1.
  https://www.youtube.com/watch?v=MBH5-oHqzp4
for your entertainment ,some of you may find it very helpful.
This part is essential to understand Zenneck Wave  later on. But it is in line with  my video
https://youtu.be/KLAPRNWuAn4?t=385

2. http://electriciantraining.tpub.com/14182/css/Surface-Wave-76.htm
This is sort of old way to understand  surface wave but very easy  explained .
It points  in fundamental to surface wave vertical polarization.

3. http://rexresearch.com/corumzenneck/US2017077715A1.pdf
This  PDF is part of http://rexresearch.com/corumzenneck/corumzenneck.html
The details about how to do it  are to be found in early versions of applications filed by Corum Bros.

4.https://worldwide.espacenet.com/publicationDetails/citingDocuments?CC=US&NR=4751515A&KC=A&FT=D&ND=&date=19880614&DB=&locale=
Thanks to our German  friend lancaIV we can easily dig in it.

Wesley

YOUR FUTURE and WORLD  FUTURE WITH  CORUM BROS FEW YEARS FROM NOW:

Patents of Corum; James F. :
do not forget there are two brothers  I have listed only one of them.


1.MODULATED GUIDED SURFACE WAVES      14838852 Aug 28, 2015

2.EMBEDDING DATA ON A POWER SIGNAL    10079573 Sep 8,  2015 patent
electric load of the receiver circuit is modulated with reference to a data signal.

3.FREQUENCY DIVISION MULTIPLEXING FOR WIRELESS POWER PROVIDERS  Sep 9, 2015 10033198 patent.
for wireless power providers using Zenneck surface waveguide probes to transmit power.

4.CLASSIFICATION OF TRANSMISSION Sep 9, 2015 10027131 patent
assigning authorization  to the user of energy   from Zenneck wave.

5.LOAD SHEDDING IN A GUIDED SURFACE WAVE POWER DELIVERY SYSTEM Aug 22, 2016 10027177  patent
send load shedding instructions to a plurality of user devices. You can be disconnected at any time.

6.ADAPTATION OF POLYPHASE WAVEGUIDE PROBES Sep 9, 2015 10027116 patent
  A probe control system can be used to adjust the polyphase waveguide probe based on characteristic
of therein.

7.GEOLOCATION WITH GUIDED SURFACE WAVES Aug 28, 2015 10001553 patent
  fixing a navigational position using guided surface waves

8.GLOBAL EMERGENCY AND DISASTER TRANSMISSION Sep 8, 20159997040 patent
method for disaster warning recovery including a power modulator.

9.MINIMIZING ATMOSPHERIC DISCHARGE ON A GUIDED SURFACE WAVEGUIDE PROBE 62467956Mar 7, 2017 application.
eliminating or minimizing atmospheric discharge within the guided surface waveguide probe.
Atmospheric discharge can be minimized to a nominal amount according to one or more factors, such as, for example, the use of a corona hood,
the effective diameter of the internal coil, the effective diameter of the tube, and the shape of the charge terminal.
methods of eliminating Schumann waveguide influence -and we need/(may) to do reverse of it.

10.CHARGE TERMINAL DESIGN FOR GUIDED SURFACE WAVEGUIDE PROBE 62467986Mar 7, 2017 application
  guided surface waveguide probe/to launch a guided surface wave/ elevated to a height above the ground/
structure supports: charge terminal;/one section of internal coil/that is coupled to generator;/
a conductive tube conductively coupled to the at least one section of internal coil at a bottom end,
and  coupling conductors that extend radially away from a top of the conductive tube to points located on an inner surface of the charge terminal.
That tube is shown  here  in Aleksey Pastuchov patent application: https://youtu.be/KLAPRNWuAn4?t=220 
with my modification.  and 90  degrees of phase shift is explained in my  video.
Fig 3. on my video https://youtu.be/KLAPRNWuAn4?t=448  shows you  original  drawing from Pastukhov

11.ADJUSTMENT OF GUIDED SURFACE WAVEGUIDE PROBE OPERATION 62468130 Mar 7, 2017 application.
Disclosed  transmitting and receiving energy device in the form of a guided surface-waveguide mode along the surface of a the ground 
excited by a guided surface waveguide probe.

12.GUIDED SURFACE WAVEGUIDE PROBE SUPERSTRUCTURE 62468213Mar 7, 2017 application.
structure includes a charge terminal elevated to a first height and a phasing coil elevated to a second height above aground.
/ includes a non-conductive support structure to support the phasing coil and the charge terminal.
The non-conductive support structure includes a truss frame that supports the phasing coil at the second height above
the lossy conducting medium and supports the charge terminal at the first height above the lossy conducting medium.
The structure further includes a substructure bunker constructed in the lossy conducting medium.
The substructure bunker can include foundational walls, a grounding grid formed in a foundational seal slab, and a
covering support slab at a ground surface elevation of the lossy conducting medium, the covering support slab supporting the non-conductive support structure.

13.GUIDED SURFACE WAVEGUIDE PROBE WITH INSULATING MATERIAL IN SUPPORT PLATFORM NEAR COIL(S) 62468022Mar 7, 2017 application.
description  similar to previous one.

14. MINIMIZING ATMOSPHERIC DISCHARGE WITHIN A GUIDED SURFACE WAVEGUIDE PROBE 62467963 Mar 7, 2017 application
a charge terminal elevated over a lossy conducting medium. The shape of the charge terminal is designed to minimize atmospheric discharge.
A top portion of a coil being configured to provide a voltage to the charge terminal with a phase delay that matches a wave tilt angle associated
with a complex Brewster angle of incidence associated with the lossy conducting medium is recessed within a hollow region of the charge terminal.
We are looking for interaction  with Schumann waveguide.

15.MEASURING OPERATIONAL PARAMETERS AT THE GUIDED SURFACE WAVEGUIDE PROBE 62467979 Mar 7, 2017 application.
Disclosed is an exemplary  of guided surface waveguide probe.,/ the guided surface waveguide probe is made of: 
charge terminal elevated to a height above the lossy conducting medium;
a support structure that supports the charge terminal;
an internal coil that is supported within the support structure and is coupled to an excitation source; a
conductive tube having a first end conductively coupled to the at least one section of internal coil, wherein a second end
of the conductive tube extends vertically towards and is electrically coupled to the charge terminal;
at least one sensor electrically coupled to the charge terminal or the internal coil, wherein the at least one
sensor measures an operational parameter of the guided surface waveguide probe; and a non-conductive
channel connected to the at least one sensor by which data associated with the operational parameter is communicated.

16.SUPPORT STRUCTURE FOR A GUIDED SURFACE WAVEGUIDE PROBE 62468163Mar 7, 2017
I did not include  abstract here. there are many of support structures with drawings.

17.ANCHORING A GUIDED SURFACE WAVEGUIDE PROBE 62467884Mar 7, 2017 application.
waveguide probe can be suspended from a support structure manufactured from a nonconductive material,
the support structure comprising a plurality of beams. A base bracket is configured to receive at least one of
the plurality of beams and further comprising a hole. The base bracket rests upon a pad. An anchor bolt protrudes
from the pad through the hole of the base bracket. Also, a fastener engages the anchor bolt to secure the base bracket to the pad.

18.SYSTEM AND METHOD FOR MEASUREMENT OF TEMPERATURE ON A GUIDED SURFACE WAVEGUIDE PROBE  62468161 Mar 7, 2017 application
he system also comprises a temperature sensor positioned on one of the non-conducting structural components.

19.Detecting Unauthorized Consumption of Electrical Energy  Sep 9, 20159885742 PATENT!!!!!
Aspects of detecting the unauthorized consumption of electrical energy are described. In some embodiments,
a system includes a guided surface waveguide probe that launches a guided surface wave along a surface of a terrestrial medium.
The system further includes metering systems that are distributed within a geographical region associated with the guided surface waveguide probe.
The system also includes at least one computing device and memory storing computer instructions that cause the at least
one computing device to generate an energy flow map using data obtained from the metering systems.

20. EXCITATION AND USE OF GUIDED SURFACE WAVE MODES ON LOSSY MEDIA Sep 10, 2014 9941566 patent.
Disclosed are various embodiments for transmitting energy conveyed in the form of a guided surface-waveguide mode
along the surface of a lossy medium such as, e.g., a terrestrial medium by exciting a guided surface waveguide probe.

21. HIERARCHICAL POWER DISTRIBUTION. Sep 8, 2015 9887557 patent.
a first guided surface waveguide probe launches a first guided surface wave along a surface of a terrestrial medium
within a first power distribution region. A guided surface wave receive structure obtains electrical energy from the first guided surface wave.
A second guided surface waveguide probe launches a second guided surface wave along the surface of the
terrestrial medium within a second power distribution region using the electrical energy obtained from the first guided surface wave.

22.EXCITATION AND USE OF GUIDED SURFACE WAVE MODES ON LOSSY MEDIA Mar 7, 2013 9912031 patent.
exciting a guided surface waveguide probe to create a plurality of resultant fields that are substantially mode-matched to a Zenneck
surface wave mode of a surface of a lossy conducting medium.

23.GLOBAL ELECTRICAL POWER MULTIPLICATION Aug 16, 2016 9899718 patent
a global power multiplier includes first and second guided surface waveguide probes separated by a distance equal to a quarter wavelength
of a defined frequency and configured to launch synchronized guided surface waves along a surface of a lossy conducting medium
at the defined frequency; and at least one excitation source configured to excite the first and second guided surface waveguide
probes at the defined frequency, where the excitation of the second guided surface waveguide probe at the defined frequency
is 90 degrees out of phase with respect to the excitation of the first guided surface waveguide probe.
THIS IS EXACTLY ALEKSEY PASTUHOV PATENT APPLICATION!!!!!!!!!!!!! FROM MY VIDEO
In another example, a method includes launching synchronized guided surface waves along a surface of a lossy
conducting medium by exciting first and second guided surface waveguide probes to produce a traveling wave propagating along the surface.

24. EXCITATION AND USE OF GUIDED SURFACE WAVE MODES ON LOSSY MEDIA Mar 7, 2013 9910144 patent.
methods for transmission and reception of electrical energy along a surface of a lossy conducting medium medium.
In one example, a receive circuit is used to receive electrical energy from a guided surface waveguide probe that
transmits the electrical energy in the form of a Zenneck surface wave along a surface of a a lossy conducting medium

25.OBJECT IDENTIFICATION SYSTEM AND METHOD 20180175630 A1 June 21, 2018  application.
An object identification system includes a guided surface waveguide probe that produces a guided surface wave;
and an object identification tag having a receive structure and a tag circuit, the tag circuit coupled to the receive structure
and electrically powered as a load on the probe by conversion of the guided surface wave to electrical current at the receive
structure, the tag circuit configured to emit a return signal containing a tag identifier when electrically powered by presence
of the guided surface wave.

26. OBJECT IDENTIFICATION SYSTEM AND METHOD 20180172798 A1 June 21, 2018 application
this is another one.

26.EXCITATION AND USE OF GUIDED SURFACE WAVES  20180166884 A1
June 14, 2018 application.

transmitting and receiving energy conveyed in the form of a guided surface-waveguide mode along the surface of
a lossy medium such as, e.g., a terrestrial medium excited by a guided surface waveguide probe.

27.SITE PREPARATION FOR GUIDED SURFACE WAVE TRANSMISSION IN A LOSSY MEDIA  20180166762 A1  June 14, 2018 application.
Aspects of a guided surface waveguide probe site and the preparation thereof are described. In various embodiments,
the guided surface waveguide probe site may include a propagation interface including a first region and a second region,
and a guided surface waveguide probe configured to launch a guided
surface wave along the propagation interface. In one aspect of the embodiments, at least a portion of the first region
may be prepared to more efficiently launch or propagate the guided surface wave.
Among embodiments, the portion of the first region, which may be composed of the Earth, may be treated or mixed
with salt, gypsum, sand, or gravel, for example, among other compositions of matter.
In other embodiments, the portion of the first region may be covered, insulated, irrigated, or temperature-controlled,
for example. By preparing the site, a guided surface wave may be more efficiently launched and/or propagated.

28.VARIABLE FREQUENCY RECEIVERS FOR GUIDED SURFACE WAVE TRANSMISSIONS 20180159374 A1 June 7, 2018 application

guided surface waveguide probe and a guided surface wave receiver, where the guided surface wave receiver comprises
processing circuitry that (a) identifies at least one frequency from a plurality of available frequencies associated with a
transmission of Zenneck surface waves along a terrestrial medium, and (b) adjusts a frequency at which the guided
surface wave receiver receives electrical energy from the Zenneck surface waves via the terrestrial medium to a predetermined frequency.

29. CHEMICALLY ENHANCED ISOLATED CAPACITANCE
20180159339A1   June 7, 2018   application
transmitting energy conveyed in the form of a guided surface waveguide mode along the surface of a lossy conducting
medium such as, e.g., a terrestrial medium by exciting a guided surface waveguide probe. In one embodiment,
compensation is provided to elevate isolated capacitance of a terminal of the waveguide probe in the form of mounted charge devices.

30.ENHANCED GUIDED SURFACE WAVEGUIDE PROBE 20180151934 A1
May 31, 2018  application.

31.SUPERPOSITION OF GUIDED SURFACE WAVES ON LOSSY MEDIA 20180151933 A1 May 31, 2018
, Zenneck surface waves are launched along a surface of a lossy conducting medium using an array of guided
surface waveguide probes and a predefined field pattern of the Zenneck surface waves is maintained.
The individual ones of the guided surface waveguide probes include a feed network electrically coupled to a charge terminal.
The feed network provides a phase delay that matches a wave tilt angle associated with a complex
Brewster angle of incidence associated with the lossy conducting medium.
32.CHANGING GUIDED SURFACE WAVE TRANSMISSIONS TO FOLLOW LOAD CONDITIONS 20180145540 A1 May 24, 2018 application

guided surface waveguide transmit system includes a guided surface waveguide probe configured to transmit a
guided surface wave along a lossy conducting medium. The system further includes a controller device configured
to receive load status data and signal for the guided surface waveguide probe to adjust transmission of the guided
surface wave based at least in part on the load status
data.

33. RETURN COUPLED WIRELESS POWER TRANSMISSION 20180138753A1 
May 17, 2018 application.

a system includes a guided surface waveguide probe including a charge terminal elevated at a height over a
lossy conducting medium, and a feed network. The system further includes a conductor coupled to the guided
surface waveguide probe that extends a distance away from the guided surface waveguide probe across the lossy
conducting medium, and at least one guided surface wave receivers coupled to the conductor. The a system includes
a guided surface waveguide probe including a charge terminal elevated at a height over a lossy conducting medium, and
a feed network. The system further includes a conductor coupled to the guided surface waveguide probe that extends a distance
away from the guided surface waveguide probe across the lossy conducting medium, and at least one guided surface wave receivers
coupled to the conductor. The conductor can help to provide additional efficiency in power transfer between the guided surface waveguide
probe and the guided surface wave receivers, especially when the operating frequency of the probe is in the medium, high, or very high frequency
ranges.conductor can help to provide additional efficiency in power transfer between the guided surface waveguide probe and the guided surface
wave receivers, especially when the operating frequency of the probe is in the medium, high, or very high frequency ranges.

34.WIRED AND WIRELESS POWER DISTRIBUTION COEXISTENCE 20180138720 A1 May 17, 2018
distribute power across various regions. Power from a power plant can be distributed to sub-transmission stations.
For example, a transmission probe can be configured to launch a transmission frequency guided surface wave
for power transmission over a transmission region. A sub-transmission station can receive the transmission
frequency guided surface wave. A sub-transmission probe can be configured to launch a sub-transmission
frequency guided surface wave to transmit power over a sub-transmission region to transmit power.
A distribution station can receive the power from the sub-transmission frequency guided surface wave. it is to shut down  entire region including your cellphone
by Viziv.

35.Guided Surface Wave Transmission of Multiple Frequencies in a Lossy Media 20180138719 A1 May 17, 2018   application

various embodiments for transmitting energy at multiple frequencies via a guided surface wave along the surface of a lossy medium such as, e.g.,
a terrestrial medium by exciting a guided surface waveguide probe.

36.SIMULTANEOUS MULTIFREQUENCY RECEIVE CIRCUITS 20180123343 A1 May 3, 2018  application
various receive circuits by which to receive a plurality of guided surface waves transmitted by a plurality of guided surface
waveguide probes over a surface of a terrestrial medium according to various
embodiments.

37.Field Strength Monitoring for Optimal Performance 20180106845 A1 April 19, 2018 application.

various embodiments for adjusting an operational parameter of a guided surface waveguide probe according to measurements
received from one or more measuring devices. A measuring device measures the conditions associated with an environment of the
measuring device. The measuring devices communicates the measured data to the guided surface waveguide probe.
Adjustments can be made to one or more operational parameters of the guided surface waveguide probe according to the measured data.
This is  the way to limit you and request you to obey requests .( of the authority)

38.HYBRID GUIDED SURFACE WAVE COMMUNICATION 20180034502 A1 February 1, 2018
hybrid communication in which a first message from a guided surface wave probe
node is embedded in a guided surface wave, and a second message from a guided surface wave receive node
uses a different messaging mechanism.

39.MEASURING AND REPORTING POWER RECEIVED FROM GUIDED SURFACE WAVES 20180031619 A1 February 1, 2018
various approaches for measuring and reporting the amount of electrical power consumed by an electrical load
attached to a guided surface wave receive structure. A guided surface wave receive structure is configured to obtain electrical
energy from a guided surface wave traveling along a terrestrial medium. An electrical load is coupled to the guided surface wave receive
structure, the electrical load being experienced as a load at an excitation source coupled to a guided surface waveguide probe generating
the guided surface wave. An electric power meter coupled to the electrical load and configured to measure the electrical load.



Wesley

expression of may personal opinion only according, to US constitution.

http://jnaudin.free.fr/html/afep01.htm
What they saw 1999 as success and why is this now 20 years " dormant" ?Somebody knows this guy named Stefan Hartmann ? 

Lanca..maybe ask him to comment [find the thread here somewhere and Ping it?
just a note ,our friend Ernst has written a book [I understand limited release] here

https://www.amazon.com/dp/1793151040

http://rexresearch.com/corumzenneck/US2017077715A1.pdf


Wesley