displayed, the mini vertical flyback 86 directs the electron beam to the position where the message started and the vertical video scan 83 on which the electron beam would have been if there were no offsets 84 and 85. Return to the (position) corresponding to the position above. After the mini-vertical flyback 86, an erase signal 87 is displayed on the subliminal message signal, and upon completion of it a vertical video scan 88 is used to display the rest of the manga character, in this case the lower leg. . This is done until the sawtooth waveform 80 reaches the bottom of the screen 73, where another vertical flyback 71 occurs. It will be appreciated that the arrangement of FIG. 7 allows a television display to display subliminal messages without forcing a complete and unnecessary vertical flyback. The only cost in terms of display quality is that the down vertical progression 84 represents a defect in the image being displayed. However, that portion of the missing image is only half a field or one fifth (1/5) of a second (in the Australian PAL system) away from the interlaced display. Will be overwritten by the vertical scan of. A further embodiment in which the waveform 90 includes a standard image video scan portion 91 immediately following the display of a subliminal message 92 is shown in FIG. When the display of the message 92 is complete, a mini vertical flyback 93 is generated which causes the erase signal 94 to rewrite the subliminal message signal. The vertical advance 95 is then required to return the electron beam to its proper position on the screen, allowing the rest of the image 96 to be displayed. FIG. 9 shows a sawtooth waveform 100 written as before and then enabling the message and erase signals to be overwritten with the desired programming material. In this configuration, the image signal 101 displaying the head and neck of the manga character is displayed as shown. The downward progression 102 occurs and the body of the manga character is omitted. This is immediately followed by the subliminal message signal 103, the mini vertical flyback 104, the display of the erase signal 105 and a further mini vertical flyback 106. The erase signal 105 is then retraced by the rest of the program material 107, which thereby acts to display the rest of the cartoon character. This embodiment serves to overcome the deficiencies of the previous embodiments which lie in the erased signal displayed for non-critical times. In the embodiment of FIG. 9, the erased image is a conventional program material that acts to ensure that only the image perceived by the viewer is that of the programmed material, not the subliminal message or that erased image. The image is retraced. The embodiment of FIG. 10A shows a sawtooth waveform 110 configured to provide the minimum vertical jitter of the image, as seen by an observer, where the subliminal message is located near the bottom of the display. Indicates. This is a special case of the embodiment shown in FIG. 8 depending on the vertical position of the message. The normal program image signal 111 is displayed followed by the message signal 112. When the drawing of the message is complete, the mini-vertical retrace 113 returns the electron beam to the starting screen position of the message 112, obscuring the message when the erased image 114 rewrites the message, or otherwise human viewing. Make it unidentifiable by the person The end of the erase signal 114 is timed to closely match the next vertical retrace 71. A vertical advance 115 may be required to drive the sawtooth waveform 110 to the bottom of the screen to cause the TV receiver or video monitor to perform the vertical retrace 71. The example of FIG. 10B shows a sawtooth waveform 200 configured to provide the minimum vertical jitter of a normal program image, as seen by an observer, where the subliminal message is displayed at the top of the display. . Here, the normal program image signal 201 is displayed for most fields. Before the end of the field, a vertical retrace 202 is performed that returns the electron beam to the top of the screen, where message 203 is displayed. When the normal program material V sync signal is detected, another vertical retrace 204 is performed that matches the vertical retrace 71 that would have been performed if the sawtooth waveform was not changed. The electron beam is now repositioned at the top of the screen and the message can be rewritten with the erase signal 205. As long as the completion of the erase signal 205 erases or otherwise obscures the message or is invisible to the observer, the erase signal may simply be the program signal 201 or a modification thereof. At the end of the erase signal 205, the normal program signal 201 is displayed again. The embodiment of FIG. 10C shows a sawtooth waveform 210 configured to provide the minimum vertical jitter of a normal program image, which could be prevented from displaying a large portion of a field of normal program material. Show. Such an embodiment may be easier to implement than some of the other embodiments described above. This embodiment has similarities to the embodiment shown in FIG. Here, the normal program material 91 is displayed, followed immediately by the display of the message 92. When the display of the message 92 is complete, a mini vertical flyback 93 is generated which positions the electron beam at the start position of the message 92 and causes the erase signal 94 to rewrite the subliminal message 92. At the end of the erase signal 94, if the electron beam traveled on the screen as usual, however, the electron beam is turned off and no image is written for the rest of the field 211. When the Vsync signal of the normal program material is detected, the normal vertical retrace 71 is executed. Vertical progression 212 may be required to drive sawtooth waveform 210 to the bottom of the screen to cause a TV receiver or video monitor to perform vertical retrace 71. FIG. 11 shows a further example of waveform 120, which is theoretically feasible but practically difficult for modern television receivers. In this configuration, the program material 121 is displayed immediately following the message signal 122 at the bottom of the screen. Instead of the standard vertical flyback 71, the mini vertical flyback 123 returns the signal to the beginning of the subliminal message and the erase signal 124 is used to overwrite the message signal. The image then returns with the vertical flyback 125 inserted. This configuration uses a vertical flyback sequence to insert the erasure, and due to the length of the erasure and message signals, vertical jitter can be observed in the display. The embodiments of Figures 7 to 11 can be implemented by modifying the charging / discharging unit 63 of Figure 5 in the manner described below. FIG. 12 shows a charging / discharging unit 130 including the charging capacitor 64 shown in FIG. 5, current sources 131, 132, and a switch 133 which acts to form the charging / discharging unit 63 of FIG. It will be apparent to those skilled in the art that current source 132 acts to discharge capacitor 64, which provides the downward ramp of sawtooth waveform 70 shown in FIG. When the switch 133 is closed by the field oscillator 61, the current source 131 acts to charge the capacitor 64 and provides the upwardly sloping ramp or vertical flyback 71 of the sawtooth waveform of FIG. The current source 131 is generally substantially larger than the current source 132 to ensure vertical flyback occurs within an appropriate time limit when the current source 132 is always present in the circuit. You will also see that it must be. Each of the embodiments of FIGS. 7-11 is implemented by varying the voltage on capacitor 64, and each of the variations shown in those embodiments includes two additional switches having corresponding electronic switches 137 and 138. Can be implemented by adding the current sources 135 and 136. In particular, switches 137 and 138 are rather configured such that neither will close at the same time to perform the required downward vertical travel and mini flyback described above. In all cases where switches 137 and 138 are activated, switch 133 remains open. In some applications, current source 135 and switch 137 may be omitted and switch 133 operated directly from controller 142. If it is desired for the electron beam to quickly traverse the screen, such as at sawtooth portions 84, 95 and 102, switch 138 is closed and current source 136 acts to draw additional current from capacitor 64. , Reduce the voltage. Therefore, the current source 136 is generally substantially larger in size than the current source 132. Once proper progress has been obtained, switch 138 is opened. Similarly, when mini flyback is required, as in sawtooth portions 86, 93, 104 and 106, switch 137 is closed and current source 135 causes current to pass through capacitor 64 to charge the capacitor to a higher voltage. To retrace the electron beam to its previous position. Each of the switches 137 and 138 is a timing and control device forming part of a subliminal message system configured therein or attached to a television receiver or some other form of raster display. Controlled by. The size of the current sources 135 and 136 depends on the length of time required to display the desired subliminal message and perform the required mini flyback. Current sources 135, 136 and switches 137, 138 form part of the subliminal message display system, the rest of which is shown to the left of it in FIG. The system includes a processor 139 provided with a program signal component 144 derived from the input composite video signal 150. The timing signal extractor 146 extracts the timing signal 148 from the input composite video signal 150 also supplied to the processor 139. Processor 139 includes a real-time clock 140 that provides a dose programmer 141. The role of the dose programmer is for the user of the subliminal message display system to program an appropriate dose rate, for example one dose every 5 minutes. The dose programmer 141 then utilizes the output of the real-time clock to determine the passage of time and output a dose signal to the main controller 142. The processor 139 includes a subliminal / erase signal 151 and an input program signal derived from the portable memory storage medium 143, such as other devices insertable into the processor 139, such as memory cards, video tapes, video disks and the like. Also included is a switch 145 configured to switch the output signal 149 to be displayed to and from 144. In this configuration, when the memory storage device 143 is input to the processor 139 and the dose is initiated by the controller, the controller switches to achieve the desired vertical scan accuracy for each of the embodiments of FIGS. Acts to operate 137 and 138. Using the example of FIG. 7, upon receiving the dose signal, the controller 142 acts to close the switch 138, causing the vertical image scan to provide downward travel of the electron beam. Once its downward travel is complete, switch 138 is opened when controller 142 enables the selection of subliminal messages from memory storage device 143. At the same time, the switch 145 is switched to connect the subliminal signal via the connection 151 to the signal output 149 to be displayed. Alternatively, the subliminal signals may be added, subtracted, multiplied, modified in any other way, or mathematically combined, mixed, or otherwise to accommodate the display of the subliminal message, or It can be juxtaposed with the input program signal 144. Once the subliminal signal is displayed, the controller 142 activates the closure of switch 137, which provides a mini flyback. Upon completion of the mini flyback, switch 137 is opened and the controller enables selection of the erase signal from memory storage device 143. This is displayed to retrace the previously displayed subliminal message output via switch 145. Upon completion of the display of the erase signal, switch 145 is switched again to connect program signal 144 to signal 149 to be displayed. The particular advantage of using the memory storage device 143 for holding subliminal and erase signals is that various subliminal messages can be inserted into the processor 139 as needed depending on the type of psychological treatment desired. Is that the user may have a choice of In addition, the use of such an arrangement allows the use of subliminal messages for any input program material, such as broadcast or cable video material, computer displays, or for prerecorded source material such as video tape. Allow display. In this way, individual users may select themselves for subliminal messages, and manufacturers may manufacture suitable devices for personal sale without fear of regulatory restrictions. . In a preferred configuration, the subliminal display system of FIG. 12 is a video monitor that meets the safety requirements in terms of television receivers, or modern television receivers that are dual protected and powered directly from the mains. Can be fully integrated inside. However, where appropriate safety measurements have been made and the additional switches 137 and 138 of FIG. 12 have been properly separated from the processor 139, the processor can be connected to a suitably modified or assembled television set. It can be configured like an independent unit. Ideally, in memory storage device 143, the erase signal is pre-aligned with the particular subliminal signal that needs to be erased. For example, the color of the cancellation signal can be selected so that it perceptually obscures the color of the subliminal message signal. Also, the erase signal can be configured to redisplay the same subliminal signal, but with a different color scheme for text and background. Where appropriate, one or more subliminal and / or erase signals may be placed on a single memory storage device 143 provided that the controller 142 is configured to select the appropriate combination or subliminal and erase signal combination. Can be supplied. For example, one such subliminal signal may be “don't eat” for psychological programming of an overweight person, and another may be a smoker's psychological one. It can be "don't smoke" which is useful for programming. Those afflicted with both conditions may choose to target themselves to both forms of the subliminal message at approximately the same time, eg, at 5 minute intervals for each dose. It will be apparent from the above that the location of the message can be anywhere on the screen. Unless the horizontal deflection system is tampered with, the message is restricted to occupying the horizontal band on the screen and the vertical position is unconstrained. A further development of the present invention differs from the normal deflection speed (percentage) during normal vertical scanning operation, which is the speed at which the electron beam is vertically deflected when writing and erasing subliminal messages. Including. For example, the rate (percentage) during the writing of a message can be slowed to increase the intensity of the erased image and thus to ensure complete erasure of the subliminal message / image. As mentioned above, the existing vertical deflection system of the TV or monitor must be modified to make the system responsive to the inserted vertical flyback. Furthermore, depending on the level of modification, control over the vertical position of the electron beam can be more complicated than just returning to the vertical origin. This allows placement of the message in any vertical position. As a result of the above modifications of existing vertical deflection systems, it may be required to minimize the adverse effects of inserted vertical flybacks. Such adverse effects may include "ringing" or damped oscillations of the vertical origin, such that the image appears to bounce vertically. Many techniques can be adopted to reduce the effects of such bounces on a fine level. Such techniques include, but are not limited to: (a) Introducing electrical components and / or circuits into the vertical deflection coil circuit to suppress unwanted modulation of the circuit in the coil. Such components and / or circuits may be known to those skilled in the art as "snubbers,""clamps," or "dampers," (b) signals affecting subliminal exposure. Introducing a compensation signal at the input of the vertical deflection system, which results in the desired subliminal exposure when added to the image; (c) the compensation signal being one of the signals affecting the subliminal exposure. Incorporating, ie incorporating both subliminal and compensation signals in one signal. In a further refinement, the display of subliminal messages can be delayed for any number of video fields following a switch from a subthreshold program source, if so desired. During this delay, any type of video may be delayed, including but not limited to single color blank images. The observer will be aware of this delay and any images used during the delay due to the number of fields in which the subliminal message was delayed. The motivations for the inclusion of this display are as follows: (a) the effect or effect of the subliminal message on the observer is somehow enhanced or otherwise modified as desired. Possibility of This is especially true if the image represented during the delay is designed to improve the acceptance and influence or effect of subliminal messages. (For example, α-wave simulation); (b) Request to issue a warning to an observer who is in the immediate vicinity of the subliminal message. This may be desirable or it may be required by law. The timing of the occurrence of subliminal exposure can be controlled or varied as desired to enhance the effect or effect of the subliminal message on the viewer. The erase signal can be constructed in such a way as to more completely erase the subliminal message. For example, if a simple signal of constant intensity is used for erasure, the fluorescent image element (pixel) previously excited by the subliminal message will be subjected to a second excitation by the electron beam from the erase signal. These fluorescent pixels emit light of higher intensity, probably for a longer duration, than pixels that were not excited by the subliminal message. The result is that the message can be consciously perceived. During the erase phase, those pixels that were already excited during the message writing phase are preferably excited less than those pixels that were not excited during the message writing phase. The difference in excitation is that at the end of the erase phase, every pixel in each horizontal line in the region of the subliminal message emits the same amount of light. Thus, at the end of the erase phase, the areas of the subliminal message appear as bands of uniformly illuminated light. The above description has described only a number of embodiments of the invention and it will be apparent to those skilled in the art that modifications can be made without departing from the scope of the invention. For example, the invention may be applied to any of the PAL, NTSC, or SEACOM systems, as well as non-interlaced raster display configurations. Also, non-electron tube displays such as rasterized liquid crystal displays (LCD's) can be controlled according to the present invention. In such an embodiment, rather than providing the electronic device responsible for the addition of the electron beam and its instantaneous image display position, additional computer programming to achieve proper addressing of pixels in such a display. It is clear that is necessary. Such displays include color LCD's using red (R), green (G), blue (B) color formats, or ferroelectric LCDs using RGBW (red, green, blue, white) formats. 's can be included. Brief description of the drawings 1A is a timing diagram of signals used in the first embodiment of the present invention; FIG. 1B is a timing diagram of signals used in the second embodiment of the present invention; FIGS. 2A to 2E are preferred. FIG. 4 is a diagram showing a frame sequence of images for explaining a visual effect of the embodiment; FIG. 3 is a schematic block diagram showing a subliminal message system of the first embodiment of the present invention; 4 is a schematic block diagram showing a second embodiment of the present invention; FIG. 5 is a schematic diagram of a vertical sweep circuit of a prior art television receiver; FIG. FIG. 7 is a diagram showing vertical deflection waveforms of the configuration of FIG. 7; FIG. 7 to FIG. 11 are diagrams showing voltage waveforms of a further corresponding embodiment of the present invention; FIG. 12 is an embodiment of FIGS. Charging of Figure 5 capable of operating it to provide Changes to the discharge device is a diagram schematically showing.

─────────────────────────────────────────────────── ─── Continued front page    (81) Designated countries EP (AT, BE, CH, DE, DK, ES, FR, GB, GR, IE, IT, LU, M C, NL, PT, SE), OA (BF, BJ, CF, CG , CI, CM, GA, GN, ML, MR, NE, SN, TD, TG), AT, AU, BB, BG, BR, BY, CA, CH, CN, CZ, DE, DK, ES, FI, G B, GE, HU, JP, KG, KP, KR, KZ, LK , LU, LV, MD, MG, MN, MW, NL, NO, NZ, PL, PT, RO, RU, SD, SE, SI, S K, TJ, TT, UA, US, UZ, VN (72) Inventor McKean Stuart James             Australia New Southway             Ruze 2093 Bargauler Burlingba             ー Street 29 (72) Inventor Gomley James Richard             Australia New Southway             Ruze 2450 Corfus Harbor Brode             Lee Drive 55

Claims (1)

[Claims] 1. Rasterized display presents subliminal messages to the viewer A method of presenting video source material consisting of multiple sequential fields Display a subliminal message for one of the fields, Immediately after the display of the subliminal message, the video source material is prohibited. The subliminal message from the display before the restart of the untampered display A method of erasing the image. 2. The subliminal message includes the video source material in the portion. Method according to claim 1, characterized in that it is replaced. 3. The subliminal message and the video source material are displayed The image shows that the subliminal message is mixed with or juxtaposed with the video source material. A method according to claim 1, characterized in that they are mixed together in the parts as indicated. Law. 4. The deletion of the subliminal message is the subliminal message. Is performed by retracing with an erased image. The method described in. 5. The deletion of the subliminal message follows the subliminal message. Block the corresponding part of the field from the subliminal message Characterized by being performed by clamping to a minimum illumination intensity sufficient for The method according to claim 1, wherein 6. The subliminal message and the deletion of the subliminal message. At least one of the other displays is at least the rasterized display. 2. Preceded by a partial vertical retrace of the spray. The method described in. 7. The vertical retrace is the start of the message signal indicating the instantaneous image display position. 7. The method according to claim 6, wherein 8. Provides the time required to perform the deletion of the subliminal message To advance the instantaneous image display position on the rasterized display to 7. The method of claim 6, further comprising: 9. The progress is before the display of the subliminal message, or the sublimina 9. The message according to claim 8, which occurs after the deletion of the default message. the method of. Ten. Subliminal image table to play subliminal messages on the display Of the processor system determined from the source material video input signal. Stem output and derived from the image generator and containing the subliminal message A video processor configured to provide an active message signal; A video timing detector configured to extract the sync signal from the input signal, In order to bring the indication of the message signal into the field of the input signal A controller configured to control the processor, the subliminal Configured to clear the subliminal message shortly after the message is displayed A subliminal image display system characterized by having an erase structure. 11. The erasure structure allows the message to be erased to allow erasure of the message signal. After displaying the message signal, return the instantaneous display position to the start position of the signal display. 11. The system of claim 10, including circuit elements configured to: . 12. The erasing structure is configured to display the message at a display position that is relative to the message signal. A device configured to clamp the display intensity of the input signal displayed subsequent to the signal. The system of claim 10 including a vise. 13. The erasure structure is configured to perform the subliminal message before further display of the input signal. The sage further comprising an erase signal configured to overwrite the sage. 0 system. 14. At least the message signal may be configured for retrieval by the system. 11. Hold in a permanent storage device capable of system. 15． The storage device is small and can be removably inserted into the image generator. The system of claim 14, wherein the system is: 16. The display is a cathode ray tube display, and the circuit element is A secondary retrace of the electron beam to the start of the subliminal message Characterized by functioning to change the vertical scan signal of the display to The system of claim 11, wherein 17． The circuit element is responsible for displaying and erasing the subliminal message. In order to compensate for the time taken, either before the subliminal message is displayed or To move the electron beam either after the subliminal message is erased The system of claim 16, wherein the system is functional. 18. The display comprises a vertical scanning device on which the electron beam A voltage representing a vertical position on the display, and the circuit element is The first means for increasing the voltage on the scanning device and the voltage on the vertical scanning device. 18. The system of claim 17 including second means for reducing. 19. The vertical scanning device is a field charging capacitor for a television display. And the first and second means each selectively connect to the capacitor. 19. The system of claim 18, including a switchable current source that can be followed. . 20. The subliminal message may include text and / or a displayed image. 11. The system of claim 1 or claim 10 including. twenty one. The blanking signal includes text and / or an image to be displayed. The system according to claim 1 or claim 10, characterized in that twenty two. It is configured to be displayed by using the present invention described in claim 1 or 10. A compact storage device containing a composed subliminal message.