TRANSVERSE WAVE INTERFERENCE.
On this slide we show the orthodox representation of EM wave interference.

The chart is stylized since we assume two single-frequency EM waves which intersect and interfere in the indicated region.

In the interference zone, in-phase wave amplitudes add (constructive interference) while out-of-phase wave amplitudes subtract (destructive interference). In our stylized mode, we show the zero-summed locations as lines.

Conventionally, these interfering waves are considered to be transverse waves in vacuum.

The point is, in this scheme we think of "putting in the waves of finite amplitude, and creating the zero-amplitude regions by destructive interference." We create additional waves of increased-amplitude regions by constructive interference.

LONGITUDINAL WAVE INTERFERENCE (SCALAR WAVES)
Here we show the same interference situation, only now we think of transmitting scalar EM waves, which we model as longitudinal waves.

Again we assume two single-frequency scalar EM waves which intersect and interfere in the indicated region.

However, to an external observer, each of these waves individually appears to have zero E and H fields, hence to contain zero EM energy. That is, conventionally we seem to be transmitting waves of "pure potential," without any "force field" amplitudes whatsoever. We say we are transmitting waves of "artificial potential," since we deliberately constructed the zero-vector-summation scalar waves in the first place.

In the interference zone, a strange thing now happens. The relative magnitudes of the artificial potential of one wave with respect to the artificial potential of the other depends upon the phase relationship between the two. Further, whether the "gradient" so established appears negative or positive also depends upon the phase relationship between the two.

What results is most interesting: the out-of-phase condition now produces an EM gradient whose sign and magnitude are functions of the location within the interference zone.

Thus one now has real, non-zero EM potential gradients, both electrical and magnetic. And so real EM energy has emerged in an interference pattern within the area.

Ironically, we get essentially what we had before! Only now we have "put in the zero-reference lines, and produced the non-zero gradient (energy) zones."

In other words, we have recreated ordinary EM energy at a distance, directly from the interference of gravitational potential energy (anenergy).

And, to the laboratory observer, there has been no "EM wave" energy flow through the intervening space.

This was Tesla's secret of "wireless transmission of energy to a distance without losses."

Further, in a hypothetically perfect case, the interference represents a sort of "energy bottle."

But now recall our need to take the sign of the scalar current into account. In this energy bottle, then, EM energy emerges and stabilizes -- if and only if our transmitters are at higher reference potential than the ambient interference zone. If our transmitters are biased at lower potential, then energy is extracted from the energy bottle and re-emerges back at the transmitters, where it must be extracted and disposed of, if the transmitters are not to be burned out.

CREATING ENERGY AT A DISTANCE.
A most useful device is obtained if one uses a scalar interferometer where the two transmitters transmit beams which intersect at a distance.

In the interference zone, an energy bottle is created.

By biasing the transmitter reference potentials well above that of the distant energy bottle, EM energy emerges in that zone. In that case the interferometer is operating in the exothermic mode.

By biasing the transmitter reference potentials well below that of the distant energy bottle, EM energy is extracted from the distant zone and emerges from the transmitter. In that case the interferometer is operating in the endothermic mode.

If the transmitters transmit continuously, the effect in the distant zone is continuous

If each transmitter transmits a pulse, and the two pulses meet in the distant intersection zone, then an explosive emergence or extraction of energy occurs at the distant interference zone, depending upon whether the interferometer is operating in the exothermic or the endothermic mode.

That concludes our discussion on resonance. In our next class, we'll explore the various modes of scalar interferometry.

This has been
Scalar Interferometer Part 4
Material based on T. Bearden, Fer de Lance
Understanding the basics of electromagnetism

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Part 4
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Part 3
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Part 2
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Part 1
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Part 5 coming soon
That concludes our discussion on resonance. In our next class, we'll explore the various modes of scalar interferometry.

.

Scalar Interferometer Part 5
Material based on T. Bearden, Fer de Lance
Military Applications

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EXOTHERMIC MODE (SCALAR INTERFEROMETER).
In a scalar interferometer, the potential gradient, denoted as "del phi," is relevant at the transmitter site and the distant intersection site, bypassing the space in between. This means the concept of "energy flow" applies directly from the transmitter to the intersection, without involving the intervening space. Within this space, energy is present as an artificial potential, rather than as electromagnetic force field energy, which would be indicative of a gradient bleed-off of potential.

In the exothermic mode, the ground potential of the transmitter is biased well above the ground potential of ambient vacuum. Energy enters the transmitter and "disappears", to "reappear" in the distant interference zone.

If continuous wave transmission is used, the energy continuously appears in the distant zone.

If pulse transmission is used and timed so that the two scalar pulses meet in the distant zone, energy explosively appears there.

If multiple frequencies are transmitted in the manner of a Fourier expansion of a particular geometric form, then a 3-dimensional energy form appears at the distant intersection. In this manner, a spherical or hemispherical shell (a globe or "dome" of EM energy) can be created at a distance.

If pulse transmission is used, this will be an impulsive or explosive emergence of that energy form.

If continuous transmission is used, this will be a continuous glowing form.

By harnessing vast amounts of energy from the earth's molten core through "energy taps" and channeling it into highly potent transmitters, it is possible to generate substantial spherical and hemispherical structures composed of electromagnetic (EM) energy. The energy concentration within the interference "shell" of these spheres or hemispheres is dense enough to elevate Dirac matter out of the vacuum's Dirac sea, resulting in the shell being filled with a luminous plasma.

Many such scalar howitzer signatures have been seen over the oceans, particularly over the North Pacific by jet airliners flying into and out of Japan. Also, such globes and domes of light have been seen deep within the Soviet Union, by observers in Afghanistan and by pilots of aircraft landing in Iran.

ENDOTHERMIC MODE (SCALAR INTERFEROMETER)
In its endothermic setting, the transmitters are adjusted to draw energy away from a remote intersection zone, causing it to reappear at the transmitter locations. This energy must then be captured and safely managed to prevent the transmitters from overheating and potentially being damaged. For the extraction of substantial amounts of energy from distant points, a "dump" strategy is often employed. This involves temporarily holding the thermal energy at the transmitters in an accumulator. Subsequently, a second scalar howitzer, operating in an exothermic mode and powered by a "scalar energy tap" from the accumulator, directs this energy towards a designated remote dump site.

In the impulsive endothermic mode, energy is impulsively extracted from the distant intersection zone. In the atmosphere this results in a sharp cooling, or a "cold explosion." It results in the type of boom and rumble often associated with thunder after a lightning bolt

On April 9, 1984 the Soviet Union tested such a "cold explosion" off the coast of Japan, near the Kuril Islands. In the suddenly induced low pressure "cold zone" above the ocean, ocean water was sharply sucked up from the ocean, forming a dense cloud. Then air rushing in to the low pressure zone forced the cloud upward, forming a mushroom much like that of an atomic explosion in visual appearance, except for the absence of a flash and the absence of a giant shock wave moving out away from the site of the explosion.

As the cloud rises, it expands by mixing -- very similar to a giant thunderhead buildup, except much faster. In this case the cloud rose to 60,000 feet in about 2 minutes, spreading out until it reached a diameter of about 200 miles. The incident was seen by the pilots and crews of several Boeing 747 jet airliners in the general vicinity.

TESLA'S "BIG EYE" FOR REMOTE VIEWING.
Nikola Tesla envisioned aN application for his endothermic scalar interferometer, aiming to create what he termed his "big eye to see at a distance."

Initially, the system operates in endothermic mode, withdrawing only a minimal quantity of energy from the target location. The beams undergo a process of "scanning" by an open receiver, moving sequentially from side to side and top to bottom. Enhancing the quality of the representation, another single beam is scanned across the intersection zone with phased pulses. Consequently, the receiver captures an image based on the energy drawn from various points within the target endothermic zone. When these signals are displayed on a screen that is scanned in a coordinated manner, it generates a visual representation of the remote area within the intersection zone. This method effectively constitutes a unique form of "microwave interferometry" when applied with contemporary techniques could yield impressively detailed imagery.

The capability of scalar electromagnetic (EM) beams to penetrate through the earth or the ocean allows for the unique application of a scanning scalar interferometer to observe what lies beneath the earth's surface or below the ocean's depths.

This feature holds significant value for strategic and tactical reconnaissance, as it renders camouflage, cover, and concealment ineffective against its detection capabilities. The system enables clear visualization inside buildings, underground facilities, and even beneath dense jungle canopies. For instance, with such a technology, the U.S. Marines at Khe Sahn would have easily identified the tunnels being excavated under their perimeter by the Viet Cong, demonstrating its potential to reveal concealed or hard-to-locate targets.