The floating dielectric field facilitates stability as well as synchronicity. It stabilizes this circuit by embodying within itself a greater proportion of the overunity of reactance (aka, a buildup of nodal voltage) which this type of circuit gains over a duration which is shorter than the duration in which it will be thermodynamically lost or spent. This embodiment of stability is best exemplified by the destruction of this type of circuit should this precaution be overlooked. The messy gloop which remains, should self-destruction occur, is indicative of Nature's attempt at creating a dielectric mass with which to belatedly protect this circuit. Alas! If we were to take the initiative to emulate Her example, we could spare ourselves a lot of messy failures!

To accommodate the repercussions of stabilizing this type of circuit with an increased dielectric floating field, it is necessary to compensate this extreme with its opposite condition by reducing the inductive spread between the voltage oriented 'L' main coils and the current oriented 'SC' starter coils by increasing the inductance of SC1 and SC2. If we had reduced this inductive spread by decreasing the inductance of the 'L' coils, then the voltage of this circuit's output would have been reduced along with its power. But if all we wish to do is reduce its overall power by not focusing on reducing its voltage, then increasing its current oriented starter coils, SC1 and SC2, is the way to go.

The 'SC' coils get their name of being starter coils by virtue of their derivation from the starter coils within a single phase, A/C induction motor.