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Sommaire du brevet 1304810 

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  • lorsque la demande peut être examinée par le public;
  • lorsque le brevet est émis (délivrance).
(12) Brevet: (11) CA 1304810
(21) Numéro de la demande: 1304810
(54) Titre français: APPAREIL VIDEO SIMULATEUR
(54) Titre anglais: VIDEO SIMULATION APPARATUS
Statut: Périmé et au-delà du délai pour l’annulation
Données bibliographiques
Abrégés

Abrégé anglais


ABSTRACT OF THE DISCLOSURE
A video simulation machine creates simulations
of various movements, such as flying or driving. The
machine has an enclosed cockpit containing movement
controls and may be occupied by one or two persons. The
machine can rotate 360° in any direction, thus simulating
movement (simultaneous pitch, roll, and yaw) and
providing the occupant or occupants with the sensations
of both position and respective motion, constant,
acceleration or deceleration. The monitor inside the
cockpit, which displays any given simulated picture,
responds through a computer to the movements of the
machine via simultaneous interaction of visual, and
mechanical motions. The rotating parts of the simulator
are driven by electric motors, which are interactively
controlled by both the operator and the computer.

Revendications

Note : Les revendications sont présentées dans la langue officielle dans laquelle elles ont été soumises.


- 17 -
THE EMBODIMENTS OF THE INVENTION IN WHICH AN
EXCLUSIVE PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS
FOLLOWS:
1. A video simulation apparatus comprising:
a stationary base mounted on a supporting
surface and defining longitudinal and lateral axes, and a
normal axis perpendicular to said longitudinal and
lateral axes;
a rotating base mounted on said stationary base
for rotation during the use of said apparatus;
first mounting means intermediate said
stationary base and said rotating base so as to permit
said rotating base to rotate 360° on said stationary base
about the normal axis;
a master ring mounted on said rotating base;
second mounting means for mounting said master
ring rotatably within and perpendicular to said rotating
base, said second mounting means allowing for 360°
rotation of said master ring about the longitudinal
axis;
a sphere housing received within said master
ring, said sphere housing rotating about the longitudinal
axis of the apparatus via said master ring;
third mounting means for rotatably mounting
said sphere housing within said master ring, said third
mounting means allowing said sphere housing to rotate
360° about the lateral axis;
a cockpit located within said sphere housing,
said cockpit having a video monitor system mounted
therein to provide video graphics to an operator of the
apparatus;
control means operable by the operator of said
apparatus for controlling the movement of said sphere
housing relative to the master ring, movement of the

- 18 -
master ring relative to the rotating base, and movement
of the rotating base relative to the stationary base,
said control means additionally controlling movement of
the video graphics of said video monitor system; and
power supply means for supplying power via said
master ring to said video monitor system and said control
means during 360° rotation about each of said axes.
2. The video simulation apparatus as claimed in
claim 1, further comprising means for returning the
sphere housing to a neutral position after a
predetermined period of time.
3. The video simulation apparatus as claimed in
claim 1 further comprising means for returning the sphere
housing to a neutral position when power for said power
supply means is interrupted.
4. A video simulation apparatus as claimed in
claim 1 wherein said first mounting means comprises a
plurality of base carriage assemblies, said base carriage
assemblies being located within said stationary base and
securing said rotating base to said stationary base while
permitting said rotating base to rotate on said
stationary base about the normal axis; each of said base
carriage assemblies including an upper base frame
supporting a base track;
a lower base frame supporting a pair of wheels,
said wheels being supported in substantially parallel
alignment with one another and being adapted to receive
therebetween said base track; and
a motor to drive one of the wheels mounted on
said lower base frame.
5. The video simulation apparatus as claimed in
claim 4 wherein each of said wheels is affixed to said
lower base frame by an adjustable wheel bracket and one
of said adjustable wheel brackets is mounted to said
lower base frame by a spring assembly.

- 19 -
6. The video simulation apparatus as claimed in
claim 1 wherein said second mounting means comprises a
plurality of master ring carriage assemblies for
rotatably securing said master ring within said rotating
base to allow said master ring to rotate about the
longitudinal axis to provide roll rotation to the sphere
housing.
7. A video simulation apparatus as claimed in
claim 6 wherein the master ring includes a pair of master
ring tracks, and each of said master ring carriage
assemblies includes:
a master ring carriage frame;
a plurality of wheels affixed to said master
ring carriage frame, said wheels being arranged to secure
therebetween said master ring tracks so that said master
ring tracks run substantially parallel to the length of
said master ring carriage frame and one of said pair of
master ring tracks lies on either side of said master
ring carriage frame; and
a motor to drive at least one of the wheels
affixed to the master ring carriage frame.
8. The video simulation apparatus as claimed in
claim 6, wherein the first mounting means comprises a
plurality of base carriage assemblies each of which
includes an upper base frame and a lower base frame; and
each of said master ring carriage frames is secured
within the rotating base by an adjustable position frame
secured to an upper base frame of a base carriage
assembly.
9. The video simulation apparatus as claimed in
claim 1 wherein said third mounting means comprises a
plurality of sphere carriage assemblies, said sphere
carriage assemblies rotatably securing said sphere
housing within the master ring so as to allow said sphere
housing to rotate about the lateral axis of the apparatus

- 20 -
and thereby provide pitch rotation to the sphere housing.
10. The video simulation apparatus as claimed in
claim 9 wherein the sphere housing includes a pair of
sphere tracks, and each of said sphere carriage
assemblies includes:
a sphere carriage frame;
a plurality of wheels affixed to said sphere
carriage frame, said wheels being arranged so as to
secure therebetween said sphere tracks so that said
sphere tracks run substantially parallel to the length of
said sphere carriage frame and one of said pair of sphere
tracks lies on either side of said sphere carriage frame;
and
a motor to drive at least one of the wheels
affixed to the sphere carriage frame.
11. A video simulation apparatus as claimed in
claim 10 wherein the master ring includes a master ring
power/signal rail and the sphere housing includes a
sphere power/signal rail, said apparatus further
comprising an electrical transfer means for contacting
said master ring power/signal rail and said sphere
power/signal rail to transfer power from said master ring
power/signal rail to said sphere power/signal rail, and
to provide power to drive the motors of said sphere
carriage assemblies.
12. A video simulation apparatus as claimed in
claim 10 further comprising tension adjusters mounted on
said sphere carriage frame, said tension adjusters
providing tension between the wheels of said sphere
carriage assembly and said sphere tracks.
13. The video simulation apparatus as claimed in
claim 1, further comprising an ascent/descent means for
raising and lowering the stationary base relative to the
supporting surface.
14. The video simulation apparatus as claimed in

- 21 -
claim 4, further comprising an ascent/descent means for
raising and lowering the stationary base relative to the
supporting surface.
15. The video simulation apparatus as claimed in
claim 14 wherein said ascent/descent means is a vertical
lift assembly affixed to the stationary base and
contacting the supporting surface for raising and
lowering said apparatus with respect to the supporting
surface.
16. The video simulation apparatus as claimed in
claim 15, wherein said vertical lift assembly is affixed
to the lower base frames of the base carriage assemblies.
17. The video simulation apparatus as claimed in
claim 15 wherein said vertical lift assembly is a rack
and pinion mechanism.
18. The video simulation apparatus as claimed in
claim 16 wherein said vertical lift assembly is a rack
and pinion mechanism.
19. A video simulation apparatus comprising:
(a) a stationary base mounted on a supporting
surface and defining longitudinal and lateral axes, and a
normal axis perpendicular to said longitudinal and
lateral axes;
(b) a rotating base mounted for rotation on
said stationary base;
(c) base carriage assemblies located
intermediate and within said stationary base and said
rotating base, said base carriage assemblies rotatably
securing said rotating base to said stationary base, such
that said rotating base is able to rotate 360° about the
normal axis of said apparatus; each of said base carriage
assemblies including an upper base frame which supports a
base track, and a lower base frame which supports sets of
pairs of wheels, each of said wheels being affixed to
said lower base frame by an adjustable wheel bracket, one

- 22 -
of the adjustable wheel brackets being mounted to said
lower base frame by a spring assembly such that the
wheels of each of said pairs of wheels are in substantial
parallel alignment with one another and are adapted to
receive said base track therebetween; each of said base
carriage assemblies also including a pair of motors to
drive at least one of the wheels mounted to said lower
base frame;
(d) a master ring mounted on said rotating
base and comprising a pair of master ring tracks and a
master power/signal rail;
(e) master ring carriage assemblies for
rotatably securing said master ring within said rotating
base such that said master ring is able to rotate 360'
about the longitudinal axis of the apparatus; each of
said master ring carriage assemblies including a master
ring carriage frame, said master ring carriage frame
supporting a plurality of wheels, said wheels being
arranged on said master ring carriage frame so as to
secure therebetween, on either side of said master ring
carriage frame, one of said pair of master ring tracks,
said master ring tracks running substantially parallel to
the length of said master ring carriage frame; and each
of said master ring carriage frames being secured to said
rotating base by an adjustable position frame secured to
the upper base frame of the base carriage assemblies,
each of said master ring carriage assemblies also
including a motor to drive at least one of the wheels
mounted on the master ring carriage frame;
(f) a sphere housing mounted within said
master ring and having mounted thereon a pair of sphere
tracks and a sphere power/signal rail;
(g) sphere carriage assemblies rotatably
securing said sphere housing within said master ring,
such that said sphere housing is able to rotate 360°

- 23 -
about the lateral axis of said apparatus; each of said
sphere carriage assemblies including a sphere carriage
frame supporting a plurality of wheels arranged on either
side of said sphere carriage frame so as to secure
therebetween one of said pair of sphere tracks, said
sphere carriage frame also supporting a motor for driving
at least one of the wheels mounted on said sphere
carriage frame;
(h) a cockpit mounted within said sphere
housing;
(i) a video monitor system mounted within said
cockpit for displaying visual effects of flight; and
(j) control means mounted within said cockpit
and operable by a user for controlling the movement of
said sphere housing relative to the master ring, movement
of the master ring relative to the rotating base, and
movement of the rotating base relative to the stationary
base, said control means including a computer, a joystick
control means and a foot control means.
20. The video simulation apparatus as claimed in
claim 19 further comprising means for providing ascent
and descent movements to said apparatus.
21. The video simulation apparatus as claimed in
claim 20 wherein said means for providing ascent and
descent movements is a vertical lift assembly affixed to
the stationary base of the apparatus and contacting the
supporting surface for raising and lowering said
apparatus with respect to the supporting surface.
22. The video simulation apparatus as claimed in
claim 21, wherein said vertical lift assembly is affixed
to said lower base frames of said base carriage
assemblies.
23. The video simulation apparatus as claimed in
claim 19, further comprising a base power assembly, said
base power assembly comprising:

- 24 -
a base unit located within the stationary
base; a support plate mounted on said base unit; a
power/signal base supported by said support plate;
a spindle anchored to said support plate
and protruding through said power/signal base;
a power/signal probe supported by said
spindle, said power/signal probe being elevated from the
power/signal base by a bushing located on said
power/signal base;
an electrical contact assembly disposed
within said power/signal probe, said electrical contact
assembly contacting said power/signal base via said
bushing; and
a contact guide mounted on said
power/signal probe, said contact guide and said
electrical contact assembly being positioned to contact
the master ring power/signal rail on the master ring.
24. A video simulation apparatus as claimed in
claim 23 further comprising a pair of power/signal busses
located on said power/signal base, said busses being
connected to said base carriage assembly and said
vertical lift assembly, so that said base power assembly
supplies power and computer commands to said base
carriage assembly.
25. The video simulation apparatus as claimed in
claim 19 wherein said joystick control means is linked to
the motors mounted on said sphere carriage assemblies, so
that when said joystick control means is moved toward and
away from the user, impulses from the computer are
conveyed to said motors to drive the wheels of said
sphere carriage assemblies, causing rotation of said
sphere housing about the lateral axis of the apparatus.
26. The video simulation apparatus as claimed in
claim 19 wherein said joystick control means is linked to
the motors mounted on said master ring carriage

- 25 -
assemblies, so that when said joystick control means is
moved to the left and right of the user, impulses from
the computer are conveyed to said motors to drive the
wheels mounted on said master ring carriage assemblies,
causing rotation of said master ring, and consequently of
said sphere housing, about the longitudinal axis of the
apparatus.
27. The video simulation apparatus as claimed in
claim 19 wherein said foot control means is linked to the
motors mounted on said base carriage assemblies, so that
when said foot control means is positioned to the left
and right of vertical by the user, the computer conveys
impulses to said motors to drive the wheels mounted on
said base carriage assemblies, causing rotation of said
rotating base, and consequently of said sphere housing,
about the normal axis.
28. The video simulation apparatus as claimed in
claim 19 further comprising means for generating sounds
of flight, means for generating sounds of weapon firing,
means for flashing instrument panel lights and means for
outputting said generated sounds and visual effects of
flight.
29. The video simulation apparatus as claimed in
claim 19 wherein said video monitor system comprises:
a computer for exerting a program; a main
screen monitor for displaying graphic pictures of the
program supplied by said computer;
a visual screen to supply enlarged pictures
displayed on said main screen monitor to the user;
an information monitor displaying control
instruments to the user; and
a control panel having control knobs which
activate various aspects of the program supplied by the
computer.
30. The video simulation apparatus as claimed in

- 26 -
claim 19 further comprising means for returning the
sphere housing to a neutral position after a
predetermined period of time.
31. The video simulation apparatus as claimed in
claim 19 further comprising means for returning the
sphere housing to a neutral position when power for said
apparatus is interrupted.

Description

Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.


~3(~ D
-- 2
BACKGROUND OF THE INVENTION
This invention relates to a video simulation
apparatus operated by one or more persons seated in a
simulated cockpit of an airplane or other transportation
device and which provides steering and response to
computer generated pictures displayed on the screen of
the video monitor, positioned at the front of the
cockpit. The video simulator contains a computer which
displays pictures via the monitor of flight or other
transportation situations or the like. In response to
the person steering to control the video simulator, the
video simulator can simultaneously rotate 360 in the
directions of pitch, roll, and yaw in addition to ascent
and descent, to provide a sense of realism to the
occupants.
The terms pitch, roll and yaw are aviation
terms which will be used to describe the rotational
directions of the video simulation apparatus. These
terms are defined hereinbelow.
These movements can further be classified as
being made about one or more of three axes of rotation.
These axes are called longitudinal, normal (sometimes
referred to as the vertical axis) and lateral. For the
purpose of describing the rotational movement of the
video simulator, the longitudinal axis runs through the
center of the simulator's cockpit sphere in the direction
fore and aft relative to the seating. The normal or
vertical axis is perpendicular to the longitudinal axis
and extends in a vertical direction when the simulator is
in the level flight mode; the lateral axis is
perpendicular to the longitudinal axis and runs starboard
and port of the seating within the cockpit. Thus, both
the longitudinal lateral axes are referenced to the
cockpit seating although both of these axes will change
35 position as the cockpit seat moves. The normal or

~3S~L~31~
-- 3 ---
vertical axis remains affixed regardless of the cockpit
seat location.
A turning maneuver rotates the simulator about
the normal axis and results in rotation in the yaw
direction. The simulation of climbing and diving
produces rotational movement around the lateral axis
which is also referred to as the pitch axis. Banking
left or right rotates the simulator about the
longitudinal or roll axis.
The present invention has the ability to create
realism to the video simulator machine via the 360
rotational movements of pitch, roll and yaw in addition
to vertical ascent and descent. ~ monitor is positioned
at the front of the cockpit and steerlng devices operated
by one or more persons in response to pictures displayed
on the screen of the monitor, in which the cockpit is
rotated in any of the pitch, roll and yaw movements, as
well as ascent and descent movements, in response to the
movements of the steering devices or computer
interaction. This invention has measures to ensure the
safety of the persons and the surrounding environment.
SUMMARY OF THE INVENTION
The present invention relates to a video
simulation apparatus which is comprised of a stationary
base; a rotating base mounted on the stationary base and
adapted to rotate during the use of the apparatus; first
mounting means intermediate the stationary base and the
rotating base so as to permit the rotating baGe to
rotate 360 on the stationary base about the normal axis;
a master ring mounted rotatably within and perpendicular
to the rotating base by a second mounting means, said
second mounting means being adapted to allow for 360
rotation of said master ring abcut the longitudinal axis
of the apparatus, the master ring being also adapted to
receive a sphere housing which is mounted rotatably

~3~ 0
-- 4 --
within the master ring. The sphere housing is mounted
within the master riny by third mounting means such tha-t
the sphere housing will rotate 360 about the lateral
axis of the video simulation apparatus. The arrangement
of the sphere housing is such that the sphere housing may
also rotate about the longitudinal axis through rotation
of the master ring about the longitudinal axis of the
video simulation apparatus. A cockpit is located within
the sphere housing and has a video monitor system mounted
therein to provide video graphics to the user. Control
means operable by the user of the simulation apparatus is
also provided to control the movement of the sphere
housing and also to control movement of the view of the
video monitor system. A power supply means located
within the stationary base is also provided to supply
power via the master ring to the video monitor systems
and the control means.
The invention further relakes to a video
simulation apparatus comprising:
a) a stationary base mounted on a supporting
surface and defining orthogonal longitudinal, lateral and
normal axes;
b) a rotating base mounted on the stationary base
and adapted to rotate 360 about the normal axis of said
apparatus;
c) a master ring mounted on the rotating base and
adapted to rotate 360 about the longitudinal axis of
said apparatus and to rotatably support a sphere housing
therein;
d) base carriage assemblies located intermediate
and within said stationary base and said rotating base,
said base carriage assembly adapted to rotatably secure
said rotating base to said stationary base such that said
rotating base can rotate 360 about the normal axis of
3~ said apparatus, said base carriage assembly including
~`

3L3~
- 5
upper and lower base frames, said lower base frame
supporting several sets of pairs of wheels, each of said
wheels being affixed to said lower base frame by an
adjustable wheel bracket, one of the adjustable wheel
brackets being mounted to said lower base frame by a
spring assembly such that each of said pair of wheels are
in substantial parallel alignment with one another and
are adapted to receive a base track therebetween, said
base track being secured to said upper base frame, said
base carriage assembly also including a pair of motors,
one each to provide drive to a pair of powered wheels of
said wheels mounted to said lower base frame;
e) master ring carriage assemblies to rotatably
support said master ring within the base of said
apparatus and allow for rotation of said master ring
about the longitudinal axis of each of said carriage
assemblies being comprised of a carriage frame supporting
thereto wheels, said wheels being so arranged on said
carriage frame so as to secure therebetween, on either
side of said carriage frame, one of a pair of master ring
tracks, said master ring tracks running substantially
parallel the length of said carriage frame, each of said
carriage frames being secured to said revolving base by
an adjustable position frame~ said adjustable position
frame also being secured to the upper base frame of said
base carriage assemblies, each of said master ring
carriage assemblies also including a motor to generate
drive to pairs of powered wheels of said wheels mounted
to said carriage frame;
f) sphere carriage assemblies adapted to rotatably
support said sphere housing within said master ring and
allow for rotation of said sphere housing about the
lateral axis of said apparatus, each of said sphere
carriage assemblies comprising a carriage frame, said
carriage frame supporting wheels so arranged on each side
k

~3~4~
.
-- 6 --
of said carriage frame so as to secure therebetween one
of a pair of sphere tracks, said sphere tracks being
secured to said sphere housing, said carriage frame also
supporting a motor, said motor providing drive to a pair
of powered wheels of said wheels located on either s:ide
of said carriage frame;
g) means to supply vertical lift, ascent and
descent to said sphere housing;
h) a video monitor system mounted within a cockpit
located within said sphere housing; and
i) control means operable by the user to control
the movement of said sphere housing said control means
including a compu-ter, a joystick control means and foot
control means.
Further features and advantages of the
invention will be compared to those skilled in the
relevant art from the following description of a
preferred embodiment of the invention read in conjunction
with the appended drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
In drawings which illustrate an embodiment of
the invention;
FIG. 1 is a side view of one preferred
embodiment of the present invention;
FIG. 2 is a front view of that preferred
embodiment;
FIG. 3 is a top view of the preferred
embodiment;
FIG. 4 is a front view in section of the
preferred embodiment;
FIG. 5 is a side view in section of the
preferred embodiment of the invention;
FIG. 6 is a perspective view of the base power
assembly of FIG. 4;
FIG. 7 is sectional view, on the scale of FIG.

:~3~g~8~1~
-- 7
6, which is ta~en a]ong a plane indicated by 7-7 in FIG.
6;
FIG. 8 is a sectional view, along the scale of
FIG. 6, which is taken along a plane indicated by 8-8 in
FIG. 6;
FIG. 9 is a front view of the base carriage
assembly of FIG. 4;
FIG. 10 is a side view of the vertical lift
assembly;
YIG. 11 is a front view of the sphere carriage
assembly of FIG. 4;
FIG. 12 is a front view of the master riny
carriage assembly of FIG. 4;
FIG. 13 is a sectional front view of the
internal units of the video simulator of the present
invention; and
FIG. 14 is a perspective view of the
electrical transfer unit.
DETAILED DESCRIPTION OF THE PRE:FERRED EMBODIMENTS
Referring to the drawings in detail, the video
simulator 9 of this invention includes a sphere housing 3
containing the simulated cockpit of an airplane or other
transport~tion device 80 (see FIG. 5). Referring to
FIGS. 1 and 4, the video simulator 9 is generally
comprised of the following elements:
A. A stationary base 1 has a rotating base 2
mounted on it by way of a pair of base carriage
assemblies 29. The base carriage assemblies attach the
rotating base 2 to the stationary base 1 in such a manner
that the rotating base 2 is able to rotate 360~ about the
normal axis during operation of the video simulator 9,
and thus provides yaw movements.
B. A master ring 4 is mounted rotatably within and
perpendicular to the rotating base 2 by way of a pair of

~L3~41~
-- 8 --
master ring carriage assemblies 5~b. The master ring
carriage assemblies 5~b attach the master ring 4 to the
rotating base 2 in such a manner as to permit the master
ring ~ to rotate 360 about the longitudinal axis of the
apparatus.
C. The sphere housing 3 is adapted to be received
inside the master ring 4. As the master ring rotates
about the longitudinal axis of the video simulator, it
carries the sphere housing 3 with it, thus enabling the
sphere housing to rotate 360D about the longitudinal axis
of the simulator, thereby providing the simulator wlth
roll movements.
D. The sphere housing 3 is rotatably secured
inside the master ring 4 by a pair of sphere carriage
assemblies 54a generally similar in structure to the
master ring carriage assemblies 54b. The sphere carriage
assemblies 54a attach the sphere housing 3 to the master
riny 4 in such a manner as to permit the sphere housing
to rotate 360 about the lateral axis of the simulator,
thereby providing the simulator with pitch movements.
E. A vertical lift assembly 43 is provided to
raise and lower ~he entire simulator 9 With respect to
the external surface 100 on which the simulator rests.
For clarlty, only one vertical lift assembly 43 is
illustrated in FIG. 4, but it is recognized that a
vertical lift assembly will be associated with each base
carriage assembly 29 for raising or lowering the base 1
o~ the simulator 9.
F. A cockpit 80 (FIG. 5) is housed inside the
sphere housing 3. The cockpit 80 contains the seat 93
which is occupied by the user, as well as the visual
screen 83 and the controls ~or operating the simulator.
In greater detail, the sphere 3 is positioned
in the master riny ~ which is in turn positioned in
35 rotating base frame 2. Rotating base frame 2 is

~l3~4~
positioned on base l. Master ring 4 consists of the
master ring track 6 and master ring power/signal rail 7.
Track 26 and power/signal rail 27 are also included on
sphere 3 (see FIG. 3). Entrance into sphere 3 is by two
sliding doors 8 (see FIGS. 2,3). Attached to master ring
4 is the protective cowling 5.
As illustrated in FIG. 4, sphere 3 is mounted
within master ring 4 by sphere carriage assembly 54a and
master ring 4 is mounted within rotating base frame 2 by
master ring carriage assembly 54b. Rotating base frame 2
is positioned on base l by base carriage assembly 29.
The power source for the video simulator is
provided by a wall plug 202 to a step down transformer 68
which transfers llO volts electricity to the power
interrupti.on relay 70. Power is provided from the power
interruption relay 70 to the base power assembly 14. The
power then proceeds through power/signal rail 7 which is
attached to master ring 4 and continues through the
electrical transfer unit 55 (see FIG. ll) to
power/signal rail 27 on sphere 3. From power/signal rail
27, power is then transferred to cockpit 80.
If the electrical power supplied to the video
simulator is interrupted, then the power interruption
relay disengages the main power supply circuit and hooks
up with and receives 12 volt power from the emergency
: battery 69. When power interruption occurs, the video
simulator will automatically return to the normal
starting position and will remai.n there until proper llO
volt electricity is restored.
In the interior of sphere 3 (FIG. 5), the
cockpit 80 is comprised of the following parts: The
computer 81 coordinates with operator controls and thus
provides command signals to control the video graphics
displayed on given monitors, programs, and e~ecutes the
game movements of pitch, roll, and yaw, as well as the

~3~
-- 10 --
vertical ascent and descent. Main screen monitor 82
displays the graphic pictures of the outer regions of the
program. The pictures displayed on the main screen
monitor 82 are projected to the larger visual screen 83.
Information monitor 84 displays airplane or other
transportation control instruments or the like. Control
panel 85 consists of various buttons which activate
various aspects of the computer program.
Foot control 86 controls the yaw movements, and
joystick control 87 controls the pitch and roll
rotations. The centre of gravity compensator 88
automatically positions the sphere in a balanced
position, so as to reduce the wear and tear to the video
simulator parts. Courtesy light ~9 is a constantly lit
12 volt light. Speaker 90 provides simulated sound of
airplane, other transportation device, engine noise, or
the like. Emergency light 91 is a self powered light
which is activated only if there should be a power
interruption. Panel 92 is the housin~ for the control
panel 85, the maln screen monitor 82, the visual screen
83, and the information monitor 84.
Seat 93 is a contoured seat whereby the
occupant positions himself into for the purpose of safety
and comfort. Seat restraint 94 is a safety restraint
which holds the occupant into the seat so as not to be
flopping about when the machine is in operation. The
machine will not operate unless the seat restraint is in
place. Step up transformer 95 converts the 12 volt
electricity back to 110 volts for the purpose of powering
the computer 81 and the main screen monitor 82 and the
information monitor 84. Floor 96 supports various
apparatus mounted thereto and provides footing for the
; user.
With reference to FIGS. 6, 7 and 8, the base
power/signal assembly 14 is located at the center of base
.~
,,~",.~

~3~`~B3L~
1 (see FIG. 4). The electrical contact assembly 17 ancl
contact guide 16 are located on the power/s~gnal probe
15. The power/signal probe 15 is supported by spindle 18
(as shown in FIGS. 7 and 8) and lifted slightly by
bushing 19, which i5 located on power signal base 20 for
the purpose of allowing the electrical contact assembly
17 to make contact on the power/signal base 20. The
spindle 18 is anchored to support plate 22 and protrudes
through power/signal base 20. The adjustable support
plate 22 is positioned on base unit 23. Power buss 21a
receives power and transfers power through power/signal
base 20, then through electrical contact assembly 17 and
into power/signal rail 7. Signal buss 21b, sends
commands from computer 81 (see FIG. 5) to the base
carriage assembly 29 (FIG. 4) and vertical lift assembly
43 (FIGS. 4 and 10).
The base carriage assembly 29, shown in detail
in FIG. 9, is located in base 1 (see FIG. 4). Upper base
frame 30 is the frame for rotating base frame 2.
Attached to upper base frame 30 is track adjuster bracket
32 which holds base track 38. Positioned on the bottom
of base track 6 is powered wheel 33b, and on the top
wheel 33a. These are suitably made from a hard rubber-
like material such as Neoprene (T.M.). Located through
wheels 33a, 33b, is wheel axle 34. Holding wheel axle 34
in wheel 33a, is the adjustable wheel bracket 35b. The
adjustable wheel bracket 35b is attached to lower base
frame 31, and reinforcement plate 37 which are connected
to the stationary base 1. Spring 36 located on
adjustable wheel bracket 35b provides the proper tension
to hold wheel 33a to base track 38. The adjustable wheel
bracket 35a which holds the powered wheel axle 34, and
powered wheel 33b, is attached to lower base frame 31 and
reinforcement plate 37. The base carriage assembly 29
provides the video simulator with the yaw movements.
.~^

- 12 -
As illustrated in FIG. 10, the vertical lift
assembly 43 raises or lowers the entlre simulator 9
relative to the external surface 100. The vertical lift
assembly operates on the rack 45 and pinion 46a, 46b
application. It consists of these parts; the leg 44
attached to the lower base frame 31 of the base carriage
assembly 29 and supported on the external surface lO0,
rack 45, pinion 46a, powered pinion 46b, pinion axle 47
and bushing guides 4~. The vertical lift assembly 43 is
attached to the lower base frame 31 so that relative
movement between the pinions 46a, 46b and the rack 45
raises and lowers the simulator 9 relative to the surface
100. This assembly provides the video simulator with the
ascent and descent movements.
The sphere carriage assemblies 54a as shown in
FIG. ll, are attached to master ring 4 via the tension
adjusters 57. The tension adjusters 57 are attached to
carriage frame 56. Wheels 33a and powered wheel 33b are
adjustable to carriage frame 56. The sphere tracks 26
(see FIG. 11) are parallel with the carriage frame 56 and
are held and driven by wheels 33a and 33b. The
electrical transfer unit 55 contacts between master ring
power/signal rail 7 and sphere power/signal rail 27. The
purpose of the sphere carriage assembly 54a is to provide
stability by holding the sphere 3 into master ring 4 via
the tension adjusters 57 and the sphere track 26
tFIGS. 11,13) as well as provide the pitch rotations.
The master ring carriage assembly 54b,
illustrated in FIG. 12, is attached to the upper base
frame 30, as shown in FIG. 4, via the adjustable position
frame 63. The adjustable position frame 63 is attached
to carriage frame 56. Wheels 33a and powered wheels 33b
are adjustable to carriage frame 56. The master ring
tracks 6 (see FIG. 13), are parallel with carriage frame
56 and are held and driven by wheels 33a and 33b. The

3~3aP48:~
- 13 -
master rin~ 4 is rotated by the master ring carriage
assembly 54b to provide the video simulator with the roll
movements.
FIG. 13 is illustrative of the top view of the
sphere carriage assembly 54a. Wheels 33a and powered
wheels 33b are adjustable to carriage frame 56 by the
tension adjustors 57 (see FIG. 11). Master ring track 6
is parallel with carriage frame 56 and is held and driven
by wheels 33a and 33b. Attached to the inside of
carriage frame 56 is the motor 58 which drives the drive
shafts 60 via the gear boxes 59. The sphere carriage
assembly 54a illustrated in FIG. 11 is similar in
construction to the master ring carriage assembly 54b
illustrated in FIGS. 12 and 13 in that the carriage Erame
56 of the sphere carriage assembly 54a is held and driven
by wheels 33a and 33b against sphere track 26 (see FIG.
11), while the carriage frame 56 of the master ring
carriage assembly 54b is held and driven by wheels 33a
and 33b against the master ring track 6 (see FIG. 13).
The differences between the sphere carriage assemhly 54a
and the master ring carriage assembly 54b are the
following: 1) sphere carriage assembly 54a has the
electrical transfer unit 55 and master ring carriage
assembly 54b does not and 2) master ring carriage
assembly 54b has an adjustable position frame 63, and
sphere carriage assembly 54a has the tension adjusters
57. Reference is made to FIGS. 11, 12.
The motors 58, are synchronized as to provide
accuracy when the video simulator is in motion.
FIG. 14 illustrates the electrical transfer
unit 55. This electrical transfer unit 55 is attached to
the master ring by power/signal rail 7. The power and
command impulses are transferred through the electrical
current wires 61 and proceed through the springs 62 and
to the electrical contact assembly 17. The electrical

~L3~
- 14 -
contact assemblies 17 ali~n with the sphere power/signal
rail 27, (see FIG. 4). The buss 64 provides the motors
58 with power and command impulses from the computer 81.
MODE OF OPERATION
In operation, the Video Simulator 9 is powered
via a wall plug 202. The operator opens the door 8 and
climbs into the eockpit 80. He then positions himself
into the seat 93. The oeeupant then proceeds to fasten
seat restraint 94 to provide safety when seated in the
cockpit 80 in preparation for simulated flight. The
start button located on the control panel 85 is then
pushed to activate the simulator. Once the simulator is
activated the center of gravity compensator 88 positions
itself to provide the video simulator with the balance
needed to reduce wear and tear on the carriage assemblies
54a and 54b. The computer 81 then displays the pictures
of a suitable game program through the main screen
monitor 82 which is projected to the visual screen 83 and
provides attitude information to the simulator. The
information monitor 84 displays various flight
information. The joystick control 87 and the foot
control 86 also become aetivated so as to control the
video simulator movements in flight. The joystick
control 87, when pulled backward, causes the front of the
sphere 3 to ascend and when pushed forward causes said
front of the sphere 3 to descend. These rotational
movements give the occupants the impression of pitch.
The computer 81 responds to the joystick control 87
impulses of forward and backward and sends impulse
commands to the motors 58 which are located in sphere
carriage assemblies 54a. The motors 58 then respond to
the given commands and cause the powered wheels 33b via
the drive shats 60 and gear boxes 59 to rotate the
sphere 3. The joystick control 87 when positioned to the

~3~
- 15 -
left causes the sphere 3 via the master ring 4 to rotate
counterclockwise. The joystick control 87 when
positioned to the right causes the sphere 3 via the
master ring 4 to rotate clockwise. These movements give
the occupants the impression of roll. The computer 81
responds to the joystick control 87 impulses of left and
right and sends command impulses to the motors 58 which
are located in master ring carriage assemblies 54b. The
motors 58, then respond to the given commands and cause
the powered wheels 33b via the drive shafts 60 and gear
boxes 59 to rotate the master ring 4 in the roll
rotations.
The foot control 86 when pushed to the left
causes the rotating base frame 2 to rotate
counterclockwise. When the foot control 86 is pushed to
the right it causes the rotating base frame 2 to rotate
clockwise. These movements give the occupants the
feeling of yaw in an airplane. The computer 81 responds
to these impulses and sends command impulses to the
motors 58 which are located on lower base frame 31 and
then respond to the given commands and cause the powered
wheels 33b via the wheel axle 34 to rotate the rotating
base frame 2 via the base carriage assembly 29.
The vertical lift assembly 43 is occupant
controlled via the computer 81 by given buttons provided
for the occupant. The computer 81 can also control
vertical lift for simulated use in the computer program.
All the said movements which are controlled by
the occupant, via the joystick control 87, foot control
86 and control panel 85 are synchronized with the
computer pictures displayed on the main screen monitor
82. The computer 81 sound synthesizer provides airplane
or other transportation device noises, or the like,
through speakers 90. This enhances the realism of this
machine.

~3~
- 16 -
When the duratlon of the simulation has lapsed,
the video simulator will return to the normal starting
position previously described in FIG. 4.
Various modifications can be made to this
present invention without departiny from the apparent
scope thereof.
.~

Dessin représentatif
Une figure unique qui représente un dessin illustrant l'invention.
États administratifs

2024-08-01 : Dans le cadre de la transition vers les Brevets de nouvelle génération (BNG), la base de données sur les brevets canadiens (BDBC) contient désormais un Historique d'événement plus détaillé, qui reproduit le Journal des événements de notre nouvelle solution interne.

Veuillez noter que les événements débutant par « Inactive : » se réfèrent à des événements qui ne sont plus utilisés dans notre nouvelle solution interne.

Pour une meilleure compréhension de l'état de la demande ou brevet qui figure sur cette page, la rubrique Mise en garde , et les descriptions de Brevet , Historique d'événement , Taxes périodiques et Historique des paiements devraient être consultées.

Historique d'événement

Description Date
Le délai pour l'annulation est expiré 2003-07-07
Lettre envoyée 2002-07-08
Accordé par délivrance 1992-07-07

Historique d'abandonnement

Il n'y a pas d'historique d'abandonnement

Historique des taxes

Type de taxes Anniversaire Échéance Date payée
TM (catégorie 1, 5e anniv.) - petite 1997-07-07 1997-06-30
TM (catégorie 1, 6e anniv.) - petite 1998-07-07 1998-07-07
TM (catégorie 1, 7e anniv.) - petite 1999-07-07 1999-06-28
TM (catégorie 1, 8e anniv.) - petite 2000-07-07 2000-06-28
TM (catégorie 1, 9e anniv.) - petite 2001-07-09 2001-07-04
Titulaires au dossier

Les titulaires actuels et antérieures au dossier sont affichés en ordre alphabétique.

Titulaires actuels au dossier
DARRELL R. NELSON
GREG W. BERG
Titulaires antérieures au dossier
S.O.
Les propriétaires antérieurs qui ne figurent pas dans la liste des « Propriétaires au dossier » apparaîtront dans d'autres documents au dossier.
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Description du
Document 
Date
(aaaa-mm-jj) 
Nombre de pages   Taille de l'image (Ko) 
Revendications 1993-11-02 10 373
Page couverture 1993-11-02 1 12
Dessins 1993-11-02 7 188
Abrégé 1993-11-02 1 21
Description 1993-11-02 15 588
Dessin représentatif 2002-04-23 1 19
Avis concernant la taxe de maintien 2002-08-05 1 177
Avis concernant la taxe de maintien 2002-08-05 1 177
Taxes 1998-07-07 2 84
Taxes 2001-07-04 1 70
Taxes 1997-06-30 1 41
Taxes 1999-06-28 1 114
Taxes 2000-06-28 1 21
Taxes 1996-07-04 3 85
Taxes 1994-07-06 1 47
Taxes 1995-05-19 1 33