LC Circuit

Resonant Charging Choke (C) in series with Excitor-array (El/E2) forms an inductor-capacitor circuit
(LC) since the Excitor-Array (ER) acts or performs as an capacitor during pulsing operations, as
illustrated in Figure (1-2) as to Figure (1-1).
The Dielectric Properties (insulator to the flow of amps) of natural water (dielectric constant being
78.54 @ 25c) between the electrical plates (El/E2) forms the capacitor (ER). Water now becomes part
of the Voltage Intensifier Circuit in the form of "resistance" between electrical ground and pulse-
frequency positive-potential ... helping to prevent electron flow within the pulsing circuit (AA) of
Figure 1-1.
______________________________________________________________________________
Stanley A. Meyer
1-1RE: Hydrogen Fracturing Process
Memo WFC 420
The Inductor (C) takes on or becomes an Modulator Inductor which steps up an oscillation of an
given charging frequency with the effective capacitance of an pulse-forming network in order to charge
the voltage zones (E1/E2) to an higher potential beyond applied voltage input
The Inductance (C) and Capacitance (ER) properties of the LC circuit is therefore "tuned" to
resonance at a certain frequency. The Resonant Frequency can be raised or lowered by changing the
inductance and/or the capacitance values. The established resonant frequency is, of course, independent
of voltage amplitude, as illustrated in Figure (1-3) as to Figure (1-4).
The value of the Inductor (C), the value of the capacitor (ER), and the pulse-frequency of the voltage
being applied across the LC circuit determines the impedance of the LC circuit
The impedance of an inductor and a capacitor in series, Z series is given by
(Eq 1)
The Resonant Frequency (F) of an LC circuit in series is given by
(Eq 4)
Olun's Law for LC circuit in series is given by