Page 153 - Elana Freeland - Under an Ionized Sky
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which at 10 are weaker by 20 billion times than an electronic digital watch. In other words,
radio transmission of a cubic centimeter of brain matter is well within the detection range of
satellites armed with SLF/ELF reception gear and antennas like the ELF satellite array, given
that human thought broadcasts on the ELF band. Such arrays work perfectly as a Very Large
Array (VLA), given that a VLA is 100X as sensitive as Ohio State University’s 1977 radio
telescope (2x10^-22 W m-2 per channel)—very high resolution for detecting brain activity
hundreds of miles below.
. . .the development time for this technology places the capability to detect brainwaves as far back as the early 1970s.
Given an average lifespan for a satellite as 5 years, with an initial deployment during 1970, the satellite technology
th
would be in its 8 generation. 60
By the early 1990s, properly equipped geosynchronous orbit satellites were able to read
minds, influence behavior, and detect human speech underground or behind walls unprotected by
lead. Beams from high above the Earth are able to “interfere” and lock onto human targets and
knock them down. Subliminals can be broadcast into the brain, including signals ordering the
target to do something criminal, sexual, or violent. Up to now, ordering up a commercial or
government satellite to track an individual target took big resources and embedded contacts;
now, all one needs is the individual’s signature frequency obtained by microprocessors
comparing incoming signals with computerized images or signatures of what the target should
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look like. A signatured target never escapes. Satellite technology as it stands now spells the
arrival of the perfect high-tech crime and clean getaway.
Now that radar can lock onto targets through the cloud cover that inhibits electro-optical
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sensors with ViSAR (video synthetic aperture radar), electro-optical satellites that can collect
data from across the electromagnetic spectrum are all the rage. Electro-optical light waveforms
are highly efficient with 1,000X more data capacity than radio frequency. For example, the
OptiSAR constellation of sixteen satellites on two orbital planes: eight satellites in polar Sun-
synchronous orbit, the other eight in a medium-inclination orbit 20–45 degrees relative to the
equator. Each SAR satellite carries two sensors, one L-band (low resolution), one X-band (high
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resolution). The only weakness electro-optical light waves are known to have is they are easily
disrupted by atmospherics like weather.
Laser Light Communications was the first Optical Satellite Service (OSS) provider with its
Global Hybrid Satellite-Terrestrial All Optical Network (HALO). Under the Defense Information
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Systems Agency (DISA) and in collaboration with Raytheon, HALO’s constellation of twelve
satellites in medium earth orbit (10,000 km) uses high-powered laser to coordinate with
terrestrial and undersea fiber-optic networks as one global surveillance network in alliance with
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the Space Fence. Not only are waves of light from one “Point of Presence” to another
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employed to overtake the controls of an aircraft, but LEDs are replacing streetlights so that
waves of light can be steered to remotely track a human being: 67
The network that Laser Light brings to the relationship is a MEO [medium earth orbit] constellation, which gives it
global coverage instead of regional coverage. The MEO system, known as HALO, also allows it to pick up data at one
Point of Presence [POP] and, after a couple of hops, deliver it to another POP somewhere else in the world,” said
[Managing Director of Laser Light Robert] Brumley. “When you put this together we have a large amount of data
capacity—the equivalent of terrestrial—and, at the same time, we have global reach, which a regional FSS [Fixed
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Satellite Service] by its very nature does not.”
