kosst,
I am saying that I know the means by which harmonic distortion is actually generated by the nonlinearity.
At any point along the [sign wave] that the gain is increased or decreased you have essentially speeded up or slowed down that segment of the sign wave which makes it appear as a higher or lower frequency. This is the only way that 2khz energy can exit a circuit fed by 1khz.
What I'm saying is the actual means for producing the harmonics is directly caused by the damaging effect the a nonlinear event has on a pure 1khz tone. We are on the same page but I can go further and describe the chain of events that ends up with the harmonics.
I have studied a kind of slow motion observation of those events in order to place a trap that is triggered by the very first sign that it has come upon a non linear obstacle You can nip it in the bud if you know how to detect that it is starting to distort. The very first thing to go is the phase of the pure tone - this is the birth of a harmonic. My circuit can spot this at such an early point that it can be stopped before it even has left the fundamental frequency of 1khz. The detector can spot a shift in phase of micro-degrees and apply a phase countermeasure that prevents it from continuing shift in phase and ultimately in frequency (as monitored on the spectrum as 2khz)
A non linear amplifier produces harmonics by literally manipulating the phase and frequency of the input signal. Period.
If you can stop the manipulation from happening - you have stopped it from distorting. As long as the detector can monitor the phase of the fundamental and apply a countermeasure to prevent it from going any further - it now has no means of distorting.
Classic negative feedback is supposed to do the same thing but it can't.
It relies on monitoring the instantaneous voltage at the output and compares a reduced version back to the input (typically a differential pair). This method is monitoring the voltage along the vertical axis. Because of this configuration - vital information is lagging do to the fact that damaging events have already occurred by the time you notice a change in voltage.
Harmonic distortion is caused by nonlinearity in the gain devices. Period.I agree 100% - we know it is caused by nonlinearity I'm not disputing that.
I am saying that I know the means by which harmonic distortion is actually generated by the nonlinearity.
At any point along the [sign wave] that the gain is increased or decreased you have essentially speeded up or slowed down that segment of the sign wave which makes it appear as a higher or lower frequency. This is the only way that 2khz energy can exit a circuit fed by 1khz.
What I'm saying is the actual means for producing the harmonics is directly caused by the damaging effect the a nonlinear event has on a pure 1khz tone. We are on the same page but I can go further and describe the chain of events that ends up with the harmonics.
I have studied a kind of slow motion observation of those events in order to place a trap that is triggered by the very first sign that it has come upon a non linear obstacle You can nip it in the bud if you know how to detect that it is starting to distort. The very first thing to go is the phase of the pure tone - this is the birth of a harmonic. My circuit can spot this at such an early point that it can be stopped before it even has left the fundamental frequency of 1khz. The detector can spot a shift in phase of micro-degrees and apply a phase countermeasure that prevents it from continuing shift in phase and ultimately in frequency (as monitored on the spectrum as 2khz)
A non linear amplifier produces harmonics by literally manipulating the phase and frequency of the input signal. Period.
If you can stop the manipulation from happening - you have stopped it from distorting. As long as the detector can monitor the phase of the fundamental and apply a countermeasure to prevent it from going any further - it now has no means of distorting.
Classic negative feedback is supposed to do the same thing but it can't.
It relies on monitoring the instantaneous voltage at the output and compares a reduced version back to the input (typically a differential pair). This method is monitoring the voltage along the vertical axis. Because of this configuration - vital information is lagging do to the fact that damaging events have already occurred by the time you notice a change in voltage.