FR2548500A1 - Interactive capacitive video disc playback system - Google Patents

Abstract

Information representative of a program content is provided together with information of a second program content on a record disc (12) having a single spiral track. When an interactive section of the disc is played the player (10) is provided with two pieces of information so that it may track the correct information. One piece is provided by the system user who selects (31) the sequence to be viewed. The other piece is the digital information (26) on the disc which tells the player where the program being transduced is and where the transducer has to go to be in the desired program. The spiral track is formed as a groove on the disc surface and the stylus cooperatively engages the groove. In another arrangement the first program content is interlaced with the second program content and a kicker is automatically operated to follow the selected program throughout the remainder of the recording.

Description

 The present invention relates to an interactive system for a video disc and more particularly to an interactive system for progressing through a number of separate programs, by viewing a single program, according to the instructions given to the system by an external source such as a spectator.

 It is desirable to have an interactive video system where the displayed video image and its sequence are chosen by the viewer. In a multi-story line system, for example, the television viewer can choose between a happy or sad end to a program. In another arrangement, an interactive video system can be used for educational purposes where a question is asked, followed by a response from the viewer. After choosing an answer, the system approves or corrects the viewer according to the chosen answer. A third interactive system can be directed to a video game. For example, in a labyrinth game, the spectator chooses a path from among several interconnected paths to cross a confused network in a labyrinth.

The interactive systems according to the prior art pose certain problems. In US patent nt 4,170,832 in the name of Zimmerman, a tape based video teaching machine is described. In the system of
Zimmerman, the band is provided with control marks to access the video sequence in response to the action of the viewer. In Zimmerman's system, the responses are recorded in a track adjacent longitudinally to the strip, like four tracks. For an immediate restitution, i.e. when a choice has been made by the spectator, the number of choices is limited to the number of tracks which can be recorded on the width of the tape. It is desirable to obtain a system interactive with a greater number of choices at a connection point
Almost continuous video can be obtained by other interactive systems, but, however, these "fast" systems are generally expensive. For example, a system has been described in which two # isques video recorders cooperate to produce an almost instantaneous connection. An example format for a two-device system is a guided city tour. For example, at the MIT Industrial Liaison Program
Symposium held on January 15, 1980, intelligent video recorders have been described. In this case, while the first device produces a video sequence, the other device puts its transducer in place for the next connection point. In the guided city tour type, an interactive device with two discs # 1 offers the video of a track to the spectator while the transducer of device no. 2 is placed for the next connection. When the spectator is confronted with an intersection and asked to make a choice among three possible routes, the transducer of the device no. 1 is placed to give the video of a route, say straight ahead and the device no. 2 depending on whether the transducer moves forwards or backwards with respect to the connection point, is placed to give the video for the other choices, for example a choice of a right turn or a choice of a left turn.

This "fast" system is costly requiring two synchronized restitution devices.

 Other interactive systems are available which offer a greater number of choices for any connection point and which are less expensive than a system with two devices or two arms, however, these systems have certain drawbacks. Some disk systems offer interactive features by locating branching data at locations far from the branching point. Indeed, the data which is chosen by the spectator is distant from the position of the transducer when the connection is initiated. These systems are generally inexpensive and give a certain number of answers but however they do not give an almost immediate restitution in response to the choice of the spectator. When a choice has been made, the transducer should look for the location of the chosen answer. The video, during the search, is usually deleted.

 In the disc system according to the present invention, a transducer is provided for reproducing information signals which are recorded in a spiral track in a disc-shaped recording medium. Information frames are recorded in segments of the spiral track to produce a visualization of the image. A jumping means cooperates with the transducer to effect a movement of the transducer so that the transducer jumps from a first turn and the transducer communicates the information signals before a jump to a second turn where the transducer communicates the signals of the information subsequent to the jump. Connection means validates the transducer so that the transducer connects from a first frame sequence to a second frame sequence. Control means generates signals to control the jumping means so that it urges the transducer to it follows a predetermined path along the spiral track, so while the transducer follows the predetermined path, the second frame sequence chosen by the connection means is presented on the display means.

 According to another characteristic of an embodiment of the invention, the first sequence is interlaced with the second sequence and therefore when a connection is made, an almost continuous video is produced during the transition from the first sequence to the second sequence .

The invention will be better understood, and other objects, characteristics, details and advantages thereof will appear more clearly during the explanatory description which follows, made with reference to the appended schematic drawings given solely by way of example illustrating a embodiment of the invention, and in which
Figure 1 is a plan view of a video disc having a spiral track formed in accordance with the principles of the present invention
FIG. 2 gives a block diagram of a system for restoring a disc comprising a jumping mechanism of the needle
- Figure 3a, 3b and 4 show disc program formats where the spiral track has been unfolded or expanded for clarity
Figure 5 is a schematic representation of an assembly of the needle arm having an electromagnetic jumping device
Figure 6 gives a block diagram of a needle jumping system
- Figure 7 is a schematic representation of a video needle following a spiral groove conforming in the surface of a video disc
FIG. 8 is a diagram of waveforms of the vertical erasure intervals preceding the odd and even frames of a television signal
Figure 9 is a representation of the digital data format that is used for interactive tracking in an interactive video disc system.
FIG. 10 is a flowchart illustrating the sequence by which the system of FIG. 6 keeps the needle in the desired track during an interactive restitution
- Figure 11 gives a block diagram of a video disc encoder according to the present invention; and
Figure 12 shows another disc program format where 16 different programs are recorded on the disc.

 Referring to Figure 1, a disc 12 for use in an interactive video recorder which has a stage which rotates at a constant angular speed is shown. The disk 12 is subdivided into eight sectors S1-S8. The information on the disc is recorded in a spiral track 101 which is continuous from its starting point 103 to its end point 104 through the surface of the disc 12. Each turn of the track 101 is subdivided into eight corresponding segments to the eight sectors of the disk. In each segment of track 101 is recorded the complete frame of the television signal, so in disc 12 of Figure 1 there are eight frames or four images of the television signal for 3600 of the information track. The angular displacement for a frame is 360/8 = 450 and 900 for an image. It should be noted that the disk 12 of FIG. 1 is simply given by way of example, other systems such as systems having two frames or more per turn can be used with the present invention.

 Referring to Figure 2, we can see a video disc playback system. The turntable 10 has a turntable 11 for supporting the disc 12 in a rotatable manner. In the figures, elements designated by identical reference numerals are identical or similar. Each turn of the spiral track 101 on the disc 12 contains image signal information containing the synchronization components and information identifying the particular turn. A needle assembly 14 comprising a signal reading needle is mounted in a carriage mechanism 13 for a radial translation of the needle assembly through the disc 12. A jumper assembly 21 is mounted very close to the reading needle to impart a movement to give the needle a translational movement over one or more turns of the track. The capacitance variations which occur between the needle and the disc are detected by read circuits 16 and applied to the video signal processing network 18 to format the signal for viewing by a conventional television set 20.

 For special (i.e. interactive) effects, the signal reading needle follows a path through the surface of the disc 12 according to the instructions given by a user by means of an interactive remote control 31 and information digital auxiliary (DAXI) recorded at the same time as the image signal information. In other words, the needle jumps into a "dance" routine so that the video sequence restored from the disc and displayed on the television 20 is a sequence chosen by the user. The needle is forced to dance in response to the jump pulses of the jumping assembly 21. A jumping mechanism 30 comprises a control circuit 25 responding to the DAXI recovered in the video processing network 18 and to the instruction signal given by the interactive remote control 31 (user input). A pulse generator 28 produces a pulse of an appropriate shape and / or amplitude to excite the jumper of the needle 21 to give, to the needle, a translational movement on a certain number of turns. The command 25 establishes the jump necessary to accomplish the sequence of translation of the needle required by the program chosen by the user.

 An example of a needle dance routine which can be practiced according to the invention will be described with reference to FIG. 1. In this example, it is assumed that a sequence of football games is recorded. on the disc 12. The needle follows the spiral 101 starting from point 103 and going inwards. The football game is viewed on a television. When the needle reaches point 105 of the spiral 101 (the beginning of the interactive material on the disc 12), the needle is forced to perform a frozen image mode by jumping to point 105 from point 107 (the start of the next turn) .During this frozen image mode or before, the user is instructed to choose between one of the three choices (of course many other choices are part of the capacity of this system). In football, the commentator on the game of football can describe that the following video sequence shows the critical phase of the game of football and that the user can see this critical phase from the 45-meter line, from the goals 1 or goals area 2 by pushing buttons A, B or C, respectively, on the remote control 31. When the user has chosen a particular camera, the playback device then initiates a dance routine of the needle to restore the selected sequence.

For example, if the user chooses the 45-meter line camera, the needle will jump from point 113 in the frozen image track to point 115 in the circle track. To stay in the circle track, the needle will jump from point 117 to point 119 and from point 121 to point 123 and so on, jumping on the diamond and triangle tracks containing the other choices.

If the user has chosen the camera at end zone 1 or the camera at end zone 2, the needle will follow the diamond tracks (jump from point 125 to 127) or triangle
(jump from point 129 to ~ 131) respectively. In this
interactive layout, the program sequence for any choice (like program a) is interspersed
other programs (oe #programs b and c). So
advantageous, the needle dance arrangement allows
an almost instant connection! from program to
another which was not possible in systems
prior art interactive like the type described above where the needle should search for the next video
which is registered or far from the connection point.

Besides, this dance arrangement can be put
implemented using a single rendering apparatus or an apparatus having a transducer thereby producing
a relatively inexpensive interactive system.

Figure 3a is a representation of a
program sequence where the turns of the track are unfolded for ease of understanding. Disk sectors 1-8 are indicated at the top of Figure 1. The turns are identified by the reference numbers
301-307 shown on the left side of the figure. The part
alphanumeric of each block represents information
can be saved in the erase interval
vertical of a television signal. An embodiment
specific of the alphanumeric part will be described in
referring to Figures 8 and 9. The first part
alphanumeric 309 is used to identify the needle position (current needle position), the
second alphanumeric part 311 is used to identify
identification of the track for the program to be returned
(future position of the needle) and the third part
alphanumeric (sign) 313 gives information about
the number of turns to jump and the direction of the jump
(displacement). A regular program R is recorded on turns 301 and 302- sectors 1; 2 and 3. Track ID and displacement are both 0 which indicates that there is no jump to be made At turn 302, sector 4, the program changes to a frozen image mode. coil 303, sector 3 Track ID is 0 and displacement is -1, so the needle will be brought back from a coil in frozen image mode if the user has not changed defective ID of the track from 0 .

As noted above, the device will remain in frozen image mode until it receives a signal from the user. If the user chooses the program
A, assuming that the needle is at turn 303, sector 1 when the user's message is received, the needle follows turn 303, sectors 1, 2 and 3 until turn 303, sector 4. Thus, the needle follows program A, TD of track A. If the user has chosen program C, a jump of +1 will have been made at turn 303, sector 2 or if he has chosen program B, a jump of + 1 at turn 303, sector 1. When the needle has acquired a program A, B or C then it follows this program according to the movement instructions given in the vertical erase interval (ID - identification) .

Referring to Figure 3b, it shows a connection diagram for connection of a first program to a second or third program. If the needle is in position 315, restoring the program
A and the user chooses program B, track ID B and moving from +1 to position 315 indicates where the new program is placed, i.e. B, 9t how to get there, that is, a displacement of + 1 must be carried out. So, at the end of position 315, the needle can continue at position 317 while remaining in program A (no new instruction from the user) or can jump to position 319 to restore program B (new instruction from If the user has chosen program C, the jump will be made from position 317
at position 321, if no new instruction has
been given by the user then the sequence will be
317, 323.

Referring to Figure 4, we can see
another program sequence. In this sequence,
the needle can take one of two paths (pro
gram A or B) when it crosses matter
interactive disk. If the user chooses the
path of program A, the needle jumps to the turn
following after each video frame. If otherwise
user chooses program B, the needle dances
around program A to produce a sequence
different. According to this arrangement, the user can
choose to watch a regular program (such as
program B) or jump through the program
regular and watch a short sequence of material
(such as program A). In this arrangement, the
represented program will take 1/8 (jumping so
to communicate one frame per turn) of the rest time
allocated to the interactive section of the disc while
that program B will take 7/8 of the restitution time.

An example of this interactive disc is a film having
a sequence of soccer games. In path 401 of
the frozen image or before entering the furrow of
the frozen image, the user will receive the instruction that
can watch the game of football, that is to say the
sequence of program B or jump through the game
football watching a sequence of cheers
on the side lines, like the program sequence
A. Of course, it should be noted that the present invention is not necessarily limited to the sequences described here.

The sequences are only limited by the imagination of the
producer of the software and the number of tracks that we
can jump reliably. Similarly, it should be noted
that the programs are recorded on the disk 12 so that the sector S1 is the frame 1 of a color television picture, the sector S2 is the frame 2, the sector S3 is the frame 3, the sector S4 is the frame 4, etc ... Thus, the phase of the color subcarrier is aligned from one turn to another.

 The needle jumping assembly will now be written with reference to Figures 5 and 6. Figure 5 illustrates a needle jumping assembly. In one embodiment, a needle 35 carrying a signal reading electrode is contoured to engage a groove 36 in a spiral track 101 on the disc 12. An electrical contact to the electrode is obtained by means of a flying conductor 38. The flying conductor 38 also produces a certain degree of pressure between the needle and the disc to allow it to follow it. The needle 35 is mounted at the free end of the arm of the needle 37, the opposite end of which is attached to the mechanism 14 of the carriage by a flexible coupling 39 which gives limited freedom of movement to the arm of the needle on A permanent magnet 45 is fixed securely to the arm of the needle 37 relatively close to the needle, and it is arranged to be in the lines of magnetic field emanating from the magnets or coils 46 selectively excited from the electrode when the the needle is in the return position. The coils 46 having non-magnetic cores are electrically connected to produce auxiliary fields to impart radial movement to the magnet 45 and therefore movement of the needle when the coils are energized.

 The partial block diagram of. FIG. 6 illustrates a jumping system for the turntable 10 of FIG. 2. In FIG. 6, a microprocessor 56, supposed to contain the associative circuit required for normal operation in response to commands from the system or from the programming program. the turntable control, monitors the position of the needle by track identification signals (DAXI) and applies jump signals inward or outward depending on the playback mode. For example, if a particular video sequence is to be frozen at this point in the playback of the disc, the needle jumps out of a turn or track outward for each revolution of the disc. The microprocessor 56 receives the track identification signals and the interactive signals (DAXI) from the recognition circuit 54.

A user input signal from the interactive remote control 31 applied to the microprocessor 56 is used to calculate the correct position of the needle and determine the appropriate adjustments of the control signal for application to the programmable pulse generator 28 'and to switch 47 to reposition the needle in the direction of the appropriate or desired turn of the spiral. The pulse generator 28 ′ produces a ramp voltage proportional to the control signal applied by the microprocessor 56 by means of an input bus 58. The signal at the output of the pulse generator at connection 51 is applied to the reversing switch 47 for application to the coil 46 of the needle jumper. The reversing switch 47, controlled by the microprocessor 56 by means of the #US: 57 regulates the direction of the current flow through the coil 46 and thus the direction of the magnetic field created between the coils and consequently the direction of the movement of the needle.

 The pulse generator 28 ′ includes a circuit 49 forming a current source which produces a regular current of high impedance in a first mode and a low impedance connection to a reference potential in a second mode. When the current source operates in the second mode, the potential through the capacitor 55 is blocked at the reference potential. Switching the current source 49 to its first mode forces the potential at connection 50 to increase monotonically according to the charge rate of the capacitor 55. The potential at connection 50 is absorbed by the amplifier 48 which produces the required range of output currents to drive coil 46 of the needle jumper.

 In a preferred embodiment of the interactive system according to the invention, the track 101 of the disc 12 has the shape of a groove on the surface of the disc having walls of a predetermined shape (as triangular).

In this embodiment, the needle 35 has a point which has the same shape as the groove formed in the disc. Needle conformity, groove helps the needle follow the surface of the disc and the engagement of the needle during a jump operation.

Referring to FIG. 7, a needle 35 having a point 701 is illustrated in engagement with a spiral groove 101 in a disc 12. The walls of the triangular groove 703 and 705 guide the point 701 of the needle so it moves to the bottom of the groove 101. In general, with current technology, it is possible to jump the needle, reliably, only on a limited number of grooves (like more or less 2 turns of the groove ). An interactive system which has a groove disc has an advantage in that the tip of the needle will generally engage the chosen groove if the bottom of the needle 707 arises in the width of the groove. As a result, a continuously slaved control loop is unnecessary, avoiding the cost of slaving, slow response speed, and the possibility of instability. In Figure 7, the tip of the needle is shown in phantom line by reference numbers 701 'and 701 "
At these extreme positions shown by the references 701 ′ and 701 ″, it can be expected that the needle engages the turn of the groove which resides below the tip. In this system, the walls 703 and 705 of the groove in spiral helps the needle to acquire the right track When the needle shown in position 701 'lands as illustrated in the groove, it is pushed to the bottom of the groove by the emptying wall 705.

Furthermore, the needle shown in fante̲ line at 701 "is pushed to the right at the bottom of the groove by the guide wall 703 of the spiral groove. Thus, one of the advantageous characteristics of the present invention resides in a needle in compliance with a groove of the disc, which favors the placement of the needle in the correct groove when a jump is accomplished.This tends to be faster than using a servo to place the needle. It will be understood that the shape and the dimension of the groove and the tip of the needle are not necessarily to scale.In commercial videodiscs using groove disks, the angle at the bottom of the groove is approximately 1400.

 Figures 8 and 9 will be used to describe the digital information (DAXI) recorded on the surface of the disc to perform a dance routine.

The particular details of an NTSC type television signal for use in a video disc system formatted using the buried subcarrier technique are described in US Patent No. 3,872,498 "Color Information Translating Systems" in the name of D Pritchard. According to the NTSC format, a vertical blanking interval (a) separates the even and odd interlaced frames from a television picture.

Referring to Figure 8, those skilled in the art of television will readily recognize the standard vertical erase interval containing a first equalization pulse interval
(b), a vertical synchronization interval (c), wn second interval of equalization pulses (d) followed by a number of horizontal line intervals at the start of each new frame. The video signal information begins on line 22 'of frame 1 and on line 284' of frame 2. Information
DAXI representative of the frame number and the interactive information appear on line 17 'of frame 1 and on line 280' of frame 2. Digital information could also be inserted in other lines of the interval To show the details of the DAXI signal format, Figure 9 expands the time scale during the horizontal line containing the data (line 17 'or line 280')
Referring to Figure 9, the data
D are represented in terms of the luminance level
100 IRE units is a logical level "1" and 0 IRE units
(erasure) is a logical level "O". The first data bit follows the standard horizontal synchronization pulse 901 and the color burst 903. The frequency of the color burst 903 is approximately 1.53 MHz, the frequency of the buried sub-router. Each bit of data is transmitted in synchronism with the subcarrier signal buried at 1.53 MHz. The digital message includes a 13-bit start code called B (X), a redundant error checking code called C (X). 13 bits and 51 bits of information called {X), 19 bits for the reserve information (a), 18 bits for the frame number (b) and 6 bits for the band number
(vs). The start of the next horizontal line is
indicated by the following horizontal synchronization pulse 901a and the color burst 903a. Thus, the individual data bits are in synchronism with the color subcarrier and the total digital message is in synchronism with the vertical synchronization pulse. Note that the data frequency can be a multiple or a sub-multiple of any practical subcarrier frequency; similarly, other luminance values can be assigned to logic level 1 and logic level 0, or more than one bit can be associated with a given luminance level. In Figure 9, (d) indicates a horizontal line and (e) indicates the interactive data.

The details of the start code B (X)> of the error verification code C (X) and of the frame number (18 bits) and of the tape number (6 bits) are given in US Pat. No. 4,308,557 " Video Disc System "on behalf of
CB Dieterich. In a video disc system of the type described here, the frame number and the tape number can be used for correction of tracking error or other special characteristics of the record player, and this information transmits the first part alphanumeric (figure 3), giving the current position of the needle. In the patent of
Dieterich, 27 unused bits of information are described. The present system uses 8 of these bits for interactive data to accomplish the needle dance.

 The first four of the 8 bits are used for the identification number of the track (second Iphanumeric part of figure 3). This number is used to identify what kind of image is in the groove according to the next vertical erase interval. For example, a track identification of O may indicate a frozen image, a track identification of 1 to 16 may identify a particular sequence in the program.

The following four bits of the 8-bit interactive data are used to identify the displacement (third alphanumeric part of FIG. 3a) The displacement is a digit provided with a sign, i.e. there can be moving inward on the disc or outward. So the first bit of the movement will be representative of the direction of this movement, for example a "1" can represent a movement towards the interior and a "0" can represent a movement towards the outside. The next three bits of the four-bit movement code indicate the number of grooves to jump. A movement of "0" indicates that no jump is necessary to stay on the right track while a movement of 1, 2 etc . is used to indicate displacements of 1, 2 grooves, respectively.

An example of a sequence of events to determine the necessary parameters for training the jumper for the microprocessor 56 of FIG. 6 is shown by the flow diagram of FIG. 10. The routine does not include general monitoring of the system. and the jump control. This particular routine assumes that the jumping arrangement of the needle to maintain the correct groove is formed according to US Patent No. 4,330,879 "Adaptive Stylus Kicker Using Disc Track and Disc Sector
Information "on behalf of CM Wine. The first block 1001 in the flowchart instructs the microprocessor to read DAXI information and receive user input. After reading DAXI information and having sought the input of the user, the first decision block 1003 determines whether the identification of the runway is equal to the identification of the required runway.

If the answer is "no", then it is determined, at decision point 1005, if the user has made an entry since the last reading of DAXI. If the answer is "yes" then the video is deleted and the audio is muted in 1007 and normal playback continues. If the answer is "no" at decision point 1005 the device continues normal playback at 1009. If the answer to decision block 1003 is "yes", then decision point 1017 is reached.

At point 1017 it is determined whether the user has made an entry. If the answer is "yes", this resets the indicator block 1019 to the initial state. This indicator signal indicates whether or not the user has just made an entry. From the reset block 1019, the device goes to the de-erase block 1011 where the video is de-erased and the audio muted. If the user has not yet made a recent entry, block 1011 is reached, de-erasing the video and deafening the audio.

The decision block 1013 determines if the displacement is equal to 0. If the answer is "yes", the device goes to a normal game or restitution in 1009 if it is "no", the device goes to block 1015 or a the required amount of movement is jumped and the apparatus continues in normal play in 1009.

The operation of the rendering device will be explained with reference to the flowchart in Figure 10. In normal cases where the user has not recently made an entry, the device encounters a
Corresponding track ID from time to time (this route is "yes" from 1003 and "no" from 1017). When this happens, the video is cleared by block 1011 and the movement is made to force the needle to stay in the chosen track. In this normal case, the device may encounter a mismatched track ID (no connection of block 1003). In this case, at block 1005, since the user has not made an entry, the device continues normal play. Thus, normal operation is intended for the user to see the selected track.

In frozen image mode, the device encounters a displacement of -1 forcing the needle to jump again to maintain the frozen image.

 In the case where the user has just made an entry to choose a particular program sequence, an indicator has been established in block 1001.

In general, track ID is not equal to the required track ID, so the device takes the "no" branch of block 1003 and the "yes" branch of block 1005 so that the video is deleted. Then, the device continues normal play. When the needle is placed so that TD of the track is equal to ID of the required track, the device takes the "yes" branch from block 1003.

After taking the "yes" branch from block 1017, the user's flag is reset and the video is cleared. According to the movement instruction, the device follows the path 1013, 1015, 1009 or 1013, 1009.

While the description given here includes a track ID and a move, those skilled in the art will note that more than one group of track IDs and moves can be expected in a vertical erase interval. This can be beneficial to allow faster track change
FIG. 11 gives a diagram of an encoder of a video disc for encoding the information in a form suitable for the manufacture of interactive discs. A composite video signal is produced by a source 1101.

 Source 1101 may be a tape recorder comprising a tape that has been prepared using studio-type editing equipment where interactive data is interspersed on the tape depending on how it will be entangled on the surface spiral track of the disc. The composite video signal is combined in the adder 1103 with a stream of digital data bits to the conductor 1105 provided by the digital data generator 1107. Synchronization means 1109 supplies color subcarrier and synchronization pulses so that the bits data produced by generator 1107 are in synchronism with the color subcarrier appearing at terminal 1111 and so that the digital message is coded on the correct horizontal line in the vertical erasure interval. appearing on the data buses 1113 and 1115 and representing the video frame number, the band number and the interactive data are produced by the device 1117. The device 1117 can be a computer offering the band data of the frame and interactive in response to a SMPTE time code supplied by the source 1101. The digital data and the video signal are combined in the adder 1103. Another means of processing signal ent 1121 conditions the composite video signal for the recording medium. The composite video signal is of the buried subcarrier type and is recorded using frequency modulation modulation techniques. The signal is applied to the cutting head 1146 which cuts a groove and the signal information simultaneously in a metal substrate 1123. A relative movement is established between the cutting head 1146 and the substrate 1123 by rotation of the plate 1125 in response to the rotation of the drive motor 1127.

Discs for consumer use are produced from the metal substrate 1123 by techniques well known in the disc manufacturing industry.

 In the system of the present invention, it should be noted that the jumps through the intermingled programs are made just before the vertical erase interval. In a groove video disc system where the jump is accomplished in a range of turns where one can jump reliably, it is believed that the jump operation can be accomplished in about a millisecond. If the jump is started about 15 horizontal lines with the clearing interval, the spectator will notice little or no effect during the jump.

Figure 12 shows another program sequence that can be recorded on an interactive disc. Referring to Figure 12, there is shown an arrangement for recording up to seven programs (AP) on an interactive disc. The frozen FF image is formed on the disc comprising two
turns. This allows access to one of the sixteen programs with a jump of two turns or less. The jump sequence for this interactive disc includes the restitution of a frame followed by a jump of two turns.

 It should also be noted, as previously described that in an intermingled disc, in general, if the needle is not in the right track at the right time, simply waiting for a duration less than a turn, the needle will generally finish in the subject of the program that has been chosen. Thus, if the user generally loses the video, he can correct it in one turn of the turntable which includes four video images in the system as described here.

 While the embodiments described include examples specific to the software described herein, these sequences should not be limiting. It will be obvious to those skilled in the art that many jump sequences for various program patterns are part of the teaching of the present invention. For example, more than sixteen program sequences can be recorded using a single turn of the frozen image. In this arrangement, the initial jump into a program will be coded using user input. This can be accomplished by the announcer on the disc indicating to the user that he must produce an entry which will be used to jump the needle to the sequence of the program chosen. Furthermore, it should be noted that the dance routines of the needle described here have been described with reference to a jump of the needle inward on the disc.

Of course, there are many programs where you may want to pop the needle out on the disc. For example, for the soccer / cheering game sequence you may want to jump out with the cheering sequence so that the soccer sequence can be watched when rotating inward.

Claims (9)

 1.- Disc rendering system having a transducer for reproducing information signals recorded in a spiral track in a disc-shaped recording medium, where information frames are recorded in segments of said disc spiral track for producing a visualization, characterized in that it comprises:  jumping means (21) cooperating with said transducer, for performing a movement of said transducer so that said transducer jumps from a first turn where said transducer communicates the signals of information before a jump to a second turn where said transducer communicates the information signals as a result of said jump  connection means (31) for validating said transducer so that it connects from a first frame sequence to a second frame sequence  control means (30) for generating signals to control said jumping means so that said jumping means urges said transducer to follow a predetermined path along said spiral track, as well as said transducer follows said predetermined path , said second frame sequence chosen by said connection means is displayed on a display means.  2.- System according to claim1, characterized in that the spiral track in the form of a groove having a needle guide wall in a surface of the recording medium and in that the transducer comprises a needle having a slope of the same shape as the groove, which engages said groove during the restitution of the information, said needle-groove assembly reducing the amount of research between the tracks, and the guide wall of the groove helps the needle to engage a turn chosen when the needle is close to said coil chosen at the end of the jump.  3.- System according to claim 2, characterized in that the groove is of triangular shape.  4.- System according to any one of claims 1 or 3, characterized in that the transducer jumps from the first turn to the second turn during an interval of video signals when the display is erased.  5.- System according to claim 4, characterized in that the interval is the vertical erasure interval of a television signal.  6.- System according to claim 2, charac terized in that the jumping means and the control means constitute a track jumping means controlled in open loop.  7.- System according to any one of the preceding claims, characterized in that it comprises a reading means, responding to the address information, for identifying the position of the transducer with respect to the information which is recorded, and means generating a control signal for following a desired sequence on the frame, the signal of said generating means being based on the position of the transducer, determined by the reading means before the start of the desired frame sequence and on the location of information to perform the desired frame sequence.  8.- System according to any one of the preceding claims, characterized in that parts of the first and second frame sequences are inter-ål e so that the control means is effective to produce substantially continuous information during the transition from the first frame sequence to the second frame sequence.  9.- Disc playback system having a transducer for reproducing information signals recorded in a spiral track in a disc-shaped recording medium, characterized by  means for receiving digital data  (54, 56) responding to information signals to read a first data word corresponding to a first position of the transducer relative to the recording medium, a second detective vrot corresponding to a predetermined frame sequence and a third data word corresponding to the displacement required to relocate the transducer from its first position its frame sequence  an input means (31) for applying an input word to the digital data receiving means to select the predetermined frame sequence  a jumping means (46) cooperating with the  transducer to perform a movement of the transducer,  said jumping means performing said movement when  said input word of said input means corresponds to the second data word so that said transducer is relocated from the first position to the frame sequence by displacement.