Tag Archives: Electrophotonics
Analysis of Stimulated Electrophotonic Glow of Liquids
Korotkov, K, Orlov, D
Department of Computer Science, St. Petersburg Federal University “ITMO”, St. Petersburg, Kronverski prospect 49, 197101
Key words: electrophotonics, photons, structured water, water energy, GDV, water quality, memory of water
OPPORTUNITIES OF GAS DISCHARGE VISUALIZATION TECHNIQUE IN THE ESTIMATION OF FUNCTIONAL STATE OF THE ORGANISM IN PE-RIOPERATIVE PERIOD
Egor U. STRUKOV
ABSTRACT of thesis for the degree of Ph. D. in Medical Science
St. Petersburg 2003
Overall estimation of functional state and internal environment of the organism is very important for the treatment of patients with serious and especially acute pathogenic processes, apart from the identification of nature and character of the latter. This diagnostic approach determines the scope and effectiveness of the performed intensive therapy (B.S. Uvarov, N.A. Mezheryakov, 1974).
Diagnosis and monitoring of the human energy-informational state and analysis of subtle energies, applying Gas Discharge Visualization technique, based on the Kirlian method.
Saint-Petersburg Technical University SPIFMO, Russia
1. Boyers D.G. Tiller W.A. Corona Discharge Photography. J of Applied Physics, 1973, 44, 3102-3112.
2. Pehek J.O., Kyler K.J., and Faust D.L. Image modulation in Corona Discharge Photography. Science 1976, 194, 263-270.
3. Opalinski J. Kirlian-type images and the transport of thin-film materials in high-voltage corona discharge. J. of Applied Physics 1979, 50, 498-504.
Konikiewicz L.W., Griff L.C. Bioelectrography – A new method for detecting cancer and body physiology. Harrisburg: Leonard Associates Press, 1982. 240 p.
Tiller W. On the evolution of Electrodermal Diagnostic Instruments. The Journal of Advancement in Medicine 1:41-72, 1988.
Mandel P. Energy Emission Analysis; New Application of Kirlian Photography for Holistic Medicine. Synthesis Publishing Co., Germany. 1986.
EPC/GDV CAMERA by Dr. Korotkov
The EPC system has been approved by Russian Health Authorities for general use, following clinical trials and the recommendation of the Russian Academy of Sciences. It utilizes almost instantaneous, non-invasive and painless measurements and sophisticated interpretive software with comparisons to an extremely large and reliable database assembled over more than 10 years. This technology has far reaching diagnostic and human performance applications.
What does the EPC method measure in physical terms?
The EPC method is based on the stimulation of photon and electron emissions from the surface of the object whilst transmitting short electrical pulses. In other words, when the object is placed in an electromagnetic field, it is primarily electrons, and to a certain degree photons, which are ‘extracted’ from the surface of the object. This process is called ‘photo-electron emissions’ and it has been quite well studied with physical electronic methods. The emitted particles accelerate in the electromagnetic field, generating electronic avalanches on the surface of the dielectric (glass). This process is called ‘sliding gas discharge’. The discharge causes glow due to the excitement of molecules in the surrounding gas, and this glow is what is being measured by the EPC method. Therefore, voltage pulses stimulate optoelectronic emission whilst intensifying this emission in the gas discharge, owing to the electric field created.
Konstantin G. Korotkov, Ph.D., Professor
Konstantin Korotkov has the following positions:
• Deputy Director of Saint-Petersburg Federal Research Institute of Physical Culture.
• Professor of Computer Science and Biophysics at Saint-Petersburg Federal University of Informational Technologies, Mechanics and Optics.
• Professor of Research in Saint Petersburg Academy of Physical Culture.
• President of the International Union for Medical and Applied Bioelectrography.
• Consultant for Aveda Co (USA).
• Member of the Editorial Board: «Journal of Alternative and Complementary Medicine», “Journal of Science of Healing Outcomes”.