Acceleration simulator

Description

BACKGROUND OF THE INVENTION

[0001] 1. Field of the Invention

[0002] The invention pertains to the field of acceleration affect and effect and applies to those areas which utilize this effect for creating a human sensation of such an affect and the use of the actual effect on masses to produce varying processes in manufacturing and entertainment, product evaluation simulation such as a flight simulator, automobile, fun ride, space craft, or space station. Numerous other uses will become known for the effects and affects which are described here.

[0003] 2. Description of the Related Art

[0004] The Inventor is not aware of any relevant art. The other known uses of similar principals are in the simulator used at NASA and centrifuges used in various manufacturing process. Another possible Art may be in Thrill rides such as roller costars and merry-go-rounds.

OBJECTIVES AND ADVANTAGES OF THE INVENTION:

BRIEF DESCRIPTION OF THE DRAWING FIGURES

[0005]
FIG. 1 is an embodiment of the invention which includes a simulated scene inside a room.

[0006]
FIG. 2 is a side view of a simulator room.

[0007]
FIG. 3 is a coordinate system relative to the simulator room.

[0008]
FIG. 4 is a coordinate system rotated relative to the platform.

SUMMARY OF THE INVENTION

[0009] The current invention is a method of producing a virtual reality effect of changing acceleration direction and magnitude by rotating a subject relative to a center axis to produce a centrifugal force, rotating the subject relative to a second axis perpendicular to centrifugal force and rotating the subject relative to a third axis perpendicular to the axis perpendicular to centrifugal force, and changing the magnitude of the centrifugal force. As a consequence the subject will perceive the acceleration upon his center of mass as changing in magnitude and angle. It is further enhanced by projecting a simulated image on a screen which is rotating in the same frame of reference as the subject.

[0010] Elements and Functions

1Table of Element and Numbers#Element DescriptionaAngle made by Simulation Vector S an Z axisASimulation Centrifugal Acceleration VectorA‘Second Simulation Centrifugal Acceleration VectordDistance Between Simulator Room Center of Mass andRoom Counter Mass Center of MassGGravitational Force Vectorr1Angle of Simulator Room Rotationr2Angle of X Axis RotationSSimulator Acceleration Vectorw1Angular Rotation Frequency of PlatformXX axis of Simulation SeatYY axis of Simulation SeatZZ axis of Simulation Seat 10Anchor Base 20Motor 30Motor Shaft 40Rotating Base 50Simulator 1st Angular Orientation Motor 60Simulator Room Motor Shaft 70Simulator Room 80Simulator 2nd Angular Orientation Motor 90aRoom Rotating Support Platform Arm 90bRoom Rotating Support Platform Arm 95Room Rotating Support Platform100aRoom Rotating Axis Arm100bRoom Rotating Axis Arm110Room Counter Balance Mass120Inputs to Computer130Outputs From Computer140Computer (micro-processor)150Counter Mass / Room Screw Adjust160Mass / Room Adjust Motor170Acceleration Seat180Net Simulator Acceleration Vector190Video Screen200Video Screen210Simulator room vertical extender

[0011]

2

Table of Functions, purposes, objectives,

goals, advantages, tasks

Objective, goal,

result or purpose
Solution, operation or function

Produce an acceleration on a
Produce a reference frame relative to

mass within a room which will
rotating frame which will rotate about 2

vary in direction.
curvilinear coordinates

Produce an acceleration on a
Change the angular frequency of

mass within a room which will
rotating base 40 or the center of mass

vary in amplitude.
distance d from the center of the rotat-

ing base or the distance

Change the angular frequency of the

rotating frame or the distance from

the center of the rotating reference

frame.

Produce an acceleration on a
Produce a reference frame relative to

mass which will vary in
rotating frame which will rotate about 2

amplitude and direction.
curvilinear coordinates

Relative to a reference object

40 or the center of mass distance d from

the center of the rotating base or the

distance

Change the angular frequency of the

rotating frame or the distance from the

center of the rotating reference frame.

Produce an acceleration on a

mass within a room which will

vary in amplitude and direction

relative to the room.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0012] In FIG. 1 an acceleration on a mass located in simulator room 70, such as a person setting in acceleration seat 140, is represented by net simulator acceleration vector 180, which varies in magnitude and varies in direction relative to simulator room 70. The variation in magnitude is produced as a consequence of the varying angular rotation w of the rotating base 40. The variation in direction r2 is produced by rotating simulator room support platform 90 relative to rotating base by causing simulator 1st angular orientation motor 50. The variation in direction r1 relative to simulator room 70 is produced by causing simulator 2nd angular orientation motor 80 to rotate simulator room 70 around room rotating axis arms 100a and 100b.

[0013] The variation in magnitude of the simulator vector can also be accomplished by varying the distance d which is distance that the simulator is from the center of rotation around platform motor 20 and the simulator room's center of mass 70. This is accomplished by room screw adjust drive 150.

[0014] In FIG. 2 an acceleration seat 170 is secured to simulator room 70. The simulation video screen 190 projects a simulated event which has an associated simulated acceleration vector S associated with it in time. The simulated event may be a prerecorded on video tape, an animated film or a computer program etc..

[0015] In FIG. 3 a reference frame XYZ is displayed which is rotating relative to some other reference frame. A simulated acceleration vector S is the composite of the gravitational vector G and the centrifugal force vector A i.e., S=A+G.

[0016]
FIG. 4 illustrates the resultant transformation S to S′ if one angle of orientation is changed by angle r1, i.e., the x axis of XYZ is rotated an angle r1 about the z axis. The simulated acceleration vector appears to change directions in the frame XYZ. If a rotation is then produced by rotating an angle r2 around the Z axis of the XYZ frame then an orientation of any angle can be obtained.

[0017] Computer 140 interfaces to the motors and video screens through inputs 120 and outputs 130. A joy stick (not shown) could be interfaced to the computer through inputs 120 and an existing video game could be modified to produce an acceleration vector parameter to be used by the computer to control the simulation acceleration vector S. An acceleration sensor could be interfaced as an input device to provide feed back as to the actual acceleration produced on a mass within the simulator room.

[0018] While my above description contains many specificities, these should not be construed as limitations on the scope of the invention, but rather as an exemplification of one preferred embodiment thereof. Many other variations are possible. The scope of the invention should be determined not by the embodiment(s) illustrated, but by the appended claims and their legal equivalents.

Claims

1. A method of producing an acceleration on a mass which has changing magnitude and direction comprising, rotating a mass relative to a center axis to produce a centrifugal force, rotating the mass relative to a second axis perpendicular to centrifugal force, rotating the mass relative to a third axis perpendicular to the axis perpendicular to centrifugal force, and changing the magnitude of the centrifugal force on the mass.
2. A method of producing a virtual reality effect of changing acceleration direction comprising, rotating a subject relative to a center axis, rotating the subject relative to a second axis perpendicular to centrifugal force, and rotating the subject relative to a third axis perpendicular to the axis perpendicular to centrifugal force.
3. A method of producing a effect of changing acceleration magnitude on a subject comprising, creating a centrifugal force on a subject by rotating the subject relative to a center axis and, changing the magnitude of the centrifugal force sensed by the subject.
4: A machine for creating a changing force direction and magnitude sensed by an object over time comprising: a positioning containment for an object, a centrifugal rotating means for rotating the positioning containment and producing a centrifugal force at the object positioning containment as a function of the rotating and, a rotating orientating positioning means for orientating the positioning containment at a varying angles to the centrifugal force.
5: A machine for creating a changing force magnitude sensed by an object over time comprising: a positioning containment for an object, a means for rotating the positioning containment and producing a centrifugal force at the object positioning containment as a function of the rotating.
6: A machine for creating a changing force direction and magnitude sensed by an object over time comprising: a positioning containment for an object, a means for rotating the positioning containment and producing a centrifugal force at the object positioning containment as a function of the rotation and, a rotating positioning means for orientating the positioning containment at a varying angles to the centrifugal force.

Acceleration simulator

Information

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CPC

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Abstract

Description

Claims