![]() These signal sets have been found highly effective by this experimenter over the years, but using hard to get very expensive machines this instrument one can build oneself and thus the amateur scientist is not limited by cost or other difficulties in getting equpment to do these experiments. This technique combines the zapper monopoarity principle discovered by Hultda Clark, with the signal sets widely available online such as at this url an similar signal sets, often called "Rife" type signals although they are limited to "audio" frequencies, as are most commercial "Rife" machines. The author has found this instrument useful for converting the frequencies such as the balancing-stimulating frequencies found at and exploring the results in oneself. This instrument is for use at pulsed frequencies of 0.01 Hz up to about 20 KHz, in the externally programmable mode and it also generates a standard Clark 30 KHz zapper signal frequency in its other stand-alone mode. ![]() It does not generate radio frequency signals, unlike some of those described on the Rife page on this wiki. So the Audio-Programmed Zapper combines all these functions into a low cost, even potentially a build-it-yourself instrument, enabling new kinds of experiments seeking new ways of wellbeing. (For a single frequency zapper, best-average, she chose the frequency area 20-40 KHz, centered at 30 KHz.) That also includes the generally much lower frequencies that electroherbalism explores, generally 0.01 Hz to 10,000 Hz. And third, this instrument converts those electroherbalism signal frequencies into the zapper waveform, Dr Clark said in her TCFAD book, that zapping can be done at any frequency, 10 Hz up to 700 KHz, the range of the biofrequencies she had measured, If I recall correctly. So the amateur scientist can see for him/herself what works and does what for themselves or their pets. The recorded waveform, or directly utilized waveform, is a square wave, whose edges enables the APZ instrument to reconstruct the exact frequency of the pulses even if far below the normal audio recorder's ability to record or play back, such as at 10 Hz. These signals are often in large sets, sometiems dozens of frequencies so this instrument enables the researcher to record those frequencies as audio recordings, spanning the chosen application time for each - typically three minutes each - and these recordings can be played back later to exactly repeat the experimental signal set, even if an hour or more long. Second, it has another mode, using the same output features of the basic zapper, which enables the instrument to deliver the electroherbalism frequencies available on the net, gathered from hobbyiest researchers around the world during the past half century. It does that with added features of its handhold output signal is fairly independent on the load in the handhold circuit, and also it has a LED that has a brightness that is proportional to the handholdhold physiological circuit, so it gives a constant qualitative evaluation of the continuity of the handhold circuit, including the conductivity of the wet-paper covered handholds connection with the skin. The basis for this experimental instrument is, first, it provides the basic zapper 30 KHz pulsed-DC function, as discovered by Hulda Clark long ago. The instrument being described here is intended for scientific use, including by the hobby-level individual experimenter seeking knowledge about the world within and without to learn a bit more about reality, and usually on subjects considered potentially beneficial to the researching experimenter, as part of that satisfying of curiosity about the true nature of reality. ![]() 3.6 Database for experiments utilizing the Audio Programmed Zapper.3.5 Creation of recorded control signal series.3.4.1 The handhold current-indicating LED.3.4 Inputs and outputs sources and loads.3.3 Operation of the Audio Programmed Zapper instrument.3.2.3 The output signal handhold circuit driver and handhold current-indicating LED.3.2.2 The internal waveform processor that takes external audio format input signals and converts them to reconstructed digital format. ![]()
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |