Did a video because it's hard to explain Dan, hope this helps:

https://www.youtube.com/watch?v=zN7YdzbqJLU&feature=youtu.be

We start off with a carrier wave, we then modulate a square wave imposed on the carrier wave but not at 50% duty cycle, at 33.3% duty cycle.
So far we HAVE NOT used TAU yet.
We then allow the entire signal to be exactly 3 seconds long without clipping it. 3 seconds is 0.333hz which means that the modulating signal is phase related to the entire length of the signal.
All you do is take your carrier wave then square wave modulate it with the same frequency then use a solid state relay to allow the entire signal to be 3 seconds long. The relay will avoid any clipping issues on the carrier and modulations and you can control the relay with a simple on off function so the relay is on for 3 seconds and off for a millisecond. As long as that pattern occurs you will interfere with the spin state of the Electrons in the water.

On the video, everything in the red channel will stay in the choke and everything in the blue channel (modulations and harmonics) will leave the choke. Why? Because the choke can only block AC signals and allow DC to pass. Because the blue modulations and harmonics are above the DC offset then the choke see's them as pure DC and will allow them to pass. BUT...the modulation frequency and the carrier frequency are the SAME so the voltage created by the initial carrier wave can leave as modulation. If anyone can't get their system working after this then I'll pack up, leave the forum and go sailing or something instead.

making another coffee to review this  nice LOL

 We start off with a carrier wave, we then modulate a square wave imposed on the carrier wave but not at 50% duty cycle, at 33.3% duty cycle.  NOTED


So far we HAVE NOT used TAU yet.
We then allow the entire signal to be exactly 3 seconds long without clipping it.

3 seconds is 0.333hz which means that the modulating signal is phase related to the entire length of the signal.

All you do is take your carrier wave then square wave modulate it with the same frequency then use a solid state relay to allow the entire signal to be 3 seconds long.

The relay will avoid any clipping issues on the carrier and modulations and you can control the relay with a simple on off function so the relay is on for 3 seconds and off for a millisecond. 
So a  sharp fast mosfet H Bridge could perform this Gate Function Right?


As long as that pattern occurs you will interfere with the spin state of the Electrons in the water. Noted

Quote from securesupplies on July 5th, 2018, 07:53 AM

We start off with a carrier wave, we then modulate a square wave imposed on the carrier wave but not at 50% duty cycle, at 33.3% duty cycle.  NOTED


So far we HAVE NOT used TAU yet.
We then allow the entire signal to be exactly 3 seconds long without clipping it.

3 seconds is 0.333hz which means that the modulating signal is phase related to the entire length of the signal.

All you do is take your carrier wave then square wave modulate it with the same frequency then use a solid state relay to allow the entire signal to be 3 seconds long.

The relay will avoid any clipping issues on the carrier and modulations and you can control the relay with a simple on off function so the relay is on for 3 seconds and off for a millisecond. 
So a  sharp fast mosfet H Bridge could perform this Gate Function Right?


As long as that pattern occurs you will interfere with the spin state of the Electrons in the water. Noted

Probably but you'd need to watch for clipping.

For anyone wondering what Stan has done here: He's using the 33.3% duty cycle of the square modulation which is superimposed over the carrier and in phase with it, to hijack the leading edge of the carrier sine wave. The choke is blocking AC carrier current but because the current lags the voltage by 90 degrees the modulation holds onto the leading edge voltage field from the sine wave and this is where step charge is born.
The modulations are allowed to pass the choke (because the choke see's them as DC) and their harmonics jump onto the sine wave leading edge which was hijacked because there is absolutely no where else for them to go.