These various embodiments serve to facilitate interlaced amplitude pulsing using a hard-tube type pulse generator having at least one energy-storage unit each comprising at least one energy-storing capacitor. Generally speaking, this comprises controlling an amount of energy withdrawn from the energy-storage unit and provided to an output load to form productive electric pulses by controlling at least one of: (1) energy replenishment; and (2) non-productive energy withdrawal of the energy-storage unit, to thereby achieve a series of productive interlaced amplitude electric pulses.

These various embodiments serve to facilitate interlaced amplitude pulsing using a hard-tube type pulse generator having at least one energy-storage unit each comprising at least one energy-storing capacitor. Generally speaking, this comprises controlling an amount of energy withdrawn from the energy-storage unit and provided to an output load to form productive electric pulses by controlling at least one of: (1) energy replenishment; and (2) non-productive energy withdrawal of the energy-storage unit, to thereby achieve a series of productive interlaced amplitude electric pulses.

Systems and methods for generating pulses are disclosed. The system can include a unipolar vector inversion generator. The unipolar vector inversion generator can include at least two striplines of a conductive material arranged in a planar spiral configuration that maintain a constant gap between layers of the planar spiral configuration. The system can include a bipolar vector inversion generator. The bipolar vector inversion generator can include a first pair of striplines forming a first unipolar vector inversion generator and a second pair of striplines forming a second unipolar vector inversion generator. The first and second unipolar vector inversion generator can be connected together at respective outer ends of the first and second pair of striplines. A fluid dielectric material can fill the constant gap within the vector inversion generator. A casing can encapsulate the vector inversion generator which can include a hermetically sealed chamber encompassing the vector inversion generator.

Systems and methods for generating pulses are disclosed. The system can include a unipolar vector inversion generator. The unipolar vector inversion generator can include at least two striplines of a conductive material arranged in a planar spiral configuration that maintain a constant gap between layers of the planar spiral configuration. The system can include a bipolar vector inversion generator. The bipolar vector inversion generator can include a first pair of striplines forming a first unipolar vector inversion generator and a second pair of striplines forming a second unipolar vector inversion generator. The first and second unipolar vector inversion generator can be connected together at respective outer ends of the first and second pair of striplines. A fluid dielectric material can fill the constant gap within the vector inversion generator. A casing can encapsulate the vector inversion generator which can include a hermetically sealed chamber encompassing the vector inversion generator.