This page was updated on January 29th, 2009.

To obtain optimal results with these circuits, use a 9V or 12V DC adaptor or a regulated power supply.

Warning:  To avoid electrocution, make sure that the power transformer has a split bobbin.


Batteries still work fine with these circuits.
This circuit is one of the simplest Clark Zapper circuits.  There are only 2  resistors, 1 capacitor, an LED and the chip.  This circuit is meant to be  powered by a split-bobbin DC power adaptor, as the frequency output of  the chip is around 11,000 hz.  If you want to use this circuit with a 9V  battery, then change the 5.1k resistor to a 22k resistor, which will give a  frequency output of around 2,500 hz...  optimal for the Clark Zapper's use  with a 9V battery.  You can find this circuit, without my LED modification,  on the internet or in Don Lancaster's CMOS Cookbook.  If you don't need  the LED, then just shunt pin 8 and the negative probe to ground.
The circuit schematic to the above left differs from the circuit in Dr. Hulda  Clark's books in a few ways.  First, there is the lack of the unnecessary stabilizing capacitor from pin 5 to ground.  Second, there is a polarity-reversal protection  light-emitting-diode from pin-8/negative-probe to ground, which, thirdly, eliminates the need of the L.E.D. and its resistor depicted in Dr. Hulda Clark's original schematic.  This configuration of  the L.E.D. alleviates the problem of the L.E.D. being powered by the  output of the circuit (which lowers the overall output voltage of the circuit)  and thereby "raises" the output voltage of the circuit.  To minimize the number of  parts used, the L.E.D. serves a dual-purpose.  It serves to protect against  power supply polarity-reversal damage when used with a battery and it's  also an indicator light.  Pin 4 doesn't need to be connected.
The circuit above is very simple.  The optimized reverse-polarity L.E.D. configuration is  present.  There is the  absence of the stabilizing capacitor from pin 5 to ground, as the output  waveform differs only in timing when the capacitor is present (I doubt that  the pathogens admire the accuracy of the tempo of the positive-offset  waveform when the positive-offset waveform is disintegrating the  pathogens).  There is not a power-supply filter-capacitor to filter out the  60-cycle-hum when using a dc adaptor because the 60-cycle-hum does  not hinder the effect of the Zapper's frequency on the body and, from what I  have seen on the net about multi-frequency Zappers and from what I have  observed when using an oscilloscope program with the Zapper, may even  assist in destroying pathogens.  The Fixed-LED Zapper 3 and the Simple  Zapper 1.1 are the same circuit that merged over time.
 
This is the Transistor Zapper.  I slapped together this version of the Clark  Zapper using common transistor driver stages because I have a lot of  transistors that need to be used.  The operating frequency varies between  approximately 5khz and 10khz.  My body's response to the signal from  this design is somewhat the mirror image of the second oscilloscope  screenshot below with the response being most effective and peaking at  around 6.1khz.
The screenshot above shows my body's response to a variable-frequency  Simple Zapper with an output of approximately 5 volts.  The probe from the  computer, a 1/4-inch phone plug, was placed in my mouth against my  right cheek.  The handholds/probes from the variable-frequency Simple  Zapper are 1" in diameter and 1.5" in length.  As you can see, frequencies  above approximately 18,000 hz do not affect the inside of my mouth as  much as frequencies between 4,400 hz and 18,000 hz.  By analyzing the  FFT graph that only measures frequencies up to approximately 22,000 hz,  one can deduce that frequencies around 30,000 hz are not optimal  frequencies at which the Zapper should be set.  I am in favor of the  frequencies around 15,750 hz because these frequencies appear to be  consistently effective even when my body chemistry changed because my  stress problems that I've had for over ten years "disappeared".

Note:  These results were obtained using a variable Clark Zapper, powered  by a 12V DC adaptor.  The signal amplitude when using Clark Zapper set  at ~15,000 hz and powered by a 12V DC adaptor is far greater than when  using the Clark Zapper powered by a 9V battery.   When using a 9V  battery with the Clark Zapper, the optimal frequency is approximately 2.5  Khz, the frequency option of several commercially-available Clark Zappers.   I've personally confirmed the validity of the claim of some commercial  Clark Zapper-producing companies that 2.5 Khz is a more effective Clark  Zapper frequency than 30 Khz, the Clark Zapper's original frequency,  through the use of the techniques described above.  Again, though, a  ~15,000 hz Clark Zapper powered by a 12V DC adaptor is much more  effective than a 2.5 Khz Clark Zapper powered by a 9V battery.
The screenshot above shows my body's response to the "Magic Bullet  Zapper", powered by a 9V DC adaptor.  This time, I placed the  oscilloscope probe (a 1/4-inch phone plug) in the sweaty crook of my knee  :).  I'm glad that I purchased so many 5.1k resistors (over 500), because  they set the output of the "Magic Bullet Zapper" at around 11,000 hz,  which is right at the tip of the amplitude curve of the screenshot above.
The circuits above are the Yin-Yang Clark Zapper Variant and the Chaos  Clark Zapper Variant.  In 1991, in Edmonds, Washington, I had been  experimenting with Craig Anderton's Tube Sound Fuzz circuit for guitar.   From books and examining guitar pedals, I knew that many guitar pedals  use a supplementary diode configuration, and so I used the diode  configuration with the CD4049 Hex Inverter.  Around a year ago, I learned  of Chua's Chaos Generator, which is not really a Chaos Generator, but  close, more like a yin-yang generator, like the circuit to the above left.   The circuit to the above right is my true Chaos Generator.  The  asymmetrical diode configuration is a fragment of a circuit in an  Electronics Now magazine featured circuit from the 90's and the rest of the  circuit is from Don Lancaster's CMOS Cookbook, Dr. Hulda Clark's book "The Cure for All Diseases" and an L.E.D. mod that I added, just in case  someone doesn't use a split-bobbin with these circuits.
This circuit filters out most of the 60-hz hum when using a DC adaptor with  the Clark Zapper Variants.  This circuit doesn't need to be used with Clark  Zapper Variants powered by 9V batteries.
There are several items of interest that seem to be recurring in pop culture that I can see:

Ethanol replacing isopropyl alcohol in beauty and hygiene products...
Ethanol as a viable potential replacement for gasoline...
Herbal entheogenic beer...
Mexico being the next Asia in terms of manufacturing...
Pre-fabricated homes that cost as much as a car...
The Anti-Parasite Pill that has yet to be manufactured by the pharmaceutical industry...
Socialized Medical programs for the U.S.
Lack of Acidosis and Alkalosis (pH balance) knowledge by the general public...  (Dr. Morter)
Lack of the knowledge that the Hulda Clark Zapper is a Class II medical device in Canada...
Taxicab vans...
DNA (human genome) identification to end the conflict between the Israelis and Palestinians...
Garbage dump recycling...
Sewage recycling (for methane and to extract viable chemicals)...
More local broadcasted TV channels for stronger communities...

This page was "lovingly" created by Mas K. in the month of September in the year 2001.
e-mail: mas1911@aol.com

This page is dedicated to my old nanny, Toshiko Komatsubara, whereever she may be.

Oh, by the way, check out C6, Q1, as well as the Mabus and King of Terror quatrains.

Long Live Dr. Hulda Clark & The Dalai Lama!

I've read that the Tibetans say that "Religion is sound..."

Clark Zapper Variants Parts List
http://www.members.tripod.com/~mas1911/partslist.html

Clark Zapper Variants Info Page
http://www.members.tripod.com/~mas1911/Zapper_Variants.html


Please visit my mom's webpage:
https://mas1911.tripod.com/nako


"Keep on digging, Watson..."