inspiration From Bashar!
So a fellow experimenter named Chuck (who has far more electrical experience and knowledge than I) is also doing some investigation with the Bashar STA. He has not only built a small scale model, but has also started doing measurements through an oscilloscope and is getting working proof of concept results! With a functioning STA, he added a metallic tetrahedron around the STA which seems to improve its ability to receive energy even further.
You can view his youtube channel, morpher44, to view any new videos that have since been posted, but for this blog post, I’ll embed the videos he’s shared with us thus far (at the time of this posting) along with a few comments about what the video is about.
How To Make a Bashar Free Energy Space Time Antenna Health Pen, Part9
Watch All of his videos here!
Video 1) Showing the completed STA
This is his completed STA. He points out that it’s only 9 inches tall, which is well below the minimum height Bashar suggested previously (needs to be able to fit under a 3 foot tall pyramid.. so the STA has to be ~19″ tall), but it’s interesting to see that it still produces results.
Video 2) Slideshow showing the construction of the STA
I find it interesting, not only that he created an internal support structure with a creative split cone, but he also added some removable spikes along the side to guide the wire as it coiled around the support structure.
Video 3) STA used in Joule Thief circuit
He hooked up the STA up to an oscilloscope, showing its usage as a transformer
Video 4) Experiments with Radiant Energy
Using a signal generator and an oscope to find the STA’s self-resonance frequency (~1.229 MHz).
Looking at Tesla’s patent #685,957 to receive radiant energy. Adding a solid flat plate antenna to receive cosmic energy. Adding an AC to DC rectifier.
(There’s about enough energy here to power an apartment for a mouse.. which is one of the jokes about Tesla’s patent.)
Works even without Tesla’s plate. Showing the STA receiving energy.
Video 5) Tetrahedron casing
Building a 3-sided (plus 4th side for the bottom) foam/aluminum tetrahedron casing around the STA, and wiring the two together. Some changes in the output waveform are noticed.
Video 6) Tetrahedron as Capacitor
Fixing the tetrahedron size. Adding a large resistive load to the output.
Putting aluminum foil on both inside and outside of tetrahedron walls to make them capacitive. More output by connecting walls in paralle rather than in series. Creating shielding with the metallic tetrahedron walls.
This device IS producing power on its own, but not much. It’s only producing power in the picowatt to nanowatt range. He wants to do further testing with moving the STA outside so that it’s not affected by the house attenuating incoming energy.
With a plasma ball nearby (so that the STA picks up emitted energy), he can get it into the 1 milliwatt to the 5 milliwatt (1 mW – 5 mW) range.
Video 7) Plasma ball as exciter
he STA/tetrahedron is natively outputting 6 mV and 448 pW.
With the Plasma ball turned on (which emits a bunch of artificial cosmic radiation that can be detected by the STA anywhere in the room), the STA produces much more energy, 30.6V and 9 mW, enough to run LED’s off of.
The closer the plasma ball is to the tetrahedron, the more power the STA gets, and vice versa.
With the plasma ball touching the tetrahedron, the output voltage starts climbing over 60V and he backs off because his caps are limited to 50V.
Video 8 ) Inverse square law
In this video, he starts testing out the inverse square law to measure how much power you get out of either a 12×12″ square plate (control) or his tetrahedron/STA by progressively moving a plasma ball farther away from the aluminum plate(s).
The flat plate works better, given that it’s both larger and not tilted away from the plasma ball, but both of them work.
He gets a linear drop off up until he reaches 12″ of distance away, then it changes and the fall-off lessens until he reaches 20″ of distance away which is when power falloff really drops out.
The STA actually starts to do better at large distances because it has a lot more surface area exposed to the room in every direction. (This is re-addressed and corrected in the follow-up video.
Video 9) Wavelength thought experiment
He addresses the previous plasma ball inverse square law experiment by noting that there are other variables at work in the room such as light bulbs, measuring tapes, and even the person’s metabolism changing.
Doing some tests to find the resonant frequencies and using sound output to help him out, the radio starts transmitting some really funky sounds, which bothers both him and his dog (and me to be honest, watching the video…
Moving the STA out from inside the metallic pyramid definitely reduces the power. Putting it back in the center boosts the energy.
He also poses a question… when energy travels down the copper wire of the cone, does the frequency of the energy change or does the velocity of the energy in the wire change?
Video 10) High voltage ping experiment
In this video, he experiments with pulsing it with high voltage fields and seeing what happens. He’s able to get some echos.
Video 11) Power Curve Experiment
In this video, he sets up the plasma ball at the apparent fuzzy distance between the near field and far field and starts experimenting with a variety of resistive loads, seeing how it affects the output voltage.
He also points out, regarding the antenna design, that the foil tetrahedron is touching the top of the coiled antenna while the bottom of the coiled antenna is wired out to the AC to DC converter.
That’s it for now, up to the date of this posting. You can continue viewing his most recent videos by visiting his youtube channel.
Thanks for all the awesome work Chuck, and for sharing your continued results with us!!
Video 12) Audio Tones from Coil
In this video, he talks about hooking the antenna up to an AC to DC converter and using that to try and charge a 9v rechargeable battery. He also uses a joule thief circuit to excite the antenna and start providing it with power. While charging 9v battery with a 6v battery, he noticed an audio tone being emitted from the center-ish of the STA itself.
Adjusting a potentiometer, he’s able to adjust the frequency of that sound. It’s interesting to note that looking at the sound through a spectrum analyzer, you see a whole collection of harmonics.. basically peaks in the spectrum.
Video 13) Full Scale
In this video, he shares the design specs for a full scale STA. It’s about 2 feet tall (to fit under the 3 ft. tall pyramid), is composed of two 370 ft. lengths of 14 gauge wire, and features 180 turns. He also shows the constructed antenna.
Video 14) LRC Circuit
Using a software circuit simulator, he simulates an electrical pulse into the STA and shows that to maximize the duration of the ringing effect, we want a small resistance, large inductance, and small capacitance.
He also creates a tesla coil spark gap and shows what happens when you connect the STA to it. It basically starts magnifying the output, decreasing the load on the other power source, and making the output more erratic.
Video 15) Give a Little, Get a Little
In this video he does a test to show that if you stimulate the coil with lower power but high voltage, the reception improves.
Video 16) Bigger Plate Antenna
In this video he hooks the STA up to a 10’x20″ flat plate which acts like an external antenna. Hooking the STA up to an oscope, he shows that the antenna is receiving a very very very small amount of power out of the air.
Source: Bashar Space Time Antenna