Are you a Targeted Individual? Do you have strange vibrations, painful sensations and pressure in and on your body? There are general sensations which make you feel vibrations or heat, an implant provides a tool to torture you repeatedly or continuously in the same place.
This misused technology uses implants to guide energy (inductive coupling) to your body to produce psychological effects and physiological pain. This page will provide links to articles you can print and show to the uninformed and nonbelievers to prove that these technologies exist, you know about them and that they are being used illegally on you against your will to degrade your health and rob you of your life, liberty and pursuit of happiness. Happiness requires control of your own mind and body and freedom to choose who to socialize with or to be left alone to develop your own thoughts. If someone takes control of your ability to think for yourself, you are no longer free to pursue anything. Technology can deprive you of the life God gave you and it can take all your rights away. This is being done to Targeted Individuals and has been taking the lives of humans in the name of research for decades in human experiments.
Beaming radio and microwave frequencies at someone to injure or cause them pain is a criminal assault. Assault deprives you of your Constitutional right to refuse this technology. The US Constitution assures your freedom from human experimentation, however, recent Executive Orders are allowing this assaault.
The Patriot Act was hastily signed to institute an illegal War on Terror using so-called non-lethal weapons using directed energy and implants for tracking and punishment. The US Government and other countries are using the technology to torture people using a 24 hour regimen of sleep deprivation, repeated covert implantation, vibration of the whole body and body parts, radiation burning and maiming, inducement of diseases such as diabetes and joint degradation, body modification (reducing bones in size and reducing cartilage from ears and face) and other cruel and unusual acts which take away the freedom God gave us and the life the Constitution assures us.
The first article I have chosen is a brilliant overview of implants, both chronic (permanent) and acute (temporary). Implants are a medical procedure and when they are done covertly, they constitute vandalism of personal property and institution of slavery over a human being. You no longer own you body and its functions. Someone else has control over your body, therefore, you are their slave.
You may make a personal decision based on what you know about who is doing this to you. However, this plan is outlined in the Patriot Act. The US Goverment contracts with companies who hire people who oversee your individual torture, keep a detailed record of when implants were done, what was done to torture you each day and a personal overall plan for your individual torture. How do we know this? Different people talk about how they are tortured, some are the same, some are different but fit the implant/torture criteria, some being age dependent. Different types of implants are in different people. Someone chooses which implants will be used to torture each individual. Who are these people and where do they go to work every day. How long are their shifts? How much are they paid? Do they have a retirement plan? How long will you be tortured. All indications are that once you are in the torture program, it is for life.
Where are the radio/microwave/ultrasound frequencies coming from, your neighbor's homes, city/utility infrastructure, cell towers, satellites, or all of them, using installations as relays of energy beams. Hopefully by learning about what kind of implants you have, you can find out what they need in the way of power or stimulation from outside sources and connect your implants with the source of energy being used to torture you and the people doing it. There is much work to be done on this subject.
If you work at a job torturing people and decide to become a whistleblower, please step forward and help humanity before they do this to you too. It is inevitable that everyone will become sick, handicapped or elderly. These are the people they are attacking first to cleanse humanity like Hitler did. He emptied the hospitals and used nurses and doctors to do it. That didn't last and neither will this regime against life and liberty. Good will prevail.
Wireless Sensor Networks
"The range of wearable and implantable biomedical devices will increase significantly in the next years, thanks to the improvements in micro-electro-mechanical systems (MEMS) technology, wireless communications, and digital electronics, achieved in recent years . These advances have allowed the development of low-cost, low power, multi-functional sensor nodes that are small in size and can communicate over short distances, and tiny sensor nodes, which consist of sensing, data processing, and communicating components, and to take advantage of the idea of sensor networks based on collaborative effort of a large number of nodes."
NearField Inductive Coupling
IEEE Transactions on Biomedical Engineering PP(99):1-1
We report design, fabrication and in-vivo animal testing of a MEMS-based wireless battery-free compact (3.1 Ã 1.5 Ã 0.3 mm) neurostimulator for the treatment of chronic pain. The neurostimulator consists of a spiral coil for inductive power coupling, Schottky diodes for rectification, an ASIC neurostimulator circuit chip, and biphasic platinum-iridium (PtIr) stimulation electrodes. The device is fully integrated and completely embedded in biocompatible SU-8 packaging. The wireless neurostimulator was implanted subcutaneously in a rat hind limb and stable and robust cortical responses during extended periods of wireless stimulation with as low as 21 dBm (125 mW) RF power at 394 MHz were recorded.
MEMS-based Pressure Systems
Integrated Sensing Systems, Inc. (ISSYS), an Ypsilanti,
MI company, has announced that “the U.S. Patent Office
has granted a patent titled “System for monitoring conduit
obstruction” (U.S. Patent No. 7,211,048), which covers the design and manufacturing of a wireless implantable sensing system for non-invasive monitoring of pressure and/or pressure gradients in a cardiac conduit.”
This is certainly not the first batteryless MEMS pressure monitoring device that we’ve seen around here. The EndoSure™ Wireless AAA Pressure Measurement System from CardioMEMS, Inc. has been 510(k)’ed by the FDA two years ago. What’s different about this system is its super-miniature size, designed to fit inside the diagnostic catheter for delivery into atrium, or into palliative shunts and conduits in pediatric heart patients, or into hydrocephalus shunts.
Company explains its technology:
Certain heart defects require implantation of a cardiac blood flow conduit in order to bypass valve aplasia or severe stenosis. One of the main issues with implanted cardiac conduits is that over time calcification or stenosis will occur and, in nearly all cases, occlusion will occur eventually. ISSYS’ novel implantable wireless sensing system allows physicians a means for accurate and non-invasive monitoring of conduit condition on a continuous basis. Using the data provided by ISSYS’ sensors, physicians can continuously monitor both pressure and blood flow rate within the conduit, in order to determine whether and when conduit revision is required. Furthermore, remote monitoring of conduit condition would simultaneously reduce the number of hospital and clinic visits while increasing the overall timeliness of treatment…
The pressure monitoring system consists of two major parts: an implantable, batteryless, telemetric sensor and a companion hand-held reader. The miniature implantable micro-device, suitable for implantation directly (via a custom catheter for minimally invasive, outpatient procedure), contains a MEMS pressure sensor along with custom electronics and an antenna for both wireless communication and tele-powering.
Using magnetic telemetry, the reader transmits power to the sensor and the sensed pressure is in turn transmitted back to the reader. Small size, optimized shape, and careful choice of materials ensure implant biocompatibility and non-thrombogenicity. Furthermore, the implant is delivered with a specially designed catheter as a low-cost outpatient procedure. Data collected by the sensor will be used by physicians to tailor treatment of the selected disease.
MEMS: Laying The Foundation For Exciting Applications
RF, biomedical, and geophysical/environment fields will be key beneficiaries.
Although microelectromechanical system (MEMS) devices started out as sensors—mostly for automotive at first, and later for medical applications—the technology has now mushroomed into commercialization in a number of other arenas. In fact, MEMS technology is proving to be a key enabler for many implementations hitherto not possible or practical with conventional electronic devices. Furthermore, it promises to become even more prevalent in at least three "killer" applications: RF, biomedical, and geophysical/environmental fields.
This is a great place to add a tagline.
Micro-Electro-Mechanical Systems, or MEMS, is a technology that in its most general form can be defined as miniaturized mechanical and electro-mechanical elements (i.e., devices and structures) that are made using the techniques of microfabrication.
The critical physical dimensions of MEMS devices can vary from well below one micron on the lower end of the dimensional spectrum, all the way to several millimeters. Likewise, the types of MEMS devices can vary from relatively simple structures having no moving elements, to extremely complex electromechanical systems with multiple moving elements under the control of integrated microelectronics.
The one main criterion of MEMS is that there are at least some elements having some sort of mechanical functionality whether or not these elements can move.
The term used to define MEMS varies in different parts of the world. In the United States they are predominantly called MEMS, while in some other parts of the world they are called “Microsystems Technology” or “micromachined devices”.
While the functional elements of MEMS are miniaturized structures, sensors, actuators, and microelectronics, the most notable (and perhaps most interesting) elements are the microsensors and microactuators.
Microsensors and microactuators are appropriately categorized as “transducers”, which are defined as devices that convert energy from one form to another. In the case of microsensors, the device typically converts a measured mechanical signal into an electrical signal.
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Matthew W. Urban,b) Mostafa Fatemi, and James F. Greenleaf
Dynamic radiation force has been used in several types of applications, and is performed by modulating ultrasound with different methods. By modulating ultrasound, energy can be transmitted to tissue, in this case a dynamic force to elicit a low frequency cyclic displacement to inspect the material properties of the tissue. In this paper, different types of modulation are explored including:
amplitude modulation (AM),
double sideband suppressed carrier amplitude modulation AM,
linear frequency modulation, and
Generalized theory is presented for computing the radiation force through the short-term time average of the energy density for these various types of modulation. Examples of modulation with different types of signals including sine waves, square waves, and triangle waves are shown. Using different modulating signals, multifrequency radiation force with different numbers of frequency components can be created, and can be used to characterize tissue mimicking materials and soft tissue. Results for characterization of gelatin phantoms using a method of vibrating an embedded sphere are presented. Different degrees of accuracy were achieved using different modulation techniques and modulating signals. Modulating ultrasound is a very flexible technique to produce radiation force with multiple frequency components that can be used for various applications.
Abstract: Several conditions and diseases are linked to the elevation or depression of internal pressures from a healthy, normal range, motivating the need for chronic implantable pressure sensors. A simple implantable pressure transduction system consists of a pressure-sensing element with a method to transmit the data to an external unit. The biological environment presents a host of engineering issues that must be considered for long term monitoring. Therefore, the design of such systems must carefully consider interactions between the implanted system and the body, including biocompatibility, surgical placement, and patient comfort. Here we review research developments on implantable sensors for chronic pressure monitoring within the body, focusing on general design requirements for implantable pressure sensors as well as specifications for different medical applications. We also discuss recent efforts to address biocompatibility, efficient telemetry, and drift management, and explore emerging trends.
Stanford Engineering Team Invents Pressure Sensor That Uses Radio Waves
Posted on August 7, 2015 by Admin
Optobionics’ Artificial Silicon Retina™ microchip (ASR™) was invented by Dr. Alan Chow and his brother Vincent Chow. Dr. Chow is an ophthalmic surgeon and assistant professor and his brother Vincent is an electrical engineer. The ASR was designed to stimulate damaged retinal cells from within the retina to allow the cells to recreate visual signals that are processed and sent to the brain. The ASR microchip is a silicon chip 2 mm in diameter, 25 microns in thickness and is less than the thickness of a human hair. It fabricated using technology similar to that used in the fabrication of computer chips and contains approximately 5,000 microscopic solar cells called “microphotodiodes,” each with its own stimulating electrode.
In retinas with retinal degeneration, these microphotodiodes convert light energy contained in images into electrochemical impulses that stimulate the remaining retinal cells. The ASR microchip is self-contained, powered solely by incident light and does not require the use of external wires, batteries, headsets or ancillary computers.
When surgically implanted under the retina—in a location known as “subretinal space”—the ASR chip is designed to produce visual signals similar to those produced by the photoreceptor layer. From their subretinal location, these artificial “photoelectric” signals from the ASR microchip can induce visual signals in the remaining functional retinal cells which may are then processed and sent via the optic nerve to the brain.
In initial laboratory testing, animal models implanted with ASR devices responded to light stimuli with retinal electrical signals (ERGs) and sometimes brain-wave signals (VEPs). The induction of these biological signals by the ASR chip indicated that visual stimulation had occurred.
Based on these studies, the FDA approved the conduct of clinical trials in collaboration with several university and VA medical centers that began in June 2000. These centers included the Hines, Cleveland and Atlanta Veterans Administration Medical Centers, Rush University Medical Center, Johns Hopkins Wilmer Eye Institute and Emory University Medical Center. http://optobionics.com/asrdevice.shtml
Midfield Wireless Powering for Implantable Systems
Efficient wireless power transfer across tissue is highly desirable for removing bulky energy storage components. Most existing power transfer systems are conceptually based on coils linked by slowly varying magnetic fields (less than 10 MHz). These systems have many important capabilities, but are poorly suited for tiny, millimeter-scale implants where extreme asymmetry between the source and the receiver results in weak coupling. This paper first surveys the analysis of near-field power transfer and associated strategies to optimize
efficiency. It then reviews analytical models that show that significantly higher efficiencies can be obtained in the electro-magnetic midfield. The performance limits of such systems are explored through optimization of the source, and a numerical example of a cardiac implant demonstrates that millimeter-sized devices are feasible.
Their approach involves beaming ultrasound at a tiny device inside the body designed to do three things: convert the incoming sound waves into electricity; process and execute medical commands; and report the completed activity via a tiny built-in radio antenna.
In a piezoelectric material, pressure compresses its molecular structure much like a child jumping on a bed compresses the mattress. When the pressure abates, the piezoelectric material's molecular structure, like the mattress, springs back into shape.
Every time a piezoelectric structure is compressed and decompressed a small electrical charge is created. The Stanford team created pressure by aiming ultrasound waves at a tiny piece of piezoelectric material mounted on the device.
"The implant is like an electrical spring that compresses and decompresses a million times a second, providing electrical charge to the chip...."
The piezoelectric effect is the power delivery mechanism. In the future, the team plans to extend the capabilities of the implant chip to perform medical tasks, such as running sensors or delivering therapeutic jolts of electricity right where a patient feels pain.
Finally, the "smart chip" contains a radio antenna to beam back sensor readings or signal the completion of its therapeutic task.
"U.S. and European brain initiatives are pushing for a more complete understanding of the central nervous system," Solzbacher said. "This requires being able to interface with cells using arrays of micro implants across the entire 3D structure of the brain."
How implants powered by ultrasound can help monitor health
Using safe sound waves to deliver both energy and instructions, a team of researchers unveil a family of ‘electroceuticals’ — tiny devices designed to diagnose and treat disease.
December 04, 2017
By Tom Abate
"Each implant contains a power-receiving module that can convert the energy from ultrasound waves into usable electricity. This is based on the well-known principle of piezoelectricity – the subtle pressure exerted by sound waves can compress certain crystals in a way that creates a flow of electrons. According to tests thus far, their implants can be powered beyond 12 centimeters below the skin, or a bit under 5 inches – which is sufficient for targeting most any vital organ in the body."
Researchers in Prof. Amin Arbabian’s laboratory have developed a modular RF-Ultrasound architecture to download data, upload data or wirelessly charge devices implanted deep in the body. With this system, an exterior RF power unit transmits signal to an internal RF transceiver which then converts the energy to ultrasound that can propagate deeply into tissue with lower loss than electromagnetic energy. This platform could deliver data as well as generate power to a wireless node via piezoelectric materials. With appropriate tuning, this system could efficiently transmit a focused beam of ultrasound to a deeply situated implant without wires or batteries. In addition, the platform could be used in Internet of Things (IoT) applications.
Body area networks (BANs) promise to enable
revolutionary biomedical applications by
wirelessly interconnecting devices implanted
or worn by humans. However, BAN wireless
communications based on radio-frequency (RF) electromagnetic waves suffer from poor propagation of signals in body tissues,which leads to high levels of attenuation. In addition, in-body transmissions are constrained to be low-power to prevent over-heating of tissues and consequent death of cells.To address the limitations of RF propagation in the humanbody, we propose a paradigm shift by exploring the use of ultrasonic waves as the physical medium to wirelessly interconnecting body implanted devices. Acoustic waves are the transmission technology of choice for underwater communications, since they are known to propagate better than their RF counterpart inmedia composed mainly of water. Similarly, we envision that ultrasound (e.g., acoustic waves at non-audible frequencies) will provide support for communications in the human body, which is composed for 65% of water. In this paper, we first assess the fea-sibility of using ultrasonic communications in intra-body BANs,i.e., in-body networks where the devices are biomedical sensors that communicate with an actuator/gateway device located inside the body. We discuss the fundamentals of ultrasonic propagation in tissues, and explore important trade-offs, including the choice of a transmission frequency, transmission power, bandwidth, and transducer size. Then, we discuss future research challenges for ultrasonic networking of intra-body devices at the physical,medium access and network layers of the protocol stack.