sábado, 18 de dezembro de 2021

Are we being chipped? New evidence emerges.

 


Mark Playne

November 29th

When we first discovered the easily replicable vaccine-induced magnetism, we quickly laughed off the idea that the magnetism was caused by chips planted under the skin.

The chips we thought of, were grain-sized, nonmetallic and simply too bulky to be used nefariously in such a mass vaccination programme.

Chips could not be floating around each vial, undetected by innocent nurses.

However, since those initial days last Spring, the evidence for 'chips' has been mounting.

Except, not large bulky chips.

This is 2021.

We are in the era of nanotechnology.


Tighten your seat belts for this one...

NEW HIGHLIGHTS VIDEO - 1.22 minutes



Much more coming on this, so watch this space.

This is research again originating from the Spanish teams under Dr Campra of Almeria University.

Source is at the end of the article.

(FW comment: we have tidied up the original machine translation provided by Not On The Beeb to better reflect the Spanish meaning. The original texts are the work of the pseudonymous Mik Andersen of C0r0n@ 2 Inspect )

 

Pattern identification in c0r0n @ v | rus vaccines: nanorouters 

 

Since graphene oxide was discovered in c0r0n @ v | rus vaccines, all the findings and discoveries made only confirm its presence (Campra, P. 2021). To date, more than reasonable evidence and indications have also been found for the existence of carbon nanotubes and nano- octopuses, mesoporous spheres, colloidal nano-robots; objects that should not be part of any vaccine and that are not declared as ingedients. Additionally, other types of objects have been identified and evidenced in images of blood samples, of people vaccinated with the c0r0n @ v | rus vaccines, specifically micro-swimmers, crystallized graphene nano-antennas and graphene quantum dots, also known as GQD.

On this occasion, when we analyze one of the images obtained by Dr. Campra, from a Pfizer vaccine sample, see figure 1, we find what is in all probability a nanorouter or part of its circuitry. In the original image, a well-defined drop can be seen in which crystalline structures of a quadrangular or cubic format appear. If you look closely, you can see some marks on these crystals, with a regular pattern, well defined in some cases, but limited by the microscope optics. 

 

 
Fig. 1. Crystalline formations that show markings of what appear to be circuits. Among these objects, the circuit of what could be a nanorouter has been discovered. Image of a sample of the Pfizer vaccine, obtained by (Campra, P. 2021)

The finding has been made possible by isolating each quadrangular crystal, applying a process of rasterizing, focusing and delineating the edges of the image, in order to further pronounce the observed marks. Once this process was completed, a rough draft was drawn with the lines and patterns inscribed on the glass, creating a clean outline of what actually looked like a circuit. Finding parallel and perpendicular lines with a different distribution from fractal patterns was very striking, and this allowed us to automatically infer the possibility that it had been a product of manufacture. For this reason, similar patterns were sought in the scientific literature, with a scheme similar to the circuit that had just been drawn. The search result was almost immediate, since the pattern of a quantum dot nanorouter was found, as shown in figure 2. 

 


Fig. 2. Possible quantum dot nanorouter observed in a quadrangular crystal, in an image obtained by the doctor (Campra, P. 2021). In the lower right corner, the quantum dot nanorouter circuit published by (Sardinha, LH; Costa, AM; Neto, OPV; Vieira, LF; Vieira, MA 2013) is observed. Note the obvious similarity between the sketch, the shape inscribed in the crystal, and the quantum dot circuit.

This discovery is of fundamental relevance, not only to understand the true purpose and components of the c0r0n @ v | rus vaccines, but also to explain the phenomenon of MAC addresses, visible through the bluetooth of many mobile devices.

Context of the discovery

Before proceeding with an explanation of the findings, we should recall to the wider context , so that we understand it well and explore further.

In the first place, it should be borne in mind that graphene and its derivatives, graphene oxide (GO) and carbon nanotubes (CNT), are components of the vaccines, as we have has already stated in this blog. The properties of graphene are exceptional from the physical point of view, but also from a thermodynamic, electronic, mechanical and magnetic perspective. Its characteristics facilitate its use as a superconductor, electromagnetic wave absorbing material (microwave EM), a , signal emitter and receiver, and a quantum antenna, which makes it possible to create advanced electronics on a nano and micrometric scale. So much so that it is the fundamental nanomaterial for the development of nano-biomedicine (Mitragotri, S.; Anderson, DG; Chen, X.; Chow, EK; Ho, D.; Kabanov, AV; Xu, C. 2015), nano-communication networks ( Kumar, MR 2019 ), new drug delivery therapies ( Yu, J.; Zhang, Y.; Yan, J.; Kahkoska, AR; Gu, Z. 2018 ) and cancer treatments ( Huang, G.; Huang, H. 2018)) and the neurological treatment of neurodegenerative diseases (John, AA; Subramanian, AP; Vellayappan, MV; Balaji, A.; Mohandas, H.; Jaganathan, SK 2015). However, all benefits aside, the scientific literature is very clear regarding its health implications for the human body. It is well known that graphene (G), graphene oxide (GO) and other derivatives such as carbon nanotubes (CNT) are toxic in almost all their forms, causing mutagenesis, cell death (apoptosis), release of free radicals, lung toxicity, bilateral pneumonia, genotoxicity or DNA damage, inflammation, immunosuppression, damage to the nervous system, the circulatory, endocrine, reproductive, and urinary systems, which can cause anaphylactic death and multi-organ dysfunction, see the pages "Damage and toxicity of graphene oxide" and" Damage and toxicity of carbon-graphene nanotubes ".

Second, graphene is a radio-modulable nanomaterial, capable of absorbing electromagnetic waves and multiplying radiation, acting as a nano-antenna, or a signal repeater (Chen, Y .; Fu, X .; Liu, L .; Zhang , Y .; Cao, L .; Yuan, D .; Liu, P. 2019). Exposure to electromagnetic radiation can cause exfoliation of the material in smaller particles (Lu, J .; Yeo, PSE; Gan, CK; Wu, P .; Loh, KP 2011), called graphene quantum dots or GQD (Graphene Quantum Dots), whose physical properties and particularities improve due to its even smaller scale, due to the effect of " Quantum Hall", since they act by amplifying electromagnetic signals (Massicotte, M.; Yu, V.; Whiteway, E.; Vatnik, D.; Hilke, M. 2013 | Zhang, X.; Zhou, Q.; Yuan, M. ; Liao, B.; Wu, X.; Ying, M. 2020), and with it the emission distance, especially in environments such as the human body (Chopra, N.; Phipott, M.; Alomainy, A. ; Abbasi, QH; Qaraqe, K.; Shubair, RM 2016). GQDs can acquire various morphologies, for example hexagonal, triangular, circular or irregular polygon (Tian, ​​P.; Tang, L.; Teng, KS; Lau , SP 2018).

The superconducting and transducing capacity makes graphene one of the most suitable materials to create wireless nanocommunication networks for the administration of nanotechnology in the human body. After the available protocols and specifications were discovered and analyzed, this approachwas intensively researched by the scientific community, as were the routing systems for data packets that would generate nano-devices and nano-nodes within the body, in a complex of systems called CORONA, whose objective is the effective transmission of signals and data on the network, optimizing energy consumption (to the minimum possible), and reducing likewise, the failures in the transmission of data packets (Bouchedjera, IA; Aliouat, Z .; Louail, L. 2020 | Bouchedjera, IA; Louail, L .; Aliouat, Z .; Harous, S. 2020 | Tsioliaridou, A .; Liaskos, C .; Ioannidis, S .; Pitsillides, A. 2015). 

In this nanocommunications network, a type of signal TS-OOK (Time-Spread On-Off Keying) is used that allows transmitting binary codes of 0 and 1, through short pulses that involve the activation and deactivation of the signal during time intervals very small of a few femtoseconds (Zhang, R .; Yang, K .; Abbasi, QH; Qaraqe, KA;Alomainy, A. 2017 | Vavouris, AK; Dervisi, FD; Papanikolaou, VK; Karagiannidis, GK 2018). Due to the complexity of nanocommunications in the human body, where the network 's nano-nodes are distributed throughout, oftein motion (due to blood flow) or attached to the endothelium of the arterial walls and capillaries or the tissues of other organs, researchers have required the development of software for the simulation of such conditions , in order to verify and validate the nanocommunication protocols that had been developed (Dhoutaut, D .; Arrabal, T .; Dedu, E. 2018).

On the other hand, the nanocommunications network oriented to the human body (Balghusoon, AO; Mahfoudh, S. 2020), has been carefully designed in its topological aspects, with specialized components conceived for the performance of this task. For example, electromagnetic nanocommunication is made up in its most basic layer by nano-nodes that are devices (presumably made of graphene, carbon nanotubes, GQD, among other objects and materials) that have the ability to interact as nanosensors, piezo-electric actuators, and in any case as nano-antennas that propagate the signals to the rest of the nano-nodes. The nano-nodes, find in the nano-routers (also called nano-controllers) the next step in the topology. Its function is to receive the signals emitted by the nano-nodes, process them and send them to the nano-interfaces,which will emit them outside of the body with the necessary frequency and range, since it must overcome the skin barrier without losing signal clarity, so that it can be received by a mobile device at a close enough distance (usually a few meters) . That mobile device would actually be a smartphone or any other device with an Internet connection, which allows it to act as a "Gateway". The topology also defines the possibility that the entire nano-node, nanorouter and nano-interface infrastructure is unified in a single nano-device, called pole or metamaterial defined by SDM software (Lee, SJ; Jung, C.; Choi, K. ; Kim, S. 2015). This model simplifies the topology, but it increases the size of the device and the complexity of its construction, conceived in several layers of graphene. In any case, regardless of the topology, nanorouters are necessary to route and decode the signals correctly, for their sending, but also for their reception, since they can be designed for a bidirectional service, which de facto implies the ability to receive signals, commands, orders, and operations that interact with the objects of the network..

To electromagnetic nanocommunication, we must add molecular nanocommunication, addressed in the entry on carbon nanotubes and new evidence in vaccine samples. In both publications, the implications of these objects in the field of neuroscience, neuromodulation and neurostimulation are analyzed, since if they are located in the neuronal tissue (something very likely, given the ability to overcome the blood-brain barrier), they can establish connections that bridge the neuronal synapse. This means that they link neurons with different shortcuts, shorter than natural axons ( Fabbro, A .; Cellot, G .; Prato, M .; Ballerini, L. 2011). Although this can be used in experimental treatments to mitigate the effects of neurodegenerative diseases, it can also be used to directly interfere with neurons, the secretion of neurotransmitters such as dopamine, the involuntary activation of certain areas of the brain, their neurostimulation or modulation, through electrical impulses, generated from carbon nanotubes (Suzuki, J .; Budiman, H .; Carr, TA; DeBlois, JH 2013 | Balasubramaniam, S .; Boyle, NT; Della-Chiesa, A .; Walsh, F .; Mardinoglu, A .; Botvich, D .; Prina-Mello, A. 2011), as a result of the reception of electromagnetic signals and pulses from the nanocommunications network (Akyildiz, IF; Jornet, JM 2010). It is not necessary to point out that an external signal, not controlled by the inoculated person, is the one that governs the segregation of neurotransmitters. For example, carbon nanotubes housed in neuronal tissue could interfere with the natural functioning of the secretion of neurotransmitters such as dopamine, which is partly responsible for cognitive processes, socialization, the reward system, desire, pleasure, conditioned learning or inhibition (Beyene, AG; Delevich, K .; Del Bonis-O'Donnell, JT; Piekarski, DJ; Lin, WC; Thomas, AW; Landry, MP 2019 | Sun, F .; Zhou, J .; Dai, B .; Qian, T .; Zeng, J .; Li, X .; Li, Y. 2020 | Sun, F .; Zeng, J .; Jing, M .; Zhou, J .; Feng, J .; Owen, SF; Li, Y. 2018 | Patriarchi, T .; Mohebi, A .; Sun, J .; Marley, A .; Liang, R .; Dong, C .; Tian, ​​L. 2020 | Patriarchi, T .; Cho , JR; Merten, K .; Howe, MW; Marley, A .; Xiong, WH; Tian, ​​L. 2018). This means that people's normal behavior patterns, their  feelings and thoughts, could be interfered with. They may even be subliminalyl conditioned without the individual being aware of what is happening. In addition to the properties already mentioned, carbon nanotubes do more than open the doors to wireless interaction with the human brain. They can also receive electrical signals from neurons and propagate them to nanorouters, since they also have the same properties as GQD graphene nano-antennas and quantum dots (without the individual being aware of what is happening) as explained in (Demoustier, S .; Minoux, E .; Le Baillif, M .; Charles, M .; Ziaei, A. 2008 | Wang, Y .; Wu, Q .; Shi, W .; He, X .; Sun, X .; Gui, T. 2008 | Da-Costa, MR; Kibis, OV; Portnoi, ME 2009 ). This means that they can transmit and monitor the neuronal activity of individuals.

For the data packets emitted and received from the nanocommunications network to reach their destination, it is essential that the communication protocol in some way implements the unique identification of the nanodevices (that is, through MAC) and transmits the information to an IP address. In this sense, the human body becomes an IoNT server (from the Internet of NanoThings) in which the communication client / server model can be assimilated. The mechanisms, commands or types of request remain to be determined, as well as the exact frequency and type of signal that operates the wireless nanocommunications network that would be installed with each vaccine, although obviously this information must be very confidential, given the possible consequences of biohacking. (Vassiliou, V. 2011) that could come to pass.In fact, in the work of ( Al-Turjman, F. 2020) links the security problems and circumstances of nanocommunication networks connected to 5G (confidentiality, authentication, privacy, trust, intrusions, repudiation) and additionally, presents a summary of the operation of electromagnetic communication between nano-nodes, nano-sensors and nano-routers, using graphene antennas and transceivers for their link with data servers, in order to develop Big-data projects. It should be noted that the risks of network hacking are very similar to those that can be perpetrated in any network connected to the Internet (masquerade attack, location tracking, information traps, denial of service, nano-device hijacking, wormhole, MITM broker attack, malware, spam, sybil, phishing, neurostimulation illusion attack), which means a further potential risk, and a very serious one, for people inoculated with the hardware of a nanocommunication network.

This is the context of the nanorouter circuits found in the Pfizer vaccine samples. This is is a key element of all the research that is being carried out and confirms the installation of hardware in the body of inoculated people, without their consent, while operating collection and interaction processes that are completely beyond their control.

Nanorouters QCA

The circuit discovered , see figure 3, corresponds to the field of quantum dot cellular automata, also known as QCA (Quantum Cellular Automata), characterized by its nanometric scale and a very low energy consumption, as an alternative for the replacement of technology based on transistors. This is how it is defined by the work of (Sardinha, LH; Costa, AM; Neto, OPV; Vieira, LF; Vieira, MA 2013) from which the scheme of said circuit was obtained. The nanorouter referred to by the researchers is characterized by an ultra-low consumption factor, high processing speed (its frequency clock operates in a range of 1-2 THz), which is consistent with power conditions and data transfer requirements in the context of nanocommunication networks for the human body described by (Pierobon, M.; Jornet, JM; Akkari, N.; Almasri, S.;Akyildiz, IF 2014).

 

 
Fig. 3. Graphene quantum dot circuit in QCA cells. Circuit diagram of (Sardinha, LH; Costa, AM; Neto, OPV; Vieira, LF; Vieira, MA 2013) observed in a Pfizer vaccine sample.

According to the explanations  of (Sardinha, LH; Costa, AM; Neto, OPV; Vieira, LF; Vieira, MA 2013), the concepts of quantum dot and quantum dot cell are to be distinguished. See figure 4. The QCA cell is made up of four quantum dots whose polarization is variable. This makes it possible to distinguish the binary code of 0 and 1 based on the positive or negative charge of the quantum dots. In the words of the authors:

  "The basic units of QCA circuits are cells made of quantum dots. A point, in this context, is just a region where an electrical charge can be located or not. A QCA cell has four quantum dots located in the corners. Each cell has two free, moving electrons that can tunnel between quantum dots. It is assumed that tunneling to the outside of the cell is not allowed due to a high potential barrier ."

Extrapolated to graphene quantum dots, known as GQDs, which were identified in blood samples (due to emitted fluorescence), a QCA cell would require four GQDs to compose, which is perfectly consistent with the description given by the researchers. This is also corroborated by (Wang, ZF; Liu, F. 2011) in his work entitled "Graphene quantum dots as building blocks for quantum cellular automata", where the use of graphene to create this type of circuit is confirmed. .



Fig. 4. Scheme of a QCA cell made up of four quantum dots (which can be graphene, among other materials). Note the great resemblance to memristors, in fact QCAs and memristors are transistors. (Sardinha, LH; Costa, AM; Neto, OPV; Vieira, LF; Vieira, MA 2013 | Strukov, DB; Snider, GS; Stewart, DR; Williams, RS 2009)

When the QCA cells are combined, cables and circuits are created, with a wide variety of shapes, schemes and applications, as can be seen in figure 5, where inverters, crossovers and logic gates are observed, which is also addressed by other authors such as ( Xia, Y .; Qiu, K. 2008 ). This gives rise to more complex structures, which facilitates the electronic diagrams of the transistors, processors, transceivers, multiplexers, demultiplexers and therefore of any router.

 


Fig. 5. QCAs can form various types of circuits, for example logic gates, cable crossovers, inverters or cables. (Sardinha, LH; Costa, AM; Neto, OPV; Vieira, LF; Vieira, MA 2013)

It is important to explain that QCA cell-based circuits can operate in several superimposed layers, which allows a 3D (three-dimensional) structure to create much more complex and compressed electronics, see figure 6.


Fig. 6. According to (Sardinha, LH; Costa, AM; Neto, OPV; Vieira, LF; Vieira, MA 2013) more complex circuits can be built by annexing several superimposed layers. This is identified by the symbol of a circle in the design. There are also three artistic illustrations that represent various levels of circuits (own elaboration).

To develop a nanorouter, according to researchers (Sardinha, LH; Costa, AM; Neto, OPV; Vieira, LF; Vieira, MA 2013), several circuit structures are needed, specifically, cable crossings (which form logic gates ), demultiplexers (demux) and parallel to serial converters, see figure X. "Demux" are electronic devices capable of receiving a signal at the input QCA (input) and sending it to one of several available output lines (output), which allows the signal to be routed for further processing. The parallel-to-series converter is a circuit capable of taking several sets of data in an input (input), transporting them through different QCA cables and transmitting them at different instants of time through the output cables (output). This would be the very component noted in the vaccine samples, see figure 7. 

 


Fig. 7. Details of the circuit for converting TS-OOK signals in series to a parallel output, confirming one of the typical tasks of a router. (Sardinha, LH; Costa, AM; Neto, OPV; Vieira, LF; Vieira, MA 2013)

Another relevant aspect of the work of (Sardinha, LH; Costa, AM; Neto, OPV; Vieira, LF; Vieira, MA 2013) is the demonstration of the circuit's operation, where the reception of a TS-OOK signal and its conversion to binary code, see figure 8. Once the binary code is obtained, the "demux" circuit is responsible for generating the data packets, according to the structure of the corresponding communications protocol. 

 


Fig. 8. The tests of the demux circuit, already observed in figure 7, provide the proof of how the TS-OOK signals are interpreted and converted to the binary code, to finally generate the data packets of the corresponding nanocommunications protocol. (Sardinha, LH; Costa, AM; Neto, OPV; Vieira, LF; Vieira, MA 2013)

Everything explained by (Sardinha, LH; Costa, AM; Neto, OPV; Vieira, LF; Vieira, MA 2013) is also corroborated by (Das, B .; Das, JC; De, D .; Paul, AK 2017). In this research, QCA circuit designs for demux and nanorouters are observed, with very similar schemes to those already presented, which confirms the search for solutions for the problem of simple transmission and processing of signals and data at the nanometric scale, in order to make nanocommunication networks effective.

Finally, although it can already be deduced from the nature, characteristics and properties of QCA cell circuits, the concept of clock speed must be highlighted. In fact, the ability of these electronic components to operate almost autonomously, without the need for a dedicated processor, is notable. This is because the QCA cell cables can measure the transfer time of the signals between the different cells, in what is called "clock zones", see figure 9 and the following investigations (Sadeghi, M .; Navi, K .; Dolatshahi, M. 2020 | Laajimi, R .; Niu, M. 2018 | Reis, DA; Torres, FS 2016 | Mohammadyan, S .; Angizi, S .; Navi, K. (2015). This effect allows the transmission of signals through the circuit, but also allows you to create a clock frequency, which is its own processing speed. If this concept is coupled with the use of superconducting materials such as graphene and more specifically graphene quantum dots, then very high processing speeds can be achieved. 

 


Fig. 9. The nanorouter does not require an independent processor, because the QCA cells organized in the circuit cables already perform this function due to the superconducting and polarization properties of the quantum dots, which allows the inferring of a clock speed by phases or zones. circuit physics. (Sardinha, LH; Costa, AM; Neto, OPV; Vieira, LF; Vieira, MA 2013 | Sadeghi, M.; Navi, K .; Dolatshahi, M. 2020)

Circuit self-assembly

Although it seems impossible, the self-assembly of circuits is a possibility to consider in the hypothesis that has been explained. According to (Huang, J .; Momenzadeh, M.; Lombardi, F. 2007) 

 "Recent developments in QCA manufacturing (involving molecular implementations) have substantially changed the nature of processing. At very small feature sizes, it is envisioned that self-assembly or large-scale cell deposition will be used on isolated substrates. In these implementations, the QCA cells (each composed of two dipoles) are laid out in parallel V-shaped tracks. The QCA cells are arranged in a dense pattern and the computation occurs between adjacent cells. These fabrication techniques are well suited for molecular implementation.

However, there are other methods as well, such as DNA nanopatterns ( Hu, W .; Sarveswaran, K.; Lieberman, M.; Bernstein, GH 2005), with which a template is created for the alignment of the graphene quantum dots, forming the QCA cells, thereby generating the aforementioned circuitry, see figure 10. 

 


Fig. 10. Self-assembly of a circuit with quantum dots from a DNA pattern. The lines of the circuit cables are very similar to those observed in the vaccine sample, see figure 2 and 3. (Hu, W .; Sarveswaran, K.; Lieberman, M.; Bernstein, GH 2005)

According to ( Hu, W.; Sarveswaran, K.; Lieberman, M.; Bernstein, GH 2005 ) "Four-tile DNA rafts have been successfully synthesized and characterized by the gel electrophoresis method in our previous work" according to the work of Sarveswaran (Sarveswaran, K. 2004). This fits with the very possible existence of a gel / hydrogel in the vaccine composition, in line with the doctor's micro-Raman analysis (Campra, P. 2021) in which peaks with values ​​close to 1450 were obtained. These could correspond to PVA, PQT-12, polyolefin, polyacrylamide, or polypyrrole, all of which are recognized in the scientific literature as gels and derivatives. On the other hand, it explicitly alludes to the electrophoresis method, or in other words, the electrical polarization process that causes teslaphoresis, on carbon nanotubes, graphene, quantum dots and other semiconductors, as described in the following research (Bornhoeft, LR; Castillo, AC; Smalley, PR; Kittrell, C .; James, DK; Brinson, BE; Cherukuri, P. 2016) . This would confirm that teslaphoresis plays a fundamental role in the composition of circuits, along with DNA patterns. If this is confirmed, it would mean that the circuits could self-assemble in the presence of electric fields or even the reception of electromagnetic waves (microwave EM). The study of (Pillers, M.; Goss, V.; Lieberman, M.2014) also confirms the construction of nanostructures and CQA using in this case graphene, graphene oxide (GO), electrophoresis and gel, causing controlled deposition in the areas indicated by the DNA pattern, reproducing results similar to those exposed in the study by Hu and Sarveswaran, and thus making possible the creation of the electronic circuits already mentioned. See figure 11. 


 

Plasmonic nano-emitters

 

Another issue that requires an explanation in the discovery of the nanorouter circuit in the vaccine sample, is its location in what appears to be a quadrangular crystal. Although it could be thought that it is a randomly generated form, the bibliographic review reveals and justifies this type of form that serves as a framework for this type of circuit. It is actually a "plasmonic nano-emitter". In other words, it would correspond to a cubic-shaped nano-antenna (single crystal) of variable size on the nano-micrometric scale, which can emit, receive or repeat signals. This is possible through the plasmon activation property of its surface ( that of the nano-emitting cube) that is locally excited to generate an oscillatory signal, as explained by ( Ge, D.; Marguet, S.; Issa, A .; Jradi, S .; Nguyen, TH; Nahra, M.; Bachelot, R 2020), see figure 12. This agrees with the type of TS-OOK signals, which are transmitted through the intra-body nanocommunication network, being an indispensable requirement for a nano-router, to have a method to capture them. In other words, the crystalline cube acts as a transceiver for the nanorouter, due to its special properties derived from the physics of the plasmon. This is corroborated when the scientific literature on electromagnetic nano-networks for the human body is consulted (Balghusoon, AO; Mahfoudh, S. 2020), when the MAC protocols are applied to the case ( Jornet, JM; Pujol, JC; Pareta, JS 2012 ), methods for debugging errors in signals ( Jornet, JM; Pierobon, M .; Akyildiz, IF 2008), or the modulation of pulses in femtoseconds in the terahertz band for nano-communication networks (Jornet, JM; Akyildiz, IF 2014), the parameterization of nano-networks for their perpetual operation ( Yao, XW; Wang, WL; Yang, SH 2015), and performance in wireless signal modulation for nano-networks ( Zarepour, E .; Hassan, M .; Chou, CT; Bayat, S. 2015 ). In all cases, nano-transceivers are essential to be able to receive or emit a TS-OOK signal. 

 


Fig. 12. Nano-micrometric scale crystals can play the role of an antenna or a transceiver, which makes it possible to imagine that finding the circuit in a quadrangular structure is not the product of chance. (Ge, D .; Marguet, S.; Issa, A .; Jradi, S.; Nguyen, TH; Nahra, M .; Bachelot, R. 2020)

Plasmonic nanoemitters can acquire a cube shape, which would be what was observed observed in the vaccine sample, but also a spherical and discoidal shape, which can self-assemble to form larger nano-microstructures ( Devaraj, V .; Lee, JM; Kim , YJ; Jeong, H .; Oh, JW 2021 ). Among the materials with which this plasmonic nano-emitter could be produced are gold, silver, perovskites and graphene, see ( Oh, DK; Jeong, H .; Kim, J .; Kim, Y .; Kim, I .; Ok, JG; Rho, J. 2021 | Hamedi, HR; Paspalakis, E .; Yannopapas, V. 2021 | Gritsienko, AV; Kurochkin, NS; Lega, PV; Orlov, AP; Ilin, AS; Eliseev, SP; Vitukhnovsky , AG 2021 | Pierini, S. 2021), although it is likely that many others can also be used.

CAM and TCAM memory for MAC and IP

If the presence of nanorouters in vaccines is considered, the hypothesis of the existence of one or more MAC addresses (fixed or dynamic) could be confirmed, which could be emitted from vaccinated people or through some other intermediary device (for example a mobile phone). This approach is in line with what has already been explained and evidenced in this publication, but also according to scientific publications on nano-communication networks for the human body . According to (Abadal, S .; Liaskos, C .; Tsioliaridou, A .; Ioannidis, S .; Pitsillides, A .; Solé-Paret, J .; Cabellos-Aparicio, A. 2017) these MAC addresses allow the nano-network to transmit and receive data, since the individual has a unique identifier that allows them to access the medium. That is, the Internet. In this way, the nano-router can receive the signals corresponding to the data from the nano-sensors and nano-nodes of the nano-network to transmit them to the outside of the body, as long as there is a mobile device in the vicinity, which serves gateway to the Internet. Therefore, the hypothesis is feasible that MAC addresses of vaccinated people can be observed (by means of bluetooth signal tracking applications) when there is some type of interaction with the mobile media that act as a link. This does not mean that there is permanent communication, due to the need to save and optimize energy consumption ( Mohrehkesh, S .; Weigle, MC 2014 | Mohrehkesh, S .; Weigle, MC; Das, SK 2015), which could explain intermittence in communications, that is, periods of connection and inactivity.

The novelty in the field of MAC addresses, which comes together with the QCA circuits, with which nanorouters can be developed, is that memory circuits can also be created. The same researchers (Sardinha, LH; Silva, DS; Vieira, MA; Vieira, LF; Neto, OPV 2015) developed a new type of CAM memory that "unlike random access memory (RAM), which returns data which is stored at the given address, CAM, however, receives the data as input and returns where the data can be found. CAM is useful for many applications that need fast lookups, such as Hought transforms, Huffman encoding, Lempel-Ziv compression, and network switches to map MAC addresses to IP addresses and vice versa. CAM is most useful for creating tables that look for exact matches, such as MAC address tables." This statement was extracted and copied verbatim to highlight that QCA circuits are the answer to MAC address storage and management for data transmission in nano-networks, which would confirm that the vaccines are, among other things, a means of installing hardware for the control, modulation and monitoring of people.

 


Fig. 13. Memory circuits for the storage of MAC and IP addresses made with the same QCA technology of the nanorouter observed in the Pfizer vaccine samples. (Sardinha, LH; Silva, DS; Vieira, MA; Vieira, LF; Neto, OPV 2015)

Additionally, (Sardinha, LH; Silva, DS; Vieira, MA; Vieira, LF; Neto, OPV 2015) also developed the TCAM memory, which is a special type of CAM memory that would be useful to "create tables to search for longer matches, such as IP routing tables organized by IP prefixes. To reduce latency and make communication faster, routers use TCAM". This statement clearly affects its use in nano-routers in order to be able to transmit the data obtained in the nano-network to a specific recipient server accessible on the Internet. In other words, the data collected by the nano-network should be stored / registered in a database, of which the vaccine recipient would be unaware and uninformed, and without any knowledge of which information is being used.



Bibliography


  1. Akyildiz, IF; Jornet, JM (2010). Electromagnetic wireless nanosensor networks = Electromagnetic wireless nanosensor networks. Nano Communication Networks, 1 (1), pp. 3-19. https://doi.org/10.1016/j.nancom.2010.04.001

  2. Al-Turjman, F. (2020). Intelligence and security in a big 5G-oriented IoNT: overview = Intelligence and security in big 5G-oriented IoNT: An overview. Future Generation Computer Systems, 102, pp. 357-368. https://doi.org/10.1016/j.future.2019.08.009

  3. Balasubramaniam, S .; Boyle, NT; Della-Chiesa, A .; Walsh, F .; Mardinoglu, A .; Botvich, D .; Prina-Mello, A. (2011). Development of artificial neuronal networks for molecular communication. Nano Communication Networks, 2 (2-3), pp. 150-160. https://doi.org/10.1016/j.nancom.2011.05.004

  4. Balghusoon, AO; Mahfoudh, S. (2020). Routing Protocols for Wireless Nanosensor Networks and Internet of Nano Things: A Comprehensive Survey. IEEE Access, 8, pp. 200724-200748. https://doi.org/10.1109/ACCESS.2020.3035646


  1. Beyene, AG; Delevich, K .; Del Bonis-O'Donnell, JT; Piekarski, DJ; Lin, WC; Thomas, AW; Landry, MP (2019). Imaging striatal dopamine release using a nongenetically encoded near infrared fluorescent catecholamine nanosensor. Science advances, 5 (7), eaaw3108. https://doi.org/10.1126/sciadv.aaw3108

  2. Bornhoeft, LR; Castillo, AC; Smalley, PR; Kittrell, C .; James, DK; Brinson, BE; Cherukuri, P. (2016). Teslaphoresis of carbon nanotubes = Teslaphoresis of carbon nanotubes. ACS nano, 10 (4), pp. 4873-4881. https://doi.org/10.1021/acsnano.6b02313

  3. Bouchedjera, IA; Aliouat, Z .; Louail, L. (2020). EECORONA: Energy Efficiency Coordinate and Routing System for Nanonetworks = EECORONA: Energy Efficiency Coordinate and Routing System for Nanonetworks. In: International Symposium on Modeling and Implementation of Complex Systems. Cham. pp. 18-32. https://doi.org/10.1007/978-3-030-58861-8_2

  4. Bouchedjera, IA; Louail, L .; Aliouat, Z .; Harous, S. (2020). DCCORONA: Distributed Cluster-based Coordinate and Routing System for Nanonetworks = DCCORONA: Distributed Cluster-based Coordinate and Routing System for Nanonetworks. In: 2020 11th IEEE Annual Ubiquitous Computing, Electronics & Mobile Communication Conference (UEMCON). IEEE. pp. 0939-0945. https://doi.org/10.1109/UEMCON51285.2020.9298084

  5. Campra, P. (2021a). Observations of possible microbiotics in COVID RNAm Version 1. vaccines. Http://dx.doi.org/10.13140/RG.2.2.13875.55840

  6. Campra, P. (2021b). Detection of graphene in COVID19 vaccines by Micro-RAMAN spectroscopy. https://www.researchgate.net/publication/355684360_Deteccion_de_grafeno_en_vacunas_COVID19_por_espectroscopia_Micro-RAMAN

  7. Campra, P. (2021c). MICROSTRUCTURES IN COVID VACCINES: Inorganic crystals or Wireless Nanosensors Network? https://www.researchgate.net/publication/356507702_MICROSTRUCTURES_IN_COVID_VACCINES_inorganic_crystals_or_Wireless_Nanosensors_Network

  8. Chopra, N .; Phipott, M ​​.; Alomainy, A .; Abbasi, QH; Qaraqe, K .; Shubair, RM (2016). THz time domain characterization of human skin tissue for nano-electromagnetic communication. In: 2016 16th Mediterranean Microwave Symposium (MMS) (pp. 1-3). IEEE. https://doi.org/10.1109/MMS.2016.7803787

  9. Da-Costa, MR; Kibis, OV; Portnoi, ME (2009). Carbon nanotubes as a basis for terahertz emitters and detectors = Carbon nanotubes as a basis for terahertz emitters and detectors. Microelectronics Journal, 40 (4-5), pp. 776-778. https://doi.org/10.1016/j.mejo.2008.11.016

  10. Das, B .; Das, JC; From d.; Paul, AK (2017). Nano-Router Design for Nano-Communication in Single Layer Quantum Cellular Automata = Nano-Router Design for Nano-Communication in Single Layer Quantum Cellular Automata. In: International Conference on Computational Intelligence, Communications, and Business Analytics (pp. 121-133). Springer, Singapore. https://doi.org/10.1007/978-981-10-6430-2_11

  11. Demoustier, S .; Minoux, E .; Le Baillif, M .; Charles, M .; Ziaei, A. (2008). Review of two microwave applications of carbon nanotubes: nano antennas and nanointerruptores = Revue d'applications des nanotubes de carbone aux micro-ondes: nano-antennes et nano-commutateurs = Review of two microwave applications of carbon nanotubes: nano-antennas and nano-switches. Comptes Rendus Physique, 9 (1), pp. 53-66. https://doi.org/10.1016/j.crhy.2008.01.001

  12. Devaraj, V .; Lee, JM; Kim, YJ; Jeong, H .; Oh, JW (2021). [Pre-print]. Designing an Efficient Self-Assembled Plasmonic Nanostructures from Spherical Shaped Nanoparticles. Designing an Efficient Self-Assembled Plasmonic Nanostructures from Spherical Shaped Nanoparticles. International Journal of Molecular Science. https://www.preprints.org/manuscript/202109.0225/v1

  13. Dhoutaut, D .; Arrabal, T .; Dedu, E. (2018). Bit Simulator, an electromagnetic nanonetworks simulator = Bit simulator, an electromagnetic nanonetworks simulator. In: Proceedings of the 5th ACM International Conference on Nanoscale Computing and Communication (pp. 1-6). https://doi.org/10.1145/3233188.3233205

  14. Fabbro, A .; Cellot, G .; Prato, M .; Ballerini, L. (2011). Interconnection of neurons with carbon nanotubes: (re) engineering neuronal signaling = Interfacing neurons with carbon nanotubes: (re) engineering neuronal signaling. Progress in brain research, 194, pp. 241-252. https://doi.org/10.1016/B978-0-444-53815-4.00003-0

  15. Ferjani, H .; Touati, H. (2019). Data communication in electromagnetic nano-networks for healthcare applications = Data communication in electromagnetic nano-networks for healthcare applications. In: International Conference on Mobile, Secure, and Programmable Networking (pp. 140-152). Springer, Cham. https://doi.org/10.1007/978-3-030-22885-9_13

  16. Ge, D .; Marguet, S .; Issa, A .; Jradi, S .; Nguyen, TH; Nahra, M .; Bachelot, R. (2020). Hybrid plasmonic nano-emitters with controlled single quantum emitter positioning on the local excitation field. Nature communications, 11 (1), pp1-11. https://doi.org/10.1038/s41467-020-17248-8

  17. Gritsienko, AV; Kurochkin, NS; Lega, PV; Orlov, AP; Ilin, AS; Eliseev, SP; Vitukhnovsky, AG (2021). Optical properties of new hybrid nanoantenna in submicron cavity = Optical properties of new hybrid nanoantenna in submicron cavity. In: Journal of Physics: Conference Series (Vol. 2015, No. 1, p. 012052). IOP Publishing. https://doi.org/10.1088/1742-6596/2015/1/012052

  18. Hamedi, HR; Paspalakis, E .; Yannopapas, V. (2021). Effective Control of the Optical Bistability of a Three-Level Quantum Emitter near a Nanostructured Plasmonic Metasurface. In: Photonics (Vol. 8, No. 7, p. 285). Multidisciplinary Digital Publishing Institute. https://doi.org/10.3390/photonics8070285

  19. Hu, W .; Sarveswaran, K .; Lieberman, M .; Bernstein, GH (2005). High resolution electron beam lithography and DNA nanopatterns for molecular QCA. IEEE Transactions on Nanotechnology, 4 (3), pp. 312-316. https://doi.org/10.1109/TNANO.2005.847034

  20. Huang, G .; Huang, H. (2018). Application of dextran as nanoscale drug carriers. Nanomedicine, 13 (24), pp. 3149-3158. https://doi.org/10.2217/nnm-2018-0331

  21. Huang, J .; Momenzadeh, M .; Lombardi, F. (2007). Design of sequential circuits by quantum-dot cellular automata. Microelectronics Journal, 38 (4-5), pp. 525-537. https://doi.org/10.1016/j.mejo.2007.03.013

  22. Huang, J .; Xie, G .; Kuang, R .; Deng, F .; Zhang, Y. (2021). QCA-based Hamming code circuit for nano communication networks = QCA-based Hamming code circuit for nano communication network. Microprocessors and Microsystems, 84, 104237. https://doi.org/10.1016/j.micpro.2021.104237

  23. John, AA; Subramanian, AP; Vellayappan, MV; Balaji, A .; Mohandas, H .; Jaganathan, SK (2015). Carbon nanotubes and graphene as emerging candidates in neuroregeneration and neurodrug delivery = Carbon nanotubes and graphene as emerging candidates in neuroregeneration and neurodrug delivery. International journal of nanomedicine, 10, 4267. https://dx.doi.org/10.2147%2FIJN.S83777

  24. Jornet, JM; Akyildiz, IF (2014). Long femtosecond pulse-based modulation for terahertz band communication in nanonetworks = Femtosecond-long pulse-based modulation for terahertz band communication in nanonetworks. IEEE Transactions on Communications, 62 (5), pp. 1742-1754. https://doi.org/10.1109/TCOMM.2014.033014.130403

  25. Jornet, JM; Pierobon, M .; Akyildiz, IF (2008). Nanocommunication Networks = Nano Communication Networks. Networks (Elsevier), 52, pp. 2260-2279. http://dx.doi.org/10.1016/j.nancom.2014.04.001

  26. Jornet, JM; Pujol, JC; Pareta, JS (2012). PHLAME: A physical layer aware mac protocol for electromagnetic nanonetworks in the terahertz band. Nano Communication Networks, 3 (1), pp. 74-81. https://doi.org/10.1016/j.nancom.2012.01.006

  27. Kumar, MR (2019). A compact graphene-based nano-antenna for communication in nano-networks = A Compact Graphene Based Nano-Antenna for Communication in Nano-Network. Journal of the Institute of Electronics and Computer, 1 (1), pp. 17-27. https://doi.org/10.33969/JIEC.2019.11003

  28. Laajimi, R .; Niu, M. (2018). Nanoarchitecture of Quantum-Dot Cellular Automata (QCA) Using Small Area for Digital Circuits. Advanced Electronics Circuits – Principles, Architectures and Applications on Emerging Technologies, pp. 67-84. https://www.intechopen.com/chapters/58619

  29. Lee, SJ; Jung, C .; Choi, K .; Kim, S. (2015). Design of wireless nanosensor networks for intrabody application. International Journal of Distributed Sensor Networks, 11 (7), 176761. https://doi.org/10.1155/2015/176761

  30. Lu, J .; Yeo, PSE; Gan, CK; Wu, P .; Loh, KP (2011). Transforming C60 molecules into graphene quantum dots = Transforming C60 molecules into graphene quantum dots. Nature nanotechnology, 6 (4), pp. 247-252. https://doi.org/10.1038/nnano.2011.30

  31. Massicotte, M .; Yu, V .; Whiteway, E .; Vatnik, D .; Hilke, M. (2013). Quantum Hall effect in fractal graphene: growth and properties of graphlocons = Quantum Hall effect in fractal graphene: growth and properties of graphlocons. Nanotechnology, 24 (32), 325601. https://doi.org/10.1088/0957-4484/24/32/325601

  32. Mitragotri, S .; Anderson, DG; Chen, X .; Chow, EK; Ho, D .; Kabanov, AV; Xu, C. (2015). Accelerating the translation of nanomaterials in biomedicine = Accelerating the translation of nanomaterials in biomedicine. ACS nano, 9 (7), pp. 6644-6654. https://doi.org/10.1021/acsnano.5b03569

  33. Mohammadyan, S .; Angizi, S .; Navi, K. (2015). New fully single layer QCA full-adder cell based on feedback model. International Journal of High Performance Systems Architecture, 5 (4), pp. 202-208. https://doi.org/10.1504/IJHPSA.2015.072847

  34. Mohrehkesh, S .; Weigle, MC (2014). Optimizing energy consumption in terahertz band nanonetworks. IEEE Journal on Selected Areas in Communications, 32 (12), pp. 2432-2441. https://doi.org/10.1109/JSAC.2014.2367668

  35. Mohrehkesh, S .; Weigle, MC; Das, SK (2015). DRIH-MAC: A distributed receiver-initiated harvesting-aware MAC for nanonetworks. IEEE Transactions on Molecular, Biological and Multi-Scale Communications, 1 (1), pp. 97-110. https://doi.org/10.1109/TMBMC.2015.2465519

  36. Oh, DK; Jeong, H .; Kim, J .; Kim, Y .; Kim, I .; Ok, JG; Rho, J. (2021). Top-down nanofabrication approaches toward single-digit-nanometer scale structures. Journal of Mechanical Science and Technology, pp. 1-23. https://doi.org/10.1007/s12206-021-0243-7

  37. Patriarchi, T .; Cho, JR; Merten, K .; Howe, MW; Marley, A .; Xiong, WH; Tian, ​​L. (2018). Ultrafast neuronal imaging of dopamine dynamics with designed genetically encoded sensors. Science, 360 (6396). https://doi.org/10.1126/science.aat4422

  38. Patriarchi, T .; Mohebi, A .; Sun, J .; Marley, A .; Liang, R .; Dong, C .; Tian, ​​L. (2020). An expanded palette of dopamine sensors for multiplex imaging in vivo. Nature methods, 17 (11), pp. 1147-1155. https://doi.org/10.1038/s41592-020-0936-3

  39. Pierini, S. (2021). [Preprint]. Experimental study of perovskite nanocrystals as single photon sources for integrated quantum photonics. Arxiv. https://arxiv.org/pdf/2105.14245.pdf

  40. Pierobon, M .; Jornet, JM; Akkari, N .; Almasri, S .; Akyildiz, IF (2014). A routing framework for energy harvesting wireless nanosensor networks in the Terahertz Band. Wireless networks, 20 (5), pp. 1169-1183. https://doi.org/10.1007/s11276-013-0665-y

  41. Pillers, M .; Goss, V .; Lieberman, M. (2014). Electron-beam lithography and molecular liftoff for directed attachment of DNA nanostructures on silicon: Top-down meets bottom-up = Electron-beam lithography and molecular liftoff for directed attachment of DNA nanostructures on silicon: Top-down meets bottom-up. Accounts of chemical research, 47 (6), pp. 1759-1767. https://doi.org/10.1021/ar500001e

  42. Reis, DA; Torres, FS (2016). A Defects Simulator for Robustness Analysis of QCA Circuits. QCA = A Defects Simulator for Robustness Analysis of QCA Circuits. Journal of Integrated Circuits and Systems, 11 (2), pp. 86-96. https://doi.org/10.29292/jics.v11i2.433

  43. Sadeghi, M .; Navi, K .; Dolatshahi, M. (2020). New efficient full adder and full subtractor designs in quantum cellular automata = Novel efficient full adder and full subtractor designs in quantum cellular automata. The Journal of Supercomputing, 76 (3), pp. 2191-2205. https://doi.org/10.1007/s11227-019-03073-4

  44. Sardinha, LH; Costa, AM; Net, OPV; Vieira, LF; Vieira, MA (2013). NanoRouter: a quantum-dot cellular automata design = Nanorouter: a quantum-dot cellular automata design. IEEE Journal on Selected Areas in Communications, 31 (12), pp. 825-834. https://doi.org/10.1109/JSAC.2013.SUP2.12130015

  45. Sardinha, LH; Silva, DS; Vieira, MA; Vieira, LF; Neto, OPV (2015). TCAM / CAM-QCA: Content addressable memory using quantum-dot cellular automata = Tcam / cam-qca: (ternary) content addressable memory using quantum-dot cellular automata. Microelectronics Journal, 46 (7), pp. 563-571. https://doi.org/10.1016/j.mejo.2015.03.020

  46. Sarveswaran, K. (2004). [Reserved document]. Self-assembly and lithographic patterning of DNA rafts. DARPA Conf. Foundations of Nanoscience: Self-Assembled Architectures and Devices, Snowbird, UT. [Link not available

  47. Strukov, DB; Snider, GS; Stewart, DR; Williams, RS (2009). The missing memristor found The missing memristor found. Nature, 459 (7250), 1154. https://doi.org/10.1038/nature06932

  48. Sun, F .; Zhou, J .; Dai, B .; Qian, T .; Zeng, J .; Li, X .; Li, Y. (2020). Next-generation GRAB sensors for monitoring dopaminergic activity in vivo = Next-generation GRAB sensors for monitoring dopaminergic activity in vivo. Nature methods, 17 (11), pp. 1156-1166. https://doi.org/10.1038/s41592-020-00981-9

  49. Suzuki, J .; Budiman, H .; Carr, TA; DeBlois, JH (2013). A simulation framework for neuron-based molecular communication. Procedia Computer Science, 24, pp. 103-113. https://doi.org/10.1016/j.procs.2013.10.032

  50. Tsioliaridou, A .; Liaskos, C .; Ioannidis, S .; Pitsillides, A. (2015). CORONA: A Coordinate and Routing system for Nanonetworks = CORONA: A Coordinate and Routing system for Nanonetworks. In: Proceedings of the second annual international conference on nanoscale computing and communication. pp. 1-6. https://doi.org/10.1145/2800795.2800809 | https://sci-hub.mksa.top/10.1145/2800795.2800809

  51. Vassiliou, V. (2011). Security issues in nanoscale communication networks. 3rd NaNoNetworking Summit, pp. 1-53. http://www.n3cat.upc.edu/n3summit2011/presentations/Security_Issues_in_Nanoscale_Communication_Networks.pdf

  52. Vavouris, AK; Dervisi, FD; Papanikolaou, VK; Karagiannidis, GK (2018). An energy efficient modulation scheme for body-centric nano-communications in the THz band. In: 2018 7th International Conference on Modern Circuits and Systems Technologies (MOCAST) (pp. 1-4). IEEE. https://doi.org/10.1109/MOCAST.2018.8376563

  53. Wang, ZF; Liu, F. (2011). Graphene quantum dots as building blocks for quantum cellular automata = Nanopatterned graphene quantum dots as building blocks for quantum cellular automata. Nanoscale, 3 (10), pp. 4201-4205. https://doi.org/10.1039/C1NR10489F

  54. Wang, WL; Wang, CC; Yao, XW (2019). MAC protocol based on energy harvesting nano-networks = Slot self-allocation based mac protocol for energy harvesting nano-networks. Sensors, 19 (21), 4646. https://doi.org/10.3390/s19214646

  55. Wang, Y .; Wu, Q .; Shi, W .; He, X .; Sun, X .; Gui, T. (2008). Radiation properties of carbon nanotubes antenna at terahertz / infrared range = Radiation properties of carbon nanotubes antenna at terahertz / infrared range. International Journal of Infrared and Millimeter Waves, 29 (1), pp. 35-42. https://doi.org/10.1007/s10762-007-9306-9

  56. Xia, Y .; Qiu, K. (2008). Design and application of universal logic gate based on quantum-dot cellular automata. In: 2008 11th IEEE International Conference on Communication Technology (pp. 335-338). IEEE. https://doi.org/10.1109/ICCT.2008.4716260 | https://sci-hub.mksa.top/10.1109/ICCT.2008.4716260

  57. Yao, XW; Wang, WL; Yang, SH (2015). Joint parameter optimization for perpetual nanonetworks and maximum network capacity. IEEE Transactions on Molecular, Biological and Multi-Scale Communications, 1 (4), pp. 321-330. https://doi.org/10.1109/TMBMC.2016.2564967

  58. Yu, J .; Zhang, Y .; Yan, J .; Kahkoska, AR; Gu, Z. (2018). Advances in bioresponsive closed-loop drug delivery systems. International journal of pharmaceutics, 544 (2), pp. 350-357. https://doi.org/10.1016/j.ijpharm.2017.11.064

  59. Zarepour, E .; Hassan, M .; Chou, CT; Bayat, S. (2015). Performance analysis of carrier-less modulation schemes for wireless nanosensor networks. In: 2015 IEEE 15th International Conference on Nanotechnology (IEEE-NANO) (pp. 45-50). IEEE. https://doi.org/10.1109/NANO.2015.7388653

  60. Zhang, R .; Yang, K .; Abbasi, QH; Qaraqe, KA; Alomainy, A. (2017). Analytical characterization of the terahertz in-vivo nano-network in the presence of interference based on TS-OOK communication scheme in the presence of interference based on TS-OOK communication scheme. IEEE Access, 5, pp. 10172-10181. https://doi.org/10.1109/ACCESS.2017.2713459

 

Source:  https://www.notonthebeeb.co.uk/post/chipped

Dr. Luis de Benito: how MAC addresses may be generated in vaxxed individuals: 

Nenhum comentário:

Postar um comentário