"Antigravity" Method 13 of 15 Gyroscopic Mechanical Electromechanical Inertial Centrifugal Group IV

Antigravity Method 13 of 15 Gyroscopic Mechanical / Electromechanical/ Inertial Impulse, Centrifugal- Group IV
Filmed 1991-1996, 13 of 15 methods of levitating an object known to the author John Iwaszko, edited from the video Antigravity the reality made in 1996. The antigravity method shown in this edit, was introduced and was referred to as Asymmetric Gyroscopic which has now been reclassified by the author as, GYROSCOPIC MECHANICAL /ELECTROMECHANICAL/ Inertial impulse centrifugal (Method 13)
The classification of the antigravity methods I have developed was an attempt to classify according to certain functional, structural properties and methodology of the systems. Whereas the structural properties are largely intrinsic, functional properties and the derived classifications depend to a certain degree on the type of interaction relative to the external environment. Some of the systems mix the various methods, resulting in hierarchies based on structural qualities.
The method I will next describe has been the cause of tremendous controversy amongst learned people and is the only method that can, so far, produce tangible and a measurable artificial gravity. Befitting and Ironic then that this method described coincidently fell in a numerical order of number 13. Perhaps the symbolism that relates to number 13 also relates to this method.
So whats is creating the defying gravity antiques within the box, here it is balancing 130 grams with no counterweight on the opposing lever. It is none other than a gyroscope.
Here we have an elementary experiment, a balanced system, I place an object on a platform, give it a little spin, and behold the object does not topple or fall as I have just created artificial gravity.
This simple method has been utilised in theme parks and unquestionably in future space vehicles and space stations and has been experienced in some form by most people. Centrifugal force represents the effects of inertia that arise in connection with rotation and which are experienced as an outward force away from the centre of rotation and pushes the object towards the platform keeping the little object firmly stable at a constant velocity of rotation. At a certain rate of rotation we can beat gravity. Everyone who has swung any heavy object around themselves has felt the centrifugal force. This 'force' can simulate gravity particularly where there is no solid surface to enable us to feel the forces of gravity. The centrifugal force is in a direction perpendicular to the rotation axis and radically outward. Its magnitude is equal to the square of the angular speed times the distance from the rotation axis. As a result the astronauts in a space station would be able to walk around inside the space station as if the artificial gravity is pulling them outward away from the centre of a toroidal or cylindrical station.
For a space station 15 metres in radius (50 feet) the station must make one revolution about every 8 seconds in order that the astronauts feel 1 g of gravitational acceleration where a persons weight would be the same as that on Earth.





The next experiment shows a motor spinning a steel cable, angular velocity is converted to a linear velocity that lifts the motor up, the weight of the motor is 42 gram, the secret of its operation is now revealed showing that there is a weight on the end of the cable which is 44 grams. A weight whirling in a horizontal plane on the end of a cable clamped to a motor on the ground is continuously changing the direction of its velocity and, therefore, has acceleration toward the tube. This acceleration is equal to the square of its velocity divided by the length of the cable.
According to Newtons second law, acceleration is caused by a force, which in this case is the tension in the cable. If the weight is moving at a constant speed and gravity is neglected, the inward-pointing cable tension is the only force acting on the weight. If the cable breaks, the weight, because of inertia, will keep on going in a straight line tangent to its previous circular path; it does not move in the outward direction as it would if the centrifugal force were real. While centripetal force is a real force,—that is, the force is due to the influence of some object or field—centrifugal force is a fictitious force. A fictitious force is present only when a system is examined from an accelerating frame of reference. If the same system is examined from a non-accelerating frame of reference, all the fictitious forces disappear.