Mind control frequency list:

(HZ,KHZ,MHZ,GHZ,THZ)
Note: in many documents it seems that the range is the band width and its work channel.. so for your professional consideration..!!
The maximum power for mind control per cm on the surface of the skull is: 0.3 watts
Brain diameter 30 to 45 cm area 0.3 watts per cm skull maximum double 45 cm 13.5 watts
per skull surface maximum 


Synthetic telepathy:
0.1 MHZ -  6 GHz (wide)
300 MHZ - 3 GHZ (reduced) 

remote neural monitoring:
3 - 5 GHz (low) / 499.2 MHz bandwidth
6 - 10 GHz (high) / 499.2 MHz bandwidth 

Teleportation - Transfer of an inanimate object, person or particle Transferring the physical dimensions or parts of the spirit to astral travel 

10 MHZ -300 GHZ
                         + Electrophoresis

Holoportation - Broadcasting holograms from place to place / Magnetic spin body organs in HZ + mind window range
or any implant range + DC - 10 GHZ nanotube antenna range neurological synthetic neural network..

10 HZ - 10 GHZ 

Teleportation + holoportation working on an ultra-band wide EMF portal of   
0.1 Hz - 1500 kHz

Medical Implant Communication Service:
380 -480 MHZ / NASA Earth Telemetry Network 
402 - 401 MHZ / 300 kHz bandwidth  

The recorded electrical activity of human brain waves of the highest
voltage and lowest frequency human brain called the cerebral cortex
The first six layers of the cerebral cortex

0.5 - 1 to 4 Hz /50 to 350 microvolts  

Frequency band    Frequency    Brain states
Gamma (γ)    35-100 Hz    Concentration
Beta (β)    12–35 Hz    Anxiety dominant, active, external attention, relaxed
Alpha (α)    8–12 Hz            Very relaxed, passive attention
Theta (θ)    4–8 Hz            Deeply relaxed, inward focused
Delta (δ)    0.5–4 Hz    Sleep

The 0.5 HZ and 0.9 hz - sensory resonance affects the autonomic nervous system 
and may cause relaxation, drowsiness,or sexual excitement

0.85 GHZ - Nanotube oscillators bioelectric signals biological sensing potential (spin transfer torque)

depending on the precise acoustic frequency near 1/2 Hz used ultra bandwide
Medical Service Communication (biological tissues) monitoring operation of the physical narrowband implantable devices

2.5 Hz - resonance include slowing of certain cortical processes,
sleepiness, and disorientation. For these effects to occur,
the acoustic intensity must lie in a certain deeply subliminal range
portable battery-powered source of weak sub audio acoustic radiation
ultra bandwide - ??

Wireless Medical Telemetry Service (WMTS)(Bio-medical Applications)GPS
401-406 MHz
413-419 MHz
426-432 MHz
438-444 MHz 
451-457 MHz
Medical Implant CommunicationService (MICS)
(401-402 MHZ)
(401-406 MHZ)
(402-405 MHz) 
(403-405 MHz) 
(405-406 MHz) 

Channels
The rules do not specify a channeling scheme for Medical Device RadiocommunicationsService
(MedRadio)devices. They may operate on any frequency in the MedRadiospectrum that does not
exceed these authorizedbandwidths:
401–401.85 MHz: 100kHz
401.85–402 MHz: 150kHz
402–405 MHz: 300kHz
405–406 MHz: 100 kHz
413-419 MHz: 6 MHz
426-432 MHz: 6 MHz
438-444 MHz: 6 MHz
451-457 MHz: 6 MHz


IMPLANTABLE SENSORS AND ANTENNAS
antenna at 402.5 MHz
433.1-434.8 MHz
868-868.6 MHz
902.8-928.0 MHz 
2400-2483.5 MHz
-15 dBi
(2.45 GHz) band Pulse - ISM 


Wireless medical telemetry service:(central monitoring location within a hospital or other medical facility)
608 - 614 MHz / 1.4 GHZ , TV channel 37
1392– 1395 MHz / 1 MHz band
1395- 1400 MHz / 1 MHz band  
1427– 1429.5 MHz / 1 MHz band 
1427 - 1432 MHz / 1 MHz band

Medical Service Communication(low)(biological tissues)GPS
403.5 MHZ / 300 kHz bandwidth                                            
402 -405 MHZ / 300 kHz bandwidth  
405 - 406 MHZ / 300 kHz bandwidth                            
413 - 419 MHZ / 300 khz bandwidth   
426 - 432  MHZ / 300 khz bandwidth  
438 -444 MHZ / 300 khz bandwidth 
400 - 450  MHZ / 1.25 + 1.4 MHz bandwidth and higher harmonics (5.340 MHz) (mental window) mind control function  
has picked up 435 MHz signals connected to HAARP,He claims that 400-450 MHz is the window to human consciousness,that cellular
phones use 435 MHz,because it is our present day reality’s background frequency. 
420 - 450  MHZ / 1.25 + 1.4 MHZ bandwidth 
451 - 457 MHZ /  300 kHz bandwidth
433 MHZ / 300 KHZ bandwidth  
530 MHZ / 300 KHZ bandwidth
3.45  –  3.98 GHZ bandwidth

The ZL70100 is an ultra low power, high bandwidth RF link for medical implantable applications. It operates in the
MICS (Medical Implantable Service Band) at 402-405 MHz. It uses a Reed-Solomon coding scheme together with
CRC error detection to achieve an extremely reliable link. For data-blocks, a maximum BER (Bit Error Rate) of less
than 1.5x10-10 is provided assuming a raw radio channel quality of 10-3 BER. An even higher quality of 2x10-14
BER is available using Housekeeping messages, a facility fully described in the ZL70100 Design Manual.

Medical Implant Communication Service(high):
Ultra band and wide 2 ranges low + 2 ranges high
(3 low ranges)
3.1 - 4.8 GHZ
3.2  – 4.7  GHZ
3.1 – 10.76 GHZ(3.1 GHZ - 5 GHZ,6 GHZ - 10.6 GHZ) / 50 MHZ (Ultra-Wideband + bandwidth) 
499 MHZ bandwidth / 70 – 90 db 
(2 high ranges)
6.2  – 10.3  GHZ
4.7 – 13.2 GHZ
499.2 MHZ bandwidth / 90 – 110 db 

IEEE 802.15.3c and IEEE 802.11ad (TDMA) hybrid access protocol 

between 0.1 THz and 10 THz / 60 , 70 , 80 GHz communication 

8 different channel bandwidths
(as multiples of 2.16 GHz)
– 2 PHY-modes (THz-SC PHY, THz-OOK-PHY)
with 7 modulation schemes:
• BPSK, QPSK, 8-PSK, 8-APSK, 16-QAM, 64
QAM, OOK
– 3 channel coding schemes:
• 14/15-rate LDPC (1440,1344), 11/15-rate LDPC
(1440,1056), 11/15-rate RS(240,224)-code.

Wireless Body Sensor Communication Systems Based on UWB and IBC Technologies: (the federel communications)
radio protocols: Bluetooth (BT), Zigbee, HBC, UWB or wireless LAN (WLAN)short-range communication

IEEE 802.15.4a
2.5GHZ central channel
Sub–GHz: 250–750 MHz (16 possible channels)
Low: 3.244–4.742 GHz
Hi: 5.944–10.234 GHz
3.9 MHz, 15.6 MHz and 62.4 MHz - pulse repetition frequency (PRF) 
 
3.1 - 4.8 GHZ (low)
6 - 10.3 GHZ (high)
3.1 - 10.6 GHZ (Wide) /  7.5 GHz bandwidth

16 possible channels in any low, high and wide range

ultra range pulse band:
499.2 MHz to 1357.97 MHz

Minimum bandwidth 500MHZ
maximum power:41.3 dbm / MHZ

IEEE 802.15.6 - Wireless Body Area Networks (WBANs)
2.5GHZ central channel
402-405 MHz
420–450 MHz
863–870 MHz
902–928 MHz
950–958 MHz
2360–2400 MHz, 2400–2483.5 MHz.
402 MHz - 2483.5 MHz (Wide)
bandwidth 300 kHz - 1 MHz (7 possible channels)
(3.25–4.75 GHz) and high (6.6–10.25 GHz), each group being divided into 500 MHz bandwidths.
two operation modes IR-UWB , FM-UWB is optional The operation band of this layer is 21 MHz with a bandwidth of 5.25 MHz.

PHYs which IEEE 802.15.6 supports are Narrowband (NB) with data rates from
57.5 kbps to 971.4 kbps, Human Body Communication (HB) with data rates from .5
Mbps to 10 Mbps and Ultra Wide Band (UWB) with data rates from 125 kbps to 2
Mbps

UWB-PHY applications
receiver sensitivity between:
-95 dBm and -82 dBm
3494.4 MHz 3993.6 MHz, 4492.8 MHz (low)
6489.6 MHz, 6988.8 MHz, 7488.0 MHz, 7987.2 MHz, 8486.4 MHz,8985.6 MHz, 9484.8 MHz, 9984.0 MHz (high)
(11 possible channels for low and high)all pulse band low and high 499.2 MHz bandwidth
6 -8.5 GHZ both on-body and in-body(nato)
7.25–8.5 GHz both on-body and in-body(nato)
It is possible that 802.15.6 also has Ultra Band pulses
ultra range pulse band:
499.2 MHz to 1357.97 MHz

high band groups:
3993.6 MHz / Channels 1
7987.2 MHz / Channels 6

3494.4 MHz - 9984.0 MHz -(11 possible channels)wideband FM (FM-UWB) central frequency ultra bandwidth (grouped in low and high)

band pulse:
10 KHZ , 25 KHZ ,100 KHZ, 1 MHZ ,5.25 MHZ ,21 MHZ ,7.5 GHZ
(21 MHZ) -97.35 dBm to -94.34 dBm 
(5.25 MHZ) -91.33 dBm to -88.32 dBm 

range pulse band:
100 - 160 MHZ

499.2 MHz operating frequency bandwidth
and ultra range pulse band:
499.2 MHz to 1357.97 MHz

Communication channel for IEEE 802.15.6 , 802.15.4

a. OB2OB - on body to on body
b. OFF2OB - off to body interference (body to body) 
c. IB2OB - for in-body to on-body (500 MHz-26.5 GHz)
d. IB2IB - in body to in body


1 402–405 MHz, 420–450
MHz, 863–870 MHz,
902–928 MHz, 950–956
MHz, 2360–2400 MHz
and 2400–2483.5 MHz for
narrowband; 3245–4742
MHz and 6240–10234
MHz for UWB; 14–18
MHz and 25–29 MHz for
HBC.

Terhertz Communications,visible light communication(vlc),Optical Wireless Communication - LIFI LED:
0.01 - 1.5 THz(0.5 to 1.5 THZ) / -15 to 5 dbm - nano sensor for intra body nano networks

IEEE 802.15.7 - Terhertz Communications

28 GHz, 38 GHz, 45 GHz, 60 GHz, 100 GHz / 0.14 THz - 10 THz bandwidth
Table 1. Performance of Optical Biotelemetry System
TRANSMITTER
ECG 3 ch. standard limb leads or
precordial unipolar leads
THE IEEE(mac)protocl 1906.1 STANDARD NANOCOMMUNICATIONS
from 0.55 THz to 1.55 THz, the transmission power, pulse features, type of modulation, etc. Regarding modulation, the Time-Spread On-Off Keying (TS-OOK
Optical implant communications are enabled by optical propagation of infrared:
operation in the 700 nm - 1 mm (300 GHz-430 THz) band
For example, Abita et al [16] used an 860 nm (348.596 GHz) carrier to
transmit an RS-232 data of rate 115.2 kbps. Here, a photonic detector LED
PDI-E804 is used over less than 24 mm communication distance where a porcine
skin is used as a channel. Although the 24 mm range is an over-estimate for the
subcutaneous implants which are often limited to less than 4 mm, the technique
at nanometer wave could be used to achieve a much faster data rate up to 50
Mbps as presented in [17] (860 nm, 4 mW power consumption, 4 mm range,

signal bandwidth 0.05–100 Hz
non-linearity less than 4%
total gain 46dB
Temperature 1 ch. thermistor
temperature range 0-–42 deg. C
time constant 0.42 deg/s
Modulation 4 ch. PWM/PPM/IM
Pulse frequency 2.6 kHz
Pulse interval ECG ch. 0.3 ms
Temp. ch. 0.6 ms
Pulse width 2μs
Current drain 1.5 mA
Dimension L36 × W60 × H138 mm3
Weight 350 g
LIGHT EMITTERS (a set of two)
Light emitter 80 IRLED’s (940 nm)
Total optical output
(when pulse on) 1 W
Current drain 20 mA
Dimension L90 × W80 × H18 mm3
Weight 85 g
LIGHT RECEIVER
Photo detector PIN Si photo diode
(effective receiving area 100 mm2)
Optical filter long pass filter
(cut off wave length 800 nm)
Dimension L100 × Wl20 × H50 mm3
Weight 450 g

Optical Biotelemetry
pulse burst signal with 500 kHz repetition of 1 μsec 

data transmission rate at 9600 bps, the clock frequency of a chip was set at 7.315
MHz. The SS modulated signal is emitted from the LED array which consists of 60 LED’s
(nominal optical power 30 mW each, wavelength 850 nm). The indirect light scattered
by a ceiling, a floor and walls reaches the Si-PIN photodiode and is transformed into an
electric signal. The received signal is amplified and its frequency is shifted to 215 MHz
in an up-conversion circuit using a double balanced mixer (DBM). This is the operating
frequency of a surface acoustic wave (SAW) convolver. In the receiver, the time-reversed
Gold series which is the same as that used in the transmitter is generated. This PN code
is also frequency-shifted to 215 MHz and fed to the SAW device. In the SAW device, the

Nano routers - clock operates in a range of 1-2 THz

graphene-based nano-antennas have been observed as potential electromagnetic radiators in the terahertz band.


Body Lan/Medical Body Area Network:monitoring operation of the physical narrowband implantable devices
2360  – 2400 MHZ(2360-2390 MHZ)
2500 MHZ - 1.785 GHZ 
400 MHZ - Wireless Body Area Network Security and Privacy
Issue in E-Healthcare   
MHZ 847- Micro link from the brain to the phone  
(Frying the victim's brain with a module)
60 GHZ-link from brain to the phone and to the cloud server and Reverse 2 way(monitoring tissue oxygen)
57–64 GHz (broad) has high oxygen consumption with less than 15 dB/km 
863 – 870 MHz/(low) 
863 - 956 MHZ/(high) 
MHz 900 / (200 MHz bandwidth)
915 MHZ - Microwave Remote Sensing volume-imaging Doppler radar layer
 
902  – 928 MHZ / -75.95 dBm / 500 KHZ bandwidth
956  MHZ / 400 KHZ bandwidth
0.1 Hz - 400 kHz /  GHZ Ultra Band 3.1 – 10.6 
 

Satellites monitor brain activity (body lan / body area network
10 , 16 ,27 MHZ / (250 – 10 mv) 

Wireless Body Area Network for Medical Applications:(nato)
(The Federal Communication Commission FCC has allocated)
3.1–10.6 GHz United States
3.4–4.2 GHz + 6–8.5 GHz Europe 
4.2–4.8 GHz mitigation technique. Beyond December 31, 2010 
3.4–4.8 GHz frequency band seems to be the most appropriate for the signal attenuation through living tissues must be the minimal possible.
6 -8.5 GHZ both on-body and in-body
7.25–8.5 GHz both on-body and in-body
maximum spectral density of –41.3 dBm/MHz
Area Network for Medical Applications
42 - 14 RTO-MP-HFM-182
regulations request the implementation of DAA and LDC in this portion of the spectrum

Overlapping ranges of Mind control (Bluetooth range):
Under (Medical Implant Communication Service)
2400  – 2480  MHz – (1 MHz bandwidth)
2320  – 2400  MHz – (1 MHz bandwidth)
2360 - 2400  MHZ - (1 MHZ bandwidth) / 4.125 MHz , 528 MHz sub-carrier bandwidth
2400 – 2438.5  MHz – (1 MHz bandwidth)


Individual channels (Bluetooth continued):
2402,2441,2480 MHZ   br,edr – mod
2402,2426,2480 MHZ  le – mod 
2478,2404,2442 MHZ    le2 – mod
2458,2430,2408  MHZ   medical implants
Channels (1,6,11) / 21.7 -30.9 db

Additional Bluetooth domain audiogram data from the brain and body:
2412  MHZ / 20 MHz bandwidth (channel 1)   
2437 MHZ / 20 MHZ Bandwidth (Channel 6) 
2462 MHZ / 20 MHz bandwidth (channel 11)    

On this module you can get the most sensitive behavior change..!!
600 - 2450 MHZ / 0.1 Hz – 400 KHZ
(50 MHz - 2450 MHz) - this is the wide range on a pulse module in the range 0.1 Hz - 400 kHz of changing human behavior

Low Power cochlear Implant System:
2483.5 – 2500  MHZ / 1 + 2 + 16.5 MHZ bandwidth
1610  – 1626.5 MHZ / 1 + 2 + 16.5 MHZ bandwidth   

Frequency range (mental window) exclusive to the police:GPS
136 – 174  MHz (low)
150 – 174   MHz (low)
174 – 216 MHz (low) 
380 – 400 MHz (medium)(400 MHZ) Wireless Body Area Network Security and Privacy Issue in E-Healthcare
400  – 420  MHz (medium)(400 MHZ) Wireless Body Area Network Security and Privacy Issue in E-Healthcare
400 - 450  MHZ / 1.25 + 1.4 MHz bandwidth and higher harmonics (5.340 MHz)   
450  – 470 MHz / 22 + 25 kHz, 4, 20 MHz
421  – 470 MHz (high)
(410– 420) MHZ dense range(60,000)word 
482 – 488 MHz (high) TV channel 16 
512 – 470 MHZ
512 – 450  MHZ
608  – 512  MHz / TV channel 21 + 36
698  – 757 MHz / 1 MHz bandwidth  
763  – 758  MHz / 1 MHz bandwidth
757  – 758 MHz / 1 MHz bandwidth
775  – 776 MHz / 1 MHz bandwidth
776  – 787 MHz / 1 MHz bandwidth
788 – 793 MHz / 1 MHz bandwidth
700 + 600 + 800 + 900 MHz / 100 kHz bandwidth frequency in use within the range 450,452,435 MHz
863 - 956 MHZ/  monitoring operation of the physical narrowband implantable devices

Bandwidth for every frequency of the police mental window:
150 KHz, 100 KHz, 75 KHz , 62.5 KHz, 50 KHz, 37.5 KHz, 22 KHZ ,25 KHz ,TV channel; 14 KHZ + 12.5 KHz, 21 KHZ + 36 KHZ
1 MHZ ,1.25 MHZ ,1.4 MHz ,6.25 MHZ ,20 MHZ (6 - 18 MHZ)   

High Performance Cognitive Radio Platform:
700 Mhz, 2.4 GHz and 5.1 Ghz / data rates: 6, 9, 12, 18, 24, 36, 48 and 54 Mbps / The figure 3.4b shows a photo
900 MHz Baseband controller and a 902-928 MHz antenna / maximum data rate of 1.5Mbps and a typical receiver sensitivity of –95dBm at 12.5% CER
2.4 GHz / -75dBm receiver sensitivity at 54Mbps
5GHz Radio Setup:2.4GHz to 2.5GHz and 5.15GHz to 5.35GHz / 20dB of gain, +32.5dBm of saturated power / both 802.11g & 802.11a
Tuning antennas for the reception of cognitive radio
810-1000, 1600-2500 and 4000-6000 MHz
size of the antenna is 50X500X0.2 mm3

The ranges or channels are listed above transmit/receive modules
of behavioral change sciences in the range: 
0.1 Hz - 400 kHz bandwidth 
446.8250 MHZ / 25 KHz , 12.5 KHz for nano node, nanotube, hydrogel, GQD
449.6000 MHZ up link / 25 KHz , 12.5 KHz bandwidth for nano node, nanotube, hydrogel, GQD
444.6000 MHZ down link / 25 KHz , 12.5 KHz bandwidth for nano node, nanotube, hydrogel, GQD
1 – 1.8 GHz / 9600 GPS working range (wide) 
10.23 MHz / this base frequency is multiplied by 154 and 120
to produce a spread spectrum signal of a bandwidth of
2.046 MHz and 20.046 MHz
All channels GPS are 1-1.8 GHz and are written in MHz
1575.42
1227.6
1381.05
1379.9133
1176.45
1164
1189
1207.140
1214
1215
1237
1239.6
1254
1260
1278.75
1300
1544
1545
1559
1563
1587
1591
1593
1610


Nav Star GPS Scalar Microwave Beam:
3600 – 3750 MHZ
3550 – 3650 MHZ
3200 – 3750 MHZ
3.45 – 3.65 GHZ /  10 MHz bandwidth 

GPS cell tower (location triangulation):
2300 - 2600 MHZ
2300 - 2900 MHZ

Aeronautical Mobile Telemetry;
(Medical application)
1276.00 MHz -80.98 dBm Satellite navigation systems, Aeronautical surveillance,Amateur



1435 – 1525 MHZ  
2200 – 2290 MHZ - NASA telemetry    
2290 – 2300 MHZ -  NASA telemetry  
2360 – 2390 MHZ / 30 MHz / Power limits (1 milliwatt) - master transmitters to control MBAN operation
2360 - 2400 MHz - The hub and sensor devices central control point
2390 - 2400 MHz / 10 MHz / Power limits (20 milliwatts)
2360 – 2600 MHZ 
2  – 7 – 8    GHZ - NASA Deep Earth Telemetry 
Maximum bandwidth 1 MHz, Same out-of-band in than 500 outside of band) strength is as apply b MCS

Brain Computer Interface Signal Kernel:
4827.448  MHZ

v2k voice to skull:(Microwave Hearing)
100 MHZ - 10 GHZ frequency modulated bursts lasting from about 500 nanoseconds to 100 microseconds
420  –  450  MHZ
1.3  GHZ
1000  MHZ
2.4  – 10  GHZ / 5 KHZ bandwidth 

Nano Acoustic Communication
(Implant Power Application)

The first wireless implants integrated inductive coupling technology at a frequency of 20 MHz or lower
570 HZ - 2 MHZ - implants and other near-by devices and then an additional frequency (such as 224.840 MHz, or higher)
10 kHz - 1 MHz / 1 mA - Intra-body communication
5 - 50 MHZ in body and on body 
2 - 134 MHZ Nano ElectroMechanical System
40 MHz - 400 MHz Communicating at the Nanoscale
105.3 MHZ - high-frequency electromechanical resonator (NEMS)carbon nanotubes or nanowires
10 – 300   MHZ (low)
100 – 300  MHZ (high)
200  MHZ - vibrating resonator, remote stimulation - an 80 MHz device for applications in resonant sensing
215 MHZ (high)    
1.544 MHz (downlink) - inputs from the body to the modem zarlink semiconductor inside nanotube System Synchronizer
2.048 MHz (downlink)- inputs from the body to the modem zarlink semiconductor inside nanotube System Synchronizer
8.192 MHz (downlink)- inputs from the body to the modem zarlink semiconductor inside nanotube System Synchronizer
16.384 MHZ (downlink)- inputs from the body to the modem zarlink semiconductor inside nanotube System Synchronizer
1.544 MHz (uplink) - down to the body from the modem zarlink semiconductor inside nanotube System Synchronizer
2.048 MHz (uplink)- down to the body from the modem zarlink semiconductor inside nanotube System Synchronizer
8.192 MHz (uplink)- down to the body from the modem zarlink semiconductor inside nanotube System Synchronizer
16.384 MHZ (uplink)- down to the body from the modem zarlink semiconductor inside nanotube System Synchronizer
4.096 MHz (uplink)- down to the body from the modem zarlink semiconductor inside nanotube System Synchronizer
zarlink bandwidth  8 KHZ,Provides 5 styles of 8 kHz framing pulses
13.56 MHZ - receiving electricity from the air(clock frequency) nanotube neurological neural network
12.5 MHz - 20 MHz / -66.89 dBm (20.50 MHz) Ultra Low Power Animal Implantable Devices nanotube
12.85 MHZ
50 MHZ
60  MHZ
20 MHZ
40 MHZ
10.9 MHZ
1.5 GHZ 
1.6 GHZ
1.85  GHZ
2.3 – 3.2 GHZ
500 KHZ
100 – 170 KHZ 
250 – 400 KHZ

Inside the range above there are visual and audio messages, causing the nanorobots to move geometrically and an opportunistic meeting between them.. (for a 1 micron nanotube antenna)

Burning in the body:
30 - 300 MHZ - external burning to the body  
10 - 100 MHZ - internal burning to the body  

Specific frequencies and ranges:
441 MHZ - operating frequency of nanorobots    
200.02 MHZ -  frequency of nano belt 
3.2  GHZ - (bio mems) operating frequency 
2.1 – 2.15 GHZ - range of nano NEMS/MEMS 
10 – 100 KHZ - range of nanorobots (pay attention to kilohertz)
3920  – 3935 MHZ (attack vector) 
1.28  GHZ - operating frequency of a graphene ring 
1 – 100 MHz - hidden acoustic signals with the doctor (nanorobots)
124.14 MHz - vibration of nano wire
1680 MHZ - used to receive a bio-signature of brain waves
2 - 18 GHZ - ultra bandwide nano cube
403 MHz and 1680 MHz - Silent Sound Subliminal Mind Control  
105.3 MHZ - high-frequency electromechanical resonator (NEMS)carbon nanotubes or nanowires
intra-body communication -100 kHz – 150 MHz
147 MHz - nanotube electromechanical resonance (physical harassment) 6 Hz - 20 kHz bandwidth with an intensity of 0.8m/cm3 causes the release of calcium ions from the body and brain

55 MHz - nanotube electromechanical resonance (physical, motor harassment) 10 MHz, 10 kHz, 300 MHz bandwidth 
0 - 55MHz Nanotube electromechanical resonantor frequency. An SEM image of a suspended
350 MHZ - vibration mode of suspended carbon nanotubes
device (top) and a schematic of device geometry (bottom). Scale bar, 300 nm. The
sides of the trench, typically 1.2–1.5 μm wide and 500nm deep
quality factor Q = 80. (c) Detected current as a function of gate

Implant Communication Technologies - This technique was originally proposed by Zimmermann [58]. Using this
scheme, he successfully transmitted a 330 kHz signal with 3 V at 2.4 kbps digital
transmission rate consuming 1.5 mW of power

100 KHZ - 10MHZ - implant communications at frequencies ranging 
The implant communication channel is very different from the
surface-to-surface channel. While the surface to surface channel has a band
pass gain characteristic where the gain picks in the region 20-60 MHz, the
implant-to-surface communication channel has a low-pass gain characteristics
that favours lower frequency transmission for minimal path loss.

50 kHz - 500 kHz. At these frequencies effects associated with surface charge and surface conduction
0.1 – 10 Hz - they could control both translational and circular motions of the cells. The optimal frequency range for such motions was found to be .We can expect, from our discussion here
500 Hz - 50 MHz - moment aligned in the direction of the field as shown for particle A negative α results in an induced dipole moment aligned 
100 HZ - 100 MHZ - MHzterm effective volume reminds us that the dominant polarizabilities of small particles (e.g.,
proteins, DNA, viruses) are often dominated by relaxations of their electrical double layers
whose total volume can be comparable to or greater than the particle. 
10 kHz and 30 MHz frequency could produce linear motions of pollen and cellulose particles, and they coined the term traveling-wave dielectrophoresis
88 MHZ - 99 MHZ is therefore interesting to note that values have been derived for the effective
104 MHZ - 154 MHZ permittivity of the interior of erythroleukaemia cells interior of blood cells
100 Hz - 500 MHz - PHYSIOMETRIC EFFECTS
30 – 150 MHz - range (wide) electromechanical resonance (nanotube) physical harassment, motor harassment
300 MHz /10 KHZ bandwidth 
10  – 400  MHZ(400 MHZ) Wireless Body Area Network Security and Privacy Issue in E-Healthcare)
40  – 400 MHZ
10 kHz - 300 MHz - Nanotube device resonator (wide) bandwidth 
434.63 – 458.21 KHZ nanotube electromechanical resonance (kilohertz) nanopillars were mounted on an external shear-force piezoactuator with quality factor of 1700
50 MHz - 2.4 GHz - wide range attack signals 
Remote extracellular sensing (the intracellular space) 
500 Hz to 50 MHz / between +1.5 and −0.5 kHz bandwidth 
wide working range Tesla attack (HAARP) + remote viewing 
3.26 -  17.54 MHZ ultra bandwidth / 10 hz band - Six harmonic sine frequencies in the ultra bandwide range 3.26 - 17.54 on the 0.62 Hz band 
with an amplitude of one nanotesla to the waist area after about 13 minutes of exposure an erection is created that can be maintained for up to one hour of therapy (the positive side)
5.340 MHZ - Tesla operating frequency    
nano-oscillators bioelectric signals, biological sensing potential (spin transfer torque)
0.85 GHZ  
0.45 - 1.42 GHZ bandwidth 
DC - 10 GHZ - working frequency range of neural network (nanotube)
Sensors nominal 15 milliwatts

DC – 10 GHZ - range of a nanotube antenna 

2.6  GHZ - operate transistors nanotubes and nanowires

The connection of the nanotube to the flesh of the parasite's white kernel cross-link of the nano-nature of the body (SWCNT) zigzag structure of cells is made
8.8 GHZ / 22db, 16-17 db
Information about the capacitors inside the nanotube (which is a neural network inside the body) fast bipolar SiGe BFP 640F
Nanotube power consumption in the range of
10 -100 mv
Corrects very small signals up to −15 dBm (nanotube)
It is charged from frequencies/magnetic induction/photosynthesis/optical/thermal/infrared radiation
from any substance that is in the dioxide state/from the circulatory system/the body's electrical activity/electrostatics and it has nuclear fuel cells
The nanotube diodes have a working range of
100 mv - 400 mv
operating frequency of graphene plasmonic transceiver
7  GHZ
AC current (250 MHz) Output trace response time (nanotube)
224.840 MHz - mind control telemetry in the field of radio amateurs
effective range for microwave audio effect
10 MHZ – 2.4 GHZ 

built a biomedical telemetry system to measure the tension
in anterior cruciate ligament after surgery. They implanted a transmitter inside
a cadaver and the receiver was on the surface (i.e., implant-to-surface setting).
26 2.4 – Implant Communication Technologies
From their experiment setup, they reported best performance when a current of
3 mA is used at 37 kHz. Following Zimmermann [58], Hadana [63] and Lindsey
[64], there has been several developments and research on surface-to-surface


dc - 100 kHz bandwidth (wide) - video from the eyes
10 + 50 + 200 HZ  / 1 + 2 + 4 + 6 + 9 MHZ bandwidth 

dc - 100 kHz bandwidth (wide) - video from the eyes   
61.9 + 66 + 72.5 HZ + 1 + 2 + 4 + 6 + 9 MHz bandwidth 

Optogenetics:Control over gene editing, viruses,nanotube functional proteins, tuning enzyme,biofilm,hydrogel,QGD etc
Ion channels (negative + positive)
10 – 100  KHZ / 10 MHz bandwidth 
Protein channels (functional proteins)
10 – 100 KHZ / 10 MHz bandwidth    
10 – 500 KHZ / 10 MHz bandwidth  
PRF signal technique pulse repeat chain frequency

In the bioengineering document (biotelemetry) GPS , it is explicitly written that FM transmissions may be used as
frequency modulation, changing the operating point of the transistor in the nanotube, changing the receiving 
capacitance and therefore changing the resonant frequency of the circuit

29.7 – 89.5 MHZ
88   – 108 MHZ (FM) / DC – 1 GHz bandwidth  
136 – 174 MHZ
146 – 174 MHZ
174 – 216  MHZ  / (low) biological details / 7 + 13 MHZ   
450 – 470 MHZ (intermediate)
5,20,6,2  MHZ bandwidth
100 + 300 + 14.3 Hz band / 11.25 + 12.5 + 6.25 + 20 + 22 + 18+ 25 + 5 + 2.4 + 1 + 0.96 + 1.2 + 4.8 + 10.29 + 10 + 40 + 50 + 75 kHz ,100 KHZ bandwidth 
608  - 614   MHZ / (intermediate) / 14 + 12 + 37   bandwidth 
614  – 698  MHZ / TV channel 38 + 51
470 – 668 MHZ / (high) 14 + 46 bandwidth   
1350 – 1390  MHZ
1395 – 1400 MHZ / (super high) 14 band      
1427 – 1432 MHZ / (super high) 14 band  
1432  –  1435 MHZ / (super high) 14 band  
555 MHZ - pass-through channel during disturbances
 
According to the document, broadband may arrive in the following channels:
(37,102,153,159,220,450) MHZ
2.4  – 2.5 GHZ  bandwidth  
5.150 –  5.875 GHZ bandwidth
It is suspected that the Ultra Bandwidth is
0.1 MHz - 10 GHz
Ultrasound Implant Device Target Drug Delivery
(piezoelectric transmissions)
0.94 – 1.28  MHZ / 1 MHz resonance operand
Implanted receiver (microstimulator) MEMS piezo ceramic
2.25  MHZ / 1.5 mw/cm2    
Resonance Photoacoustic Image (nanotube)
11.7 – 2.8 MHZ
8 – 2.8 MHZ (low)
15 – 2  MHZ (medium)
25 – 8.5 MHZ (high)
2  – 33  MHZ /  Bandwidth (27.12 MHZ) for all ranges 

Neurostimulator receiver each 256 - 1024 nerve stimulation channels capable of transmitting biphasic current in each channel 1 - 250 phase pairs
Capable of stimulating each channel at repetition rates of
100 – 10  HZ (dense)
10 -   250 HZ (wide) 
Nominal stimulation rate at 30 Hz
Each channel is adjustable in the range of 0 - 12700 Resolution 100 microseconds Maximum output current of each module 1024 microamps
- communication between the implants (nanotube) inside the body and between people or elements or products in the environment. Repulsion or attraction between people like magnets
570 HZ -  2 MHZ   
range of attacks by needles and pins in the body or blows to the body or head
425  – 1310 MHZ
audiogram communication includes all the biological details of control
Cerebral (eeg, emg, ecg, ccr, gsr, etc. with the help of the nanotube networked throughout the body..
125 – 1310  MHZ / 80 db / (up to 1500 kbps)raw data rate requirement of 10–100 kbps whereas the former has 10–200 kbps

projection of nano tube fiber signals into the environment (electromagnetic resonance) detects signals of animals and 
substances and manages an independent life intelligence against them which includes a wide range of mechanical/kinetic/chemical reactions (selections) in which to avoid or continue..
1 - 2.4 GHZ



The frequencies the values displayed by the selective card in the electromagnetic spectrum while filtering noises and displaying the powers and widths of the small: KHZ
Electromagnetic emission into the environment of any living creature (range)
16 HZ – 150 KHZ
Telemetry tracking ultrasound signal
19.6 KHZ / 50 kHz bandwidth   
Electromechanical resonance frequency range of a nanotube
458.21 - 434.6   KHZ
it was not written but in my opinion in combination with ultra bandwidth and wide nanotube electromechanical resonance range in the range
30 - 150 MHz (default 55 MHz)

reaction of microorganisms in the body to physical signals (fast movement with 1490 S/M sensing)
2.28  KHZ

Ultra low power active medical implant (bio telemetry)
5 – 300  KHZ
9 – 315 KHZ
creating bubbles on the surface of the skin and inside the 
body (sensing)
20  KHZ
75 - 200  KHZ - remote viewing   
175  – 150  MHZ - remote neural monitoring (MHZ)
(60,000 thousand words and translation into many languages)
Emergency net on the ground
GPS nanotube implants (bio telemetry)
11.875 - 10 KHZ
Biomedical Engineering Chemical Engineering (nanotube)
The sound communication range of nanotube implants (broad)
1500 – 300 KHZ / (low) 1 MHz band 
1650 – 550   KHZ / (medium) 1 MHz band 
In the high range, the document mixes mind control through the television on AM
30 – 3  MHZ (high)
225  –  400  KHZ - biofeedback NSA
tracking and decoding biological - signals (eeg ecg, emg, gsr, ccr) transmission and reception of the ultra-band and 
100 HZ – 1 KHZ 
wide wave carrier range in the megahertz range
125 – 1310 MHZ (there is also a range in MHz) 
100 – 10 KHZ - range of nano robots  
electromechanical simulation in the body of micro/nano robots (NEMS, MEMS))
55.1 + 55.2 KHZ
Electronic torture (I have a feeling that both can be bandaged) I did not find any more information
(20 – 340 Hz) + (20 – 200 KHZ)
A range of silent subliminal transmissions
20  - 14 KHZ (wide) 
20  – 16 KHZ  (dense) 

The overall combination of electronic attack and the widest ranges where either range can be nad wide
0.1 - 100 HZ
          +
0.1 - 1500 KHZ 
          +
0.1 MHZ - 10 GHZ 

100 – 1000 HZ  + carrier frequency (450 MHz) is used to interact with the nervous system of the target
0.1 HZ - 400 KHZ  (wide)   
(crowded) negative symptoms: cough - phlegm, headache, suffocation, etc. + carrier frequency
50 - 100 HZ
May be on Ultra Bandwidth
50 – 2450 MHZ
Suspect that it is possible to play manually
0.1 MHz - 10 GHz
(mental access window frequencies) They can overlap each other in bandwidth
7.83 HZ  –  7.81 HZ +  400 MHZ – 750 MHZ

Sound signals (downlink) enter the brain
18.5 – 18.7   KHZ (wide) 
35  – 15 KHZ (high)
150 HZ Bandwidth / 1-10 micro volts     
16.2 – 13.6  KHZ (wide) 
10 –  19 KHZ (high) 
15.96 – 16.21 MHZ
possible trauma, tissue heating  nerve stimulation, burns, dehydration + bandage
5 – 30  KHZ
a dense range that causes bleeding and spasms + bandwidth Sound signals (uplink) coming out of the brain
0.5 -2.5 KHZ
162 – 136  KHZ (wide)
130 – 190 kHz (high)
135.7 – 137.8 KHZ (wide)
130 – 190 kHz (low)
136 kHz (default)  
160 - 190 KHZ - mind control (radio enthusiasts) 

10 - 190 KHZ - White House radar
Additional details (nanotube):
The discharge of capacitors inside the nanotube and chips is
0.4  HZ
Sub Carrier Oscillator
320  HZ
Multivibrator Electrode Nanotube Shifted Subcarrier
1 KHZ (electromechanical resonance at 400 hertz)
Crystal controlled oscillator inside the nanotube
4 x 115 MHZ 
Crystal filter 8 pole / 10 kilohertz, band width selective receiver
Discriminator Oscillator Automatic Frequency Control
1 kHz / low pass filter 50 Hz (biological details)
The runners/Micro Tesla - 0.1 Hz - 1500 kHz
Clock rate of the output/input current inside the nanotube 13.56 MHz Modulation or Protocol Bluetooth v5.0, LTE AC current (absorbing electricity from the air)

Nanotube active vibrations, chemical and thermal reactions and smart thermal reaction intelligence in the range:
300 – 200 Kelvin
The total heat capacity at constant volume (Cv) is about 38 J/(K mol) of a nanotube

17.64HZ the electrical frequency of the heart
70.56HZ muscular electrical frequency
(Full range in HZ, full control over the body's biological activity)
On a 13.56MHZ nanotube current source

Implanted devices:
402 MHZ / 19, 27 MHZ 
433 MHZ  MHz / 19, 22, 28  
868 MHz / 25 ,28 MHZ / -80.03 dBm
915  MHz /  25, 28 ,30 MHZ  
1.4   GHZ / 31 MHZ
2.45 GHZ /  21, 23 ,27, 31 MHZ
DC - 6  GHZ Ultra Band

Ingestion devices:
433  MHZ /  34 MHZ 
500 MHZ /  35 , 36 MHZ
800 MHZ / 34 MHZ
1.2  GHZ / 34 MHZ  
1.4  GHZ /  37, 38 MHZ 
2.4 GHZ / 39, 40 MHZ    

Injectable devices:
132  KHZ / 41 MHZ 
2 MHz / 42, 43 MHZ 
13.56 MHZ  MHz / 44
915  MHz  / 45 MHZ

Injectable devices,Ingestion devices,Implanted devices:
Communication Service (MedRadio) band of 403.5 MHz, and the Industrial,
Scientific and Medical (ISM) band of 2.4 GHz. In general, selection of
operation frequency involves several trade-offs. Specifically, low frequencies
tend to be more attractive as they are associated with lower loss through the
biological tissues. As an example, high frequencies in the order of 3-5 GHz imply
attenuation as high as 20-30 dB for every 2 cm of biological tissue


satellites communications Microwave Surveillance operations
 
“C” band (low)

3.7 to 4.2 GHZ

“Ku” band (high)

10.7 to 12.75 GHZ(low)
11.7 to 12.2 GHZ(meduim)
12.2 - 12.7 GHZ(high)

In some documents it was written that the pulse may reach
300 MHz to 300 GHz