Introduction
Electrical Conductivity, Metal, Water; Sea Water is usually one of the highest ratings in radar attenuation, it has ions and conducts electricity, and absorbs energy. If you think of a microwave oven water boils and metal "sparkles" but safe for most dry, plastic and ceramic type, and non-metallic containers. If you think of a Faraday Cage, it's a metallic enclosure that is grounded, when microwaves hit the metal the energy is absorbed and sent to or conducted to the ground.
If you think about ground penetrating radar it is the moisture of the ground, clays, and the ferric content, ferric sand and rocks, slate with iron for example. If you think about the industry, it's about the thickness and density of concrete that contains metal, and the use of lead, a very dense metal, to shield from x-rays and radar.
Ferric Slate Test
Water boils and metal "sparkles", iron absorbs radar, conducts the energy linked to the Faraday Cage application and generates heat. If you think of a simple test for the efficiency of ferric or graphite slate to absorb microwaves you can microwave different pieces for 15-30 seconds and compare the heat it generated, how hot the slate pieces are. Some will stay cold, no metal content or conductive content, and some will get hot, the one with a high metal content. (water and (graphite/carbon are dielectric, graphite is also conductive))
One attenuation research document claims that magnetic metals, MgZn and MnZn, are better than dielectric types at attenuating radar.
Lead is used in the industry for its density and relatively low cost but toxic, a neuro-toxin, iron is the cheapest metal.
GPR Attenuation Summary
The exponential attenuation coefficient, a, is primarily determined by the ability of the material to conduct electrical currents. In simple uniform materials this is usually the dominant factor; thus a measurement of electrical conductivity (or resistivity) determines attenuation.
In most materials energy is also lost to scattering from material variability and to water being present. Water has two effects; first, water contains ions which contribute to bulk conductivity. Second, the water molecule absorbs electromagnetic energy at high frequencies typically above 1000 MHz (exactly the same mechanism that accounts for why microwave ovens work).
Attenuation increases with frequency as depicted in Figure 2. In environments which are amenable to GPR sounding there is usually a plateau in the attenuation versus frequency curve which defines the "GPR window".
Attenuation varies with excitation frequency and material. This family of graphs depicts general trends. At low frequencies (<1 MHz) attenuation is primarily controlled by DC conductivity. At high frequencies (> 1000 MHz) water is a strong energy absorber.
Lowering frequency improves depth of exploration because attenuation primarily increases with frequency. As frequency decreases, however, two other fundamental aspects of the GPR measurement come into play.
Mobbing in Modern Society
Powerful radar, which is linked to different deadly cancers is being used in some countries to assault citizens in their own homes, it's an energy type weapon. One strategy example is that criminal allegations and insinuations the accused is dangerous, participants and uttering threats for example, are combined with power radar assaults over long and delayed judicial proceedings. Threats of intervention that leads to incarceration and assessment orders during the proceedings are used for any behavior linked to protection measures, shielding and attenuation. The threat of intervention that leads to incarceration and assessment orders is linked to possible attempts to sanction the allegations and possible police wrong doing such as entering a dwelling home without a warrant that amounts to trespassing for example through assessment orders before trial, abusive or unlawful procedures.
1. radar assaults
2. criminal allegations
3. insinuations that accused is dangerous
4. "you have to run", threats of intervention, incarceration, assessment orders,, cancer, homelessness
The criminal allegations trap the accused while the accused is assaulted with powerful radar, any violent reactions or behavior by the accused resulting from the radar assaults help fit the allegations and frame the accused.
Both the criminal allegations and radar assaults increase the expenses of the accused, and increased through wrongful or unlawful court orders needing appeals, transcripts, and legal services etc. The criminal allegations deplete finances needed to take action for radar shielding, and distract the accused who is assaulted by radar linked to cancer. The radar assaults are linked to a runaway and lawsuit deterrent strategy used in smear campaigns, false allegations, and malicious prosecution.
A strategy linked to the combination of criminal allegations and radar assaults is illustrated in the Movie Scene video Logan's Run, a run away strategy where runaways become fugitives or risk getting a deadly cancer "run away or get cancer" aka "Run Runner!".
http://ireport.cnn.com/docs/DOC-629378
Hidden homicides through the medical system, the powerful radar assaults over several months are linked to deadly cancers such as leukemia, lung cancer, bone cancer, colon, prostate, and testicular cancer.
Creating a vulnerability to the countries medical system, the mob or participating medical community members for coercion or to induce fear, inflict pain and suffering, to set an example similar to the use of homelessness.
The use of cancer in strategy by countries, the mob, etc, creates an incentive to prevent or repress cures cancer, with cures for cancer the hidden homicides are not successful and neither are the strategies.
Epidemiologic evidence relevant to radar (microwave) effects
"Four types of effects were originally reported in multiple studies: increased spontaneous abortion, shifts in red and white blood cell counts, increased somatic mutation rates in lymphocytes, and increased childhood, testicular, and other cancers."
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1469943/
[7] Abstract
Public and occupational exposures to microwave (RF) are of two main types. The first type of exposures are those connected with military and industrial uses and, to some extent broadcast exposures. It is this type that most of the data cited in this study draw upon. The second type, cellular telephones and their associated broadcast requirements, have raised concerns about current exposures because of their increasingly widespread use. Four types of effects were originally reported in multiple studies: increased spontaneous abortion, shifts in red and white blood cell counts, increased somatic mutation rates in lymphocytes, and increased childhood, testicular, and other cancers. In addition, there is evidence of generalized increased disability rates from a variety of causes in one study and symptoms of sensitivity reactions and lenticular opacity in at least one other. These findings suggest that RF exposures are potentially carcinogenic and have other health effects. Therefore, prudent avoidance of unneeded exposures is recommended as a precautionary measure. Epidemiologic studies of occupational groups such as military users and air traffic controllers should have high priority because their exposures can be reasonably well characterized and the effects reported are suitable for epidemiologic monitoring. Additional community studies are needed.
Industry Radar Attenuation
Powerful radar attenuation consists of using dense materials, lead is used by the industry but toxic, a neuro-toxin, it gets into the brain and bones, adding barium to cement, cement density and metal content.
Faraday Cages (shielding and attenuation)
Faraday Cages can be used to shield from radar and microwaves, a faraday cage is simply a metal inclosure that is grounded, as the radar hits the metal inclosure the energy is attenuated and dispersed towards the ground.
Faraday Cages and Radar Assaults
Faraday cages cannot block static and slowly varying magnetic fields, such as Earth's magnetic field (a compass will still work inside). To a large degree though, they also shield the interior from external electromagnetic radiation (radar for example) if the conductor is thick enough and any holes are significantly smaller than the radiation's wavelength.
For example, certain computer forensic test procedures of electronic components or systems that require an environment devoid of electromagnetic interference may be conducted within a screen room. These screen rooms are essentially work areas that are completely enclosed by one or more layers of fine metal mesh or perforated sheet metal.
The metal layers are grounded to dissipate any electric currents generated from the external electromagnetic fields and thus block a large amount of the electromagnetic interference. See also electromagnetic shielding.
The reception of external radio signals, a form of electromagnetic radiation, through an antenna within a cage can be greatly attenuated or even completely blocked by the cage itself.
1. Metal Inclosure (if the conductor is think enough, ex: metal plates/sheet).
2. The metal layers are grounded to dissipate any electric currents generated from the external electromagnetic radiation (ex: radio waves, radar).
3. The reception of external radio signals, a form of electromagnetic radiation (radar for example), through an antenna within a cage can be greatly attenuated or even completely blocked by the cage itself.
http://en.wikipedia.org/wiki/Faraday_cage
Evaluation of Road Pavement Density Using Ground Penetrating Radar
http://scialert.net/fulltext/?doi=jest.2009.100.111
From the Fig. 6, it can be found that the density of the road pavement is proportional with attenuation for all the frequencies. In other words, the high density would produce the high attenuation. This due to the fact that the more electromagnetic energy will be absorbed more by the molecules of the road pavement with high density compared with the lower density. This is valid for all frequencies as can be seen in Fig. 6a-d. Besides, it also clearly can be seen that the increasing of the frequency would produced the highest attenuation. It can be proved in Fig. 6d, the highest frequency, 2.6 GHz produce the range of the attenuation is from 57.09 to 71.09 dB whereas the lowest frequency, 1.7 GHz produces the range from 38.88 to 50.98 dB as can be seen in Fig. 6d and a, respectively. Thus, it is interesting to note that density plays an important factor in causing a major difference in the attenuation of GPR signal. --
From Fig. 6, as expected, the attenuation increases with the increasing of density. Generally, the measured attenuation of various road pavement samples shows a good agreement and acceptable results. The proportional relationship between the attenuation and density show that this approach is suitable in this purpose. From the results, it is interesting to consider that based on the characteristic of road pavement molecules, a microwave passing through the road pavement is absorbed by the molecules and the quantity of attenuation change according to the density. --
CONCLUSION
This study discussed an approach to get a relationship between attenuation and density for various densities of pavement slab samples. From the results, it can be concluded that the different density of pavement slab sample gave an effect for received signal strength and attenuation where the attenuation will increase with the increasing of the density. It is found that density plays an important factor in causing a major difference in the recorded signal strength. Therefore ground penetrating radar data is influenced greatly by density, the void from the materials that will cause power strength data difference and frequencies used whether in the range of 1.7 GHz towards 2.6 GHz. It is also can be found that the increasing of the frequency will causes increasing of the attenuation. The recommended frequency in this study is 1.7 GHz because it gave a more consistent reading and low sensitivity compared with other frequencies such as 2.6 GHz. The four best fitting equations from the results also produce the linear equations where the density will increase with the increasing of attenuation. The figure can be used as a calibration chart where the values of density can be read out directly once the attenuation value are known at various testing. In future development, the GPR result from this study can be used for further GPR research that capable to characterize more properties of road pavement sample.
Radar Attenuation: Slate and Granite
Radar is attenuated through density of material, metal, and reflection. The industry uses lead, a dense metal, to attenuate and shield from x-ray and radar but it is a neurotoxin and not safe to handle.
Grey Slate contains a high amount of alumina, aluminum is a metal and reflects radar, and Granites like Dark Granites can also contain aluminum, iron, titanium, etc.
Slate Stone
Description: Slate Stone or simply slate is compact metamorphic rock, composed primarily of silica and alumina.
Alumina - Aluminum oxide (Al2O3)
Chemical Properties of Slatestone
The necessary mineral composition of a slate-stone consists of members of mica group and clay group.
The mica group includes sericite and muscovite. Among these, sericite is an alteration mineral of plagioclase feldspars and muscovite is a phyllosilicate mineral of potassium and aluminum.
The second group, i.e., clay group consists of paragonite, kaonilite, and chlorite. Oxides, quartz, feldspar, calcites, and little amount of ferro-magnesium constitutes the accessory minerals.
Granite
Granite - An unstratified igneous rock composed of coarse grains or crystals of quartz, feldspar, mica and sometimes hornblende.
Biotite - A dark, iron and magnesium-rich mica found in granite. Biotite or black mica, K(Mg,Fe2+)3(Al,Fe3+)Si3O10(OH,F)2, is rich in iron and magnesium and typically occurs in mafic rocks. Biotite occurs widely throughout many different rock types, adding glitter to schist, "pepper" in salt-and-pepper granite, and darkness to sandstones. But it is the predominant mica in mafic rocks like gabbro.
Feldspar - Any of a group of crystalline minerals, all silicates of aluminum with either potassium, sodium, calcium, or barium. An essential constituent of nearly all crystalline rocks.
Hornblende - A group of minerals including calcium, iron, magnesium, and aluminum silicates. -- Hornblende is the most common amphibole; it is usually black, shiny and brittle. A long, dark mineral with abundant cleavage faces in a granitic rock is hornblende more often than not. The chemical makeup of hornblende is quite variable, so its formula is ugly: (Ca,Na)2-3(Mg,Fe+2,Fe+3,Al)5(OH)2[(Si,Al)8O22]. Hornblende is usually black but can also be dark green or brown. It is a common primary mineral in granitic rocks and a common metamorphic mineral in gneiss and schist.
Kaolinite - A hydrous aluminum silicate mineral.
Muscovite - A white, aluminum-rich mica found in granite.
Gabbro is a dark plutonic rock that is considered to be the plutonic equivalent of basalt. -- This particular gabbro is mostly hornblende, magnetite and light-colored plagioclase.
Granite consists mainly of quartz, feldspar, and ferromagnesian ("dark") minerals: hornblende, augite, and biotite (though not necessarily). The overall color of granite is due mainly to the feldspar: pink, gray, greenish, white, and even bluish. Black-looking "granites" get their color from a high percentage of hornblende or other dark mineral; but by this point they are not really granites anymore (see "diorite" and "gabbro").
Ground-Penetrating Radar
http://www.epa.gov/esd/cmb/GeophysicsWebsite/pages/reference/methods/Surface_Geophysical_Methods/Electromagnetic_Methods/Ground-Penetrating_Radar.htm
Basic Concept
Ground-penetrating radar (GPR) uses a high-frequency (e.g. 40 to 1,500 MHz) EM pulse transmitted from a radar antenna to probe the earth. The transmitted radar pulses are reflected from various interfaces within the ground, and this return is detected by the radar receiver. Reflecting interfaces may be soil horizons, the groundwater surface, soil/rock interfaces, man-made objects, or any other interface possessing a contrast in dielectric properties. The dielectric properties of materials correlate with many of the mechanical and geologic parameters of materials.
The radar signal is imparted to the ground by an antenna that is in close proximity to the ground. The reflected signals can be detected by the transmitting antenna or by a second, separate receiving antenna. The received signals are processed and displayed on a graphic recorder. As the antenna (or antenna pair) is moved along the surface, the graphic recorder displays results in a cross-section record or radar image of the earth. As GPR has short wavelengths in most earth materials, resolution of interfaces and discrete objects is very good. However, the attenuation of the signals in earth materials is high, and depths of penetration seldom exceed 10 m. Clay materials with a high cation exchange capacity increase the attenuation and decreasing penetration. Additonally, the presence of solutes or other substances which increase the electrical conductance of groundwater and have the same attenuation and penetration results.
The objective of GPR surveys is to map near-surface interfaces. For many surveys, the location of objects such as tanks or pipes in the subsurface is the objective. Dielectric properties of materials are not measured directly. The method is most useful for detecting changes in the geometry of subsurface interfaces.
Geologic problems conducive to solution by GPR methods are numerous and include the following: bedrock configuration, location of pipes and tanks, location of the groundwater surface, borrow investigations, and others. Geologic and geophysical objectives determine the specific field parameters and techniques. Delineation of the objectives and the envelope of acceptable parameters are specified in advance. However, as the results cannot be foreseen from the office, considerable latitude is given to the field geophysicist to incorporate changes in methods and techniques.
The following questions are important considerations in advance of a GPR survey.
What is the target depth? Though target detection has been reported under unusually favorable circumstances at depths of 100 m or more, a careful feasibility evaluation is necessary if the investigation depths need to exceed 10 m.
What is the target geometry? Size, orientation, and composition are important.
a) What are the electrical properties of the target? As with all geophysical methods, a contrast in physical properties must be present. Dielectric constant and electrical conductivity are the important parameters. Conductivity is most likely to be known or easily estimated.
b) What are the electrical properties of the host material? Both the electrical properties and homogeneity of the host must be evaluated. Attenuation of the signal is dependent on the electrical properties and on the number of minor interfaces that will scatter the signal.
c) Are there any possible interfering effects? Radio frequency transmitters, extensive metal structures (including cars) and power poles are probable interfering effects for GPR.
The physics of electromagnetic wave propagation are beyond the scope of this manual. However, there are two physical parameters of materials that are important in wave propagation at GPR frequencies. One property is conductivity (σ), the inverse of electrical resistivity (ρ). The relationships of earth material properties to conductivity, measured in mS/m (1/1,000 Ωm), are given in the section on electrical methods.
The other physical property of importance at GPR frequencies is the dielectric constant (ε), which is dimensionless. This property is related to how a material reacts to a steady-state electric field; that is, conditions where a potential difference exists but no charge is flowing. Such a condition exists between the plates of a charged capacitor. A vacuum has the lowest ε, and the performance of other materials is related to that of a vacuum. Materials made up of polar molecules, such as water, have a high ε. Physically, a great deal of the energy in an EM field is consumed in interaction with the molecules of water or other polarizable materials. Thus, waves propagating through such a material both go slower and are subject to more attenuation.
Earth Material Properties
The roles of two earth materials that cause important variations in the EM response in a GPR survey need to be appreciated. The ubiquitous component of earth materials is water; the other material is clay. At GPR frequencies, the polar nature of the water molecule causes it to contribute disproportionately to the displacement currents that dominate the current flow at GPR frequencies. Thus, if significant amounts of water are present, the ε will be high, and the velocity of propagation of the electromagnetic wave will be lowered. Clay materials with their trapped ions behave similarly. Additionally, many clay minerals also retain water.
The physical parameters in table 18 are typical for the Characterization of earth materials. The range for each parameter is large; thus, the application of these parameters for field use is not elementary.
Simplified equations for attenuation and velocity (at low loss) are:
(1)
(2)
where
V = velocity in m/s,
ε = dielectric constant (dimensionless),
a = attenuation in decibels/m (db/m),
σ = electrical conductivity in mS/m.
A common evaluation parameter is dynamic range or performance figure for the specific GPR system. The performance figure represents the total attenuation loss during the two-way transit of the EM wave that allows reception; greater losses will not be recorded. As sample calculations, consider a conductive material (σ = 100 mS/m) with some water content (ε=20). The above equations indicate a velocity of 0.07 m per nanosecond (m/ns) and an attenuation of 38 dB/m. A GPR system with 100 dB of dynamic range used for this material will cause the signal to become undetectable in 2.6 m of travel.
The transit time for 2.6 m of travel would be 37 to 38 ns. This case might correspond geologically to a clay material with some water saturation. Alternatively, consider a dry material (ε=5) with low conductivity (σ = 5 mS/m). The calculated velocity is 0.13 m/ns and the attenuation is 3.8 dB/m, corresponding to a distance of 26‑27 m for 100 dB of attenuation and a travel time of 200 ns or more. This example might correspond to dry sedimentary rocks.These large variations in velocity and especially attenuation are the cause of success (target detection) and failure (insufficient penetration) for surveys in apparently similar geologic settings. As exhaustive catalogs of the properties of specific earth materials are not readily available, most GPR work is based on trial and error and empirical findings.
Table 1. Electromagnetic properties of earth materials.
| Material | E | Condutivity |
Velocity, (m/ns)
|
Attenuation, (dB/m) |
| Air | 1 | 0 |
0.3
|
0 |
| Distilled Water | 80 | 0.001 |
0.033
|
0.002 |
| Frest Water | 80 | 0.5 |
0.033
|
0.1 |
| Sea Water | 80 | 3,000 |
0.01
|
1,000 |
| Dry Sand | 3-5 | 0.01 |
0.15
|
0.01 |
| Wet Sand | 20-30 | 0.1-1 |
0.06
|
0.03-0.3 |
| Limestone | 4-8 | 0.5-2 |
0.12
|
0.4-1 |
| Shales | 5-15 | 1-100 |
0.09
|
1-100 |
| Silts | 5-30 | 1-100 |
0.07
|
1-100 |
| Clays | 5-40 | 2-1,000 |
0.06
|
1-300 |
| Granite | 4-6 | 0.01-1 |
0.13
|
0.01-1 |
| Dry Salt | 5-6 | 0.01-1 |
0.13
|
0.01-1 |
| Ice | 3-4 | 0.01 |
0.16
|
0.01 |
| Metal |
Faraday Cage Upgrade, Feb 6, 2012, Granite and Lead Panels
Powerful radar shielding panels that are made from granite and lead, connected to a metal faraday cage through aluminum tape.
http://www.youtube.com/watch?v=_EwRM-gKxTE
http://ireport.cnn.com/docs/DOC-743164
The sea water or salt water faraday cage is probably the cheapest powerful radar attenuation method that I can think of and also shields from focused ultra sound technology or weapon type. Rocks or other material can also be placed inside the plastic containers with the sea water.
- Faraday Cage Upgrade, Feb 6, 2012, Granite and Lead Panels
- Faraday Cage Upgrade Dec 6, 2011
- Faraday Cage Upgrade Dec 4, 2011
- Faraday Cage Nov 24, 2011
Ted Talks; Focused Ultrasound, Brain Lesions, "Hitting The Brain", Lobotomy, Stroke
http://ireport.cnn.com/docs/DOC-747227
http://www.youtube.com/watch?v=khowlGbarLI
Ted Talks; Focused Ultrasound, Brain Lesions, "Hitting The Brain", Lobotomy, Stroke
Focused Ultrasound for use in the medical field can also be used in domestic homicides, "hitting the brain" similar to attempts to poison a person's brain with lead, and similar to powerful radar assaults linked to leukemia and other deadly cancers, can be used from neighboring homes.
The 2005 Award Winning sound technology HSS Hypersonic Sound that creates sound at great distances and in specific targeted locations also uses focused ultrasound, a possible like to stroke and heart attack victims.
What Are the Different Types of Brain Lesions?
Although they share a common definition -- injury or damage to tissue within the brain -- brain lesions vary greatly. Here are some common brain lesions.
Cerebral infarction: Infarction refers to death of tissue. So a cerebral infarction is a brain lesion in which a cluster of brain cells have died. Most often, this brain lesion is caused by a stroke.
Microwave Research: Industry Canada Spectrum Management and Telecommunications
http://ireport.cnn.com/docs/DOC-522475
Microwave and Radiation:
"Childhood leukemia can occur if a fetus is exposed to x-rays during the first trimester of pregnancy." - Prescription for Nutritional Healing fourth edition p. 662
Microwave (radar) Technology:
UWB 1.6–10.5 GHz 18.75 cm – 2.8 cm used for through-the-wall radar and imaging systems.
Weather Radar etc:
S 2–4 GHz 7.5–15 cm 'S' for 'short'
C 4–8 GHz 3.75–7.5 cm
X 8–12 GHz 2.5–3.75 cm
Longer waves like UWB can penetrate through walls or dry objects.
Radar frequency bands Band name Frequency range Wavelength range Notes
HF 3–30 MHz 10–100 m coastal radar systems, over-the-horizon radar (OTH) radars; 'high frequency'
P < 300 MHz 1 m+ 'P' for 'previous', applied retrospectively to early radar systems
VHF 30–300 MHz 1–10 m Very long range, ground penetrating; 'very high frequency'
UHF 300–1000 MHz 0.3–1 m Very long range (e.g. ballistic missile early warning), ground penetrating, foliage penetrating; 'ultra high frequency'
L 1–2 GHz 15–30 cm Long range air traffic control and surveillance; 'L' for 'long'
S 2–4 GHz 7.5–15 cm Moderate range surveillance, Terminal air traffic control, long-range weather, marine radar; 'S' for 'short'
C 4–8 GHz 3.75–7.5 cm Satellite transponders; a compromise (hence 'C') between X and S bands; weather; long range tracking
X 8–12 GHz 2.5–3.75 cm Missile guidance, marine radar, weather, medium-resolution mapping and ground surveillance; in the USA the narrow range 10.525 GHz ±25 MHz is used for airport radar; short range tracking. Named X band because the frequency was a secret during WW2.
Ku 12–18 GHz 1.67–2.5 cm high-resolution
K 18–24 GHz 1.11–1.67 cm from German kurz, meaning 'short'; limited use due to absorption by water vapour, so Ku and Ka were used instead for surveillance. K-band is used for detecting clouds by meteorologists, and by police for detecting speeding motorists. K-band radar guns operate at 24.150 ± 0.100 GHz.
Ka 24–40 GHz 0.75–1.11 cm mapping, short range, airport surveillance; frequency just above K band (hence 'a') Photo radar, used to trigger cameras which take pictures of license plates of cars running red lights, operates at 34.300 ± 0.100 GHz.
mm 40–300 GHz 7.5 mm – 1 mm millimetre band, subdivided as below. The frequency ranges depend on waveguide size. Multiple letters are assigned to these bands by different groups. These are from Baytron, a now defunct company that made test equipment.
V 40–75 GHz 4.0 - 7.5 mm Very strongly absorbed by atmospheric oxygen, which resonates at 60 GHz.
W 75–110 GHz 2.7 – 4.0 mm used as a visual sensor for experimental autonomous vehicles, high-resolution meteorological observation, and imaging.
UWB 1.6–10.5 GHz 18.75 cm – 2.8 cm used for through-the-wall radar and imaging systems.
Radar engineering: Radar components
A radars components are:
* A transmitter that generates the radio signal with an oscillator such as a klystron or a magnetron and controls its duration by a modulator.
* A waveguide that links the transmitter and the antenna.
* A duplexer that serves as a switch between the antenna and the transmitter or the receiver for the signal when the antenna is used in both situations.
* A receiver. Knowing the shape of the desired received signal (a pulse), an optimal receiver can be designed using a matched filter.
* An electronic section that controls all those devices and the antenna to perform the radar scan ordered by a software.
* A link to end users.
en.wikipedia.org/wiki/Radar
Dear Lung Association
I would like to inform you and address a concern linked to lung cancer.
Criminal harassment networks, organized crime, is using microwave technology, radiation, in this case and issue of concern microwave radar technology, which irritates the lungs, irritation is linked to inflammation, and inflammation is linked to cancer, in this case lung cancer.
The use of microwave radar technology in this manner is linked to criminal harassment, intimidation, physical harm linked to cell damage and irritation, and cancer, which can lead to a person's death, a form of assassination or murder.
Lung cancer being the #1 killer of men and women.
Sincerely,
Powerful Radar Run Away Strategy Example - CNN iReport (article link)
1. Radar assaults.
2. False allegations, searching a dwelling home and seizing computers, private information, without warrants.
3. Assessment order to escape false allegations and police wrong doing, no warrants, through non-criminal responsibility of having committed a crime when the accused has not committed a crime, a type of smear campaign.
4. Radar Run Away strategy, when the accused run's away an arrest warrant is issued, he looks guilty for coercion or threat of being framed, why did you run away? assaulted with radar, the assessment order for non-criminal responsibility is used when he is detained.
5. Another linked strategy is to inflict serious illness, cancer.
http://ireport.cnn.com/docs/DOC-735586
Powerful Radar Assault Effects
1. Powerful radar aimed at the shine bone, linked to leukemia.
2. At the lungs, burning and irritation, difficulty breathing, linked to lung cancer.
3. At the bone, joints, bone pain, linked to bone cancer.
4. Radar pulses or streams aimed at the testicles, testicular pain, linked to testicular cancer.
5. Radar streams aimed at the prostate area, painful area and urine loss issues, linked to prostate cancer.
6. At the neck and throat lymph-node area, possible link to neck, head, lymph-nodes, cancers.