Part 3. The Experiment

At the heart of the experiment is a device (see Fig. 4) made up of a circular metal plate with two exactly parallel front surface mirrors connected at opposite ends bolted exactly perpendicular to the plate and exactly ten feet apart. There are two small holes drilled at the top and bottom of one of the mirrors. The top hole 1/2 inch diameter, the bottom 1/8th inch diameter. The entire device floats on a contained bed of mercury. The bottom hole is for a pencil laser beam just under 1/8th inch in diameter to pass through generated from a laser connected to the mirror from behind with the beam running nearly exactly perpendicular to the two mirrors. The second and higher hole is for the pencil beam to exit after it has been reflected back and forth ninety eight times or after it has traveled 1000 feet.

Fig. 4

The laser is then calibrated by minutely adjusting it’s angle, first so the beam doesn’t run into itself, second to insure the laser beam exits the top hole cleanly after the right number of reflections. This is done while the line of the beam is parallel to the forward motion of the Earth in it’s orbital line around the Sun

(Fig. 5). The laser is then locked in position.

With the laser turned on the entire device is then slowly rotated on it’s bed of mercury so as not to disturb alignment of the pencil beam. It is rotated clockwise 360 degrees stopping at 3:00, 6:00, 9:00 o’clock, finally returning to 12:00 o’clock (Earth’s forward motion line).

If the beam behaves in the Einsteintinian way, the beam’s trajectory will pay no attention to the motion of the Earth or it’s gravitational field, and will exit the hole cleanly in the 12:00 and 6:00 positions since the hole will still be in-line and parallel even the hole has moved , but miss the hole in the 3:00 and 9:00 positions by approximately an inch as the exit hole will no longer be in-line with the beam’s trajectory in these two perpendicular positions. In the time it takes the laser beam to traverse 1000 feet (about a millionth of a second), Earth will have moved approximately one inch as illustrated in Fig. 6.

Fig.6

If, however, Tovi Sciences is right the beam will exit the hole cleanly in all positions as one of the gravitational forces previously described will either push the beam synchronizing with Earth’s movement or the conduit will be synchronized with Earth’s movement, moving with the light beam in it as illustrated in Fig. 7.

Fig. 7

We will attempt to have this experiment performed at a University with a strong Physics department. If we are given a poor reception we will go outside the establishment to perform it under scientific conditions then publish the results on this web-site.