In-Line Circuit Components

Lengthening Inductor (L11L2) lengths applies an even higher Voltage Potential (66/67)
across Resonant Capacitor (140 -170) (ER) since Inductance Reactance "Stores" Energy and, is
expressed by

 

 way of Inductance Pulsing-Core (190) of Figure (3-23) as to VIC Coil Assembly (580) of Figure (6- 1) enters into and passes through both Inductors (LIIL2) simultaneously and offers not only further electron-flow restriction (Rp l/Rp2) to both Inductor Chokes (56/62) but automatically increases voltage potential (xxx V g xxx Vh xxx Vn) of opposite voltage intensity of equal magnitude (66/67) across Resonant Cavity (140 -170) ... overcoming any potential loss of pulse signal due to resistive interaction (Rsl/Rs2) of either or both Inductor Cores (L1/L2) wire-material to the formation of Inductance Fields (FLl!FL2) during reoccurring pulse on-time (T1a xxx T1n). Electron Inhibiting Effect (631) in direct relationship to Voltage Enhancement Effect (528) is accomplished since stainless steel 430F/FR wire-material is "Electromagnetic Inductive" to incoming electromagnetic flux-lines (71a xxx 71n) (Rp) without (s/s) inductor-wire-coil (L1/L2) becoming permanently magnetized ... paralleling and performing the same electromagnetic characteristic of copper wire when it comes to magnetic field reformation (Rp - Rp 1 - Rp2) of Figure (7-8), as further illustrated in electromagnetic coupling fields (71 - 511 - 512) of Figure (6-1) that encourages, brings-on, and perform Voltage Inducement Process (580) of Figure (6-1) as to (620) of Figure (7-1) without amp "influxing" (inhibiting amp flow) between Positive Voltage Potential (66) and Negative Voltage Potential (67) electtically applied across Resonant Cavities (140 -170). In-Line Circuit Components Lengthening Inductor (L11L2) lengths applies an even higher Voltage Potential (66/67) across Resonant Capacitor (140 -170) (ER) since Inductance Reactance "Stores" Energy and, is expressed by (Eq 19)

Where,

(Wa) is the energy in Joules (Watt-seconds); (L) is the Inductance in Henries; and (I) is the current in amperes.

Inductance Reactance directly determines "Stored" Energy (Wa) which is controlled by input Voltage Potential attenuated or varied by way of Voltage Amplitude (Vo xxx Va xxx V b - Vf xxx Vg xxx Vn) of Figure (7-13) and/or Gated Pulse-Frequency (49a xxx 49n - T3 - 49a xxx 49n), or both.

Inductance Reactance performs several functions simultaneously or to given stimuli:

• increases applied voltage amplitude (Vo - Vn),
• doubles input frequency (64a * 64b) when 50% Duty Cycle Pulse (Tl = T2) is inputted,
• effectuates "Step Charging Effect" (680) of Figure (7-7) when Pulse off-time (T2) is less than Pulse on-time (T1)

... determining voltage swing from highest voltage level (Vn) to volts switch-off point (Vff), and establishing Impedance (FL) which minimizes heat loss of electrical input power (49) by impairing electron movement.

Inductor (Ll) acts and performs in like manner to Inductor (L2) since both Inductor (L1/L2) are physically the same size and shape. 

Thermal Explosive Energy-Yield (gtnt) (16a xxx 16n) instantly produced from water (85) is determined by:

• Voltage Amplitude ( xxx Vn)
• Duty Cycle of Pulse Train (T1 - T2a xxx T1 – T2n)
• Gated Pulse-Frequency of applied Voltage Potential (49a xxxx 49n - T3 - 49a xxx 49n)
• Inductor (L1/L2) length
• Secondary Pickup Coil (523) Length (FL3a xxx FL3n)
• dielectric gap-spacing (Cp)
• or any combination thereof.