So let’s put this into perspective shall we:

Rishi Sunak took the peoples money to deliberately cause an economic depression, to push through a central bank digital currency sytem.

And the money taken from the people was spent on nanoparticle vaccines capable of tranferring trapped ion qubits to be used in conjunction with a central bank digital currency... and has a side effect of inducing oxidative stress diseases.

Yeah, Merry Xmas Mr Sunak.

Prick.

"In March 2020, we published a discussion paper on CBDC. This outlined one possible approach to the design of a central bank digital currency." Bank of England.

On March 23rd 2020 #BorisJohnson announced a lockdown to 'flatten the curve'.
What a coincidence. Mentioned purchasing #pcrtest kits #LIAR
https://www.youtube.com/watch?v=Haaq59UpINI

"As of 19 March 2020, COVID-19 is no longer considered to be a high consequence infectious disease (HCID) in the UK. There are many diseases which can cause serious illness which are not classified as HCIDs.
The ACDP is also of the opinion that COVID-19 should no longer be classified as an HCID."
https://www.gov.uk/guidance/high-consequence-infectious-diseases-hcid

March 23 2020 report global trade#COVID19 test kits 2008/2018
https://www.globaltradealert.org/reports/51

https://www.bankofengland.co.uk/research/digital-currencies

Good reply, the last time I checked the CBDC sytem will be a dual block(blochsphere)chain distributed ledger combined with quantum trapped ion qubit encryption.

It has now been established that the vaccine is a cationic lipid microsphere nanoparticle that is by definition an ion that can be trapped with optical tweezers creating a cavity resonating laser diode emitting photons as bits of light to conduct an electric potential to open up the ion channel to gain control of the function of your brain.

A lot of videos I saved have been removed. Came across this one #ElonMusk Neural Lace, he bought the company. Thre's another video where EM said everyone should be chipped using the reasoning that if everyone was, then nobody would be able to take control which is a load of bunkum.

https://www.bitchute.com/video/Ydfn7WNGoSio/

Truly hoping he is now an activated white hat/ assett. Willingly would be the best option. reluctant/ clone second option. Honey pot/ black hat - worst option.

There is an interview somewhere in which President Trump said he (Musk) had no choice, or words to that effect.

Wow, look at the news from MSM!

https://www.google.com/search?client=firefox-b-d&q=President+Trump

My thinking is the eyes have to be in front of a screen to be neurolinked.

Newswise — Neuralink, a startup co-founded by Elon Musk, is developing technology to improve the connection between humans and computers through implanted chips in the brain. The technology is purported to be able to restore a person's vision or assist people with mobility issues.

Neuralink, another of Elon Musk’s companies, held its Show & Tell on Wednesday, and many revelations were shared in the live stream. One of those revelations included restoring vision even if someone was born blind. And also restoring full body functionality to someone with a severed spinal cord.

Elon Musk founded Neuralink to answer the question, “What do we do if there is a superintelligence that is much smarter than human beings? How do we, as a species, mitigate the risk or, in a benign scenario, go along for the ride?”

Before SpaceX's Starship has even completed its first orbital flight successfully, Elon Musk is already dreaming of joining its maiden voyage to Mars.

be on another planet

Tesla was incorporated in July 2003 by Martin Eberhard and Marc Tarpenning as Tesla Motors. The company's name is a tribute to inventor and electrical engineer Nikola Tesla. In February 2004, via a $6.5 million investment, Elon Musk became the largest shareholder of the company. He has served as CEO since 2008. According to Musk, the purpose of Tesla is to help expedite the move to sustainable transport and energy, obtained through electric vehicles and solar power.

Tesla developed the alternating-current power system

that provides electricity for homes and buildings.

He also pioneered the field of radio communication and was granted more than 100 U.S. patents.

On this day in 1891, Nikola Tesla was granted U.S. Patent No. 447,921 for an ALTERNATING ELECTRIC CURRENT GENERATOR. In the systems of distribution of electrical energy from alternating-current generators in present use the generators give ordinarily from one to three hundred alternations of current per second.

Latin alternatio; compare French alternation. Morphologically alternate +‎ -ion

An ion trap is a combination of electric and/or magnetic fields used to capture charged particles — known as ions — often in a system isolated from an external environment.

Atomic and molecular ion traps have a number of applications in physics and chemistry such as precision mass spectrometry, improved atomic frequency standards, and quantum computing.

The primary role of ion channels is to regulate the passage of ions across the cell membrane, and the alteration of intracellular ion concentration can be seen as the primary signaling mechanism of ion channels.

Optogenetics was born in 2004 when Karl Deisseroth and Ed Boyden at Stanford University in California investigated a molecule called channelrhodopsin-2, normally present in green algae. The molecule is an ion channel: in other words, the right trigger makes it change shape, opening up an internal channel that allows sodium ions to flow into an alga’s eyespot.

From eye +‎ spot.

I spy with my little eye

One possible solution is to control cell signaling by modulating ion channel gating, using an alternative, highly sensitive optoelectronically activated nanostructure. Such a structure would enable optical control of endogenous (internal) ion channel activity, helping to repair a biological system that has deteriorated with minimum surgery. This solution would also provide an alternative to genetically introduced photosensitive proteins, taking the study and control of cell activities and signaling in a new direction.

Our research explores optical control of cellular and neural activity using optically excited quantum dots (QDs).3 This approach combines the advantage of semiconductors, namely, high sensitivity, fast response, and high design flexibility, with the advantage of photosensitive proteins, namely, small size and cell-specific targeting. Due to their 3D confined structure, QDs offer unique optoelectronic properties that outperform conventional semiconductor materials. These include spectrally sharper emission peaks under excitation, and higher quantum efficiency.

The continued growth in the demand of data storage and processing has spurred the development of high-performance storage technologies and brain-inspired neuromorphic hardware. Semiconductor quantum dots (QDs) offer an appealing option for these applications since they combine excellent electronic/optical properties and structural stability and can address the requirements of low-cost, large-area, and solution-based manufactured technologies. Here, we focus on the development of nonvolatile memories and neuromorphic computing systems based on QD thin-film solids. We introduce recent advances of QDs and highlight their unique electrical and optical features for designing future electronic devices. We also discuss the advantageous traits of QDs for novel and optimized memory techniques in both conventional flash memories and emerging memristors.

Then, we review recent advances in QD-based neuromorphic devices from artificial synapses to light-sensory synaptic platforms. Finally, we highlight major challenges for commercial translation and consider future directions for the postsilicon era.

Neuromorphic engineering, also known as neuromorphic computing,[1][2][3] is the use of electronic circuits to mimic neuro-biological architectures present in the nervous system.[4][5] A neuromorphic computer/chip is any device that uses physical artificial neurons (made from silicon) to do computations.[6][7] In recent times, the term neuromorphic has been used to describe analog, digital, mixed-mode analog/digital VLSI, and software systems that implement models of neural systems (for perception, motor control, or multisensory integration).

The implementation of neuromorphic computing on the hardware level can be realized by oxide-based memristors,[8] spintronic memories, threshold switches, transistors,[9][7] among others. Training software-based neuromorphic systems of spiking neural networks can be achieved using error backpropagation, e.g., using Python based frameworks such as snnTorch,[10] or using canonical learning rules from the biological learning literature, e.g., using BindsNet.[11]

A key aspect of neuromorphic engineering is understanding how the morphology of individual neurons, circuits, applications, and overall architectures creates desirable computations, affects how information is represented, influences robustness to damage, incorporates learning and development, adapts to local change (plasticity), and facilitates evolutionary change.

Neuromorphic engineering is an interdisciplinary subject that takes inspiration from biology, physics, mathematics, computer science, and electronic engineering[7] to design artificial neural systems, such as vision systems, head-eye systems, auditory processors, and autonomous robots, whose physical architecture and design principles are based on those of biological nervous systems.[12] One of the first applications for neuromorphic engineering was proposed by Carver Mead[13] in the late 1980s.

Machine vision (MV) is the technology and methods used to provide imaging-based automatic inspection and analysis for such applications as automatic inspection, process control, and robot guidance, usually in industry. Machine vision refers to many technologies, software and hardware products, integrated systems, actions, methods and expertise. Machine vision as a systems engineering discipline can be considered distinct from computer vision, a form of computer science. It attempts to integrate existing technologies in new ways and apply them to solve real world problems. The term is the prevalent one for these functions in industrial automation environments but is also used for these functions in other environment vehicle guidance.

Computer vision is an interdisciplinary scientific field that deals with how computers can gain high-level understanding from digital images or videos. From the perspective of engineering, it seeks to understand and automate tasks that the human visual system can do.[

The visual system comprises the sensory organ (the eye) and parts of the central nervous system (the retina containing photoreceptor cells, the optic nerve, the optic tract and the visual cortex) which gives organisms the sense of sight (the ability to detect and process visible light) as well as enabling the formation of several non-image photo response functions. It detects and interprets information from the optical spectrum perceptible to that species to "build a representation" of the surrounding environment.

The visual system carries out a number of complex tasks, including the reception of light and the formation of monocular neural representations, colour vision, the neural mechanisms underlying stereopsis and assessment of distances to and between objects, the identification of a particular object of interest, motion perception, the analysis and integration of visual information, pattern recognition, accurate motor coordination under visual guidance, and more. The neuropsychological side of visual information processing is known as visual perception, an abnormality of which is called visual impairment, and a complete absence of which is called blindness. Non-image forming visual functions, independent of visual perception, include (among others) the pupillary light reflex and circadian photoentrainment.

Efficient delivery of drugs to the retina is critical but difficult to achieve with current methods. There have been a number of attempts to use intravitreal injection of liposomes, artificial vesicles composed of a phospholipid bilayer, to overcome the limitations of conventional intravitreal injection (short retention time, toxicity, poor penetration, etc.). Here, we report an optimal liposomal formulation that can diffuse through the vitreous humor, deliver the incorporated agents to all retinal layers effectively, and maintain them for a relatively long time. We first delivered lipophilic compounds and phospholipid-conjugated hydrophilic agents to the inner limiting membrane using engineered liposomes. Subsequently, the agents penetrated the retina deeply, presumably via extracellular vesicles, nanoscale vesicles secreted from retinal-associated cells.