U.S. patent number RE33,662 [Application Number 07/410,651] was granted by the patent office on 1991-08-13 for tv animation interactively controlled by the viewer.
Invention is credited to Preston E. Blair, Frank S. Preston.
United States Patent |
RE33,662 |
Blair , et al. |
August 13, 1991 |
TV animation interactively controlled by the viewer
Abstract
The motion picture branching method is superseded by an
animation method which enables rapid and repeated switching of
multiple tracks of different camera-originated animation of the
same character during continuous action in a scene, and enables
branching at the termination of an action to multiple actions or
scenes. This method is the basis of a double-circuit video system
that enables a player to repeatedly touch or hit an animated
character during a continuous action as displayed on a projection
screen or television monitor and thus change the action repeatedly.
Another system embodiment enables the player to swing a racket
before the screen or television monitor, hit the mid-air projected
image of a perspective ball animated action, return the ball back
to the animated character opponent, and play a simulated game
during the the player exercises the same skills used to play the
game simulated. An ultrasonic transducer of a playing instrument
and a microphone combination on the television face or at angles to
the playing action produces a readout of the television product
position or the mid-air position of the playing instrument relating
to the game. The readout signal is converted into digital form and
compared to a similar readout in digital form of the position of
the character or object in the frame of the animation displayed by
the television and digitally coded in the video tape or disc.
Inventors: |
Blair; Preston E. (Carmel,
CA), Preston; Frank S. (Williamsburg, VA) |
Family
ID: |
27021084 |
Appl.
No.: |
07/410,651 |
Filed: |
September 21, 1989 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
|
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526464 |
Aug 25, 1983 |
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Reissue of: |
831170 |
Apr 14, 1986 |
04695953 |
Sep 22, 1987 |
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Current U.S.
Class: |
463/3; 463/39;
463/43; 463/5; 463/7; 352/87 |
Current CPC
Class: |
A63F
13/06 (20130101); A63F 13/5252 (20140902); A63F
13/04 (20130101); G09B 5/065 (20130101); A63F
13/47 (20140902); A63F 13/00 (20130101); G06F
3/0346 (20130101); A63F 2300/8011 (20130101); A63F
13/812 (20140902); A63F 2300/1062 (20130101) |
Current International
Class: |
A63F
13/04 (20060101); A63F 13/06 (20060101); A63F
13/00 (20060101); A63F 13/02 (20060101); G06F
3/033 (20060101); G09B 5/00 (20060101); G09B
5/06 (20060101); G06F 015/44 (); G11B 031/00 ();
A63F 009/22 () |
Field of
Search: |
;364/2MSFile,9MSFile,410,411,521 ;434/307,308,309,323
;273/316,333,1E,85G,DIG.28,185A,185B ;73/607,618,620 ;352/50,87
;340/720 |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
Other References
McGuigan, C. et al., "Mini-Movies Make the Scene", Newsweek, Aug.
8, 1983, 79. .
Solomon, C., "Fantasy, technology meets in Dragon's Lair", Los
Angeles Times, Aug. 9, 1983, 1,5. .
Rifkin, I., "Video industry draws new life from animation", Daily
News, Aug. 11, 1983. .
"Videodisc games to hit the arcades this summer", Softalk, Aug.
1983, 268,273. .
Wood, D. B., "Interactive Laser Game Ignites Enthusiasm-and
Controversy", Christian Science Monitor, Feb. 17, 1987..
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Primary Examiner: Jablon; Clark A.
Attorney, Agent or Firm: Schroeder, Davis & Orliss
Parent Case Text
This application is a continuation of Ser. No. 526,464, filed Aug.
25, 1983 and now abandoned.
Claims
I claim:
1. A video game system providing repeated switching of multiple
tracks of different actions of the same animated character
according to the skill of the operator in contacting the
camera-originated animation display, comprising:
multiple tracks of animated motion picture production of different
actions of the same character providing coded frames for track
switching and coded location coordinates of said character
target,
a video-audio input terminal providing means to operate multiple
tracks of animation, providing for the switching thereof during
operation, and providing for film track selection, masking, and
centering to the full raster,
a player input terminal including a playing instrument deployed
before the display with a transducer and a microphone combination
mounted on the mutually perpendicular sides of the face of said
monitor, providing means for producing digital signals
representative of the two coordinates of the location of said
playing instrument with respect to the image on said monitor,
means of entering a table of values representing digital
coordinates of the locations of animation targets per frame and
means for entering episode cueing (cuing) data into memory storage
at the start of the episode,
means of retrieval of said digital coordinates of the location of
said target area at a designated frame from the memory storage,
means of comparing and matching the coodinates of the location of
said playing instrument transducer to the coordinates of the
location of said animated target area retrieved from said memory
storage at a designated frame, to obtain the category of
proximity,
means of processing and dispatching to effect the switching of
multiple tracks of animation to the said video-audio terminal based
on the said determined category of proximity obtained by the
comparison of the location of said playing instrument transducer to
animated target area and frame cueing from said memory storage,
continuing means of processing and dispatching for instructing said
video-audio terminal to re-wind multiple tracks of animation to
another episode determined by means of random choice or player
input at the termination of an episode.
2. Apparatus as set forth in claim 1 as a primary circuit, and a
secondary circuit providing digital animation, digital graphics and
audio scoring the game and related to the game-originated animation
and player's actions, and controlling the progress of both primary
and secondary circuits, comprising:
a second player input terminal providing means of system control
for the said means of processing and dispatching,
permanent memory means providing a mass storage of digital graphics
image data for a means to generate cartoon graphics for a video
monitor display,
said means of retrieval retrieving said digital graphics image data
from said permanent memory means for storage in a random access
memory means,
said permanent memory .Iadd.means .Iaddend.providing storage of
control data including cue commands, said cue commands comprising
schedule commands for said processing and dispatching means,
said means of retrieval retrieving said control data from said
permanent memory means for storage in said random access memory
means, said permanent memory means storing audio and/or graphics
data for a random access memory of object video staging,
said means of retrieval retrieving said audio and/or graphics data
from said permanent memory means for said random access memory of
object video staging,
said processing and dispatching means controlling the course of the
digital animation,
a cue table memory means for storing cue commands from said
processing and dispatching means,
a cueing unit repeatedly scanning said cue table memory means to
get said cue commands, and to execute said cue commands,
said processing and dispatching means requesting successive blocks
of control information from said means of retrieval for operations
scheduling instructions for storage in said cue table memory means
for use by said cueing unit.Iadd., .Iaddend..[.-.]. said processing
and dispatching means repeatedly updating said operations
scheduling instructions as the cartoon progresses,
said cueing unit executing cue commands at the times therein
specified by conveying to the said means to generate cartoon
graphics blocks of binary coded data from said means of retrieval
from storage in said random-access memory of video staging, to
generate cartoon frames for display on said video monitor,
program memory cartridge means for providing individual game data
to reinforce said audio and/or graphics data stored in said
random-access memory of object video staging,
said means of retrieval obtaining digital audio data from said
permanent memory means for said randon-access memory of object
video staging, to be sent to a means of converting digital data to
analog form, and hence to a system speaker,
said processing and dispatching means controlling progress of the
game involving said primary and secondary circuits using data from
said program memory cartridge means, said permanent memory means
obtained through said means of retrieval and said cueing unit, said
means of processing and dispatching ordering said control
information of the game for the primary circuit to be sent from
said cueing unit to the video-audio input terminal.
3. Apparatus as set forth in claim 2 utilizing the video system and
monitor circuits to measure the playing instrument action and
position, comprising:
means providing the playing instrument position determination by
analysis of the video monitor display's cathode ray beam sweep
circuits or other display drive circuits using a pulse signal from
a light detector at the playing instrument position, and pulse time
to determine the position of the sweep and thereby define the
relative relationship of the playing instrument within the
image.
4. Apparatus as set forth in claim 2 utilizing the circuits of the
video monitor to effect a strobe or cursor and to measure their
coordinates of scene field location, comprising:
means created by both the height N/S and the width E/W movement of
the playing instrument activating respective circuits creating and
controlling movements of a strobe or cursor aimed at the animation
target position, and activating analysis providing a digital
readout of the cursor/strobe position for comparison to the
coordinates of the position of the animation target, and embodiment
of a rifle mounted in an adjustable socket joint activating said
N/S and E/W circuits to effect a strobe or cursor at the position
on the image of the video monitor corresponding to the position
aimed at by the rifle.
5. Apparatus as set forth in claim 2 including means enabling the
player to operate a second playing instrument in a simulation of an
athletic game, and repeatedly hit designated mid-air projected
positions of displayed foreshortened perspective animated actions,
and effect returns of said animated actions to the video
monitor,
wherein said player input terminal includes the second playing
instrument containing a transducer, a configuration of single-point
microphones before the face of a television monitor, and providing
means for producing digital signals representative of the
coordinates of the mid-air location of said playing instrument
transducer with respect to the said microphone positions,
wherein said means of entering a table of values enters the mid-air
location.Iadd., .Iaddend.
and wherein said means of retrieval retrieves the mid-air
location,
and wherein said means of comparing and matching compares and
matches the mid-air location.
6. Apparatus as set forth in claim 5 including means providing a
video game based on the speed of the playing instrument and the
resulting effect of such speed measurements in the displayed
animation action, comprising:
said player input terminal including the second playing instrument
containing a transducer controlled to send out pulses at fixed time
intervals, and one or more microphones arranged to permit
measurements of the components of playing instrument motion,
means of measuring the frequency of received pulses from said
playing instrument transducer by said microphone and by other
microphone installations, to provide means for determining the
Doppler Effect, and thus determining the velocity of said playing
instrument,
means to combine the velocity and mid-air location to improve the
information used by the system logic for track switching and
scoring.
7. Apparatus as set forth in claim 5 providing a portable playing
instrument,
wherein said player input terminal includes a portable playing
instrument containing a power source, a controlled time base, a
pulse generator synchronized by the time base, and an ultrasonic
transducer.
8. Apparatus as set forth in claim 7 providing means for a game
during which the player constantly attempts to evade mid-air
projected foreshortened perspective animation action,
wherein said player input terminal includes two portable transducer
units, one as a playing instrument component, and the other
attached to the player,
wherein said means for producing digital signals representative of
the coordinates produces signals of the location of each of two
portable transducer units with respect to a configuration of
microphones.
9. Apparatus as set forth in claim 7 incorporating alternate means
of viedo-audio recording and display, comprising:
means to utilize motion picture recording for large screen
projection,
and means to utilize video recording of pictures as images and/or
digital representations. .Iadd.
10. An interactive video game system comprising:
moveable user input means disposed in front of a display, means
said moveable user input means manipulable by a user and including
transmitter means for generating and transmitting position signals
representative of the location of said moveable user input means
with respect to said display means;
storage means for storing and playing back data representing a
plurality of randomly selectable action sequences of visual images,
said storage means including storage media for storing said data in
multiple tracks, each said action sequence comprising at least one
coded frame representative of said visual images, each said coded
frame including coded location coordinates associated with said
visual images, said storage means responsive to selection signals
for switching between said multiple tracks for selection and play
back of action sequences for display;
said display means coupled to said storage means for displaying
selected ones of said plurality of action sequences;
memory means for storing a table of values, said values
representing digital coordinates corresponding to said coded
location coordinates of said coded frames in a selected action
sequence, said table of values entered in said memory means at the
commencement of display of a selected action sequence;
control means coupled to said storage means, said display means and
said memory means, including receiving means for receiving said
transmitted position signals, said control means for determining
the position of said moveable user input means and comparing said
position to said digital coordinates associated with a selected
visual image of a currently displayed action sequence for
determining the position of said moveable user input means with
respect to the position of at least one currently displayed
selected visual image, said control means responsive to said
moveable user input means respective position for selecting a next
successive one of said plurality of action sequences for display.
.Iaddend. .Iadd.11. An interactive video game system as in claim 10
wherein said transmitter means comprises a transducer and a signal
generator, said signal generator generating said position signal,
said position signal being radiated by said transducer. .Iaddend.
.Iadd.12. An interactive video game system as in claim 11 wherein
said transducer comprises an ultrasonic transducer and said signal
generator comprises a pulse generator for generating an ultrasonic
pulse signal, said ultrasonic transducer radiating a repetitive
ultrasonic pulse signal. .Iaddend. .Iadd.13. An interactive video
game system as in claim 12 wherein said receiving means comprises
at least two transducers, said transducers disposed on said display
means in spaced-apart relationship adjacent said displayed action
sequences, each of said transducers receiving said transmitted
position signal and providing location signals indicative of said
moveable user input means position with respect to said
transducers.
.Iaddend. .Iadd.14. An interactive video game system as in claim 13
wherein said moveable user input means comprises a player
instrument allowing a user to contact a display screen of said
display means indicating a user response to a currently displayed
action sequence, said player instrument coupled to said control
means. .Iaddend. .Iadd.15. An interactive video game system as in
claim 14 wherein said player instrument includes switch means
disposed at a contact tip thereof, said switch means providing a
signal indicating when said contact tip is in
touch contact with said display screen. .Iaddend. .Iadd.16. An
interactive video game system as in claim 12 wherein said receiving
means comprises a plurality of transducers disposed in spaced
apart-position, each of said transducers receiving said transmitted
position signal and providing location signal indicative of said
moveable user input means position with respect to said
transducers. .Iaddend. .Iadd.17. An interactive video game system
as in claim 16 wherein at least one of said plurality of
transducers is mounted on said display means adjacent said
displayed action sequences. .Iaddend. .Iadd.18. An interactive
video game system as in claim 16 wherein said moveable user input
means comprises a player instrument adapted for user movement
responsive to said currently displayed action sequence. .Iaddend.
.Iadd.19. An interactive video game system as in claim 18 wherein
said player instrument comprises a baseball bat, said baseball bat
including a transducer disposed at a predetermined impact point,
said baseball bat further including a pulse generator coupled to
said transducer, said transducer radiating a repetitive pulse
signal, said receiving transducers receiving said repetitive pulse
signal and providing location signals indicative of the position of
said impact point with respect to said receiving transducers.
.Iaddend. .Iadd.20. An interactive video game system as in claim 19
wherein said baseball bat is coupled to said control means, said
baseball bat adapted for swinging motion provided by a user
responsive to said currently displayed action sequence, said
selected visual image comprising a pitched baseball, said
controller means selecting a next successive one of said action
sequences for display by said display means in response to said
impact point position with respect to said pitched baseball image
at a predetermined
point in space during the swing of said baseball bat. .Iaddend.
.Iadd.21. An interactive video game system as in claim 10 wherein
said control means includes selection means responsive to a user
input for selecting a desired action sequence to be displayed
following the conclusion of a current play episode, said play
episode comprising at least one of said plurality of action
sequences. .Iaddend. .Iadd.22. An interactive video game system as
in claim 10 wherein said control means includes random selection
means for randomly selecting a next action sequence to be displayed
following the conclusion of a current play episode, said play
episode comprising at least one of said plurality of action
sequences. .Iaddend. .Iadd.23. An interactive video game system as
in claim 10 wherein said randomly selectable action sequences of
visual images comprise prerecorded animated motion picture
segments, each said segment comprising coded frames of visual
images for track switching, said segments stored in multiple tracks
of said storage media. .Iaddend. .Iadd.24. An interactive video
game system as in claim 23 wherein said motion picture segments are
arranged in related groups forming game episodes, each of said
groups comprising at least one of said motion picture elements,
said game episodes stored on multiple tracks on video tape media.
.Iaddend. .Iadd.25. An interactive video game system as in claim 24
wherein said storage means includes tape reading means coupled to
said control means for reading said video tape media for display
and rewinding said video tape, said tape reading means responsive
to control signals generated by said control means for rewinds of
said videotape to play selected motion picture segments or game
episodes. .Iaddend.
.Iadd. An interactive video game system as in claim 25 wherein said
control means generates said control signals providing for random
selection of a game episode to be displayed at the conclusion of a
currently displayed game episode in accordance with a random number
device. .Iaddend. .Iadd.27. An interactive video game system as in
claim 25 wherein said control means generates said control signals
for selection of a desired game episode in response to a user
input. .Iaddend. .Iadd.28. An interactive video game system as in
claim 23 wherein said storage media comprises a video disc.
.Iaddend. .Iadd.29. An interactive video game system as in claim 10
wherein said randomly selectable action sequences of visual images
includes camera-originated animated motion picture segments and
computer generated graphics. .Iaddend. .Iadd.30. An interactive
video game system as in claim 29 wherein said randomly selectable
action sequences of visual images are stored in digital form in a
read-only-memory means. .Iaddend. .Iadd.31. An interactive video
game system as in claim 30 wherein said read-only-memory means
comprises a
plug-in game cartridge. .Iaddend. .Iadd.32. A method of simulating
an active game in which a player participates comprising the steps
of:
storing data in coded frames on multiple tracks defined in storage
media, said data representing a plurality of randomly selectable
action sequences of visual images;
assigning coded location coordinates of selected visual images
associated with each said coded frame;
storing a table of values, said values representing digital
coordinates corresponding to said coded location coordinates of
said selected visual images;
displaying selected ones of said plurality of action sequences on a
display means, said display means for displaying selected ones of
said plurality of action sequences, said table of values entered in
a memory means at the commencement of display of a selected action
sequence;
providing a moveable input means disposed in front of said display
means, said moveable input means adapted for user manipulation for
generating position signals representative of the location of said
moveable input means in response to a currently displayed action
sequence;
generating and transmitting position signals representing the
position of said moveable input means;
receiving said transmitted position signals;
comparing the position of said moveable input means with said
digital coordinates associated with at least one of said visual
images to determine the position of said moveable input means with
respect to the position of a currently displayed selected visual
image;
selecting a next successive one of said action sequences for
display by said display means in response to the location of said
moveable input means with respect to said currently displayed
selected image; and
switching between said multiple tracks for selection and display of
said next successive action sequence. .Iaddend. .Iadd.33. The
method of claim 32 including the additional steps of:
forming game episodes comprising at least one of said plurality of
action sequences; and
randomly selecting a next successive game sequence to be displayed
at the conclusion of a currently displayed game sequence in
accordance with a random number generator. .Iaddend.
Description
BACKGROUND OF THE INVENTION
The present invention pertains to an animated cartoon method
incorporating a method of motion picture branching as controlled
with human skill. The action of the user switches the display to
make the picture respond interactively. A plurality of means for
such action are specified in this invention. The preferred means
for embodiment herewith described is ultrasonic position detection
or simulation. The system matches readouts from an ultrasonic
transducer and microphone combination placed on the face of a
television monitor, or at angles to the user's game action, and
from digitally coded data on a videotape, disc, or film, all in the
context of a video game or educational system.
Prior-art video game devices enable players to control video images
via buttons, knobs, and control sticks or wheels. These operating
devices exercise limited finger movements and in no way simulate
the actions and skills required of the player in the real-life
games simulated by the video games.
Prior art systems are unable to allow the player to strike,
throw-at, hit, or shoot a gun at the television monitor and hit a
moving animated character or object and change the action multiple
times at frictional to several second intervals in the course of an
animated scene according to accurate drama and according to the
skill of the player or operator in so doing.
Prior art systems are unable to allow the user to swing a baseball
bat, tennis racket, or other game instrument interactively in
accord with the projected perspective of the animated scene, in
front of the television monitor, and thus hit or change animated
projectory according to a game or dramatics.
Another problem endemic to the prior art systems with digitally
produced animation is the confined and restricted graphics which
coincide with needlepoint art in the large grid squares. Primarily
two dimensional, such digital animation is inferior to the
camera-originated and the computor type animation of theatrical
productions. Accordingly, it is the object of this invention to
afford the three dimension effectiveness of the camera-originated
type animation to video game grapics which are controlled by the
player.
Prior art video branching system use apparatus that switches
between two or more channels or picture quadrants on the conclusion
of a scene or dramatic action. Such switching depends on the
viewer's judgement as expressed by pushing, buttons, other
restricted video game controls, or a voice response as in the
embodiment of U.S. Pat. No. 4,305,131 issued to Best. The result of
such switching or branching is the beginning of another scene,
episode, or game action. Different type actions can be animated in
a transition number of frames into a common matching drawing that
affords multiple branching, but these converging actions terminate
the multiple different actions, and result in multiple beginnings
of actions.
Accordingly, it is the object of this invention to provide an
animation method that affords rapid and repeated switching from and
to continuously radically different types of action smoothly,
logically, and according to the dramatics.
Another object is to simulate the exact playing action, requiring
the player to exercise the same muscular coordination, eye-hand
coordination, and kinesthetic skills of the real-life game or
dramatic action.
Other objectives are to create a camera-originated three
dimensional visual game simulation of the view from a player's eyes
that approaches reality; and to accompany the foregoing with the
audio voices of umpires, spectators, and scorekeepers together with
the sound effects of the operator's and the animated player's
action.
SUMMARY OF THE INVENTION
The foregoing objects and others are achieved in accordance with
the principles of this invention by an ultrasonic transducer and
microphone combination that produces a signal which is responsive
to the placement of the head of the invention playing instrument on
a plastic shield which is over the face of the television monitor.
This signal is converted to digital form and compared to a digital
readout from the coded motion picture frame of the animated object
location and displayed at the time of the instrument contact. This
comparison is used to determine a specific alternate track and a
switch by the multiple track video apparatus to that track, or to
determine that the player had missed and the animation should
continue on the same track.
In one embodiment a playing missile such as a ball or dart is cast
by the player at the face of the television monitor. A point
microphone combination placed on the monitor face and and below on
both sides of the path of the thrown missile are responsive to an
ultrasonic transducer in the missile, and produce digital signals
which measure the path of the missile, the speed, and the contact.
A readout of this contact digital position is compared to the
digitally coded animation.
Three or more point microphones are placed on the monitor face and
below a baseball batter, or a tennis player, as a configuration
similar in use to a home plate or a base position. The playing
instrument, bat, or racket contains an ultrasonic transducer at the
simulated ball-contact point. As the player swings the instrument
at the animated illusion of an approaching ball, the angles and
distances between the transducer and microphone are measured in
respect to the passage of the transducer over the simulated
home-plate playing and hitting area. The resulting digitally
determined mid-air position is compared to the coded animation as a
projected position in front of the television where the animated
ball illusion would travel if it were reality, and where the player
would hit the ball. The speed of the player's swing may also be
measured from the microphone readout, and this factor may effect
the animated ball return in the event of a hit ball. In the event
of a hit or a coincidence of the digital numbers during comparison,
the proximity of the exact coincidence, and the angle of
coincidence may effect the swinging and resulting ball return
action.
Other methods are described that allow the action or the voice of
the user to switch the display to make the animated picture respond
interactively.
The animation method of the invention applies to multiple tracks of
operating animation and the switching thereof. Rapid and multiple
switching may occur in the course of a scene of only several
seconds duration without effecting the followthrough and smooth
action of the animation drawing progression or the illusion of
reality. This is accomplished by a method of forced relating and
joining interwoven, parallel, and converging animation paths and
thus affording switching, back and forth, at close intervals, and
by a method of delayed switching to compensate for animated
illusion factors or dramatic factors simulating nature.
The system consists of a plurality of game or educational episodes
of a minute or more duration and that allow a plurality of
switching points.- as a tennis volley or a player at bat during a
baseball game. On the conclusion of each of these camera-originated
animated film episodes, the system switches to a circuit of
digitally produced animation displaying scenes that score or
supplement the video game or educational system. During this period
a random number device may select one of the sixty to a hundred
episodes of animation--in the preferred embodiment--and a rewind to
the selected episode is effected. Thus the system of multiple
scenes interactively switched by the action of the user and
multiple episodes that may be determined by random choice, user
action, or user choice creates such a complexity of graphic pattern
and dramatic odds that the uncertainties of reality are simulated
although the animation is pre-photographed, prerecorded, and
programmed.
The preferred embodiment of the invention incorporates a single
track that carries the audio and picture combination of four
different animation actions which in the absence of other
processing would be displayed one in each quarant of the television
tube. The system incorporates blanking circuitry which eliminates
video signals from all but one quadrant and circuitry that selects
this television action in one quadrant and then centers and expands
the picture to occupy the entire raster of the tube. The concept is
detailed in U.S. Pat. No. 3,837,003. The audio in U.S. Pat. No.
3,845,498.
DESCRIPTION OF THE DRAWING
The invention will be more fully comprehended from the following
detailed description and accompanying drawing in which:
FIG. 1 is a schematic block diagram showing one embodiment of the
invention using a video-tape and a video-tape reader for the
primary circuit and a secondary circuit of digitally produced
animation for scoring and diagram scenes.
FIG. 2 is a schematic block diagram of an alternate section of FIG.
1. The method incorporates three single-point microphones placed in
a triangular pyramid configuration before the television monitor as
illustrated in FIG. 3. The microphones measure the distance from a
mid-air transducer inside a swinging playing instrument. The
digital coordinates of the mid-air ball hit position are compared
to the coordinates of a projected position of the perspective in
the animation action displayed.
FIG. 3 illustrates the placement of the single-point microphones in
a triangular pyramid configuration with the playing instrument
transducer before the tlevision monitor.
FIG. 4 diagrams ultrasonic transponder transmission of pulse waves
to a single-point receiver.
FIG. 5 diagrams pulses transmitted and received.
FIG. 6 diagrams transmitted and received pulses graphically
explaining the Doppler Effect.
FIG. 7 is an illustration of a rifle version of a video game
Joy-Stick instrument used to control a cursor.
FIG. 8 is a schematic diagram of an alternate section of FIG. 1
incorporating the Joy-Stick rifle as a rheostat determining the
strobe position on the television monitor. The coordinates of the
strobe position are compared to animation position coordinates as
diagrammed in FIG. 1.
FIG. 9 is a cross section diagram of a playing instrument, light
pen, or other embodiment incorporating a photo cell or diode light
measurement.
FIG. 10 is a schematic block diagram of an alternate section of
FIG. 1. A light pen or other embodiment of this light measurement
device incorporates the diagrammed circuitry to establish player
determined position coordinates which are compared to coded
animation coordinates.
FIG. 11(a) and 11(b) are illustrations of animated walk and run
cycles. The primary path of character action is shown. The
illustration of the run cycle reveals a wider action in the path of
the character drawings.
FIG. 12 is a diagram of a path of action for a character running or
walking in a stationary position on a moving pan background.
FIG. 13 is a diagram of four different character paths of action
all moving on a pan background, and all incorporating a coincidence
at the lift drawings in these cycles of the same animated cartoon
character.
FIG. 14 is a diagram of four different paths of action, all moving
in a stationary position on a moving pan background, and all
incorporating the coincidence of a forced drawing at a universal
position in the sinking action of the cycles.
FIG. 15 diagrams an angular reversal of action, a widely spaced
fast action progression of animated drawings, and a circular
reversal in the path of action.
FIG. 16 diagrams a point of parallel between two different
animation actions and an intersection of paths of actions that are
moving in the same general direction.
FIG. 17 diagrams four converging circular reversal actions at a
drawing with forced details designed to fit all four actions and
serve as a switching point.
FIG. 18 diagrams four animated actions converging at the point of
angular reversal in a drawing with forced details designed to fit
all four actions.
FIG. 19 diagrams a switching point of the invention animation
method incorporating a circular reversal, a parallel action, and an
angular reversal of animated action.
FIG. 20 diagrams three different golf swing actions that coincide
according to the forced drawing method at the point of golf ball
contact, loss of silhouette definition, and widely spaced fast
action.
FIG. 21 is a schematic diagram of an embodiment of the animation
method that schedules an episode single scene of an attack against
the player by a dragon, monster, tiger, bear, cave man, man from
space, or other dangerous adversary.
FIG. 22 is a schematic diagram of an episode of the animation
method as one embodiment of a tennis game volley.
DETAILED DESCRIPTION
Referring to FIG. 1 there is shown a block diagram of the invention
video amusement system as an embodiment of two different types of
video-game circuits. The primary circuit incorporates
camera-originated motion pictures with audio as supplied by video
tape 11 and video tape player 12. The invention method of animation
switching is incorporated in the animation art and coded in the
track 1. At the completion of a game episode the tape rewinds to
another game episode according to a random number device 20
(psuedo-random number device). During this rewind a secondary
animation circuit displays the scoreboard with the score of the
game and related audio. The secondary circuit incorporates
digitally produced animation. In embodiments the secondary circuit
may supply the audio of audience response, score announcements, and
the video of superimposed scores similar to a DX run on an
animation camera. The secondary circuit embodiment diagrammed in
FIG. 1 is prior art which is described in detail in U.S. Pat. No.
4,305,131 Best. The embodiment diagrammed is incorporated in said
patent of a video game system which affords simulated conversation
and voice orders between the human operator and the apparatus.
Accordingly, the complete apparatus diagrammed in FIG. 1 may be
enlarged to constitute a video game that allows the player to talk
to, and answer questions from the apparatus with verbal response
and orders that effect the course of the animation, and to touch or
otherwise contact the animation picture and effect the course of
the animation, or a combination of both verbal response and player
contact with the televised animated character.
The invention encompasses the multiple combinations and variations
of the specified elements of the invention. For example, the
player's skill or mental choice as indicated by touching or
speaking creates a change in the animation as described herewith.
Hundreds of other scenes may follow that are a continuation of the
player's choice or skill as specifically related to this one
original scene. Instead of a rewind to another scene or episode
that is determined by random number mechanics, as specified in the
preferred embodiment, the player's action or choice may determine
rewinds to another scene or episode. During such rewinds the
secondary circuit displays digital animation scenes as described in
the preferred embodiment; however, the scope and spirit of the
invention encompasses the obvious addition of video disc player or
another tape player to the invention secondary circuit tat would
effect a continuous series of camera-originated animation scenes.
Further, the use of the word "animation" in the present invention
application in no way restricts the obvious scope and spirit of the
invention to hand drawn animated graphics. The invention
encompasses any type of timed or humanly manipulated motion
pictures. Such scope encompasses optically-timed live-action motion
pictures and computor type motion picture graphics.
Referring to FIG. 1, a clear transparent sheet of heavy plastic 7
is installed over the screen 24 of the television monitor 25. The
two strip microphones 8 and 10 are mounted along the mutually
perpendicular edges of the sheet 7 in a position above and at the
side of screen 24. A playing instrument 6 includes a tip 5.
Instrument 6 is connected to a pulse generator 22 which causes the
tip 5 of instrument 6 to produce repetitive ultrasonic pulse
outputs. The ultrasonic pulses can be produced by a ceramic
transducer or high voltage sparking between two electrodes on the
instrument 6. Instrument 6 also includes an internal switch which
indicates whether or not the contact tip 5 is in contact with the
surface of sheet 7.
The two strip microphones 8 and 10 are responsive to the ultrasonic
pulses produced by instrument 6. These microphones 8 and 10, in
conjunction with clock 23, counters 14 and 16, and logic circuitry
21, measure the time for the propagation delay between the
radiation of a pulse at instrument 6 and its arrival at the
respective microphones 8 and 10. Logic circuitry 21 can comprise
circuits well known in the art for combining the outputs from
microphones 8 and 10, pulse generator 22 and clock 23 to control
counters 14 and 16 which count or measure the time delays. Counters
14 and 16 also comprise known electrical circuits. The measured
time delays establish the coordinates of the location of contact
tip 5 on the surface of sheet 7 at the time of any particular pulse
output. The foregoing method of ultrasonic pulse measurement to
establish coordinates of an instrument contact location is prior
art. The application of this ultrasonic method to a television
video recording apparatus using the invention animation switching
method is unique and unknown in the art.
The animator's field position of the vital target point in the
animated character or object is entered by the animator on each
frame of the production exposure sheet that instructs the exposure
of those drawings of animation that detail an object in a position
to be contacted, fired at, shot, hit, touched, or otherwise
effected by the player's action and skill. Such locations per frame
are converted to digital binary coordinates. The motion picture
frames are counted, specified, and used to enter a table of values
holding these object or character positions and vital data on the
tape or disc at the beginning of each episode. All of these numbers
are stored in the circuit R A M 51 of FIG. 1 and retrieved when
applicable to the animation action and video game play. This
process is simpler than recording the data on each frame as it
appears. The frame number is recorded at intervals on the video
tape track 11 and used as a track guide instead of a frame meter
which would create problems in the event of a tape breakage.
Special track coding allows fast rewinds to specific frames located
from track signals. Referring to FIG. 1 (may be FIG. 11) the coded
field positions with frame numbers are stored by player 12 from
tape or disc 11 into R A M 51 at the beginning of each episode.
This table of values in R A M 51 supplies pertinent data to logic
circuitry 17 on time to be compared to the coordinates of the
player's actions and skills as described heretofore in the various
embodiments of position determination.
The comparator circuit 18 of FIG. 1 compares the two field
coordinates derived from the digital readouts of counters 14 and 16
to the two coordinates of the animation target position from logic
circuit 17 and R A M 51.
The comparator 18 instructs the processor circuit 19 if the player
has scored a hit at, or close to, the point of coincidence, giving
the degree or proximity of the hit to the point of coincidence and
the angle of animation progression that will result from an
off-center hit. Based on this data an order for a track switch, if
indicated, is dispatched by processor 19 to video tape player 12
which switches between tracks 1, 2, 3, and 4 based on the program
of the episode and track instruction from program memory cartridge
26, R A M 55, and cueing (cuing) unit 53.
Referring to FIG. 1, the secondary circuit animation and scoreboard
graphics is generated by cartoon graphics generator 57 from digital
data which may be read along with digitalized audio from R O M
memory 27 or other magnetic mass-storage device. Retrieval unit 52
is a conventional peripheral input controller which stores into
memory the digitally coded blocks of information obtained from R O
M memory 27. This information includes control data which retrieval
unit 52 stores into random access memory (R A M) 51 for use by
dispatcher unit 19, and audio and/or graphics data which unit 52
stores into R A M 55 for use by cueing unit 53. The control data
includes cue commands and schedule commands. Cue commands specify
short term operation during an interval of time, while schedule
commands represent longer term points in time, and form chains
which define and relate to alternate (multiple track) schedule.
Dispatcher 19 controls the course of the animated cartoon or
scoreboard audio-video and stores cue commands into cue table 54.
Cueing unit 53 executes the cue commands. Cueing unit 53 repeatedly
scans cue table 54 to get commands telling it what to do and the
time it should done. Dispatcher unit 19 may request successive
blocks of control information from retrieval unit 52 and output
into cue table memory 54 a schedule (called a cue table) of
operations for cueing unit 53. Dispatcher 19 repeatedly updates the
cue table schedule as the cartoon progresses. Dispatcher 19
processes the various optional player input control 29 which may be
input via the conventional video game hand-held instruments and
stores the different player commands into cue table 54.
As described, dispatcher 19 controls the course of the cartoon and
stores cue commands into cue table 54. Cueing unit 53 executes the
cue commands at the times specified therein by conveying to the
cartoon graphics generator circuit 57 blocks of binary-coded data
previously stored into R A M 55 by retrieval unit 52, and these
blocks of data are used by the cartoon graphics generator 57 to
generate cartoon frames which are then displayed on television
monitor 25. Digital audio passes from R O M memory 27 through
retrieval unit 52 to memory 55 to digital to analog converter 56
and hence to system speaker 28. The binary coded data stored into R
A M 55 is reinforced by individual game data supplied by program
memory cartridge 26. The circuits described as components of the
secondary digital animation circuit are known in the prior art.
The primary four track video tape animation circuit of the present
invention, which is diagrammed in FIG. 1, is operated and scheduled
by the processor dispatcher 19 which has control of the course of
the camera-originated animation. The comparator 18 furnishes the
results of the player's action to the processor 19 which instructs
the switching of tracks 1, 2, 3, and 4 with game position to video
tape player 12. At the termination of a game episode either random
number generator 20, player input 29, or instrument 6 placement on
sheet 7 specifies an episode to processor 19 which instructs tape
player 12 of the ewind. The progress of the game comprising both
animation circuits is controlled by processor 19 based on data from
program game memory 26 and R O M memory 27 and the operation of the
secondary circuit retrieval, cueing, and memory circuits as
described above. As ordered by processor 19, this instruction is
sent to tape player 12 by the cueing unit 53.
The invention operates using film, video tape, video disc, or
digital stored and/or generated animation. All of these video
mediums can be coded and adapted to the invention circuits and
apparatus. The embodiment described is video tape.
The motion picture film embodiment of the invention operates using
multiple film tracks of operating film read by multiple heads,
multiple tracks of animation exposed on one motion picture film in
a parallel or alternate exposure, conventional single frame
exposure with each frame carrying a picture combination of four
quadrants, and multiple tracks of such quadrant type film. All of
such film methods may be incorporated in film cassettes. Film
quadrants are masked in projection. Such film is projected on
screens that are related to the microphone installation described.
The large and wide screen projection afforded by film creates a
panoramic animation display that is interactive with the player or
human operator use of large instrument simulations as airplane
cockpits, automobile driving interiors, or various weaponry all of
which move when guided by the player during action requiring a
simulated skill. Simulated audio effects and the use of voice
recognition, command, questions, and animation reaction to such
audio adds to the simulation effect.
In FIG. 1 the digital memory cartridge 26 can be various types of
memory and may be plugged in to change the scenario. And, memory
cartridge 26 may supply the coded animation used by the primary
circuit of the invention.
The video tape embodiment of the invention may operate using
multiple video tape tracks read by multiple heads, multiple video
and audio tracks incorporated in a single tape on a line sharing
basis, or a single track signal that carries a picture quadrant
using a blanking circuit that centers and enlarges the selected
picture, or a combination of the above methods.
An embodiment of ultrasonic position detection FIG. 2 and FIG. 3
incorporates an installation of single-point microphones for the
face 24 of television monitor 25, which is the location of
microphone 8, and to the right and left of center on the floor,
which are the locations of microphones 9 and 10. The circuitry of
counting the microphone reading of pulses is similar to FIG. 1.
FIG. 2 is a block diagram section which replaces the similar
circuits and apparatus of FIG. 1. Using the three triangular
formation variable measurements, 5 to 8, 5 to 9, 5 to 10, a mid-air
location of the hitting point transducer 5 of the swinging bat is
determined and interactively related to the animation--which may be
a baseball pitcher throwing a baseball, in perspective, at the
player. Simulating reality, the player swings the bat 6 or racket
at the oncoming animated ball. As the transducer 5 in the bat
passes a mid-air position over the plate (or triangular microphone
installation) where the perspective projection of the animated ball
(if it were real) would be hit, the proximity to coincidence of
animation code position and player instrument is determined, the
angle between ball code position and bat hit position 5 is
determined, the velocity of the player's bat is measured from the
microphone readout, and the animation reacts accordingly.
In other embodiments of ultrasonic position detection the playing
instrument 6 of FIG. 2 or FIG. 3 may be a portable missile such as
a dart, rubber ball, schuttle-cock, or suction tip arrow that
comprises batteries, electrodes, and switches to effect ultrasonic
pulse output. A switch assembly may be intalled under the sides of
a clear plastic shield over the face 24 of the television monitor
25 of FIG. 3 that would be respective to pressure on the plastic
shield, and thus indicate the point in time of missile contact. The
position of the thrown missile is calculated by three vectors 5-8,
5-9, 5-10 diagrammed in FIG. 2 and FIG. 3. Another embodiment uses
the two strip microphones 8 and 10 of FIG. 1.
Various means of ultrasonic measurement may be used according to
game needs, distances, and vector geometry. FIG. 4 shows an
ultrasonic transponder XMIT 1 which transmits audio waves 2 or
pulses in response to an electrical signal. These are received by
single-point microphone REC 3. FIG. 5 shows these pulses
transmitted in position 4 and received at position 5. To avoid
problems with ambiguity, the transmit pulses must be spaced in time
farther apart than the longest distance of interest to be measured.
A clock or digital counter is set to zero by the transmit pulse and
started up.
When the first part of the received signal arrives the timing is
stopped. The time t.sub.x of 5 can be converted to distance when
the velocity of sound in the medium is used as a scale factor. This
process is simple if it is all in one plane, and if point receivers
and transmitters are used, and there is no reflections. An
additional measurement can be made using the Doppler Effect. Refer
to FIG. 6 position 6. This is the same as FIG. 5 position 4 and
represents the case where the transmitter XMIT is not moving
relative to the receiver REC. If the tranmsmitter XMIT is
controlled to send out pulses at fixed time intervals measured
within the transmitter, the additional Doppler Effect measurement
can be made. In FIG. 6 position 7 the transmitter is moving toward
the receiver and moves the distance X 9 between pulses. Likewise as
in FIG. 6 position 8 where the transmitter is moving away a
distance Y 10 occurs. The Doppler Effect is determined by measuring
the frequency of the received pulses. This measures the velocity of
the transmitter relative to the receiver, and is a factor in
determining the velocity of the transmitter playing instrument.
An embodiment of position detection incorporating a Light Pen is
diagrammed in FIG. 9 and FIG. 10. The Light Pen is so called
because it is used like a pen - but it does not produce any light.
In FIG. 9 a photo cell or diode 80 is enclosed in a case 83. An
opening hole 82 allows light exposure to reach the diode 80 which
is connected by, and signals on, the wire 81. Such device is
incorporated as part of a playing instrument of the invention video
game--or educational system. The Light Pen is held on, or close to,
the face of the TV CRT with the opening 82 lined up parallel to the
face. The detector inside produces a pulse when the cathode ray
beam of the television sweeps past the Light Pen opening 82. The
pulse signal is used to "tell" the system where the Pen 83 is
located by referring the pulse back to the sweep circuits of the TV
system. Referring to FIG. 10, the horizontal position is found by
taking a sample of the sweep voltage at the pulse time, and from
this determining the percent of the sweep or time. The vertical
position of the Pen contact is determined by counting the sweeps to
the contact point on the face of the monitor. The Light Pen device
may be encased in a plurality of forms or playing instruments. One
embodiment similar to a spatula is illustrated in FIG. 9. The
handle holds a limited movement knuckle joint 85. The Light Pen 86
is encased in the extension from the knuckle joint 85 to a contact
surface 87 which may be in multiple shapes including a strung
racket to simulate a badminton racket. Thus the player touches the
television face with the simulated racket to hit and return an
animated schuttle-cock across the net to an animated opponent.
Other embodiments of position detection incorporate known circuits
and devices as those named a Mouse, a Tracking Ball, and a
Joy-Stick. The Tracking Ball and Joy-Stick use the same type of
circuitry as diagrammed in FIG. 8. Such devices control the
movement of a strobe, a cursor, or some other displayed element.
FIG. 7 illustrates a mounted rifle playing instrument which is a
variation of a Joy-Stick. The aiming of the rifle in a socket joint
moves rheostats 2 and 3 as shown in FIG. 8. The voltage readout
effects means which are well known to effect a strobe. Pulling the
trigger of the rifle activates the apparatus. Using this position
orientation as a guide the player reaims the rifle to hit or cover
the animation target and effect the animation via the unique means
of this invention. Other circuitry for the rifle device uses a
simple switch, rather than the voltage readout. The switch turns on
a counter which is shut-off by the player when the strobe spot is
in the desired position. The counter signal can be used to move the
strobe or cursor--and activate means giving a digital readout to
compare to the coded animation position. Combinations of such
strobe position means may be incorporated with the previous devices
described as additions to enhance simulation.
The animation method comprises means of rapid and repeated
switching in multiple possible directions from converging multiple
directions in paths of action, and in this process retaining a
continuity of shape progression that is dramatically believable and
does not violate an illusion of reality while retaining widely
divergent drawing in the key extreme positions between the
different actions and thus retaining the character of each action.
The invention applies this method to a system of multiple switching
positions that may be spaced (timed) as close together as twelve
frames (1/2 second) or longer periods that amount to an entire
scene. A plurality of such switching positions may occur at even
intervals or widely variable intervals during the course of the
animation.
For an understanding of animation technique, the reader is referred
to two art instruction books by the inventor, Preston Blair,
titled: "Animation" No. 26 and "How to ANIMATE Film Cartoons" No.
190 published by Walter Foster Art Books. The examples of an
animated walk and run cycle illustrated in FIGS. 11(a) and FIG.
11(b) are from "Animation" No. 26.
The invention can accommodate the switching at certain times in an
action to make the animation look smooth. At these proper moments
in a movement a degree of forced drawing is introduced to also
accomodate the switching. The types of switching points of the
invention are illustrated in diagrams and drawings in FIGS. 11(a)
through 20.
In FIG. 11(b) the path of action 301 indicates the primary
direction of movement of the character in a walk cycle. Path of
action 300 indicates the wider movement of a run cycle. The paths
of action referred to in this invention are these primary or
principle paths of action of the entire character mass, as
indicated by paths 300 and 301. Secondary paths of action in a
character as the reversing swing of the arms and hands and the
circular lifting and falling of the feet action with other
secondary animation paths may, in certain scenes and staging,
become the primary action of the scene.
An animation character walk or run cycle constitutes two steps or
forward leg actions. The switching points of the invention occur at
points where all converging animations have the uniform right or
left leg action. In FIGS. 11(a) and 11(b) the extremes of action
are the point of foot contact 302-307 and 312-317, the recoil
position 303-308 and 313-318, and the high lift position 305 and
315. The extreme arm and leg positions of the walk 302-307 and run
312-317 have silhouette definition that separates and gives
character to each action, whereas, the method points of silhouette
loss and action convergance are during the upward lift action 304
and 314. The action drawing at these points is forced into a brief
proximity by the invention method for switching purposes. The
method forcing or revision of the action in both side-view cycles
is effected without damaging or causing the two actions to look
like each other. The reason is that the vital silhouettes of the
different looking extremes have not been tampered or altered. In
side-view actions, as here illustrated, switching occurs--and
method forced drawing occurs--at areas of animation wherein
silhouette definition is lost, which is due in this case to the
passing of the arms and legs in action. Other cases of silhouette
loss and opportunity for method forced drawing occur in
foreshortened perspective action. These are actions wherein the
character is progressing directly at, or away from the viewer. An
opportunity for the method forced drawing occurs in most animated
actions. The method is illustrated by different golf swings as
diagrammed in FIG. 20. The wind-ups 338 differ widely in path and
character drawing as do the follow-through actions 337. The method
switching and forced drawing is at the ball contact 336 when
silhouette definition is lost. Position 336 also illustrates
another method switching and forced drawing point in an animated
action. Such points occur at the center of widely spaced or fast
actions. This type of switching point is diagrammed in FIG. 15
position 329. All types of leaps, jumps, dives, or other quick
actions contain such switching and forced drawing points that allow
for the method. The movement of the background effects the pattern
of paths of action. The walk and run cycle becomes circular in the
example diagrammed by FIG. 12 wherein the character progresses in a
stationary area while on a moving pan. The switching method point
of FIG. 12 cycles would thus be at the rising action point 324 or
325. Four such cycles thus converging momentarily for switching in
FIG. 13 incorporate the switching point at the lift 327. Other
types of cycles offer switching according to the method in FIG. 14
at the sinking point 328 of the actions.
The method switching points also occur at points in actions of
momentary uniformity as: parallel actions, circular reversals or
recoils, angular reversals or recoils, various intersections of
actions that are angular and traveling in the same direction
together, a uniform turning of characters, and twirls. Obvious
switching points in animation are also used by the invention as:
from a pose or held position, from a point of brief disappearance
of the characters behind objects, or from brief movement
offstage.
FIG. 15 diagrams the method points in actions of angular reversal
330 and circular reversal 331. Both of these actions occur in
recoils and many other actions. FIG. 18 diagrams four actions into
a common point of angular reversal 334. FIG. 17 diagrams four
circular reversal actions that incorporate method switching at
point 338.
FIG. 16 diagrams a method switching point at an angled intersection
of two actions (moving together) and a third parallel action to the
point of intersection. Thus FIG. 16 shows two switching examples:
during parallel actions, and during actions with angled
intersection.
Combinations of switching patterns are diagrammed in FIG. 19. The
switching point 333 combines two parallel actions with an angular
point of reversal and a circular point of reversal. Accordingly,
the invention method enables many different types of animated
action to be connected by multiple switching points which are of
multiple types in combination.
Each episode of the invention games is diagrammed or planned
according to a schematic schedule. Educational system lessons are
similarly planned.
Referring to FIG. 21, a schematic schedule of an embodiment of a
dragon or monster attack episode diagrams a three dimension
foreshortened action which races forward from the the distant
background directly at the player. The video tape rewinds to one of
a hunded different wild animal attacks determined by random number
mechanics. One of four tracks is selected by random choice 231. In
area 232 the monster advances from the distance reaching the firing
range of the player 235 at which time the frames are coded allowing
a player hit. During the advancing area 233, a hit in a vital area
of the dragon monster will effect a switch of the animation at
track switch 242 to the track four injured action 238 of the
monster. A scheduled delay between firing limit 236 and the track
switch 242 compensates for dramatic and animation factors needed in
certain actions. If the player can hit the injured monster a second
time in the following advance area 234, the injured action track
action is switched to the fatal injury action 239 at switching
point 243. The animated demise of the attacking monster occurs at
demise 243. Thus two hits are required to injure the monster and
fatally wound the beast in two advancing areas. Each demise 244,
245, etc. is a different dramatic end of the monster. If the
player's skill is insufficient to save him from destruction by the
monster he will meet his fate at player demise 241. If the game is
played by two players, the survivor is the winner. If played by two
teams, the surviving team wins--or those still alive. Variations of
this game and schedule incorporate space attack by alien
spaceships, underwater shark attacks, aerial dogfights, or
shoot-outs of western or other styles, etc. In a game in which the
attacker shoots at the player, the vulnerable position of the
player is registered by the player using the instrument position
detection and establishment means of the invention. Such player
position embodiment may incorporate a gun belt with the transducer
5 of FIG. 3 installed in the buckle center.
Referring to FIG. 22 a schematic schedule of a tennis game volley
is diagrammed. The game is played by two players who alternate in
volleys against an animated tennis opponent, and the game is scored
exactly as tennis. At the start of each volley, the video tape
rewinds to one of a hundred different tennis volleys that is
determined by random choice. The volley begins with the random
choice 240 (unevenly weighted) of one of four tracks of the
animated tennis player preparing for the serve 241. On track 1 the
serve is good and the ball animates to the foreground to a position
where the human player hits the ball 245. On track 2 a similar
action occurs with a different action and paths of action. On track
3 the first serve is a fault 242, but the second serve is good and
the and the ball advances in a different path of action to the
player hit positions 245. On track 4 the animated player double
faults 244 and the volley is over. If the human player misses the
ball the volley is over at track switch 248. If the player hits the
ball 245, the track selection 248 and return of the ball is
determined by the accuracy and the related angle of return. Track 1
hits the net in an error and the volley ends. Track 2, 3, and 4
return the ball in different patterns which converge as the
animated character hits the ball at the return hit 246 back to the
following human player hit position 247. The game is played from
the perspective of the eye of a tennis player. The ball is hit from
the distant background and comes forward in perspective to the
player hitting area. As the game moves from side to side to then
tennis court the perspective of the entire court is animated--using
computor type theatrical animation--to simulate reality. Thus the
camera-originated animation includes both the hand-drawn full
character animation and the computor type animation used in science
fiction features.
Many game embodiments may be simulated by the invention animation
and player action. Suspense and dramatic situations place the
player in a simulated danger or in positions requiring skills and
reflex action. Such animation simulates, for example, the three
dimensional visual action confronting the eye of a space traveler,
an explorer attacked by ancient monsters in an unknown land
resembling the pre-historic, an underwater swimmer attacked by huge
sharks, octopuses, torpedos from enemy submarines, and frogmen
denizens of the deep. An eskimo is attached by polar bears and
wolves. On an African Safari rhinos, elephants, and tigers attack
the player. Based on World War I airplanes, an aerial dogfight
casts the player in the cockpit of a plane being attached by
on-coming planes and destroying enemy planes and dirigibles
according to his accuracy with a gun. The clouds of the sky pass by
in the realism of feature type three dimension animation art. The
player serches every mist for the appearance of the devil Red Baron
and his squadron of executioners. Suddenly the sound of enemy
machines guns fill the air as planes attack from every angle. If
all forms of combat the player may use the ultrasonic detection
means of the invention to shoot at attackers, and the ultra sonic
means enable the animated attacker to shoot at or contact the
player - thus ending the game. In these many fantastic adventures
the player is allied and helped by friends. Dolphins help the
player attack huge strange denizons of the deep sea. SUPERMAN,
BATMAN, BUGS BUNNY, THE HULK, WONDER WOMAN, friendly space
creatures, or the likes of DICK TRACY help, talk to the player, ask
the players questions about strategy, and act according to the
player's verbal response as described in the previously referenced
Best ('131) patent. Thus, funny rabbits, wise owls, friendly
racoons, big birds, small mice, giant dragons, and tiny insects may
speak, act, and reason with the player in educational games based
on player action and voice.
PING-PONG, badminton, volleyball, baseball, tennis, skeet-shooting,
and other ball-return games are embodiments. Games as baseball may
use camera-originated animation with diagrammatic digital
animation. Games may be played on diagram scenes displaying playing
boards that use episodes of camera-originated animation to advance
the game play.
Other games of combat incorporate embodiments wherein the player
evades being shot be gunfighters or hit by cavemen throwing stones
by his movement before the face of the television monitor. A
transducer mounted on the player creates a digital readout that may
coincide with digital position of the oncoming bullet or other
animated projectile unless the player is able to move out of the
way--or line of fire.
While the invention has been described with reference to a specific
embodiment it is understood that various modifications, alternate
construction and equivalents may be employed without departing from
the true spirit and scope of the invention.
The invention uses are not restricted to video games, and the uses
of the invention incorporate educational systems with memory
circuits that record and grade the player action and response.
Alternate versions of the circuits dscribed may be used to displace
those specified. Therefore, the above description, circuits
specified, apparatus specified, and graphic diagrams should not be
construed as limiting the scope of the invention.
The invention is the combination of the above methods, circuits,
and apparatus. Such a combination results in a unique operation and
unknown function in prior art, although fractions of such
combination are prior art.
The invention combination is defined by the appended and following
claims.
* * * * *