The Zero Point
After frame by frame analysis of video taped operation of a CSET, I can see that the spark gap fires about three times per second. This is consistent with the estimated pulse rate of one of the old vibrator tubes of around 100 per second, which powers the transformer. This, of course, doesn't equate to the interrupter rate of 6,000 per second. So it's my opinion that both of these frequencies were present in the arc, when it formed. If so, this could account for the excess energy.
When two waves of two different frequencies travel through a medium, there will be times when the faster changing wave overtakes the slower wave. When this happens, electrical forces between nearby nodes and anti nodes produce a gradient which polarizes momentarily appearing quantum potentials. These potentials, when they appear, produce a stress in the curvature of space. Likewise, when the potentials almost immediately recombine, the underlying space time metric is relaxed. In fact, it's high frequency vibrations of this metric which cause the potentials to spontaneously appear, when they do. The amount of energy which can spontaneously appear in this fashion is inversely proportional to the size of the volume's wavelength, with an infinite amount of Energy potentially appearing in a Point which has the dimensionality of Zero.
Gradients arising from inter nodal forces between adjacent waves polarize these quantum fluctuations so that dipoles appear, oriented in the direction the waves are traveling. As the higher frequency (or higher voltage) wave starts to pull away from the other, these dipoles are stretched. When this charge separation reaches a certain distance, it's no longer statistically probable that the quantum charges will recombine. This produces an electrical force on one end of the dipole and an anti-magnetic force on the other end. This results in an increased voltage across the medium and a cancellation of magnetic heat in the nearby environment. Or the wires ice up, if all forces stay within a circuit.
This twin frequency is also shown in Pat. #3890548, Fig. 1, as 21a and 22a. These are the pulses which are sent through the magnetically associated motor harness coils. (The delay lines) The interaction of these different frequencies is probably what caused the buzzing sound witnesses reported coming from the motor.
With my diode T-Tap, the transformer and the arc make a loud buzzing sound, since the frequency of the diode tap is a lot higher than that of the transformer's supply. This might account for what seems to me to be a considerably greater amount of energy in the sparks flying around rapidly in my CSET, compared to the normal sparks I can get with just the transformer. If this is the case, then I should be able to charge a capacitor a lot faster with the CSET than with the transformer. Provided the diode is oriented correctly. (Cathode pointing towards the negative pole of the battery.)
After frame by frame analysis of video taped operation of a CSET, I can see that the spark gap fires about three times per second. This is consistent with the estimated pulse rate of one of the old vibrator tubes of around 100 per second, which powers the transformer. This, of course, doesn't equate to the interrupter rate of 6,000 per second. So it's my opinion that both of these frequencies were present in the arc, when it formed. If so, this could account for the excess energy.
When two waves of two different frequencies travel through a medium, there will be times when the faster changing wave overtakes the slower wave. When this happens, electrical forces between nearby nodes and anti nodes produce a gradient which polarizes momentarily appearing quantum potentials. These potentials, when they appear, produce a stress in the curvature of space. Likewise, when the potentials almost immediately recombine, the underlying space time metric is relaxed. In fact, it's high frequency vibrations of this metric which cause the potentials to spontaneously appear, when they do. The amount of energy which can spontaneously appear in this fashion is inversely proportional to the size of the volume's wavelength, with an infinite amount of Energy potentially appearing in a Point which has the dimensionality of Zero.
Gradients arising from inter nodal forces between adjacent waves polarize these quantum fluctuations so that dipoles appear, oriented in the direction the waves are traveling. As the higher frequency (or higher voltage) wave starts to pull away from the other, these dipoles are stretched. When this charge separation reaches a certain distance, it's no longer statistically probable that the quantum charges will recombine. This produces an electrical force on one end of the dipole and an anti-magnetic force on the other end. This results in an increased voltage across the medium and a cancellation of magnetic heat in the nearby environment. Or the wires ice up, if all forces stay within a circuit.
This twin frequency is also shown in Pat. #3890548, Fig. 1, as 21a and 22a. These are the pulses which are sent through the magnetically associated motor harness coils. (The delay lines) The interaction of these different frequencies is probably what caused the buzzing sound witnesses reported coming from the motor.
With my diode T-Tap, the transformer and the arc make a loud buzzing sound, since the frequency of the diode tap is a lot higher than that of the transformer's supply. This might account for what seems to me to be a considerably greater amount of energy in the sparks flying around rapidly in my CSET, compared to the normal sparks I can get with just the transformer. If this is the case, then I should be able to charge a capacitor a lot faster with the CSET than with the transformer. Provided the diode is oriented correctly. (Cathode pointing towards the negative pole of the battery.)
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