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Post by brillbilly on Apr 9, 2017 4:51:21 GMT 10
What does Billions upon Billions spent by our government on brain mapping the human mind, psychotronic touchless torture, targeted individuals, self-replicating nano-bots, Morgellons disease, smart dust, geoengineering, scalar waves, GWEN towers, Dwave Quantum super computers, Black goo, Gray Goo, Goo-gle and Archons have in common?
They are all being used together for a mass mind control agenda using wireless remote brain mapping to be able to override one's own thoughts, feelings and actions from anywhere in the world, anytime using smart dust released from geoengineering smart dust carrying planes released into the air to enter our bodies with sub atomic particulate matter. This is the ultimate mind control technology where machines are taking control of human minds around the world since at least the mid 1970's to the point where we are all Phase I affected and many TI's (targeted individuals) are Phase II where voices are inside your head, body functions are controlled remotely and lives are ruined to the pt. that some TI's commit suicide to escape the torture.
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Post by brillbilly on Apr 10, 2017 5:33:55 GMT 10
I hope you all get to watch this,Damn creepy stuff! Everybody knows there is aluminum, barium, strontium and titanium in the chemtrails. But have you ever heard about piezoelectric crystals and of the so called "Smart Dust" - of Morgellons? Are these technologies of human origin? What are they and how they relate to each other? Learn more and lets start with the very basics, that is not commonly known at all. Morgellon analysis: www.aquarius-technologies.de/d...
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Post by brillbilly on Apr 20, 2017 6:45:58 GMT 10
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Post by Wes Gear on Apr 20, 2017 20:32:04 GMT 10
SmartdustSmartdust is a system of many tiny microelectromechanical systems (MEMS) such as sensors, robots, or other devices, that can detect, for example, light, temperature, vibration, magnetism, or chemicals. They are usually operated on a computer network wirelessly and are distributed over some area to perform tasks, usually sensing through radio-frequency identification. Without an antenna of much greater size the range of tiny smart dust communication devices is measured in a few millimeters and they may be vulnerable to electromagnetic disablement and destruction by microwave exposure. Design and engineeringThe concepts for Smart Dust emerged from a workshop at RAND in 1992 and a series of DARPA ISAT studies in the mid-1990s due to the potential military applications of the technology. The work was strongly influenced by work at UCLA and the University of Michigan during that period, as well as science fiction authors Stanislaw Lem, Neal Stephenson and Vernor Vinge. The first public presentation of the concept by that name was at the American Vacuum Society meeting in Anaheim in 1996. A Smart Dust research proposal was presented to DARPA written by Kristofer S. J. Pister, Joe Kahn, and Bernhard Boser, all from the University of California, Berkeley, in 1997. The proposal, to build wireless sensor nodes with a volume of one cubic millimeter, was selected for funding in 1998. The project led to a working mote smaller than a grain of rice, and larger "COTS Dust" devices kicked off the TinyOS effort at Berkeley. The concept was later expanded upon by Kris Pister in 2001.A recent review discusses various techniques to take smartdust in sensor networks beyond millimeter dimensions to the micrometre level. The Ultra-Fast Systems component of the Nanoelectronics Research Centre at the University of Glasgow is a founding member of a large international consortium which is developing a related concept: smart specks. link Piezoelectricity
Piezoelectricity /piˌeɪzoʊˌilɛkˈtrɪsɪti/ is the electric charge that accumulates in certain solid materials (such as crystals, certain ceramics, and biological matter such as bone, DNA and various proteins) in response to applied mechanical stress. The word piezoelectricity means electricity resulting from pressure. It is derived from the Greek piezō (πιέζω) or piezein (πιέζειν), which means to squeeze or press, and ēlektron (ήλεκτρον), which means amber, an ancient source of electric charge. Piezoelectricity was discovered in 1880 by French physicists Jacques and Pierre Curie. The piezoelectric effect is understood as the linear electromechanical interaction between the mechanical and the electrical state in crystalline materials with no inversion symmetry. The piezoelectric effect is a reversible process in that materials exhibiting the direct piezoelectric effect (the internal generation of electrical charge resulting from an applied mechanical force) also exhibit the reverse piezoelectric effect (the internal generation of a mechanical strain resulting from an applied electrical field). For example, lead zirconate titanate crystals will generate measurable piezoelectricity when their static structure is deformed by about 0.1% of the original dimension. Conversely, those same crystals will change about 0.1% of their static dimension when an external electric field is applied to the material. The inverse piezoelectric effect is used in the production of ultrasonic sound waves. linkPiezoelectricity is found in useful applications, such as the production and detection of sound, generation of high voltages, electronic frequency generation, microbalances, to drive an ultrasonic nozzle, and ultrafine focusing of optical assemblies. It is also the basis of a number of scientific instrumental techniques with atomic resolution, the scanning probe microscopies, such as STM, AFM, MTA, SNOM, etc., and everyday uses, such as acting as the ignition source for cigarette lighters, and push-start propane barbecues, as well as the time reference source in quartz watches. link
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Post by Wes Gear on Apr 20, 2017 21:00:45 GMT 10
Smart Dust Is Coming: New Camera Is the Size of a Grain of SaltMiniaturization is one of the most world-shaking trends of the last several decades. Computer chips now have features measured in billionths of a meter. Sensors that once weighed kilograms fit inside your smartphone. But it doesn't end there. Researchers are aiming to take sensors smaller—much smaller. In a new University of Stuttgart paper published in Nature Photonics, scientists describe tiny 3D printed lenses and show how they can take super sharp images. Each lens is 120 millionths of a meter in diameter—roughly the size of a grain of table salt—and because they're 3D printed in one piece, complexity is no barrier. Any lens configuration that can be designed on a computer can be printed and used. This allows for a variety of designs to be tested to achieve the finest quality images. According to the paper, the new method not only demonstrates high-quality micro-lenses can be 3D printed, but it also solves roadblocks to current manufacturing methods. These include limitations on how small you can go, failure to combine multiple elements, surface design restrictions, and alignment difficulties. A multi-lens system (right) next to a single doublet lens (left). Image credit: Timo Gissibl/University of Stuttgart
The lenses—which included single, double, and triple optical elements—were printed on strands of optical fiber and standard digital sensors like those used in cameras. The researchers believe future applications include less invasive endoscopic medical imaging of the body—even injection into the brain—and nearly invisible camera sensors on miniature drones or robots. "This will lead to a plethora of novel devices with tremendous impact on biotechnology, medical engineering, and safety/security monitoring," they wrote. The array of doublet lenses pictured here were printed directly onto a CMOS image sensor. Perhaps the most interesting aspect of the research, however, is that the lenses don't require custom multi-million-dollar lab equipment—rather, they were made on a commercially available Nanoscribe laser lithography 3D printer. The printer sends ultra-fast laser pulses into a photosensitive resin, hardening it layer by layer into the finished product. A few years ago, Nanoscribe showed off the printer's ability by recording it in real time as it rapidly built a 3D model of a spaceship the size of a human hair. singularityhub.com/2016/06/28/smart-dust-is-coming-new-camera-is-the-size-of-a-grain-of-salt/
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Post by brillbilly on Apr 21, 2017 4:37:02 GMT 10
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