Technology
The modules: photon ray beam hardware, multi-sensor imaging, and the machinery that carries them.
Establishing the Base Knowledge on Brain-Targeting Photon Ray Beam Modules
Nowadays, one leading technology rules globally people’s lives and behaviors, diplomacy, economics, and warfare: high-precision brain-targeting photon ray beams (close to lasers).
More commonly known as bosonic-excitation photons, these photon ray beams have physical properties very close to those of gamma-rays while being non-ionizing. They are mounted on highly sophisticated and precise hardware powered by nuclear fission reactors, emitted by particle accelerators: SRF Inverse Compton Scattering Source (SRF-ICS) and targeted thanks to geometrically adapted lenses made of rare crystals like synthetic diamonds and “cannons” hardware, coupled with high-precision real time 3D imaging using Coherent Ballistic Photon Imaging (CBPI), as well as regular LIDARs and RADARs for interferometric multi-sensor fusion.
The non-linear quantum properties of high energy photon ray beams are exploited to cross precisely quantified energy thresholds, at a precise point in space where the lens's focal point is calibrated, in order to release electrons and deliver an electrical potential. Multi-sensor fusion cameras (CBPI, RADARs and LIDARs imaging combined with interferometry) render very detailed 3D and temporal 3 millisecond resolutions to map bodies and objects in real time and target a very precise group of neurons in the brain or in the nervous system, across walls and multi-layered thick surfaces. Once targeted, a photonic ray impulse is shot on the precise area of the brain up to a single neuron-level precision to release an electrical potential, activating neuronal ion channels and triggering neuronal response to generate a behavior on the target.
The photonic ray impulses are sent at very high speed and accuracy (order of tens of impulses a minute are possible) to the target’s brain, so that it can emulate precise cognitive inputs and can be processed by the target’s brain cortex.
Different costs and efficiencies of photonic ray beam hardware and multi-sensor fusions are used, and manufactured. The most advanced ones (extremely high precision CBPI and sensors with fine-tuned AI models and precise photonic ray beams) are used on the most important targets and operations.
Targets can be animal or human, as long as they have a nervous system.
The range of cognitive input this technology can trigger (or stop) is limitless. Here is the non-exhaustive list:
These effects are additive and can be performed simultaneously on the target. A photonic ray impulse on the pituitary gland or the heart of the target kills the target in fractions of seconds.
Technical Usage of Photonic Ray Cannons
The hardware coupled with 3D temporal imaging devices is mounted on LEO (Low Earth Orbit) military satellites. The range is very wide and can be all around the globe.
Given this information, we can also straightforwardly deduce that intelligence agencies possessing this technology can target individuals on the entire planet if they have access to military satellites, and the given technology.
We can call the couple ‘photonic ray beam hardware + 3D imaging sensors’ a module. Modules could be used in theory from the ground, or from vehicles, airplanes and satellites at full speed.
The target can be moving relative to the module at the speed of a satellite (28000km/h) or even more: the hardware has a precise enough calibration to counter the relative speed of the target (light-speed particles).
The module’s imagery is designed to map out precisely the structure of the brain, down to neuronal level. All urban planning is designed to be transparent to the module's imagery detection. CBPI can visualize anything through bitumen, and through almost all materials making our cities. Even at a depth of 10m of bitumen in the subway, modules can map out physical movement in real time, as well as imaging and deducing brain activity from the target using the brain’s blood flow imagery. Bosonic-excitation photonic ray beams don’t react to bitumen and other common urban materials, and are calibrated with lenses to precisely reach the brain of the target, at neuronal scale precision.
Moreover, modern imagery systems are able to infer, thanks to predictive analysis and blood flow imagery, exactly which neural group in the target’s brain is active at a time T, T being precise to the 3-millisecond scale. Given this information, modern systems can reliably interpret and store the target’s reactions and analysis of his environment, his actions and even thoughts in real time but also retroactively.
Module operations and the live behavior of every single person are constantly monitored in real time and stored into historical timeseries datasets.
Logistical System to Maintain Modules
In the following parts, we add the military satellite and the embedded hardware to the denomination 'module'.
The modules are deployed on a very large scale as a coherent constellation of LEO satellites and most of the so-called ‘rich’ countries operate modules and cooperate in unison to operate them in synchronization, as well as for the logistic chain and personnel to produce and maintain them.
Under the cover of military hardware and satellites, military and civil personnel handle opaquely the production of the module's parts, the assembly, and the deployment of modules from the ground using rockets.
The cost of modules and their supply chain is extremely high and composes a big part of the state’s defense budget, given its importance in global human control and for geopolitics.
The modules are closely monitored and tracked using radars and remote control technology by personnel on the ground. Each module's historical and live data is stored in ground data centers as well as on the embedded hardware. Live data is transmitted to the module and from the module at light speed. Ground personnel supervise operations, coupled with computer systems, validation systems and AI (Bayesian decision tree, as well as perceptron-like networks). Targets' data are used for predictive behavior analysis. The computer systems themselves will be described more precisely in a later part.
The logistic supply chain, and the command chain to ensure operations' continuity are extremely compartmentalized. Operations are crafted by intelligence agencies' elite groups.
The intelligence personnel operating illegal module programs reside in photonic-ray opaque facilities, walled-in with bent-crystal bosonic-excitation ray beam diffraction composites (Synthetic Diamonds and Carbon lattice) and hardened by Lead and Tungsten, to perform their tasks with immunity.
States operating modules have different manufacturing capabilities and expertise. Some states possess the industrial complex and competent personnel to produce the high-precision hardware required to assemble the modules. Other operating states need to purchase them via proxy states or directly to other states.
Thus, the supply chain to produce modules (assembly factories, hardware, chemical material for batteries, computer systems, etc.) is complex and most states operating them purchase either parts or assembled modules since they don’t possess the complete supply chain and natural resources.
Modules are deployed and serviced on orbit using chaser spacecraft on a rotational basis (for the ones that can be repaired). This way, the nuclear fuel can be renewed, and the parts maintained, changed, and improved regularly.
Systems Attached to Modules
More than brain-targeting photon-ray cannons, a lot of systems are embedded on modules. Here is a non-exhaustive list:
In tens of minutes, these systems can generate localized rainy weather, thunder, snow, wind, raising temperatures, etc. This is done thanks to photonic and gamma ray beams as well. By charging electrically precise air areas, it’s possible to alter or create any kind of climate condition. A hurricane can be created in a few hours to devastate a given area and create a sea tsunami. The possibilities are almost limitless in terms of weather. Most hurricanes, tsunamis and weather-related natural catastrophes in the past decades have been engineered using weather control systems. They’re created to fit intel agencies’ agendas, scenarios, or for real estate investors to take ownership of a given land area.
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