Abstract:
A modified Colorstripe™ copy protection process utilizes a basic anti-copy protection (ACP) signal that causes attenuation of a video signal, wherein, in one embodiment, the process modifies (lowers) the level of a front porch portion and adds an incorrect color signal (color burst) in the region of the sync tip. When an illegal copy is made, a pre-blanked end of line portion causes a TV set to trigger the color burst sample pulse ahead of time and cause the incorrect color signal in the sync tip region to be sampled. Thus, since the sync tip region has incorrect color phase or frequency, the resulting illegal copy will have enhanced color distortions. In other embodiments, other portions of the horizontal blanking interval are lowered in level and incorrect color bursts are added to a portion or portions of the back porch and/or a portion of the front porch. 
     A further embodiment employs lowering a back porch portion above a sync tip level near the beginning of a video line to form a pseudo sync/AGC pulse pair. The various embodiments of the process may include an adaptable process, as well as several alternative ACP signals for use in combination with the process.

Description:
CROSS REFERENCE TO RELATED APPLICATION 
     This application is a continuation application of U.S. application Ser. No. 09/639,452 filed Aug. 15, 2000, now U.S. Pat. No. 7,050,698, the disclosure of which is herein incorporated by reference in its entirety. 
    
    
     BACKGROUND OF THE INVENTION 
     The present invention is related to copy protection processes such as those which cause a darkening or lightening effect in an illegal copy of a video signal when displayed, and more particularly to a copy protection process which enhances the copy protection effect by adding further chroma distortion to an illegal copy of the copy protected video signal. 
     It follows therefore that a preferred embodiment of the invention is used in combination with typical copy protection processes which selectively attenuate the video signal. Such video copy protection signals typically may consist of sync or pseudo sync and automatic gain control (AGC) pulses. In a video cassette recorder (VCR), erroneous gain levels are generated by the sync and/or pseudo sync/AGC signals, which cause the VCR to turn down the video gain. Once the video gain is turned down, a number of enhancement signals may be added primarily to affect the integrity of the sync signal in the VCR and/or television (TV) set. These typical copy protection signals cause the VCR and TV set to sense a false sync signal due at least in part to the lowered video gain. Such signals will for instance cause the TV set to scan an illegal copy of the video signal improperly by either pre scanning and/or post scanning the video horizontal lines. Also, the VCR or TV set may develop extra or erroneous color burst sample pulses in an illegal copy. 
     Such typical copy protection signals thus may also contain various signals to enhance the copy protection effect such as end of line signals, end of field signals, post pseudo sync and pre pseudo sync signals, etc. Descriptions of the above mentioned signal attenuating copy protection processes are found in, for example, U.S. Pat. No. 4,631,603 issued Dec. 23, 1986 to Ryan, U.S. Pat. No. 4,918,098 issued Apr. 4, 1989 to Ryan, and U.S. Pat. No. 4,163,253 issued Jul. 31, 1979 to Morio et al., all incorporated by reference herein. 
     It is common practice for color videotape recorders to utilize the color burst component of a video signal to generate velocity error-correction signals to compensate for the inevitable fluctuations of the head to tape velocity. The velocity error corrector circuit in a video-tape recorder measures the phase of the color burst signal on a line-by-line basis. Any variation of phase is assumed to be due to head to tape velocity errors, and a correction signal is generated. The correction signal alters the phase of the chrominance signal in an attempt to eliminate these errors. 
     In accordance with a copy protection technique disclosed in U.S. Pat. No. 4,577,216 (&#39;216) issued Mar. 18, 1986 to Ryan and known as the “Colorstripe™” copy protection process or system, (and incorporated by reference herein), deliberate phase errors are introduced into the color burst signal by phase modulating the color burst signal with a noise signal to produce “Colorstripe bursts” of incorrect phase. 
     The velocity error correction circuit in the videotape recorder (VCR) accordingly will attempt to eliminate the deliberate phase errors introduced. In so doing, the velocity error correction circuit will transfer the error from the color burst to the chrominance signal, thus giving rise to color noise or error in the viewed picture reproduced from the videotape recording. However, the characteristics of the modified color burst signal are such that the phase modulation is ignored by a television receiver, i.e., TV set, which produces a substantially normal color picture. 
     The term Colorstripe is a trademark of Macrovision Corporation, Sunnyvale, Calif. However, to facilitate the description, a variation of the term is used herein after, namely, “color stripe”, or “color stripe burst” to indicate a correspondingly modified normal color burst. 
     The color stripe process has a disadvantage in that the color stripe signal cannot be recorded onto a video tape without causing a “playability” problem when the recorded tape is viewed upon reproduction. That is, the color stripe signal can be used successfully in a video signal transmission environment such as cable, broadcast television or as an add on signal to a digital video disk (DVD) player, but cannot be included in a prerecorded videotape environment without degrading the playability of the prerecorded tape. “Playability” is an expression indicative of the (degree of success of) viewing of a video signal containing an anti-copy protection (ACP) process when the protected video signal is applied directly to a TV set. 
     Accordingly, it would be highly desirable to provide a color burst modifying copy protection process which could be used in a prerecorded videotape environment as well as in the signal transmission and DVD player environments. 
     SUMMARY OF THE INVENTION 
     The present invention overcomes the playability problems of the prior art color stripe processes by providing a recordable color stripe process for use in videotape recorder copy protection systems (i.e., tape to tape or player to recorder), or in transmitted copy protection signal systems (i.e., cable or broadcast video or internet), or as a video copy protected signal embedded into video sources such as DVD units, consumer disk read only memory (CD ROM) units or storage devices. 
     To this end, in accordance with the present invention, the chroma portion of the video signal is further distorted when viewed during reproduction of an illegal copy. In previous prior art processes such as for example shown in the &#39;216 patent of previous mention, the color burst is modified generally in the “normal” color burst area. In the present invention, incorrect color burst signals are added in non-normal areas such as the sync signal area as well as after the period of normal color burst. In addition, the actual normal sync signal width may be modified or shortened. The front porch breezeway also may be modified, which also allows accommodating an incorrect color burst. An “incorrect” color burst is a color burst signal in which the frequency or phase is incorrect. 
     The present invention is applied to a video signal in conjunction with added copy protecting pulses such as conventional pseudo sync pulses and/or AGC pulses which cause darkening in the reproduction of an illegal copy. The present invention includes by way of example one or more of the following features in various embodiments. 
     a) A preferably lowered end of line signal, a lowered front porch signal, and/or a pre sync signal. 
     b) An incorrect color burst signal in at least the sync area and its vicinity. 
     c) A post pseudo sync or lowered backporch portion signal. 
     d) A correct color signal in the nominal backporch area including optionally the post pseudo sync area. 
     e) An incorrect color signal after the post pseudo sync pulse. 
     A basis of this invention is to utilize the signals that can cause the VCR and/or TV set to generate spurious color burst sampling signals, and then put incorrect color signals in portions of the horizontal blanking interval to cause the VCR and/or TV set to incorrectly reference the incorrect color burst signal. For instance, by using a pre pseudo sync pulse such as a lowered front porch signal (for example, from blanking to −30 IRE), and an incorrect color burst signal in the sync signal area, the VCR and/or TV set will sample the incorrect color burst signal, as a result of the darkening effects of a basic copy protection signal which is already applied to the video signal. In this particular case, the TV set will scan prematurely due to the pre pseudo sync signal and the attenuated video signal, to thus cause an early horizontal flyback or burst pulse. This early flyback or burst pulse then causes the TV set to sample the burst in the sync signal area where an incorrect color burst signal has been inserted. Thus, the TV set will display further enhanced color distortions in accordance with the invention. Under normal conditions the video level is at normal levels and the horizontal sync causes the TV set to scan correctly, whereupon the flyback pulse of the TV set samples the normal color burst signal in the normal back porch area. 
     In another embodiment of the present invention, when a post pseudo sync signal is applied and the video signal is reduced, the post pseudo sync signal is sensed by the VCR and/or TV set, which can cause a color burst sampling signal to appear after the post pseudo sync signal. When an incorrect color burst signal is inserted after the post pseudo sync pulse signal, an incorrect color reference is sampled by the TV set and/or VCR, which causes an increase in color distortion in a reproduction of an illegal copy of the copy protected video signal. 
     An advantage of the invention is that the incorrect color signals generally are not sensed by the circuits when the video signal is supplied directly to a normal TV set, whereby a normal picture is displayed, whereas the prior art color stripe video copy protection signals are sensed by the TV set. Of course, the present invention may be combined with various prior art video copy protection processes including the color stripe process of previous mention, or its variations such as that using segmented color bursts. 
     A modified color burst comprising an incorrect color subcarrier for example, may be a waveform having a frequency which various from the color subcarrier frequency. However, the waveform may be phase, frequency, and/or amplitude modulated. One function of the incorrect color burst is to cause improper static and/or dynamic color hues. Another function of the incorrect color burst signal is to cause static and/or dynamic color saturation. 
     An alternative modification of the color burst signal may be achieved by varying the phase from field to field as to cause for example, color flicker within a frequency range of 1 HZ to 25 HZ. 
     In a further embodiment, the post pseudo sync signal is moved toward the beginning of the TV line by sensing the active video portion, to thereby maximize the extra darkening. That is, the post pseudo sync (PSTPS) signal is inserted near the beginning of the video line whenever there is a voltage level in the beginning of active video which is greater than black level. The greater than black level then behaves as an AGC pulse with respect to the post pseudo sync signal. The movement of the post pseudo sync signal can be done dynamically by sensing the video levels of the first few microseconds of the active video lines. When a gray to white level is sensed, the PSTPS signal is moved toward the beginning of the video line, i.e., to the end of the horizontal blanking interval (HBI). 
     Another embodiment of the invention may employ parts of the previous embodiment within certain video scrambling systems such as sync suppression scrambling systems. For example, the placement of an incorrect color burst in the sync signal area of a sync suppression system can result in increased concealment. In the case of an improved sync suppression system where blanking to predetermined levels (i.e., blanking level) of areas just outside the horizontal blanking interval, (HBI) such as the last and beginning 2 μs of the video line, the insertion of incorrect color burst in the sync signal area (i.e., at least a portion of the sync tip area, and the sync tip area and at least a portion of the back porch area), will cause more color distortions, especially when the 2 μs area of the video signal before the HBI is blanked. 
     Also included in the description of the present invention are various methods and/or apparatuses for at least weakening the effects of the color burst modifying process of previous discussion. 
     In addition, the present inventive process of modifying the front porch level and/or duration, and inserting incorrect color burst signals in the sync area and its vicinity, can also be applied to enhance the concealment effect of certain video scrambling processes such as, for example, a sync suppression scrambling process. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a waveform illustrating a standard unmodified horizontal blanking interval (HBI) and adjacent vicinity of lines of a video signal, identifying the various areas and the respective standard video levels, in IRE units, of the HBI. 
         FIGS. 2A ,  2 B and  2 C are waveforms illustrating an embodiment of the invention and including color burst sample signals for normal and modified front porch levels. 
         FIG. 3A  is a waveform illustrating an embodiment of the present invention similar to that of  FIG. 2A  employing a modified (lowered) front porch (MFP) signal level but depicting further modifications. 
         FIG. 3B  is a waveform illustrating another embodiment employing a post pseudo sync (PSTPS) signal. 
         FIG. 3C  is a waveform illustrating a further embodiment of the invention employing a PSTPS signal moved sufficiently close to the beginning of the active video signal to cause the active video signal to function as an AGC signal with respect to the PSTPS signal. 
         FIG. 3D  is a waveform of a further embodiment of the invention wherein an incorrect color burst is added in the front porch area of an expanded HBI. 
         FIG. 4  is a block diagram illustrating the present invention in an exemplary environment. 
         FIG. 5  is a block diagram illustrating circuitry of the present invention for generating the modified waveforms of for example  FIGS. 2B-2C  and  3 A- 3 D. 
         FIG. 6  is a schematic diagram illustrating an incorrect subcarrier generator circuit. 
         FIG. 7  is a block diagram illustrating another embodiment of the present invention. 
         FIG. 8  is a waveform illustrating the signals provided by the circuits of  FIGS. 7 and 9 . 
         FIG. 9  is a schematic diagram illustrating further details of the block diagram of  FIG. 7 . 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
       FIG. 1  depicts by way of example a normal or standard horizontal blanking interval (HBI) in a video line of a television signal. In particular, the  FIG. 1  shows the end of one line of active video and the HBI, followed by the beginning of a subsequent line of active video. The HBI includes a front porch of for example 1.5 microseconds (μs), a horizontal sync signal of 4.7 μs and a back porch of about 4.7 μs, with the front and back porches set at blanking level (zero IRE) and sync tip set at −40 IRE. Reference black level is for example +7 IRE, and a color burst signal of 40 IRE amplitude is disposed on the back porch following the sync signal. 
     As previously discussed, the present invention preferably requires the attenuation affects imparted to a video signal by a typical anti-copy protection (ACP) process to initiate the incorrect triggering and/or sampling in a TV set and/or VCR, to thereby cause further enhancement of the chroma distortion of the copy protected video signal in accordance with the invention. 
       FIG. 2A  depicts a modified HBI which illustrates a first embodiment of the present invention. Here the front porch of the video signal is preferably modified to a lowered level signal, that is, provides a modified front porch (MFP) signal  18 , as is depicted in dashed line. Signal MFP  18  may be lowered to a level in the range of from blanking to −30 IRE and may be of sufficient width as to cause an early scan in a TV set. When the MFP  18  is combined with a basic anticopy protection signal, and the combined signal is attenuated by the AGC amplifier of a VCR and the resulting copy is displayed on the TV set. A typical width range of MFP may be from about 1 μs to 3.5 μs. Although signal MFP  18  is preferably lowered to below blanking level, it may be dynamically varied from above blanking level to a lowered level at a selected frequency.  FIGS. 2A-2C  illustrate how the present invention causes an incorrect color reference in a TV and/or VCR, to thus enhance the anti-copy protection effect. As a general rule, the color burst is sampled about 5 μs after the leading edge of the normal sync signal  20 . Thus, under normal conditions, that is, a substantially normal front porch level, the video signal  22  will cause the TV set and/or VCR to generate a color burst sample signal  24 ,  FIG. 2B  5 μs after the leading edge of sync signal  20 . Since sample signal  24  is coincident with a correct color burst  26  ( FIG. 2A ) and not an incorrect pre-color burst (PRICB)  28 , the TV set and/or VCR will display and/or record or playback without the enhanced color distortion of the present invention. 
     On the other hand, if the video signal is reduced to lower the front porch signal, simultaneously with attenuating the video signal via for example an ACP process, the lowered front porch portion, i.e., signal MFP  18 , rather than the normal sync signal  20 , will be detected by at least some VCR or TV set circuits. This will generate a color burst sample signal  30 ,  FIG. 2C , about 5 μs after the leading edge of signal MFP  18 , thereby causing it to appear earlier than the normal color burst sample signal  24 . Since there is an incorrect color burst subcarrier signal (PRICB  28 ) superimposed on the sync signal  20 , signal MFP  18  thus causes a TV set and/or VCR to pick up the incorrect pre color burst signal PRICB  28  and not the correct color burst signal  26 . As a result, the TV set and/or VCR will display, record or playback incorrect and distorted colors caused by the incorrect phase and/or frequency color burst signal  28 , in accordance with the invention. 
       FIG. 3A  illustrates variations in the embodiment of  FIG. 2A  and includes a modified front porch (MFP) signal  32 , shown in dashed line, an incorrect pre color burst signal PRICB  34  which may extend into the back porch area as depicted at  36 , and a portion of a normal color burst  40 . In a further variation, a positive going pulse  38  which approaches peak white level may be disposed on the lowered MFP signal  32 , as illustrated in dashed line in  FIG. 3A . The incorrect pre color burst signal  36 , or signals  36  and  34 , are preferably used in DVD, pay per view (PPV) etc., signal transmission environments, and may not be as desirable in a prerecorded videotape environment because the incorrect pre color burst signal  36  situated at the beginning of the back porch can cause playability problems in a VCR. 
     As discussed in  FIGS. 2A-2C , the lowered level of the signal MFP  32  in  FIG. 3A  causes the color burst sample signal ( 30  of  FIG. 2C ) to sample the pre and post incorrect color burst signals  34 ,  36 , respectively, to insure the enhanced color distortion affects in a reproduced video signal in accordance with the invention. 
     In a further variation of the invention, the MFP signal  32  and the positive going pulse  38  shown in dashed line in  FIG. 3A , may form yet another pseudo sync/AGC pulse pair signal, preferably simultaneously with the attenuated video signal conditions caused by a combination of sync/pseudo sync/AGC pulses used to provide the ACP process for combination with the present invention to provide the enhanced color distortion, as discussed above. 
       FIGS. 3B and 3C  illustrate further embodiments of the invention employing post pseudo sync signals PSTPS  46  and  48 , respectively. In  FIG. 3B , the levels of a MFP signal  44  and a PSTPS signal  46  selectively are lowered to cause the TV set and/or VCR to sense an incorrect PSTICB signal  50 , when the video signal simultaneously is attenuated by an ACP process as previously explained. 
     The false sensing caused by the MFP and PSTPS signals of for example  FIGS. 3A-3C , can by themselves cause extra horizontal tearing or luminance concealment, but because there are incorrect color subcarrier signals following the MFP and PSTPS signals, such as the PRICB signal and the PSTICB signal, respectively, extra color distortions are incurred during the viewing of an illegal copy or during an attenuated video situation. Once false-sampling or triggering is established, the present invention causes further, i.e. enhanced, color distortion in the TV set and/or VCR by placing incorrect color subcarrier signals in areas where the TV set and/or VCR will falsely sense or sample the incorrect color subcarrier signals under the attenuated circumstances. 
       FIGS. 3B ,  3 C illustrate specific cases of the PSTPS signals  46  and  48  positioned towards and adjacent, respectively, the beginning portions  41  and  52  of the active video line. When the signal in  FIGS. 3B ,  3 C are combined with any copy protection process that includes an attenuation effect, the PSTPS signals  46 ,  48  are sensed as a sync or pseudo sync signal during the playback of an illegal copy. When the level at the beginning portion  41  or  52  of the active video line is greater than black or blanking level (as depicted in dashed line at  42  [ FIG. 3B ] and at  56  [ FIG. 3C ]), the PSTPS signal  46  and/or signal  48  will form a pulse pair situation of post pseudo sync and AGC pulses due to the non black level at the beginning portion  41  or portion  52  of the video lines of  FIG. 3B  or  3 C, that then causes further attenuation or darkening of the illegal copy when viewed. This further darkening will be dynamic since the beginning portion  52  of the video line varies in signal levels according to the program content. 
     In a further embodiment, the position of the PSTPS signals  46 ,  48  may be alternated/varied from the positions shown in  FIGS. 3B ,  3 C in an adaptive manner as well. For instance the position of the PSTPS signal  48  in  FIG. 3C  may be determined when a minimum gray to white level is sensed at the beginning portion  52  of the video line during the program video. Also shown is a PRICB signal  54 , an incorrect burst signal that can reside in the sync signal portion and/or in a portion  58  of the back porch area, as earlier depicted in  FIG. 3A . 
     The embodiments of FIGS.  2 A and  3 A- 3 C illustrate examples of the invention where at least a portion of the front porch, and/or at least a portion of the end of the active video line, and/or at least a portion of the back porch, are replaced by a signal near or below blanking. Typically, this signal may be about −10 IRE to −20 or −30 IRE, or varied through a range of for example from a few IRE above zero to −30 IRE at some selected fixed or random frequency, for selected lines of the video field. 
     In addition, it should be noted that in this invention, the horizontal blanking interval may be varied from its normal duration. For instance, the typical duration of the horizontal blanking interval, HBI, is normally about 10.9 microseconds for the NTSC color standard. For this embodiment, the HBI preferably may be expanded to 12 μs by extending the HBI into the end of the active video line one or more microseconds. 
     To this end,  FIG. 3D  depicts an expanded HBI which allows for extra cycles of incorrect color burst PSTICB to be inserted after a PSTPS signal (for example, PSTPS signal  46  and PSTICB  50 ,  FIG. 3B ) for increased concealment or color distortion in a viewed illegal copy. In addition, the expanded HBI allows for the lowered front porch area to cause an earlier pre scan for increased concealment, while also allowing for better playability because an incorrect color signal PRICB  60  can now reside on a lowered front porch area MFP  62  and/or the first half of the sync tip as depicted as PRICB  64 . 
       FIG. 4  illustrates a system level block diagram including the present invention. Program video is supplied to a basic anti-copy protection (ACP) system  100  that causes darkening or attenuation when an illegal copy is played back and viewed. The output of the basic copy protection system  100  is applied to the process of the invention, namely a color stripe enhancer system  102 . The output of the color stripe enhancer system  102  is a copy protection video signal with enhanced color distortion, which is then supplied to typically a duplicating VCR. When an illegal copy is made from the processes illustrated in  FIG. 4 , the resulting playback and display of the recorded video signal will be darkened video caused by the basic anti-copy protection process, combined with the enhanced color distortions caused by the present invention (system  102 ). Further darkening can also result by aligning the PSTPS signal to the position near the beginning portion of the program&#39;s active video lines that are above blanking level, as discussed in  FIG. 3C . 
     Referring to the block diagram of  FIG. 5 , a normal HBI duration is assumed and the video input signal is a program video signal that preferably contains a basic anti-copy protection signal that causes attenuation in an AGC system such as the AGC system in a VCR. Some examples of the basic anti-copy protection signals are described for example in the patents of previous mention by Ryan &#39;603, Morio &#39;253, and Ryan &#39;098. With certain applications (preferably video player and transmission systems) the invention can include the basic copy protection signal in combination with a color stripe signal process as disclosed in Ryan &#39;216 or a modified attenuated effects color stripe signal as disclosed in U.S. Pat. No. 5,784,523 to Quan (&#39;523). 
     In  FIG. 5 , the program video signal with ACP on input  110  is assumed to be clamped at blanking level or about zero volt, and is coupled to a switch  112  and a sync separator circuit  114 . One output of the circuit  114  then is supplied to a one shot  116 . One shot  116  is non retriggerable and is set to greater than about 32 μs so that its output is a horizontal rate pulse. The output of one shot  116  is then a horizontal rate pulse with its leading edge coincident with the leading edge of the horizontal sync of the input program video signal. The one shot  116  is coupled to a circuit  118  which may comprise a horizontal frequency phase lock loop, a horizontal frequency bandpass filter or a phase shifter, which generates a pulse prior to the occurrence of the leading edge of the horizontal sync. The output of the circuit  118  is thus a signal that has a phase lead with respect to the incoming horizontal sync, and is supplied to a pre sync one shot  120 . The output of one shot  120  occurs then a selected duration before the leading edge of the incoming horizontal sync, typically about 2 μs to 3.5 μs. Thus the output of the one shot  120  is a logic high pulse during for example the MFP signals  32 ,  44 ,  62  in  FIGS. 3A ,  3 B,  3 D. 
     The output of one shot  120  is logically ANDed with a line location signal from a circuit  122  via an AND circuit  124 . Line location circuit  122  is supplied a vertical sync signal from separator circuit  114 . The output of AND circuit  124  is logic high during selected lines and selected portions of the video field. For example from lines  21  to  250  there are pulses of about 2.5 μs before a leading edge of incoming horizontal sync. The output of AND circuit  124  turns on the switch  112  to thereby insert an MFP signal of selected (generally lowered) level from a voltage source  125  in the incoming video signal. Thus the output of switch  112  is normally the input program video with a preselected modified front porch area of a selected level, Vpresync. The video signal may include an HB 1  of expanded duration. Vpresync can be a fixed voltage of about blanking level or lower than blanking level. 
     On the other hand, Vpresync can vary as a function of scene content, that is, average picture level (APL), as described for example in  FIGS. 7-9 . For example, Vpresync may assume the approximate values: 0 IRE to +10 IRE for bright scenes, about −5 IRE for average gray scenes, and about −10 IRE for dark scenes. 
     A presync color burst gate signal is generated by a presync gate circuit  126  following the trailing edge of the pulse of the one shot  120 . The output of gate circuit  126  is a presync pulse that will provide for inserting a color burst (correct or otherwise) in the sync area and/or before the color burst of the input program video signal. The output of the gate circuit  126  is coupled to an OR gate  128 . The other input of OR gate  128  is another color burst gate pulse (for example a PSTPS burst gate) in the back porch interval to allow adding or inserting a color burst (correct or otherwise) in a back porch portion of the HB 1 . Thus the output of OR gate  128  is a series of pulses coincident within the horizontal blanking interval, which when selectively ANDed via an AND gate  130 , with the line location signal from the line location circuit  122  and an incorrect color subcarrier signal from an oscillator  132 , causes the insertion of incorrect (or otherwise) color burst phase or frequency signals into the horizontal blanking interval at corresponding various locations. 
     In the generation of the PSTPS color burst gate, a one shot delay  134  is triggered by the leading edge of sync supplied by the one shot  1 . 16 . Then a one shot  136  coupled to one shot  134  provides a logic high pulse to a postsync gate circuit  138 , whose output is supplied to the OR gate  128  as the PSTPS color burst gate signal. The presync and postsync gate circuits  126 ,  138 , respectively, may comprise timing circuits such as one shot circuits. 
     An output signal from the one shot  136 , a logic high pulse in a back porch portion, is used to control a switch  140  to cause the level of a back porch portion to go below normal blanking level. This lowered back porch portion corresponding to the PSTPS signals of previous mention, is set by a signal voltage V PSTPS  from a voltage source  142 . 
     A summing circuit  144  then produces a modified video signal with basic copy protection with preferably incorrect burst in various locations of the horizontal blanking interval. That is, the modified video signal may include an incorrect burst in the MFP signal area ( FIG. 3D ), in the portion of the sync area as for example shown in  FIGS. 3A ,  3 C,  3 D, or an incorrect burst in the back porch portion preferably after the trailing edge of the PSTPS signal as shown for example in  FIG. 3B . Also the output of summing circuit  144  may include a lowered back porch portion or PSTPS signal (see  FIG. 3B ). 
     The results of the circuits of  FIG. 5  are exemplified in  FIG. 3A  where the MFP signal  32  is realized by the output of the voltage source  125  and switch  112 , and the PRICB signal  34  is realized by the circuits  132 ,  126 ,  128 ,  130 ,  148  and  144 . 
     Referring to  FIG. 3B  the PSTPS signal  46  is realized by the circuits  136 ,  140 ,  142  and  144 . Also in  FIG. 3B , the incorrect color burst PSTICB signal  50  following a PSTPS signal, is realized by the circuits  132 ,  138 ,  128 ,  130 ,  148  and  144 . 
       FIG. 3C  illustrates the situation where the PSTPS signal  48  is moved or inserted near the beginning of the active video line to cause a VCR to further attenuate the signal once the basic anti-copy protection signals take affect. Also the PSTPS signal  48  in  FIG. 3C  can cause the TV set to have less viewability because under attenuated circumstances from the VCR (directly or from a copy), the PSTPS signal may cause a TV to generate an incorrect horizontal sync signal. 
       FIG. 6  illustrates by way of example an implementation of an incorrect color subcarrier oscillator circuit, such as the oscillator  132  of  FIG. 5 . To this end, an inverting amplifier  160  is coupled at its input to an adjustable capacitor  162  and thence to ground. The output of the amplifier  160  is coupled to another adjustable capacitor  164  and thence to ground via a resistor Ro. A crystal oscillator  166  and a resistor R f  are coupled across the amplifier  160 . By adjusting the capacitors C 10  and/or C 20  electronically or manually, the phase and frequency generated by the oscillator  132  changes thus providing an incorrect color subcarrier signal ICSC rather than the nominal frequency which normally is NTSC or PAL color subcarrier frequency. It should be noted that the circuit in  FIG. 6  is generally not locked with the video subcarrier frequency but may be locked in phase with the incoming video subcarrier but with a phase offset or variable phase offset. 
     Adaptively changing the MFP and/or PSTPS signal&#39;s negative or low levels in a video signal may be preferable in certain situations where maximum playability is desired. To this end,  FIG. 7  illustrates a technique of the invention for adaptively changing the levels of the modified front porch area (MFP) and/or end of the active video line, and also for adaptively modifying the PSTPS amplitude or post pseudo sync tip level. Here the program video or copy protected video is supplied on input  110 ′ to a scene detector circuit  170 , whose output is supplied to a transfer function system  172  and/or  174 , such as look up tables or some type of scene to voltage transformation circuit. The output terminal of system  172  then supplies a voltage source on output  176  and the output terminal of system  174  supplies a voltage source on output  178 . 
       FIG. 8  illustrates via a waveform, adaptively varying the post pseudo sync amplitude and/or tip level, as well as the level of the MFP and/or end of the active video line, in accordance with the present invention. Thus the MFP signal indicated at  180  may vary in level as depicted in dashed line and the vertical arrow, in response to a signal indicative of the average picture level (APL). Likewise, the PSTPS signal indicated at  182  may be varied in amplitude and/or tip level as depicted in dashed line and vertical arrows, in response to the detected APL of the video signal. 
     To this end,  FIG. 9  is a schematic diagram, illustrating by way of example only, further detailed circuitry of the block diagram of  FIG. 7 . Here the program or ACP video signal on input  110 ′ is coupled to a sync separator circuit  186  whose output is coupled to a back porch sample circuit  188  which generates a pulse coincident with a substantially normal blanking level, thereby avoiding sampling in an area of substantially modified level in a back porch portion. The video signal on input  110 ′ also is AC coupled via a capacitor  190  and a grounded resistor  192 , whereby the absolute values of the unmodified back porch area levels will change in relationship to the average picture level. On bright scenes, the unmodified back porch level measured at an output of a buffer amplifier  194  will go below zero volt. On dark scenes, the unmodified back porch level measured at the output will be about zero volt. An unmodified back porch area is sampled via a switch  196  and storage capacitor  198 , which thus generate a voltage indicative of the average picture level. This voltage is then supplied to amplifiers  200  and  202 , each of which can have a different voltage gain. Coupled to a second input of amplifier  200  is an offset voltage Voff 1  from a voltage source  204 , and coupled to a second input of the amplifier  202  is another offset voltage Voff 2  from a voltage source  206 . An output  176  of amplifier  202  comprises the MFP signal corresponding for example, to the voltage Voff 2 , and will preferably generate a negative voltage for dark scenes and preferably no voltage for bright scenes. An output  178  of amplifier  200  comprises the PSTPS signal corresponding for example to the voltage Voff 1 , and the gain of the amplifier  200  is selected to range from a preferable negative voltage during bright scenes to a preferably more negative voltage for dark scenes. The output voltages on the outputs  176  and  178  of  FIGS. 7 and 9  thus correspond to one another. 
     While a preferred embodiment uses standard horizontal blanking intervals and/or sync widths and/or color envelope durations, other embodiments of the invention contemplate implementing the horizontal blanking intervals and/or syncs and/or color envelope durations with non-standard intervals and durations. For instance, the horizontal sync may be narrowed and/or delayed and/or the horizontal blanking interval may be widened or narrowed. 
     Accordingly, various such modifications and adaptations of the embodiments and examples of the invention will be apparent from the description and drawings, and thus the scope of the invention is defined by the attached claims and their equivalents.