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• How to build a rig for a solenoid coil
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  • Application Notes
    • Scalar Networks
      • Class E amplifier and larger solenoid shaped coils 3
      • Class E amplifier and solenoid shaped coils 2
      • Cone or pyramid shaped coils 1
      • Counter-propagating collisions of electromagnetic waves, part 2. Mono oscillation frequency source
      • Counter-propagating collisions of electromagnetic waves, part 3. Pancake coils
      • Counter-propagating collisions of electromagnetic waves, part 5. Five solenoid coil system
      • Experiment on counter-propagating collisions of solitary waves. Part 1 wave interactions
      • Solenoid shaped coils 1
      • Solenoid shaped coils 4, 6 port isolated signal splitter
    • Scalar wave communication
      • Scalar wave communication options part 1
      • Scalar wave communication options part 10, connecting the earth ground to the water table
      • Scalar wave communication options part 2. The envelop detector
      • Scalar wave communication options part 3. The biased envelop detector
      • Scalar wave communication options part 4. The properties of deployment in nature
      • Scalar wave communication options part 6, precision operational amplifier with envelope detector
      • Scalar wave communication options part 7, Superheterodyne versus TRF receiver, IF Amplifier, active bandpass filter and quartz crystal oscillator test circuit
      • Scalar wave communication options part 8, properties of deployment in nature 2
      • Scalar wave communication options part 9, Full-scale TRF receiver and long distance transmission in nature 3
      • Scalar wave communication part 5, Class A biased and DC biased Full Wave envelope detector
      • Scalar wave communication part 6, LM386, Class AB Operational Amplifier, undocumented scalar wave receiver function
  • Atmospheric Electricity
    • Materials and structures to harness electrical potential from the atmosphere
    • Part 2, Materials and structures to harness electrical potential from the atmosphere
    • Part 3, Charging a Capacitor from electrostatic electrical potential from a Wimshurst machine
  • Atmospheric Electricity-2
  • Audio Description – Solid State Back EMF charging, Part 5
  • Dielectric Field propagation
    • Dielectric Fields, receiver and transmitter
  • EMF Battery Charging
    • Back EMF Battery Charging, Part 1
      • Audio Description – Earth Battery Part 1
      • Audio Description – Part 1, Back EMF Battery Charging
    • Back EMF Battery charging, Part 2
      • Audio Description – Back EMF battery charging, Part 2
    • Back EMF battery charging, Part 3
      • Audio Description – Back EMF battery charging, Part 3
    • Solid State Back EMF charging, Part 1
      • Audio Description – Solid State Back EMF charging , Part 1
    • Solid State Back EMF charging, Part 2
      • Audio Description – Solid State Back EMF charging , Part 2
    • Solid State Back EMF charging, Part 3
      • Audio Description – Solid State Back EMF charging , Part 3
    • Solid State Back EMF charging, Part 4
      • Audio Description – Solid State Back EMF charging, Part 4
    • Solid State Back EMF charging, Part 5
      • Audio Description –  Solid State Back EMF charging, Part 5
  • Ferrite core systems performance in Joule thief configuration
    • 3E25 Performance Evaluation
    • Large N30 core, performance evaluation
    • M-088 performance Evaluation
    • N30, Performance Evaluation
    • Nanoperm M-049-02 Performance Evaluation
    • RM8/I – 3C90 core performance evaluation
  • Geometric Objects and the influence of the Aether
    • Geometric Objects, part 1
    • Geometric Objects, part 2
    • Geometric Objects, part 3
    • Harnessing Atmospheric electricity, Lift-off, first try
  • NG Coil Design
    • Next Generation Coil Design, Part 1
    • Next Generation Coil Design, Part 2
    • Next Generation Coil Design, Part 3
    • Next Generation Coil Design, Part 4
    • Next Generation Coil Design, Part 5
  • Space Conditioning
    • Construction of a Space Energy Concentrator
    • High Voltage Transformer for Space Activation Device
    • Space Conditioning , Part 1
      • Audio Description – Space Conditioning, Part 1
    • Space Conditioning Part 5
    • Space Conditioning, Part 2
      • Audio Description – Space Conditioning, Part 2
    • Space Conditioning, Part 3
      • Audio Description – Space Conditioning, Part 3
    • Space Conditioning, Part 4
      • Audio Description – Space Conditioning, Part 4
    • Space Conditioning, Part 6
      • Audio Description – Space Conditioning, Part 6
    • Space Conditioning, Part 7
      • Audio Description – Space Conditioning, Part 7
    • Voltage Multiplier for Space Activation Device
  • Tesla Coil Functions
    • Complex impedance and Class E amplifier in a scalar network
    • Driving high power low resistance loads
    • Energy distribution in a scalar network
    • Enhanced scalar wave technology with passive amplification and reduced power consumption
    • First test type A pancake coil from Prof. Dr. Konstantin Meyl
    • Impedance anomalies in a scalar network and potential free measurements
    • Investigating amplifier options for a prove of concept of a self-sustaining scalar wave energy system
    • Investigating scalar wave hypothesis of power gain by larger coils, phase 1
    • Load investigation for highest power delivery in a scalar network
    • Scalar network the way to alternative energy
    • Scalar wave frequency transmission
    • Scalar wave frequency, configuration and measurements
    • Scalar wave functions, propagation and phenomena
    • Scalar wave technology passive amplification, phase 2
    • Test of Tesla’s recommended copper weight ratio between transmitter and receiver coil via λ/4 resonation
    • Test type C pancake coil from Prof. Dr. Konstantin Meyl
  • Vortices Fields
    • Colliding vortices fields in a scalar network
    • Colliding Vortices Fields, Part 1
    • Colliding Vortices Fields, Part 2
    • Colliding Vortices Fields, Part 3
    • Colliding Vortices Fields, Part 4
    • Colliding Vortices Fields, Part 5
    • Colliding Vortices Fields, Part 6
  • YouTube Videos
    • Amplifier Topologies
    • Biefeld Brown Experiments
    • Plasma Experimentations
    • Power transmission in a lumped circuit and Negative Resistance
    • Radiant Energy
    • Steorn Magnetic Motor Replication
    • The Bipolar Tesla coil and the benefit of orienting asynchronous
    • Wireless Power Transmission
  • Earth Battery
    • Earth Battery Part 1
    • Earth Battery Part 2
      • Audio Description – Earth Battery Part 2
    • Earth Battery Part 3
      • Audio Description – Earth Battery Part 3
    • Earth Battery Part 4
      • Audio Description – Earth Battery Part 4
  • Earth Magnetic Fields
    • Earth Magnetic Fields, Part 1
    • Earth Magnetic Fields, Part 2
      • Audio Description – Earth Magnetic fields, Part 2
  • Magnetic Shielding
    • Introduction to Magnetic Shielding, Part 1
      • Audio Description – Part 1, Introduction to Magnetic shielding
    • Magnetic Shielding, Part 2
      • Audio Description – Part 2, Magnetic Shielding, Battery Benchmark and harnessing Back EMF energy
    • Magnetic Shielding, Part 3
      • Audio Description – Part 3, Magnetic Repulsion via Solenoids
  • LED Driver Performance and Systems
    • Audio Description – LED Driving Transformer Efficiency, Part 6
    • Audio Description – LED Driving Transformer Efficiency, Part 7
    • LED driving performance efficiency Part 7
  • Tesla Wireless Power Part 1
• Power delivery and distribution between resonating air coils
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  • Components and Partlist
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  • Small LED driver Circuit
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    • Akashic Fields
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    • Arthur Mathews – Tesla’s last Assistance
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    • Gustave Le Bon
    • John Worrell Keely
    • Nikola Tesla
    • Oliver Heaviside
    • Rudolf Steiner
    • T. Henry Moray and Moray B. King
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    • Walter and Lao Russell
    • William Lyne
  • Companies, Researches and Inventors
    • THE R.M. SANTILLI FOUNDATION
  • Courses
    • Active Components
      • Operational amplifier part 1, use cases and configurations
      • Operational Amplifier part 3, LM386 Class AB audio amplifier
      • Operational Amplifier part2, OPA37, voltage gain versus voltage supply
    • Calculations, Simulations and Experimentations
      • Class A versus Class D amplifier power analysis and simulation
      • Class E amplifier driven Tesla coil
      • Class E Radio frequency amplifier analysis and simulation
      • Class E Radio frequency amplifier simulation and build
      • How to measure impedance
    • Coil Design
      • Scalar wave technology and the defiant to Ohms law and Lenz law
    • Electricity
      • HV Systems
      • Ohm’s Law, Kirchhoff’s Voltage Law
    • Electromagnetic Waves and Fields
      • Bifilar versus Monofilar coil design
      • Components and performance
        • Transformer and Dot convention
        • Transformer coiling performance
      • Lenz’s Law, Counter Electromotive Force
      • Load Matching for LED Drivers
      • Magnetic Coupling of coil systems
      • Tesla Coil design
      • The Standing Wave Ratio
      • Transformer Core Material
    • Electronics Design
      • Class B Amplifier, TC4421A, TC4422A
      • IR 2110
      • IR 2183 and IR21834, H – Bridge Driver
      • IR 2184 and IR 2103 Half H – Bridge Driver
      • IRS 2453D Full H – Bridge Driver with internal Oscillator
      • NCP 5181
      • Performance Evaluation Electronic Components
      • Signal Generator Design
    • Frequency Filter Design
    • One wire Power transfer
    • Passive component measurements
      • How to measure Inductors
      • How to measure Self – Capacitance of an air core solenoid coil
    • Performance Evaluation
      • Component Performance Evaluation Part 1
      • Component Performance Evaluation Part 6
      • Component Performance Evaluation, Part 2
      • Component Performance Evaluation, Part 3
      • Component Performance Evaluation, Part 4
      • Component Performance Evaluation, Part 5
      • GDT controlled Tesla coil
      • High Performance GDT for Anti-Parallel Tesla coil
      • Metallic Glas C-core performance Evaluation
      • Thyristor controlled Tesla coil
    • Scientific Laws
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    • Coulomb’s law
    • CP Violation
    • Dirac Sea
    • Electrical Impedance
    • Electrical Reactance
    • Electrical Resitance and Conductance
    • Electricity
    • Euclidean Space
    • Euler-Bernoulli Beam Theory
    • Farad
    • Gauge Fixing
    • Gaussian Function
    • Henry Unit
    • Inductance
    • Joule Unit
    • Kelvin
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    • Lagrangian Mechanics
    • Lorentz Force
    • Lorentz Transformation
    • Magnetic Reluctance
    • Maxwell’s Equations
    • Minkowski space
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    • Permeability (electromagnetism)
    • Quantum
    • Schuhmann Resonance
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    • The Coandă effect
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    • Watt
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    • How to build a Pyramid
    • How to remove the GFCI protection on a NST
    • RF Amplifier Part 1
    • RF Amplifier Part 2
    • Soldering PL-259 Coax Plugs
    • Synchronous Rotary Spark Gap
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    • The Tesla Bifilar Spiral Coil
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  • Seminar from 17.03.2020, Resonance in biological entities
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posts

• Counter-propagating collisions of electromagnetic waves, part 5. Five solenoid coil system, new video
• Solenoid shaped coils 4, 6 port isolated signal splitter, new video
• Counter-propagating collisions of electromagnetic waves, part 3. Pancake coils, new video
• Counter-propagating collisions of electromagnetic waves, part 2. Mono oscillation frequency source, new video
• Experiment on counter-propagating collisions of solitary waves. Part 1 wave interactions, new video
• Scalar wave communication options part 10, connecting the earth ground to the water table, new video
• Scalar wave communication options part 9, Full-scale TRF receiver and long distance transmission in nature 3, new video
• Scalar wave communication options part 8, properties of deployment in nature 2, new video
• Scalar wave communication options part 7, Superheterodyne versus TRF receiver, IF Amplifier, active bandpass filter and quartz crystal oscillator test circuit.new video
• Scalar wave communication options part 6, precision operational amplifier with envelope detector, new video